Small Animal Internal Medicine, 5th Edition (Vetbooks.ir) .pdf - PDFCOFFEE.COM (2024)

Contents PART ONE  CARDIOVASCULAR SYSTEM DISORDERS, 1

PART THREE  DIGESTIVE SYSTEM DISORDERS, 367

Wendy A. Ware

1 Clinical Manifestations of Cardiac Disease, 1 2 Diagnostic Tests for the Cardiovascular System, 13 3 Management of Heart Failure, 53 4 Cardiac Arrhythmias and Antiarrhythmic Therapy, 74 5 Congenital Cardiac Disease, 96 6 Acquired Valvular and Endocardial Disease, 115 7 Myocardial Diseases of the Dog, 130 8 Myocardial Diseases of the Cat, 145 9 Pericardial Disease and Cardiac Tumors, 159 10 Heartworm Disease, 173 11 Systemic Arterial Hypertension, 190 12 Thromboembolic Disease, 199

PART TWO  RESPIRATORY SYSTEM DISORDERS, 217 Eleanor C. Hawkins 13 Clinical Manifestations of Nasal Disease, 217 14 Diagnostic Tests for the Nasal Cavity and Paranasal Sinuses, 224 15 Disorders of the Nasal Cavity, 234 16 Clinical Manifestations of Laryngeal and Pharyngeal Disease, 247 17 Diagnostic Tests for the Larynx and Pharynx, 249 18 Disorders of the Larynx and Pharynx, 253 19 Clinical Manifestations of Lower Respiratory Tract Disorders, 258 20 Diagnostic Tests for the Lower Respiratory Tract, 263 21 Disorders of the Trachea and Bronchi, 297 22 Disorders of the Pulmonary Parenchyma and Vasculature, 316 23 Clinical Manifestations of the Pleural Cavity and Mediastinal Disease, 337 24 Diagnostic Tests for the Pleural Cavity and Mediastinum, 343 25 Disorders of the Pleural Cavity, 349 26 Emergency Management of Respiratory Distress, 356 27 Ancillary Therapy: Oxygen Supplementation and Ventilation, 361

Michael D. Willard 28 Clinical Manifestations of Gastrointestinal Disorders, 367 29 Diagnostic Tests for the Alimentary Tract, 390 30 General Therapeutic Principles, 410 31 Disorders of the Oral Cavity, Pharynx, and Esophagus, 428 32 Disorders of the Stomach, 442 33 Disorders of the Intestinal Tract, 455 34 Disorders of the Peritoneum, 492

PART FOUR  HEPATOBILIARY AND EXOCRINE PANCREATIC DISORDERS, 501 Penny J. Watson 35 Clinical Manifestations of Hepatobiliary Disease, 501 36 Diagnostic Tests for the Hepatobiliary System, 512 37 Hepatobiliary Diseases in the Cat, 536 38 Hepatobiliary Diseases in the Dog, 559 39 Treatment of Complications of Hepatic Disease and Failure, 588 40 The Exocrine Pancreas, 598

PART FIVE  URINARY TRACT DISORDERS, 629 Stephen P. DiBartola and Jodi L. Westropp

41 42 43 44 45 46 47

Clinical Manifestations of Urinary Disorders, 629 Diagnostic Tests for the Urinary System, 638 Glomerular Disease, 653 Acute and Chronic Renal Failure, 663 Canine and Feline Urinary Tract Infections, 680 Canine and Feline Urolithiasis, 687 Obstructive and Nonobstructive Feline Idiopathic Cystitis, 698 48 Disorders of Micturition, 704

PART SIX  ENDOCRINE DISORDERS, 713 Richard W. Nelson 49 Disorders of the Hypothalamus and Pituitary Gland, 713

50 51 52 53

Disorders of the Parathyroid Gland, 731 Disorders of the Thyroid Gland, 740 Disorders of the Endocrine Pancreas, 777 Disorders of the Adrenal Gland, 824

PART SEVEN  METABOLIC AND ELECTROLYTE DISORDERS, 863 Richard W. Nelson and Sean J. Delaney 54 Disorders of Metabolism, 863 55 Electrolyte Imbalances, 877

PART ELEVEN  ONCOLOGY, 1126 C. Guillermo Couto

72 73 74 75 76 77 78 79

Cytology, 1126 Principles of Cancer Treatment, 1134 Practical Chemotherapy, 1138 Complications of Cancer Chemotherapy, 1144 Approach to the Patient with a Mass, 1154 Lymphoma, 1160 Leukemias, 1175 Selected Neoplasms in Dogs and Cats, 1186

PART TWELVE  HEMATOLOGY, 1201 C. Guillermo Couto

PART EIGHT  REPRODUCTIVE SYSTEM DISORDERS, 897 Autumn P. Davidson

56 57 58 59

The Practice of Theriogenology, 897 Clinical Conditions of the Bitch and Queen, 915 Clinical Conditions of the Dog and Tom, 944 Female and Male Infertility and Subfertility, 951

PART NINE  NEUROMUSCULAR DISORDERS, 966 Susan M. Taylor 60 Lesion Localization and the Neurologic Examination, 966 61 Diagnostic Tests for the Neuromuscular System, 990 62 Intracranial Disorders, 1000 63 Loss of Vision and Pupillary Abnormalities, 1008 64 Seizures and Other Paroxysmal Events, 1016 65 Head Tilt, 1028 66 Encephalitis, Myelitis, and Meningitis, 1036 67 Disorders of the Spinal Cord, 1048 68 Disorders of Peripheral Nerves and the Neuromuscular Junction, 1074 69 Disorders of Muscle, 1090

80 Anemia, 1201 81 Clinical Pathology in Greyhounds and Other Sighthounds, 1220 82 Erythrocytosis, 1227 83 Leukopenia and Leukocytosis, 1230 84 Combined Cytopenias and Leukoerythroblastosis, 1239 85 Disorders of Hemostasis, 1245 86 Lymphadenopathy and Splenomegaly, 1264 87 Hyperproteinemia, 1276 88 Fever of Undetermined Origin, 1279

PART THIRTEEN  INFECTIOUS DISEASES, 1283 Michael R. Lappin

89 90 91 92 93 94 95 96 97

Laboratory Diagnosis of Infectious Diseases, 1283 Practical Antimicrobial Chemotherapy, 1293 Prevention of Infectious Diseases, 1305 Polysystemic Bacterial Diseases, 1315 Polysystemic Rickettsial Diseases, 1326 Polysystemic Viral Diseases, 1341 Polysystemic Mycotic Infections, 1356 Polysystemic Protozoal Infections, 1367 Zoonoses, 1384

PART FOURTEEN  IMMUNE-MEDIATED DISORDERS, 1398 J. Catharine R. Scott-Moncrieff

PART TEN  JOINT DISORDERS, 1103 Susan M. Taylor and J. Catharine R. Scott-Moncrieff 70 Clinical Manifestations of and Diagnostic Tests for Joint Disorders, 1103 71 Disorders of the Joints, 1111

98 Pathogenesis of Immune-Mediated Disorders, 1398 99 Diagnostic Testing for Immune-Mediated Disease, 1402 100â•… Treatment of Primary Immune-Mediated Diseases, 1407 101 Common Immune-Mediated Diseases, 1417

SMALL ANIMAL INTERNAL MEDICINE

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SMALL ANIMAL INTERNAL MEDICINE FIFTH EDITION

Richard W. Nelson, DVM, DACVIM (Internal Medicine) Professor and Department Chair Department of Medicine and Epidemiology School of Veterinary Medicine University of California, Davis Davis, California

C. Guillermo Couto, DVM, DACVIM (Internal Medicine and Oncology) Couto Veterinary Consultants Columbus, Ohio Vetoclock Zaragoza, Spain

3251 Riverport Lane St. Louis, Missouri 63043

SMALL ANIMAL INTERNAL MEDICINE, FIFTH EDITION Copyright © 2014 by Mosby, an imprint of Elsevier Inc. Copyright © 2009, 2003, 1998, 1992 by Mosby, Inc., an affiliate of Elsevier Inc.

ISBN: 978-0-323-08682-0

All rights reserved. No part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying, recording, or any information storage and retrieval system, without permission in writing from the publisher. Details on how to seek permission, further information about the Publisher’s permissions policies and our arrangements with organizations such as the Copyright Clearance Center and the Copyright Licensing Agency, can be found at our website: www.elsevier.com/permissions. This book and the individual contributions contained in it are protected under copyright by the Publisher (other than as may be noted herein).

Notices Knowledge and best practice in this field are constantly changing. As new research and experience broaden our understanding, changes in research methods, professional practices, or medical treatment may become necessary. Practitioners and researchers must always rely on their own experience and knowledge in evaluating and using any information, methods, compounds, or experiments described herein. In using such information or methods they should be mindful of their own safety and the safety of others, including parties for whom they have a professional responsibility. With respect to any drug or pharmaceutical products identified, readers are advised to check the most current information provided (i) on procedures featured or (ii) by the manufacturer of each product to be administered, to verify the recommended dose or formula, the method and duration of administration, and contraindications. It is the responsibility of practitioners, relying on their own experience and knowledge of their patients, to make diagnoses, to determine dosages and the best treatment for each individual patient, and to take all appropriate safety precautions. To the fullest extent of the law, neither the Publisher nor the authors, contributors, or editors assume any liability for any injury and/or damage to persons or property as a matter of products liability, negligence or otherwise, or from any use or operation of any methods, products, instructions, or ideas contained in the material herein. Library of Congress Cataloging-in-Publication Data Small animal internal medicine / [edited by] Richard W. Nelson, C. Guillermo Couto.—Fifth edition. â•…â•… p. ; cm. â•… Includes bibliographical references and index. â•… ISBN 978-0-323-08682-0 (hardcover : alk. paper)â•… 1.╇ Dogs—Diseases.â•… 2.╇ Cats—Diseases.â•… 3.╇ Veterinary internal medicine.â•… I.╇ Nelson, Richard W. (Richard William), 1953- editor of compilation.â•… II.╇ Couto, C. Guillermo, editor of compilation. â•… [DNLM:â•… 1.╇ Cat Diseases.â•… 2.╇ Dog Diseases.â•… 3.╇ Veterinary Medicine—methods.â•… SF 991] â•… SF991.S5917 2014 â•… 636.089′6—dc23 2013031891

Vice President and Publisher: Linda Duncan Content Strategy Director: Penny Rudolph Content Development Specialist: Brandi Graham Publishing Services Manager: Catherine Jackson Project Manager: Rhoda Bontrager Design Direction: Ashley Eberts

Printed in Canada Last digit is the print number:â•… 9â•… 8â•… 7â•… 6â•… 5â•… 4â•… 3â•… 2â•… 1â•…

Section Editors Richard W. Nelson, DVM, DACVIM (Internal Medicine), Professor and Department Chair, Department of Medicine and Epidemiology, School of Veterinary Medicine, University of California, Davis. Dr. Nelson’s interest lies in clinical endocrinology, with a special emphasis on disorders of the endocrine pancreas, thyroid gland, and adrenal gland. Dr. Nelson has authored numerous scientific publications and book chapters, has co-authored two textbooks, Canine and Feline Endocrinology and Reproduction with Dr. Ed Feldman and Small Animal Internal Medicine with Dr. Guillermo Couto, and has lectured extensively nationally and internationally. He was an associate editor for the Journal of Veterinary Internal Medicine and serves as a reviewer for several veterinary journals. Dr. Nelson is a co-founder and member of the Society for Comparative Endocrinology and a member of the European Society of Veterinary Endocrinology. Dr. Nelson has received the Norden Distinguished Teaching Award, the BSAVA Bourgelat Award, and the ACVIM Robert W. Kirk Award for Professional Excellence.

C. Guillermo Couto, DVM, DACVIM (Internal Medicine and Oncology), Couto Veterinary Consultants, Columbus, Ohio; Vetoclock, Zaragoza, Spain. Dr. Couto earned his doctorate at Buenos Aires University, Argentina. He has been editor-in-chief of the Journal of Veterinary Internal Medicine and President of the Veterinary Cancer Society. He has received the Norden Distinguished Teaching Award; the OSU Clinical Teaching Award; the BSAVA Bourgelat Award for outstanding contribution to small animal practice; the OTS Service Award; the Legend of Small Animal Internal Medicine Award, Kansas State University, Department of Veterinary Clinical Sciences; the Faculty Achievement Award, American Association of Veterinary Clinicians; and the Class of 2013 Teaching Award, The Ohio State University College of Veterinary Medicine. Dr. Couto has published more than 350 articles and chapters in the areas of oncology, hematology, and immunology.

Autumn P. Davidson, DVM, MS, DACVIM, Clinical Professor, Department of Medicine and Epidemiology, School of Veterinary Medicine, University of California, Davis. Dr. Davidson obtained her BS and MS at the University of California, Berkeley, with an emphasis in wildlife ecology and management. Dr. Davidson is a graduate of the School of Veterinary Medicine, University of California, Davis. She completed an internship in small animal medicine and surgery at Texas A&M University, and a residency in small animal internal medicine at the University of California, Davis. She became board certified in internal medicine in 1992. Dr. Davidson is a clinical professor at the School of Veterinary Medicine, University of California, Davis, in the Department of Medicine and Epidemiology. She specializes in small animal reproduction and infectious disease. Additionally, Dr. Davidson practices at Pet Care Veterinary Hospital in Santa Rosa, a private referral practice, where she receives both internal medicine and

reproduction cases. From 1998 to 2003, Dr. Davidson served as the Director of the San Rafael veterinary clinic at Guide Dogs for the Blind, Inc., overseeing the health care of 1000 puppies whelped annually, as well as a breeding colony of 350 and approximately 400 dogs in training. Dr. Davidson served on the board of directors for the Society for Theriogenology from 1996 to 1999 and the Institute for Genetic Disease Control from 1990 to 2002. Dr. Davidson consults with the Smithsonian Institution National Zoological Park in Washington, D.C., concerning theriogenology and internal medicine. She has authored numerous scientific publications and book chapters and is a well-known international speaker on the topics of small animal theriogenology and infectious disease. She has traveled the world working with cheetahs, ring-tailed lemurs, and giant pandas in the field. Dr. Davidson was the 2003 recipient of the Hill’s Animal Welfare and Humane Ethics Award, which recognizes an individual who has advanced animal welfare through extraordinary service or by furthering humane principles, education, and understanding.

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Section Editors

Stephen P. DiBartola, DVM, DACVIM (Internal Medicine), Professor of Medicine and Associate Dean for Academic Affairs, Department of Veterinary Clinical Sciences, The Ohio State University, Columbus, Ohio. Dr. DiBartola received his DVM degree from the University of California, Davis, in 1976. He completed an internship in small animal medicine and surgery at Cornell University in Ithaca, New York, in June 1977 and a residency in small animal medicine at The Ohio State University College of Veterinary Medicine from July 1977 to July 1979. He served as Assistant Professor of Medicine at the College of Veterinary Medicine, University of Illinois, from July 1979 until August 1981. In August 1981, he returned to the Department of Veterinary Clinical Sciences at The Ohio State University as Assistant Professor of Medicine. He was promoted to Associate Professor in 1985 and to Professor in 1990. He received the Norden Distinguished Teaching Award in 1988 and completed a textbook titled Fluid Therapy in Small Animal Practice, first published by W.B. Saunders Co. in 1992. The fourth edition of this book was published in 2011. Dr. DiBartola currently serves as co-editor-in-chief for the Journal of Veterinary Internal Medicine. His clinical areas of interest include diseases of the kidney and fluid, acid-base, and electrolyte disturbances.

Eleanor C. Hawkins, DVM, DACVIM (Internal Medicine), Professor, Department of Clinical Sciences, North Carolina State University College of Veterinary Medicine. Dr. Hawkins has served as President and as Chair of the American College of Veterinary Internal Medicine (ACVIM) and as President of the Specialty of Small Animal Internal Medicine (ACVIM). She has been a board member of the Comparative Respiratory Society and has been an invited lecturer in the United States, Europe, South America, and Japan. Dr. Hawkins is the author of many refereed publications and scientific proceedings and a contributor or the respiratory editor for numerous wellknown veterinary texts. Her areas of research include canine chronic bronchitis, pulmonary function testing, and bronchoalveolar lavage as a diagnostic tool.

Michael R. Lappin, DVM, PhD, DACVIM (Internal Medicine), Kenneth W. Smith Professor of Small Animal Clinical Veterinary Medicine, College of Veterinary Medicine and Biomedical Sciences, Colorado State University; Director of the Center for Companion Animal Studies. After earning his DVM at Oklahoma State University in 1981, Dr. Lappin completed a small animal internal medicine residency and earned his doctorate in parasitology at the University of Georgia. Dr. Lappin has studied feline infectious diseases and has authored more than 250 research papers and book chapters. Dr. Lappin is past associate editor for the Journal of Veterinary Internal Medicine and serves on the editorial board of Journal of Feline Medicine and Surgery. Dr. Lappin has received the Norden Distinguished Teaching Award, the Winn Feline Foundation Excellence in Feline Research Award, and the ESFM International Award for Outstanding Contribution to Feline Medicine.

J. Catharine R. Scott-Moncrieff, MA, VetMB, MS, DACVIM (SA), DECVIM (CA), Professor, Department of Veterinary Clinical Sciences, School of Veterinary Medicine, Purdue University. Dr. Scott-Moncrieff graduated from the University of Cambridge in 1985 and completed an internship in small animal medicine and surgery at the University of Saskatchewan and a residency in internal medicine at Purdue University. In 1989 she joined the faculty of Purdue University, where she is currently Professor of small animal internal medicine and Director of International Programs. Her clinical and research interests include immune-mediated hematologic disorders and clinical endocrinology. She is the author of numerous manuscripts and book chapters and has lectured extensively nationally and internationally.

Susan M. Taylor, DVM, DACVIM (Internal Medicine), Professor of Small Animal Medicine, Department of Small Animal Clinical Sciences, Western College of Veterinary Medicine, University of Saskatchewan. Dr. Taylor has received several awards for teaching excellence and has authored numerous manuscripts and book chapters and one textbook. She has presented research and continuing education lectures throughout Canada, the United States, and abroad. Clinical, academic, and research interests include neurology, neuromuscular disease, clinical immunology, and infectious disease. Dr. Taylor has an active research program investigating medical and neurologic disorders affecting canine athletes, particularly the inherited syndromes of dynamin-associated exercise-induced collapse in Labrador Retrievers (d-EIC) and Border Collie collapse.

Section Editors

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Wendy A. Ware, DVM, MS, DACVIM (Cardiology), Professor, Departments of Veterinary Clinical Sciences and Biomedical Sciences, Iowa State University. Dr. Ware earned her DVM degree and completed her residency training at The Ohio State University. At Iowa State, she teaches clinical cardiology and cardiovascular physiology and serves as Clinical Cardiologist in the ISU Lloyd Veterinary Medical Center. She has been an invited speaker at many continuing education programs around the country and internationally. Dr. Ware has authored the highly illustrated clinical textbook Cardiovascular Disease in Small Animal Medicine, released in softcover edition in 2011 (Manson Publishing, London, UK). She also has written and edited the case-based Self-Assessment Color Review of Small Animal Cardiopulmonary Medicine (2012, Manson Publishing), as well as numerous journal articles and over 60 book chapters. Dr. Ware’s other professional activities have included service as President and Chairman of the Board of Regents of the American College of Veterinary Internal Medicine, Associate Editor for Cardiology for the Journal of Veterinary Internal Medicine, and reviewer for several veterinary scientific journals.

Jodi L. Westropp, DVM, PhD, DACVIM (Internal Medicine), Associate Professor, Department of Medicine and Epidemiology, School of Veterinary Medicine, University of California, Davis. Dr. Westropp received her DVM degree from The Ohio State University College of Veterinary Medicine. She completed an internship in small animal medicine and surgery at the Animal Medicine Center in New York City, and a residency in small animal internal medicine at The Ohio State University. She continued her training and received her PhD in 2003 at Ohio State, where she studied the neuroendocrine abnormalities in cats with feline interstitial cystitis. She then joined the faculty at the University of California, Davis, School of Veterinary Medicine, where she is currently an Associate Professor. Her clinical and research interests include feline interstitial cystitis, urinary tract infections, urinary incontinence, and urolithiasis. She is the author of numerous manuscripts and book chapters and has lectured extensively nationally and internationally. She is also the Director of the G.V. Ling Urinary Stone Analysis Laboratory at the University of California, Davis.

Penny J. Watson, MA, VetMD, CertVR, DSAM, DECVIM, MRCVS, Senior Lecturer in Small Animal Medicine, Queen’s Veterinary School Hospital, University of Cambridge, United Kingdom. Dr. Watson received her veterinary degree from the University of Cambridge. She spent four years in private veterinary practice in the United Kingdom before returning to Cambridge Veterinary School, where she now helps run the small animal internal medicine teaching hospital. She is both a member of the Royal College of Veterinary Surgeons and a European recognized specialist in Small Animal Internal Medicine. Dr. Watson was on the examination board of the European College of Veterinary Internal Medicine (ECVIM) for five years, two as Chair. Her clinical and research interests are focused on gastroenterology, hepatology, pancreatic disease, and comparative metabolism. She gained a doctorate for studies of canine chronic pancreatitis in 2009 and continues to research, lecture, and publish widely on aspects of canine and feline pancreatic and liver disease.

Michael D. Willard, DVM, MS, DACVIM (Internal Medicine), Professor, Department of Veterinary Small Animal Medicine and Surgery, Texas A&M University. Dr. Willard is an internationally recognized veterinary gastroenterologist and endoscopist. He has received the National SCAVMA Teaching Award for clinical teaching and the National Norden Teaching Award. A past President of the Comparative Gastroenterology Society and past Secretary of the specialty of Internal Medicine, his main interests are clinical gastroenterology and endoscopy (flexible and rigid). Dr. Willard has published more than 80 journal articles and 120 book chapters on these topics and has given over 2700 hours of invited lectures on these subjects around the world. Dr. Willard is an associate editor for the Journal of Veterinary Internal Medicine.

Contributors Sean J. Delaney, DVM, MS, DACVN, Founder DVM Consulting, Inc. Dr. Delaney is a recognized expert in veterinary clinical nutrition. He received his DVM and MS in Nutrition from the University of California, Davis. He also completed the first full-time clinical nutrition residency at the University of California, Davis. Dr. Delaney was a clinical faculty member of the Department of Molecular Biosciences at the University of California, Davis, between

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2003 and 2013. During that time he helped develop and establish one of the largest veterinary clinical nutrition teaching programs in the country. He also founded Davis Veterinary Medical (DVM) Consulting, Inc., a pet food industry consulting firm that also maintains and supports the Balance IT® veterinary nutrition software and products available at balanceit.com. Dr. Delaney is a frequent speaker nationally and internationally on veterinary nutrition. He is a past President and Chair of the ACVN and co-editor/ co-author of Applied Veterinary Clinical Nutrition.

We would like to dedicate this book to Kay and Graciela. This project would not have been possible without their continued understanding, encouragement, and patience. I (Guillermo) also dedicate this book to Jason and Kristen, who in following my path have made me the proudest dad.

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Preface In the fifth edition of Small Animal Internal Medicine, we have retained our original goal of creating a practical text with a strong clinical slant that is useful for both practitioners and students. We have continued to limit authorship, with each author selected for clinical expertise in his or her respective field, to ensure consistency within each section and allowing differences to be expressed when topics overlap between sections of the book. We have continued to focus on the clinically relevant aspects of the most common problems in internal medicine, presenting information in a concise, understandable, and logical format. Extensive use of tables, algorithms, and cross-referencing within and among sections, as well as a comprehensive index, help make Small Animal Internal Medicine a quick, easy-to-use reference textbook. •

ORGANIZATION

As before, the book contains 14 sections organized by organ systems (e.g., cardiology, respiratory), or when multiple systems are involved, by discipline (e.g., oncology, infectious diseases, immune-mediated disorders). Each section, when possible, begins with a chapter on clinical signs and differential diagnoses, followed by chapters on indications, techniques, and interpretation of diagnostic tests; general therapeutic principles; specific diseases; and finally a table listing recommended drug dosages for drugs commonly used to treat disorders within the appropriate organ system or discipline. Each section is supported extensively by tables, photographs, schematic illustrations, and algorithms, which address clinical presentations, differential diagnoses, diagnostic approaches, and treatment recommendations. Selected references and recommended readings are provided under the heading “Suggested Readings” at the end of each chapter. In addition, specific studies are cited in the text by author name and year of publication and are included in the Suggested Readings.

• • •

KEY FEATURES OF THE FIFTH EDITION We have retained all of the features that were popular in the first four editions and have significantly updated and expanded the new fifth edition. Features of the fifth edition include: • Thoroughly revised and updated content, with expanded coverage of hundreds of topics throughout the text, including new information on:

• Management of heart failure, chronic mitral valve disease, and heartworm disease • Collapsing trachea and canine infectious respiratory disease complex • Molecular diagnostics for gastrointestinal disorders and management of inflammatory bowel disease • Diagnosis of hepatobiliary disease in cats and treatment of pancreatitis in dogs • Treatment and monitoring of diabetic dogs and cats • Dietary recommendations for obesity in dogs and cats • Diagnosis and management of seizure disorders • Novel diagnostics and therapeutics in dogs and cats with cancer • New diagnostic methods in patients with hematologic disorders The expertise of two new authors who have completely revised the urinary tract section The expertise of a new author who has completely revised the reproduction section Hundreds of clinical photographs, the majority in full color Algorithms throughout the text to aid readers in the decision-making process Extensive cross-referencing to other chapters and discussions, providing a helpful roadmap and reducing redundancy within the book Hundreds of functionally color-coded summary tables and boxes to draw the reader’s eye to quickly accessible information, such as:

Etiology

Differential diagnoses

Drugs (appearing within chapters)

Drug formularies (appearing at the end of sections)

Treatment

General information (e.g., formulas, clinical pathology values, manufacturer information, breed predispositions) xi

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Preface

Finally, we are grateful to the many practitioners, faculty, and students worldwide who provided constructive comments on the first four editions, thereby making it possible to design an even stronger fifth edition. We believe the expanded content, features, and visual presentation will be positively received and will continue to make this book a valuable, user-friendly resource for all readers.

ACKNOWLEDGMENTS We would like to extend our sincerest thanks to Wendy, Eleanor, Mike, Penny, Sean, Sue, Michael, and Catharine for

their continued dedication and hard work to this project; to Jodi, Stephen, and Autumn for their willingness to become involved in this project; and to Penny Rudolph, Brandi Graham, Rhoda Bontrager, and many others at Elsevier for their commitment and latitude in developing this text. Richard W. Nelson C. Guillermo Couto

Contents PART ONE  CARDIOVASCULAR SYSTEM DISORDERS, 1 Wendy A. Ware

1 Clinical Manifestations of Cardiac Disease, 1 Signs of Heart Disease, 1 Signs of Heart Failure, 1 Weakness and Exercise Intolerance, 1 Syncope, 1 Cough and Other Respiratory Signs, 3 Cardiovascular Examination, 3 Observation of Respiratory Pattern, 4 Mucous Membranes, 4 Jugular Veins, 5 Arterial Pulses, 5 Precordium, 6 Evaluation for Fluid Accumulation, 6 Auscultation, 7 2 Diagnostic Tests for the Cardiovascular System, 13 Cardiac Radiography, 13 Cardiomegaly, 14 Cardiac Chamber Enlargement Patterns, 14 Intrathoracic Blood Vessels, 16 Patterns of Pulmonary Edema, 17 Electrocardiography, 17 Normal ECG Waveforms, 17 Lead Systems, 18 Approach to ECG Interpretation, 18 Sinus Rhythms, 21 Ectopic Rhythms, 21 Conduction Disturbances, 26 Mean Electrical Axis, 28 Chamber Enlargement and Bundle Branch Block Patterns, 29 ST-T Abnormalities, 29 Electrocardiographic Manifestations of Drug Toxicity and Electrolyte Imbalance, 30 Common Artifacts, 32 Ambulatory Electrocardiography, 33 Other Methods of ECG Assessment, 35 Echocardiography, 35 Basic Principles, 35 Two-Dimensional Echocardiography, 36 M-Mode Echocardiography, 37 Contrast Echocardiography, 43 Doppler Echocardiography, 43 Transesophageal Echocardiography, 47 Other Echocardiographic Modalities, 47

Other Techniques, 48 Central Venous Pressure Measurement, 48 Biochemical Markers, 48 Angiocardiography, 49 Cardiac Catheterization, 49 Other Imaging Techniques, 50 3 Management of Heart Failure, 53 Overview of Heart Failure, 53 Cardiac Responses, 53 Systemic Responses, 54 General Causes of Heart Failure, 56 Approach to Treating Heart Failure, 57 Treatment for Acute Congestive Heart Failure, 58 General Considerations, 58 Supplemental Oxygen, 58 Drug Therapy, 60 Heart Failure Caused by Diastolic Dysfunction, 62 Monitoring and Follow-Up, 62 Management of Chronic Heart Failure, 63 General Considerations, 63 Diuretics, 63 Angiotensin-Converting Enzyme Inhibitors, 64 Positive Inotropic Agents, 65 Other Vasodilators, 67 Dietary Considerations, 69 Chronic Diastolic Dysfunction, 70 Reevaluation and Monitoring, 71 Strategies for Refractory Congestive Heart Failure, 71 4 Cardiac Arrhythmias and Antiarrhythmic Therapy, 74 General Considerations, 74 Development of Arrhythmias, 74 Approach to Arrhythmia Management, 74 Diagnosis and Management of Common Arrhythmias, 75 Clinical Presentation, 76 Tachyarrhythmias, 76 Bradyarrhythmias, 82 Antiarrhythmic Agents, 84 Class I Antiarrhythmic Drugs, 85 Class II Antiarrhythmic Drugs: β-Adrenergic Blockers, 89 Class III Antiarrhythmic Drugs, 91 Class IV Antiarrhythmic Drugs: Calcium Entry Blockers, 92 Anticholinergic Drugs, 93 Sympathomimetic Drugs, 94 Other Drugs, 94 xiii

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Contents

5 Congenital Cardiac Disease, 96 General Considerations, 96 Extracardiac Arteriovenous Shunt, 96 Patent Ductus Arteriosus, 98 Ventricular Outflow Obstruction, 100 Subaortic Stenosis, 101 Pulmonic Stenosis, 103 Intracardiac Shunt, 106 Ventricular Septal Defect, 106 Atrial Septal Defect, 107 Atrioventricular Valve Malformation, 107 Mitral Dysplasia, 107 Tricuspid Dysplasia, 108 Cardiac Anomalies Causing Cyanosis, 108 Tetralogy of Fallot, 109 Pulmonary Hypertension with Shunt Reversal, 110 Other Cardiovascular Anomalies, 112 Vascular Ring Anomalies, 112 Cor Triatriatum, 112 Endocardial Fibroelastosis, 112 Other Vascular Anomalies, 113 6 Acquired Valvular and Endocardial Disease, 115 Degenerative Atrioventricular Valve Disease, 115 Radiography, 117 Electrocardiography, 118 Echocardiography, 118 Infective Endocarditis, 123 7 Myocardial Diseases of the Dog, 130 Dilated Cardiomyopathy, 130 Radiography, 131 Electrocardiography, 132 Echocardiography, 133 Clinicopathologic Findings, 133 Occult Dilated Cardiomyopathy, 134 Clinically Evident Dilated Cardiomyopathy, 134 Arrhythmogenic Right Ventricular Cardiomyopathy, 136 Cardiomyopathy in Boxers, 136 Arrhythmogenic Right Ventricular Cardiomyopathy in Nonboxer Dogs, 138 Secondary Myocardial Disease, 138 Myocardial Toxins, 138 Metabolic and Nutritional Deficiency, 138 Ischemic Myocardial Disease, 139 Tachycardia-Induced Cardiomyopathy, 139 Hypertrophic Cardiomyopathy, 140 Myocarditis, 140 Infective Myocarditis, 140 Noninfective Myocarditis, 142 Traumatic Myocarditis, 142 8 Myocardial Diseases of the Cat, 145 Hypertrophic Cardiomyopathy, 145 Radiography, 147 Electrocardiography, 147 Echocardiography, 147

Subclinical Hypertrophic Cardiomyopathy, 149 Clinically Evident Hypertrophic Cardiomyopathy, 151 Chronic Refractory Congestive Heart Failure, 152 Secondary Hypertrophic Myocardial Disease, 152 Restrictive Cardiomyopathy, 153 Dilated Cardiomyopathy, 155 Other Myocardial Diseases, 157 Arrhythmogenic Right Ventricular Cardiomyopathy, 157 Corticosteroid-Associated Heart Failure, 157 Myocarditis, 157 9 Pericardial Disease and Cardiac Tumors, 159 General Considerations, 159 Congenital Pericardial Disorders, 159 Peritoneopericardial Diaphragmatic Hernia, 159 Other Pericardial Anomalies, 160 Pericardial Effusion, 161 Hemorrhage, 161 Transudates, 162 Exudates, 162 Cardiac Tamponade, 162 Radiography, 163 Electrocardiography, 164 Echocardiography, 164 Clinicopathologic Findings, 164 Pericardiocentesis, 167 Constrictive Pericardial Disease, 168 Cardiac Tumors, 169 10 Heartworm Disease, 173 General Considerations, 173 Pulmonary Hypertension, 173 Heartworm Life Cycle, 173 Heartworm Disease in Dogs, 174 Heartworm Disease Testing, 175 Radiography, 176 Electrocardiography, 177 Echocardiography, 177 Clinicopathologic Findings, 177 Pretreatment Evaluation, 177 Adulticide Therapy in Dogs, 178 Microfilaricide Therapy, 180 Pulmonary Complications, 181 Right-Sided Congestive Heart Failure, 182 Caval Syndrome, 182 Heartworm Prevention, 183 Heartworm Disease in Cats, 184 Tests for Heartworm Disease in Cats, 185 Radiography, 186 Echocardiography, 186 Electrocardiography, 187 Other Tests, 187 Medical Therapy and Complications, 187 Surgical Therapy, 188

Contents

Microfilaricide Therapy, 188 Heartworm Prevention, 188 11 Systemic Arterial Hypertension, 190 General Considerations, 190 Blood Pressure Measurement, 193 Antihypertensive Drugs, 195 Hypertensive Emergency, 197 12 Thromboembolic Disease, 199 General Considerations, 199 Pulmonary Thromboembolism, 201 Systemic Arterial Thromboembolism in Cats, 201 Prophylaxis Against Arterial Thromboembolism, 207 Systemic Arterial Thromboembolism in Dogs, 208 Prophylaxis Against Arterial Thromboembolism, 210 Venous Thrombosis, 211

PART TWO  RESPIRATORY SYSTEM DISORDERS, 217

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Eleanor C. Hawkins 13 Clinical Manifestations of Nasal Disease, 217 General Considerations, 217 Nasal Discharge, 217 Sneezing, 221 Reverse Sneezing, 222 Stertor, 222 Facial Deformity, 222 14 Diagnostic Tests for the Nasal Cavity and Paranasal Sinuses, 224 Nasal Imaging, 224 Radiography, 224 Computed Tomography and Magnetic Resonance Imaging, 226 Rhinoscopy, 227 Frontal Sinus Exploration, 229 Nasal Biopsy: Indications and Techniques, 229 Nasal Swab, 230 Nasal Flush, 231 Pinch Biopsy, 231 Turbinectomy, 231 Nasal Cultures: Sample Collection and Interpretation, 232 15 Disorders of the Nasal Cavity, 234 Feline Upper Respiratory Infection, 234 Bacterial Rhinitis, 236 Nasal Mycoses, 237 Cryptococcosis, 237 Aspergillosis, 237 Nasal Parasites, 240 Nasal Mites, 240 Nasal Capillariasis, 240 Feline Nasopharyngeal Polyps, 240 Canine Nasal Polyps, 241 Nasal Tumors, 241

19

20

xv

Allergic Rhinitis, 243 Idiopathic Rhinitis, 243 Feline Chronic Rhinosinusitis, 243 Canine Chronic/Lymphoplasmacytic Rhinitis, 245 Clinical Manifestations of Laryngeal and Pharyngeal Disease, 247 Clinical Signs, 247 Larynx, 247 Pharynx, 247 Differential Diagnoses for Laryngeal Signs in Dogs and Cats, 248 Differential Diagnoses for Pharyngeal Signs in Dogs and Cats, 248 Diagnostic Tests for the Larynx and Pharynx, 249 Radiography, 249 Ultrasonography, 249 Fluoroscopy, 249 Computed Tomography and Magnetic Resonance Imaging, 249 Laryngoscopy and Pharyngoscopy, 249 Disorders of the Larynx and Pharynx, 253 Laryngeal Paralysis, 253 Brachycephalic Airway Syndrome, 255 Obstructive Laryngitis, 256 Laryngeal Neoplasia, 256 Clinical Manifestations of Lower Respiratory Tract Disorders, 258 Clinical Signs, 258 Cough, 258 Exercise Intolerance and Respiratory Distress, 259 Diagnostic Approach to Dogs and Cats with Lower Respiratory Tract Disease, 260 Initial Diagnostic Evaluation, 260 Pulmonary Specimens and Specific Disease Testing, 261 Diagnostic Tests for the Lower Respiratory Tract, 263 Thoracic Radiography, 263 General Principles, 263 Trachea, 263 Lungs, 264 Angiography, 271 Ultrasonography, 271 Computed Tomography and Magnetic Resonance Imaging, 271 Nuclear Imaging, 271 Parasitology, 272 Serology, 274 Urine Antigen Tests, 274 Polymerase Chain Reaction Tests, 274 Tracheal Wash, 274 Techniques, 275 Specimen Handling, 279 Interpretation of Results, 279 Nonbronchoscopic Bronchoalveolar Lavage, 281 Technique for NB-BAL in Cats, 283 Technique for NB-BAL in Dogs, 283

xvi

Contents

Recovery of Patients after BAL, 284 Specimen Handling, 285 Interpretation of Results, 285 Diagnostic Yield, 286 Transthoracic Lung Aspiration and Biopsy, 286 Techniques, 287 Bronchoscopy, 288 Technique, 288 Thoracotomy or Thoracoscopy with Lung Biopsy, 288 Blood Gas Analysis, 290 Techniques, 290 Interpretation of Results, 291 Pulse Oximetry, 295 Method, 295 Interpretation, 295 21 Disorders of the Trachea and Bronchi, 297 General Considerations, 297 Canine Infectious Tracheobronchitis, 297 Canine Chronic Bronchitis, 300 General Management, 302 Drug Therapies, 302 Management of Complications, 303 Feline Bronchitis (Idiopathic), 304 Emergency Stabilization, 306 Environment, 307 Glucocorticoids, 307 Bronchodilators, 308 Other Potential Treatments, 308 Failure to Respond, 309 Collapsing Trachea and Tracheobronchomalacia, 309 Allergic Bronchitis, 313 Oslerus Osleri, 313 22 Disorders of the Pulmonary Parenchyma and Vasculature, 316 Viral Pneumonias, 316 Canine Influenza, 316 Other Viral Pneumonias, 317 Bacterial Pneumonia, 317 Toxoplasmosis, 321 Fungal Pneumonia, 321 Pulmonary Parasites, 321 Capillaria (Eucoleus) aerophila, 321 Paragonimus kellicotti, 321 Aelurostrongylus abstrusus, 322 Crenosoma vulpis, 323 Aspiration Pneumonia, 323 Eosinophilic Lung Disease (Pulmonary Infiltrates with Eosinophils and Eosinophilic Pulmonary Granulomatosis), 325 Idiopathic Interstitial Pneumonias, 326 Idiopathic Pulmonary Fibrosis, 327 Pulmonary Neoplasia, 329 Pulmonary Hypertension, 331 Pulmonary Thromboembolism, 331 Pulmonary Edema, 333

23 Clinical Manifestations of the Pleural Cavity and Mediastinal Disease, 337 General Considerations, 337 Pleural Effusion: Fluid Classification and Diagnostic Approach, 337 Transudates and Modified Transudates, 338 Septic and Nonseptic Exudates, 339 Chylous Effusions, 340 Hemorrhagic Effusions, 340 Effusion Caused by Neoplasia, 341 Pneumothorax, 341 Mediastinal Masses, 341 Pneumomediastinum, 342 24 Diagnostic Tests for the Pleural Cavity and Mediastinum, 343 Radiography, 343 Pleural Cavity, 343 Mediastinum, 343 Ultrasonography, 345 Computed Tomography, 345 Thoracocentesis, 345 Chest Tubes: Indications and Placement, 346 Thoracoscopy and Thoracotomy, 348 25 Disorders of the Pleural Cavity, 349 Pyothorax, 349 Chylothorax, 352 Spontaneous Pneumothorax, 354 Neoplastic Effusion, 354 26 Emergency Management of Respiratory Distress, 356 General Considerations, 356 Large Airway Disease, 356 Extrathoracic (Upper) Airway Obstruction, 356 Intrathoracic Large Airway Obstruction, 358 Pulmonary Parenchymal Disease, 358 Pleural Space Disease, 359 27 Ancillary Therapy: Oxygen Supplementation and Ventilation, 361 Oxygen Supplementation, 361 Oxygen Masks, 361 Oxygen Hoods, 361 Nasal Catheters, 361 Transtracheal Catheters, 363 Endotracheal Tubes, 363 Tracheal Tubes, 363 Oxygen Cages, 363 Ventilatory Support, 364

PART THREE  DIGESTIVE SYSTEM DISORDERS, 367 Michael D. Willard 28 Clinical Manifestations of Gastrointestinal Disorders, 367 Dysphagia, Halitosis, and Drooling, 367

Distinguishing Regurgitation from Vomiting from Expectoration, 369 Regurgitation, 370 Vomiting, 371 Hematemesis, 374 Diarrhea, 376 Hematochezia, 380 Melena, 380 Tenesmus, 381 Constipation, 382 Fecal Incontinence, 383 Weight Loss, 383 Anorexia/Hyporexia, 385 Abdominal Effusion, 385 Acute Abdomen, 385 Abdominal Pain, 387 Abdominal Distention or Enlargement, 388 29 Diagnostic Tests for the Alimentary Tract, 390 Physical Examination, 390 Routine Laboratory Evaluation, 390 Complete Blood Count, 390 Coagulation, 390 Serum Biochemistry Profile, 390 Urinalysis, 391 Fecal Parasitic Evaluation, 391 Fecal Digestion Tests, 391 Bacterial Fecal Culture, 392 ELISA, IFA, and PCR Fecal Analyses, 392 Cytologic Evaluation of Feces, 393 Electron Microscopy, 393 Radiography of the Alimentary Tract, 393 Ultrasonography of the Alimentary Tract, 393 Imaging of the Oral Cavity, Pharynx, and Esophagus, 394 Indications, 394 Indications for Imaging of the Esophagus, 394 Imaging of the Stomach and Small Intestine, 397 Indications for Radiographic Imaging of the Abdomen without Contrast Media, 397 Indications for Ultrasonography of the Stomach and Small Intestines, 398 Indications for Contrast-Enhanced Gastrograms, 399 Indications for Contrast-Enhanced Studies of the Small Intestine, 399 Indications for Barium Contrast Enemas, 401 Peritoneal Fluid Analysis, 401 Digestion and Absorption Tests, 402 Serum Concentrations of Vitamins, 402 Other Special Tests for Alimentary Tract Disease, 403 Endoscopy, 403 Biopsy Techniques and Submission, 408 Fine-Needle Aspiration Biopsy, 408 Endoscopic Biopsy, 408 Full-Thickness Biopsy, 408

Contents

xvii

30 General Therapeutic Principles, 410 Fluid Therapy, 410 Dietary Management, 412 Special Nutritional Supplementation, 413 Diets for Special Enteral Support, 416 Parenteral Nutrition, 417 Antiemetics, 417 Antacid Drugs, 418 Intestinal Protectants, 419 Digestive Enzyme Supplementation, 420 Motility Modifiers, 420 Antiinflammatory and Antisecretory Drugs, 421 Antibacterial Drugs, 422 Probiotics/Prebiotics, 423 Anthelmintic Drugs, 424 Enemas, Laxatives, and Cathartics, 424 31 Disorders of the Oral Cavity, Pharynx, and Esophagus, 428 Masses, Proliferations, and Inflammation of the Oropharynx, 428 Sialocele, 428 Sialoadenitis/Sialoadenosis/Salivary Gland Necrosis, 428 Neoplasms of the Oral Cavity in Dogs, 428 Neoplasms of the Oral Cavity in Cats, 430 Feline Eosinophilic Granuloma, 430 Gingivitis/Periodontitis, 431 Stomatitis, 431 Feline Lymphocytic-Plasmacytic Gingivitis/ Pharyngitis, 431 Dysphagias, 432 Masticatory Muscle Myositis/Atrophic Myositis, 432 Cricopharyngeal Achalasia/Dysfunction, 432 Pharyngeal Dysphagia, 433 Esophageal Weakness/Megaesophagus, 433 Congenital Esophageal Weakness, 433 Acquired Esophageal Weakness, 434 Esophagitis, 435 Hiatal Hernia, 436 Dysautonomia, 437 Esophageal Obstruction, 437 Vascular Ring Anomalies, 437 Esophageal Foreign Objects, 438 Esophageal Cicatrix, 438 Esophageal Neoplasms, 439 32 Disorders of the Stomach, 442 Gastritis, 442 Acute Gastritis, 442 Hemorrhagic Gastroenteritis, 442 Chronic Gastritis, 443 Helicobacter-Associated Disease, 444 Physaloptera rara, 444 Ollulanus tricuspis, 445

xviii

Contents

Gastric Outflow Obstruction/Gastric Stasis, 445 Benign Muscular Pyloric Hypertrophy (Pyloric Stenosis), 445 Gastric Antral Mucosal Hypertrophy, 445 Gastric Foreign Objects, 447 Gastric Dilation/Volvulus, 448 Partial or Intermittent Gastric Volvulus, 449 Idiopathic Gastric Hypomotility, 450 Bilious Vomiting Syndrome, 450 Gastrointestinal Ulceration/Erosion, 451 Infiltrative Gastric Diseases, 452 Neoplasms, 452 Pythiosis, 453 33 Disorders of the Intestinal Tract, 455 Acute Diarrhea, 455 Acute Enteritis, 455 Enterotoxemia, 456 Dietary-Induced Diarrhea, 456 Infectious Diarrhea, 457 Canine Parvoviral Enteritis, 457 Feline Parvoviral Enteritis, 459 Canine Coronaviral Enteritis, 460 Feline Coronaviral Enteritis, 460 Feline Leukemia Virus–Associated Panleukopenia (Myeloblastopenia), 460 Feline Immunodeficiency Virus–Associated Diarrhea, 460 Salmon Poisoning/Elokomin Fluke Fever, 461 Bacterial Diseases: Common Themes, 461 Campylobacteriosis, 461 Salmonellosis, 462 Clostridial Diseases, 462 Miscellaneous Bacteria, 463 Histoplasmosis, 464 Protothecosis, 464 Alimentary Tract Parasites, 465 Whipworms, 465 Roundworms, 466 Hookworms, 467 Tapeworms, 467 Strongyloidiasis, 467 Coccidiosis, 468 Cryptosporidia, 468 Giardiasis, 468 Trichomoniasis, 470 Heterobilharzia, 470 Maldigestive Disease, 471 Exocrine Pancreatic Insufficiency, 471 Malabsorptive Diseases, 471 Antibiotic-Responsive Enteropathy, 471 Dietary-Responsive Disease, 472 Small Intestinal Inflammatory Bowel Disease, 472 Large Intestinal Inflammatory Bowel Disease, 474 Granulomatous Enteritis/Gastritis, 474 Immunoproliferative Enteropathy in Basenjis, 474 Enteropathy in Chinese Shar-Peis, 475 Enteropathy in Shiba Dogs, 475

Protein-Losing Enteropathy, 475 Causes of Protein-Losing Enteropathy, 475 Intestinal Lymphangiectasia, 475 Protein-Losing Enteropathy in Soft-Coated Wheaten Terriers, 476 Functional Intestinal Disease, 477 Irritable Bowel Syndrome, 477 Intestinal Obstruction, 477 Simple Intestinal Obstruction, 477 Incarcerated Intestinal Obstruction, 478 Mesenteric Torsion/Volvulus, 478 Linear Foreign Objects, 478 Intussusception, 479 Miscellaneous Intestinal Diseases, 481 Short Bowel Syndrome, 481 Neoplasms of the Small Intestine, 482 Alimentary Lymphoma, 482 Intestinal Adenocarcinoma, 483 Intestinal Leiomyoma/Leiomyosarcoma/Stromal Tumor, 483 Inflammation of the Large Intestine, 483 Acute Colitis/Proctitis, 483 Chronic Colitis (IBD), 483 Granulomatous/Histiocytic Ulcerative Colitis, 483 Intussusception/Prolapse of the Large Intestine, 484 Cecocolic Intussusception, 484 Rectal Prolapse, 484 Neoplasms of the Large Intestine, 484 Adenocarcinoma, 484 Rectal Polyps, 485 Miscellaneous Large Intestinal Diseases, 485 Pythiosis, 485 Perineal/Perianal Diseases, 486 Perineal Hernia, 486 Perianal Fistulae, 486 Anal Sacculitis, 487 Perianal Neoplasms, 487 Anal Sac (Apocrine Gland) Adenocarcinoma, 487 Perianal Gland Tumors, 487 Constipation, 488 Pelvic Canal Obstruction Caused by Malaligned Healing of Old Pelvic Fractures, 488 Benign Rectal Stricture, 488 Dietary Indiscretion Leading to Constipation, 488 Idiopathic Megacolon, 489 34 Disorders of the Peritoneum, 492 Inflammatory Diseases, 492 Septic Peritonitis, 492 Sclerosing Encapsulating Peritonitis, 494 Hemoabdomen, 495 Abdominal Hemangiosarcoma, 495 Miscellaneous Peritoneal Disorders, 495 Abdominal Carcinomatosis, 495 Mesothelioma, 496 Feline Infectious Peritonitis, 496

Contents

PART FOUR  HEPATOBILIARY AND EXOCRINE PANCREATIC DISORDERS, 501 Penny J. Watson 35 Clinical Manifestations of Hepatobiliary Disease, 501 General Considerations, 501 Abdominal Enlargement, 501 Organomegaly, 501 Abdominal Effusion, 502 Abdominal Muscular Hypotonia, 504 Jaundice, Bilirubinuria, and Change in Fecal Color, 504 Hepatic Encephalopathy, 508 Coagulopathies, 510 Polyuria and Polydipsia, 510 36 Diagnostic Tests for the Hepatobiliary System, 512 Diagnostic Approach, 512 Diagnostic Tests, 513 Tests to Assess Status of the Hepatobiliary System, 513 Tests to Assess Hepatobiliary System Function, 514 Urinalysis, 518 Fecal Evaluation, 519 Abdominocentesis—Fluid Analysis, 519 Complete Blood Count, 519 Coagulation Tests, 521 Diagnostic Imaging, 522 Survey Radiography, 522 Ultrasonography, 524 Computed Tomography, 529 Scintigraphy and Magnetic Resonance Imaging, 529 Liver Biopsy, 529 General Considerations, 529 Techniques, 531 37 Hepatobiliary Diseases in the Cat, 536 General Considerations, 536 Hepatic Lipidosis, 536 Primary Hepatic Lipidosis, 536 Secondary Hepatic Lipidosis, 536 Biliary Tract Disease, 543 Cholangitis, 543 Cholecystitis, 549 Biliary Cysts, 549 Extrahepatic Bile Duct Obstruction, 549 Hepatic Amyloidosis, 551 Neoplasia, 551 Congenital Portosystemic Shunts, 553 Hepatobiliary Infections, 555 Toxic Hepatopathy, 555 Hepatobiliary Manifestations of Systemic Disease, 557

xix

38 Hepatobiliary Diseases in the Dog, 559 General Considerations, 559 Chronic Hepatitis, 559 Idiopathic Chronic Hepatitis, 561 Copper Storage Disease, 566 Infectious Causes of Canine Chronic Hepatitis, 569 Lobular Dissecting Hepatitis, 570 Toxic Causes of Chronic Hepatitis, 570 Acute Hepatitis, 570 Biliary Tract Disorders, 572 Cholangitis and Cholecystitis, 572 Gallbladder Mucocele, 572 Extrahepatic Bile Duct Obstruction, 573 Bile Peritonitis, 573 Congenital Vascular Disorders, 575 Disorders Associated with Low Portal Pressure: Congenital Portosystemic Shunt, 575 Disorders Associated with High Portal Pressure, 578 Focal Hepatic Lesions, 580 Abscesses, 580 Nodular Hyperplasia, 581 Neoplasia, 582 Hepatocutaneous Syndrome and Superficial Necrolytic Dermatitis, 583 Secondary Hepatopathies, 584 Hepatocyte Vacuolation, 585 Hepatic Congestion and Edema, 585 Nonspecific Reactive Hepatitis, 586 39 Treatment of Complications of Hepatic Disease and Failure, 588 General Considerations, 588 Hepatic Encephalopathy, 588 Chronic Hepatic Encephalopathy, 588 Acute Hepatic Encephalopathy, 591 Portal Hypertension, 593 Splanchnic Congestion and Gastrointestinal Ulceration, 593 Ascites, 594 Coagulopathy, 595 Protein-Calorie Malnutrition, 596 40 The Exocrine Pancreas, 598 General Considerations, 598 Pancreatitis, 598 Acute Pancreatitis, 599 Chronic Pancreatitis, 614 Exocrine Pancreatic Insufficiency, 617 Routine Clinical Pathology, 619 Pancreatic Enzymes, 619 Other Diagnostic Tests, 620 Drugs, 621 Diet, 621 Exocrine Pancreatic Neoplasia, 622 Pancreatic Abscesses, Cysts, and Pseudocysts, 622

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Contents

PART FIVE  URINARY TRACT DISORDERS, 629 Stephen P. DiBartola and Jodi L. Westropp 41 Clinical Manifestations of Urinary Disorders, 629 Clinical Approach, 629 Presenting Problems, 630 Hematuria, 630 Dysuria, 632 Polyuria and Polydipsia, 633 Renomegaly, 635 42 Diagnostic Tests for the Urinary System, 638 Glomerular Function, 638 Blood Urea Nitrogen, 638 Serum Creatinine, 638 Cystatin C, 639 Creatinine Clearance, 639 Single-Injection Methods for Estimation of Glomerular Filtration Rate, 640 Iohexol Clearance, 640 Radioisotopes, 640 Urine Protein-to-Creatinine Ratio, 640 Microalbuminuria, 641 Bladder Tumor Antigen Test, 641 Tubular Function, 641 Urine Specific Gravity and Osmolality, 642 Water Deprivation Test, 642 Gradual Water Deprivation, 642 Fractional Clearance of Electrolytes, 643 Urinalysis, 643 Physical Properties of Urine, 643 Chemical Properties of Urine, 643 Urinary Sediment Examination, 644 Microbiology, 649 Diagnostic Imaging, 649 Radiography, 649 Ultrasonography, 650 Urodynamic Testing, 650 Urethral Pressure Profile, 650 Cystometrography, 651 Urethrocystoscopy, 651 Renal Biopsy, 651 43 Glomerular Disease, 653 Normal Structure, 653 Pathogenesis, 654 Mechanisms of Immune Injury, 655 Progression, 655 Histopathologic Lesions of Glomerulonephritis, 656 Amyloidosis, 657 Clinical Findings, 658 Management of Patients with Glomerular Disease, 659 Complications, 661 Hypoalbuminemia, 661

44

45

46

47

Sodium Retention, 661 Thromboembolism, 661 Hyperlipidemia, 662 Hypertension, 662 Acute and Chronic Renal Failure, 663 Acute Renal Failure, 663 Chronic Renal Failure, 669 Uremia as Intoxication, 670 Hyperfiltration, 670 Functional and Morphologic Changes in Remnant Renal Tissue, 671 External Solute Balance, 671 Development of Polyuria and Polydipsia, 672 Calcium and Phosphorus Balance, 672 Acid-Base Balance, 674 Anemia, 674 Hemostatic Defects, 674 Gastrointestinal Disturbances, 674 Cardiovascular Complications, 674 Metabolic Complications, 675 Conservative Treatment, 675 Supportive Care, 679 Canine and Feline Urinary Tract Infections, 680 Introduction, 680 Classification of Urinary Tract Infections, 680 Treatment of Uncomplicated Urinary Tract Infections, 683 Bacterial Prostatitis, 685 Canine and Feline Urolithiasis, 687 Introduction, 687 Principles of Stone Analysis, 687 Stone Removal, 687 Struvite and Calcium Oxalate Calculi, 689 In Dogs, 689 In Cats, 689 Ureterolithiasis in Dogs and Cats, 690 Clinical Signs of Ureterolithiasis, 690 Diagnostic Imaging, 690 Medical Treatment, 691 Surgical Intervention for Treatment of Ureteral Calculi, 691 Urate Urolithiasis in Dogs, 694 Urate Urolithiasis in Cats, 695 Calcium Phosphate Calculi in Cats and Dogs, 696 Cystine and Silica Urolithiasis in Cats and Dogs, 696 Dried Solidified Blood Calculi in Cats, 696 Xanthine Uroliths, 697 Conclusions, 697 Obstructive and Nonobstructive Feline Idiopathic Cystitis, 698 Introduction, 698 Pathophysiology, 698 Histopathology, 698 Bladder Abnormalities, 698 Infectious Agents, 698

Contents

Systemic Abnormalities, 699 Pathophysiology of the Blocked Cat, 699 Diagnostic Tests for Cats with Lower Urinary Tract Signs, 699 Treatment Options, 700 Acute Episodes, 700 Chronic Management, 701 Conclusions, 702 48 Disorders of Micturition, 704 Anatomy and Physiology, 704 Definitions and Types of Urinary Incontinence, 704 Ectopic Ureters, 704 Urethral Sphincter Mechanism Incompetence, 706 Urinary Incontinence, 709

PART SIX  ENDOCRINE DISORDERS, 713 Richard W. Nelson 49 Disorders of the Hypothalamus and Pituitary Gland, 713 Polyuria and Polydipsia, 713 Diabetes Insipidus, 714 Central Diabetes Insipidus, 715 Nephrogenic Diabetes Insipidus, 715 Signalment, 715 Clinical Signs, 715 Physical Examination, 716 Modified Water Deprivation Test, 716 Response to Desmopressin, 717 Random Plasma Osmolality, 717 Additional Diagnostic Tests, 718 Primary (Psychogenic) Polydipsia, 719 Endocrine Alopecia, 719 Feline Acromegaly, 722 Acromegaly versus Hyperadrenocorticism, 725 Managing Insulin-Resistant Diabetes, 725 Pituitary Dwarfism, 726 Signalment, 726 Clinical Signs, 726 50 Disorders of the Parathyroid Gland, 731 Classification of Hyperparathyroidism, 731 Primary Hyperparathyroidism, 731 Signalment, 732 Clinical Signs, 732 Physical Examination, 733 Primary Hypoparathyroidism, 737 Signalment, 737 Clinical Signs, 737 Physical Examination, 737 51 Disorders of the Thyroid Gland, 740 Hypothyroidism in Dogs, 740 Dermatologic Signs, 741 Neuromuscular Signs, 743 Reproductive Signs, 745 Miscellaneous Clinical Signs, 745

xxi

Myxedema Coma, 745 Cretinism, 745 Autoimmune Polyendocrine Syndromes, 746 Dermatohistopathologic Findings, 747 Ultrasonographic Findings, 747 Tests of Thyroid Gland Function, 747 Factors Affecting Thyroid Gland Function Tests, 752 Diagnosis in a Previously Treated Dog, 755 Diagnosis in Puppies, 755 Therapy with Sodium Levothyroxine (Synthetic T4), 756 Therapeutic Monitoring, 756 Thyrotoxicosis, 757 Hypothyroidism in Cats, 757 Hyperthyroidism in Cats, 760 Signalment, 762 Clinical Signs, 762 Physical Examination, 762 Common Concurrent Problems, 763 Canine Thyroid Neoplasia, 772 Surgery, 774 External Beam Radiation, 774 Chemotherapy, 775 Radioactive Iodine (131I), 775 Oral Antithyroid Drugs, 775 52 Disorders of the Endocrine Pancreas, 777 Hyperglycemia, 777 Hypoglycemia, 777 Diabetes Mellitus in Dogs, 780 Signalment, 780 History, 781 Physical Examination, 781 Overview of Insulin Preparations, 782 Storage and Dilution of Insulin, 783 Initial Insulin Recommendations for Diabetic Dogs, 783 Diet, 785 Exercise, 785 Identification and Control of Concurrent Problems, 786 Protocol for Identifying Initial Insulin Requirements, 786 History and Physical Examination, 787 Single Blood Glucose Determination, 787 Serum Fructosamine Concentration, 787 Urine Glucose Monitoring, 788 Serial Blood Glucose Curves, 788 Insulin Therapy during Surgery, 792 Complications of Insulin Therapy, 793 Chronic Complications of Diabetes Mellitus, 797 Diabetes Mellitus in Cats, 798 Signalment, 800 History, 800 Physical Examination, 801 Initial Insulin Recommendations for Diabetic Cats, 802

xxii

Contents

Diet, 802 Identification and Control of Concurrent Problems, 803 Oral Hypoglycemic Drugs, 803 Identifying Initial Insulin Requirements, 804 Insulin Therapy during Surgery, 806 Complications of Insulin Therapy, 806 Chronic Complications of Diabetes Mellitus, 808 Diabetic Ketoacidosis, 809 Fluid Therapy, 810 Insulin Therapy, 813 Concurrent Illness, 815 Complications of Therapy and Prognosis, 815 Insulin-Secreting β-Cell Neoplasia, 815 Signalment, 816 Clinical Signs, 816 Physical Examination, 816 Clinical Pathology, 816 Overview of Treatment, 818 Perioperative Management of Dogs Undergoing Surgery, 818 Postoperative Complications, 818 Medical Treatment for Chronic Hypoglycemia, 819 Gastrin-Secreting Neoplasia, 820 53 Disorders of the Adrenal Gland, 824 Hyperadrenocorticism in Dogs, 824 Pituitary-Dependent Hyperadrenocorticism, 824 Adrenocortical Tumors, 824 Iatrogenic Hyperadrenocorticism, 825 Signalment, 825 Clinical Signs, 825 Pituitary Macrotumor Syndrome, 826 Medical Complications: Thromboembolism, 827 Clinical Pathology, 828 Diagnostic Imaging, 829 Tests of the Pituitary-Adrenocortical Axis, 831 Trilostane, 837 Mitotane, 839 Ketoconazole, 841 l-Deprenyl, 841 Adrenalectomy, 842 External Beam Radiation, 842 Occult (Atypical) Hyperadrenocorticism in Dogs, 843 Hyperadrenocorticism in Cats, 844 Clinical Signs and Physical Examination Findings, 844 Clinical Pathology, 845 Diagnostic Imaging, 846 Tests of the Pituitary-Adrenocortical Axis, 846 Hypoadrenocorticism, 849 Signalment, 849 Clinical Signs and Physical Examination Findings, 850 Clinical Pathology, 850

Electrocardiography, 851 Diagnostic Imaging, 851 Therapy for Acute Addisonian Crisis, 852 Maintenance Therapy for Primary Adrenal Insufficiency, 853 Atypical Hypoadrenocorticism, 854 Pheochromocytoma, 855 Incidental Adrenal Mass, 857

PART SEVEN  METABOLIC AND ELECTROLYTE DISORDERS, 863 Richard W. Nelson and Sean J. Delaney 54 Disorders of Metabolism, 863 Polyphagia with Weight Loss, 863 Obesity, 864 Hyperlipidemia, 871 55 Electrolyte Imbalances, 877 Hypernatremia, 877 Hyponatremia, 879 Hyperkalemia, 880 Hypokalemia, 883 Hypercalcemia, 885 Hypocalcemia, 889 Hyperphosphatemia, 891 Hypophosphatemia, 891 Hypomagnesemia, 893 Hypermagnesemia, 894

PART EIGHT  REPRODUCTIVE SYSTEM DISORDERS, 897 Autumn P. Davidson 56 The Practice of Theriogenology, 897 Estrous Cycle of the Bitch, 897 Breeding Soundness Examinations in the Bitch or Queen, 899 Canine Ovulation Timing, 899 Evaluation of the Estrous Cycle to Identify the Optimal Time to Breed, 899 Serum Hormone Interpretation, 900 Clinical Protocol: Veterinary Breeding Management, 902 Feline Breeding Management, 904 Breeding Husbandry, 905 Semen Collection, 905 Semen Analysis, 906 Artificial Insemination: Vaginal, 907 Artificial Insemination: Intrauterine, 907 Obstetrics, 909 Pregnancy Diagnosis, 909 Gestational Length and Fetal Age Determination, 910

Contents

Nutrition and Exercise in Pregnancy, 910 Vaccination and Medications in the Pregnant Bitch or Queen, 911 Neonatal Resuscitation, 912 57 Clinical Conditions of the Bitch and Queen, 915 Normal Variations of the Canine Estrous Cycle, 915 Delayed Puberty, 915 Silent Heat Cycles, 915 Split Heat Cycles, 915 Abnormalities of the Estrous Cycle in the Bitch, 916 Prolonged Proestrus/Estrus, 916 Prolonged Interestrous Intervals, 917 Prolonged Anestrus, 917 Prolonged Diestrus, 917 Shortened Interestrous Intervals, 918 Exaggerated Pseudocyesis (Pseudopregnancy), 919 Vaginal Hyperplasia, 919 Manipulation of the Estrous Cycle, 920 Prevention of Estrous Cycles, 920 Estrus Induction, 920 Pregnancy Termination, 920 Prepartum Disorders, 922 Semen Peritonitis, 922 Pregnancy Loss, 922 Canine Brucellosis, 925 Metabolic Disorders, 926 Hyperemesis Gravidarum, 926 Vasculidities, 926 Gestational Diabetes, 927 Pregnancy Toxemia, 927 Parturition and Parturient Disorders, 927 Normal Labor, 928 Dystocia, 928 Postpartum Disorders, 932 Inappropriate Maternal Behavior, 933 Metabolic Disorders, 933 Uterine Disorders, 934 Mammary Disorders, 936 Neonatology, 937 Disorders of the Reproductive Tract in Ovariohysterectomized Bitches and Queens, 939 Chronic Vestibulovaginitis, 939 Ovarian Remnant Syndrome/ Hyperestrogenism, 942 58 Clinical Conditions of the Dog and Tom, 944 Cryptorchidism, 944 Testicular Torsion, 944 Scrotal Dermatitis, 945 Balanoposthitis, 945 Persistent Penile Frenulum, 946 Urethral Prolapse, 946 Priapism, Paraphimosis, and Phimosis, 946 Testicular Neoplasia in Stud Dogs, 949

xxiii

59 Female and Male Infertility and Subfertility, 951 The Female, 951 Infertility versus Subfertility in the Bitch and Queen, 951 Microbiology and Female Fertility, 951 Cystic Endometrial Hyperplasia/Pyometra Complex, 952 The Male, 955 Acquired Male Infertility, 955 Infectious Orchitis and Epididymitis, 957 Prostatic Disorders in the Valuable Stud Dog, 958 Obstructive Disorders of Ejaculation, 962 Defects of Spermatogenesis, 962 Congenital Infertility: Disorders of Sexual Differentiation, 962

PART NINE  NEUROMUSCULAR DISORDERS, 966 Susan M. Taylor 60 Lesion Localization and the Neurologic Examination, 966 Functional Anatomy of the Nervous System and Lesion Localization, 966 Brain, 966 Spinal Cord, 967 Neuromuscular System, 970 Neurologic Control of Micturition, 971 Screening Neurologic Examination, 971 Mental State, 972 Posture, 972 Gait, 973 Postural Reactions, 975 Muscle Size/Tone, 977 Spinal Reflexes, 977 Sensory Evaluation, 980 Pain/Hyperpathia, 980 Urinary Tract Function, 983 Cranial Nerves, 983 Lesion Localization, 987 Diagnostic Approach, 988 Animal History, 988 Disease Onset and Progression, 988 Systemic Abnormalities, 988 61 Diagnostic Tests for the Neuromuscular System, 990 Routine Laboratory Evaluation, 990 Immunology, Serology, and Microbiology, 990 Routine Systemic Diagnostic Imaging, 991 Radiographs, 991 Ultrasound, 991 Diagnostic Imaging of the Nervous System, 991 Spinal Radiographs, 991 Myelography, 991 Computed Tomography and Magnetic Resonance Imaging, 992

xxiv

Contents

Cerebrospinal Fluid Collection and Analysis, 992 Indications, 992 Contraindications, 995 Technique, 995 Analysis, 996 Electrodiagnostic Testing, 997 Electromyography, 997 Nerve Conduction Velocities, 998 Electroretinography, 998 Brainstem Auditory Evoked Response, 998 Electroencephalography, 998 Biopsy of Muscle and Nerve, 998 Muscle Biopsy, 998 Nerve Biopsy, 998 62 Intracranial Disorders, 1000 General Considerations, 1000 Abnormal Mentation, 1000 Intoxications, 1000 Metabolic Encephalopathies, 1000 Hypermetria, 1000 Diagnostic Approach to Animals with Intracranial Disease, 1001 Intracranial Disorders, 1001 Head Trauma, 1001 Vascular Accidents, 1002 Feline Ischemic Encephalopathy, 1003 Hydrocephalus, 1003 Lissencephaly, 1004 Cerebellar Hypoplasia, 1004 Inflammatory Diseases (Encephalitis), 1004 Inherited Degenerative Disorders Affecting the Brain, 1005 Cerebellar Cortical Degeneration (Abiotropy), 1005 Neuroaxonal Dystrophy, 1005 Neoplasia, 1006 63 Loss of Vision and Pupillary Abnormalities, 1008 General Considerations, 1008 Neuroophthalmologic Evaluation, 1008 Vision, 1008 Menace Response, 1008 Pupillary Light Reflex, 1008 Dazzle Reflex, 1009 Pupil Size and Symmetry, 1009 Disorders of Eyeball Position and Movement, 1010 Lacrimal Gland Function, 1010 Loss of Vision, 1010 Lesions of the Retina, Optic Disk and Optic Nerve, 1010 Lesions of the Optic Chiasm, 1012 Lesions Caudal to the Optic Chiasm, 1012 Horner Syndrome, 1013 Protrusion of the Third Eyelid, 1015 64 Seizures and Other Paroxysmal Events, 1016 Seizures, 1016 Paroxysmal Events, 1016

Seizure Descriptions, 1017 Seizure Classification and Localization, 1017 Differential Diagnosis, 1018 Idiopathic Epilepsy, 1018 Intracranial Disease, 1019 Scar Tissue–Related Acquired Epilepsy, 1019 Extracranial Disease, 1020 Diagnostic Evaluation, 1020 Anticonvulsant Therapy, 1022 Anticonvulsant Drugs, 1023 Phenobarbital, 1023 Potassium Bromide, 1024 Zonisamide, 1025 Levetiracetam, 1025 Gabapentin, 1025 Felbamate, 1025 Diazepam, 1025 Clorazepate, 1026 Alternative Therapies, 1026 Emergency Therapy for Dogs and Cats in Status Epilepticus, 1026 65 Head Tilt, 1028 General Considerations, 1028 Nystagmus, 1028 Localization of Lesions, 1028 Peripheral Vestibular Disease, 1028 Central Vestibular Disease, 1029 Paradoxical (Central) Vestibular Syndrome, 1030 Disorders Causing Peripheral Vestibular Disease, 1030 Otitis Media-Interna, 1030 Geriatric Canine Vestibular Disease, 1032 Feline Idiopathic Vestibular Syndrome, 1032 Neoplasia, 1032 Nasopharyngeal Polyps, 1033 Trauma, 1033 Congenital Vestibular Syndromes, 1033 Aminoglycoside Ototoxicity, 1033 Chemical Ototoxicity, 1033 Hypothyroidism, 1033 Disorders Causing Central Vestibular Disease, 1034 Inflammatory Diseases, 1034 Intracranial Neoplasia, 1034 Cerebrovascular Disease, 1034 Acute Vestibular Attacks, 1034 Metronidazole Toxicity, 1034 66 Encephalitis, Myelitis, and Meningitis, 1036 General Considerations, 1036 Neck Pain, 1036 Noninfectious Inflammatory Disorders, 1037 Steroid-Responsive Meningitis-Arteritis, 1037 Canine Meningoencephalitis of Unknown Etiology, 1038

Granulomatous Meningoencephalitis, 1039 Necrotizing Meningoencephalitis, 1040 Necrotizing Leukoencephalitis, 1040 Canine Eosinophilic Meningitis/ Meningoencephalitis, 1040 Canine Steroid-Responsive Tremor Syndrome, 1041 Feline Polioencephalitis, 1041 Infectious Inflammatory Disorders, 1041 Feline Immunodeficiency Virus Encephalopathy, 1041 Bacterial Meningoencephalomyelitis, 1042 Canine Distemper Virus, 1043 Rabies, 1043 Feline Infectious Peritonitis, 1044 Toxoplasmosis, 1044 Neosporosis, 1045 Lyme Disease, 1046 Mycotic Infections, 1046 Rickettsial Diseases, 1047 Parasitic Meningitis, Myelitis, and Encephalitis, 1047 67 Disorders of the Spinal Cord, 1048 General Considerations, 1048 Localizing Spinal Cord Lesions, 1048 C1-C5 Lesions, 1048 C6-T2 Lesions, 1048 T3-L3 Lesions, 1050 L4-S3 Lesions, 1050 Diagnostic Approach, 1050 Acute Spinal Cord Dysfunction, 1051 Trauma, 1051 Hemorrhage/Infarction, 1053 Acute Intervertebral Disk Disease, 1053 Traumatic Disk Extrusions, 1059 Fibrocartilaginous Embolism, 1059 Atlantoaxial Instability, 1060 Neoplasia, 1060 Progressive Spinal Cord Dysfunction, 1060 Subacute Progressive Disorders, 1060 Chronic Progressive Disorders, 1062 Progressive Disorders in Young Animals, 1071 Nonprogressive Disorders in Young Animals, 1072 68 Disorders of Peripheral Nerves and the Neuromuscular Junction, 1074 General Considerations, 1074 Focal Neuropathies, 1074 Traumatic Neuropathies, 1074 Peripheral Nerve Sheath Tumors, 1074 Facial Nerve Paralysis, 1077 Trigeminal Nerve Paralysis, 1078 Hyperchylomicronemia, 1079 Ischemic Neuromyopathy, 1079 Polyneuropathies, 1080 Congenital/Inherited Polyneuropathies, 1080

Contents

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Acquired Chronic Polyneuropathies, 1081 Acquired Acute Polyneuropathies, 1083 Disorders of the Neuromuscular Junction, 1084 Tick Paralysis, 1084 Botulism, 1086 Myasthenia Gravis, 1086 Dysautonomia, 1088 69 Disorders of Muscle, 1090 General Considerations, 1090 Inflammatory Myopathies, 1090 Masticatory Myositis, 1090 Extraocular Myositis, 1091 Canine Idiopathic Polymyositis, 1092 Feline Idiopathic Polymyositis, 1092 Dermatomyositis, 1093 Protozoal Myositis, 1093 Acquired Metabolic Myopathies, 1093 Glucocorticoid Excess, 1093 Hypothyroidism, 1094 Hypokalemic Polymyopathy, 1094 Inherited Myopathies, 1095 Muscular Dystrophy, 1095 Centronuclear Myopathy of Labrador Retrievers, 1095 Myotonia, 1095 Inherited Metabolic Myopathies, 1096 Involuntary Alterations in Muscle Tone and Movement, 1096 Opisthotonos, 1097 Tetanus, 1097 Myoclonus, 1098 Tremors, 1098 Dyskinesias, 1098 Disorders Causing Exercise Intolerance or Collapse, 1098

PART TEN  JOINT DISORDERS, 1103 Susan M. Taylor and J. Catharine R. Scott-Moncrieff 70 Clinical Manifestations of and Diagnostic Tests for Joint Disorders, 1103 General Considerations, 1103 Clinical Manifestations, 1103 Diagnostic Approach, 1103 Diagnostic Tests, 1105 Minimum Database, 1105 Synovial Fluid Collection and Analysis, 1106 Synovial Fluid Culture, 1109 Synovial Membrane Biopsy, 1109 Radiography, 1109 Immunologic and Serologic Tests, 1110 71 Disorders of the Joints, 1111 General Considerations, 1111 Noninflammatory Joint Disease, 1111 Degenerative Joint Disease, 1111

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Contents

Infectious Inflammatory Joint Diseases, 1113 Septic (Bacterial) Arthritis, 1113 Mycoplasma Polyarthritis, 1115 Bacterial L-Form-Associated Arthritis, 1115 Rickettsial Polyarthritis, 1115 Lyme Disease, 1116 Leishmaniasis, 1116 Fungal Arthritis, 1116 Viral Arthritis, 1116 Noninfectious Polyarthritis: Nonerosive, 1117 Reactive Polyarthritis, 1117 Idiopathic Immune-Mediated Nonerosive Polyarthritis, 1118 Systemic Lupus Erythematosus–Induced Polyarthritis, 1120 Breed-Specific Polyarthritis Syndromes, 1121 Familial Chinese Shar-Pei Fever, 1121 Lymphoplasmacytic Synovitis, 1121 Noninfectious Polyarthritis: Erosive, 1122 Canine Rheumatoid-Like Polyarthritis, 1122 Erosive Polyarthritis of Greyhounds, 1123 Feline Chronic Progressive Polyarthritis, 1123

PART ELEVEN  ONCOLOGY, 1126 C. Guillermo Couto 72 Cytology, 1126 General Considerations, 1126 Fine-Needle Aspiration, 1126 Impression Smears, 1127 Staining of Cytologic Specimens, 1127 Interpretation of Cytologic Specimens, 1127 Normal Tissues, 1128 Hyperplastic Processes, 1128 Inflammatory Processes, 1128 Malignant Cells, 1128 Lymph Nodes, 1132 73 Principles of Cancer Treatment, 1134 General Considerations, 1134 Patient-Related Factors, 1134 Family-Related Factors, 1134 Treatment-Related Factors, 1135 74 Practical Chemotherapy, 1138 Cell and Tumor Kinetics, 1138 Basic Principles of Chemotherapy, 1138 Indications and Contraindications of Chemotherapy, 1140 Mechanism of Action of Anticancer Drugs, 1141 Types of Anticancer Drugs, 1141 Metronomic Chemotherapy, 1142 Safe Handling of Anticancer Drugs, 1142 75 Complications of Cancer Chemotherapy, 1144 General Considerations, 1144 Hematologic Toxicity, 1144

76

77 78

79

Gastrointestinal Toxicity, 1148 Hypersensitivity Reactions, 1148 Dermatologic Toxicity, 1149 Pancreatitis, 1150 Cardiotoxicity, 1150 Urotoxicity, 1151 Hepatotoxicity, 1152 Neurotoxicity, 1152 Acute Tumor Lysis Syndrome, 1152 Approach to the Patient with a Mass, 1154 Approach to the Cat or Dog with a Solitary Mass, 1154 Approach to the Cat or Dog with Metastatic Lesions, 1155 Approach to the Cat or Dog with a Mediastinal Mass, 1156 Lymphoma, 1160 Leukemias, 1175 Definitions and Classification, 1175 Leukemias in Dogs, 1176 Acute Leukemias, 1177 Chronic Leukemias, 1181 Leukemias in Cats, 1183 Acute Leukemias, 1183 Chronic Leukemias, 1184 Selected Neoplasms in Dogs and Cats, 1186 Hemangiosarcoma in Dogs, 1186 Osteosarcoma, 1188 Mast Cell Tumors in Dogs and Cats, 1191 Mast Cell Tumors in Dogs, 1191 Mast Cell Tumors in Cats, 1194 Injection Site Sarcomas in Cats, 1195

PART TWELVE  HEMATOLOGY, 1201 C. Guillermo Couto 80 Anemia, 1201 Definition, 1201 Clinical and Clinicopathologic Evaluation, 1201 Management of the Anemic Patient, 1205 Regenerative Anemias, 1206 Nonregenerative Anemias, 1212 Semiregenerative Anemias, 1215 Transfusion Therapy, 1216 Blood Groups, 1217 Cross-Matching and Blood Typing, 1217 Blood Administration, 1218 Complications of Transfusion Therapy, 1218 81 Clinical Pathology in Greyhounds and Other Sighthounds, 1220 Hematology, 1220 Erythrocytes, 1220 Leukocytes, 1221 Platelets, 1221

Contents

82 83

84

85

86

Hemostasis, 1221 Clinical Chemistry, 1221 Creatinine, 1222 Liver Enzymes, 1222 Serum Electrolytes and Acid-Base Balance, 1222 Protein, 1222 Thyroid Hormones, 1223 Cardiac Troponins, 1223 Clinical Pathology in Greyhounds: The Ohio State University Experience, 1223 Conclusions, 1225 Erythrocytosis, 1227 Definition and Classification, 1227 Leukopenia and Leukocytosis, 1230 General Considerations, 1230 Normal Leukocyte Morphology and Physiology, 1230 Leukocyte Changes in Disease, 1231 Neutropenia, 1231 Neutrophilia, 1234 Eosinopenia, 1235 Eosinophilia, 1235 Basophilia, 1235 Monocytosis, 1236 Lymphopenia, 1236 Lymphocytosis, 1237 Combined Cytopenias and Leukoerythroblastosis, 1239 Definitions and Classification, 1239 Clinicopathologic Features, 1239 Bone Marrow Aplasia-Hypoplasia, 1242 Myelodysplastic Syndromes, 1243 Myelofibrosis and Osteosclerosis, 1243 Disorders of Hemostasis, 1245 General Considerations, 1245 Physiology of Hemostasis, 1245 Clinical Manifestations of Spontaneous Bleeding Disorders, 1246 Clinicopathologic Evaluation of the Bleeding Patient, 1247 Management of the Bleeding Patient, 1251 Primary Hemostatic Defects, 1251 Thrombocytopenia, 1251 Platelet Dysfunction, 1254 Secondary Hemostatic Defects, 1256 Congenital Clotting Factor Deficiencies, 1256 Vitamin K Deficiency, 1256 Mixed (Combined) Hemostatic Defects, 1257 Disseminated Intravascular Coagulation, 1257 Thrombosis, 1261 Lymphadenopathy and Splenomegaly, 1264 Applied Anatomy and Histology, 1264 Function, 1264

xxvii

Lymphadenopathy, 1264 Splenomegaly, 1268 Approach to Patients with Lymphadenopathy or Splenomegaly, 1271 Management of Lymphadenopathy or Splenomegaly, 1274 87 Hyperproteinemia, 1276 88 Fever of Undetermined Origin, 1279 Fever and Fever of Undetermined Origin, 1279 Disorders Associated with Fever of Undetermined Origin, 1279 Diagnostic Approach to the Patient with Fever of Undetermined Origin, 1280

PART THIRTEEN  INFECTIOUS DISEASES, 1283 Michael R. Lappin 89 Laboratory Diagnosis of Infectious Diseases, 1283 Demonstration of the Organism, 1283 Fecal Examination, 1283 Cytology, 1285 Tissue Techniques, 1287 Culture Techniques, 1287 Immunologic Techniques, 1288 Molecular Diagnostics, 1289 Animal Inoculation, 1290 Electron Microscopy, 1290 Antibody Detection, 1290 Serum, 1290 Body Fluids, 1291 Antemortem Diagnosis of Infectious Diseases, 1291 90 Practical Antimicrobial Chemotherapy, 1293 Anaerobic Infections, 1293 Bacteremia and Bacterial Endocarditis, 1297 Central Nervous System Infections, 1299 Gastrointestinal Tract and Hepatic Infections, 1299 Musculoskeletal Infections, 1300 Respiratory Tract Infections, 1301 Skin and Soft Tissue Infections, 1302 Urogenital Tract Infections, 1302 91 Prevention of Infectious Diseases, 1305 Biosecurity Procedures for Small Animal Hospitals, 1305 General Biosecurity Guidelines, 1305 Patient Evaluation, 1305 Hospitalized Patients, 1306 Basic Disinfection Protocols, 1307 Biosecurity Procedures for Clients, 1307 Vaccination Protocols, 1307

xxviii Contents

92

93

94

95

96

97

Vaccine Types, 1307 Vaccine Selection, 1308 Vaccination Protocols for Cats, 1309 Vaccination Protocols for Dogs, 1311 Polysystemic Bacterial Diseases, 1315 Canine Bartonellosis, 1315 Feline Bartonellosis, 1316 Feline Plague, 1318 Leptospirosis, 1319 Mycoplasma and Ureaplasma, 1322 Polysystemic Rickettsial Diseases, 1326 Canine Granulocytotropic Anaplasmosis, 1326 Feline Granulocytotropic Anaplasmosis, 1328 Canine Thrombocytotropic Anaplasmosis, 1329 Canine Monocytotropic Ehrlichiosis, 1330 Feline Monocytotropic Ehrlichiosis, 1334 Canine Granulocytotropic Ehrlichiosis, 1335 Rocky Mountain Spotted Fever, 1336 Other Rickettsial Infections, 1337 Polysystemic Viral Diseases, 1341 Canine Distemper Virus, 1341 Feline Coronavirus, 1343 Feline Immunodeficiency Virus, 1347 Feline Leukemia Virus, 1350 Polysystemic Mycotic Infections, 1356 Blastomycosis, 1356 Coccidioidomycosis, 1359 Cryptococcosis, 1360 Histoplasmosis, 1363 Polysystemic Protozoal Infections, 1367 Babesiosis, 1367 Cytauxzoonosis, 1368 Hepatozoonosis, 1369 Leishmaniasis, 1370 Neosporosis, 1372 Feline Toxoplasmosis, 1374 Canine Toxoplasmosis, 1377 American Trypanosomiasis, 1378 Zoonoses, 1384 Enteric Zoonoses, 1384 Nematodes, 1384 Cestodes, 1389 Coccidians, 1389 Flagellates, Amoeba, and Ciliates, 1391 Bacteria, 1391 Bite, Scratch, or Exudate Exposure Zoonoses, 1391 Bacteria, 1391 Fungi, 1394 Viruses, 1394 Respiratory Tract and Ocular Zoonoses, 1394 Bacteria, 1394 Viruses, 1395 Genital and Urinary Tract Zoonoses, 1395 Shared Vector Zoonoses, 1396 Shared Environment Zoonoses, 1396

PART FOURTEEN  IMMUNE-MEDIATED DISORDERS, 1398 J. Catharine R. Scott-Moncrieff 98 Pathogenesis of Immune-Mediated Disorders, 1398 General Considerations and Definition, 1398 Immunopathologic Mechanisms, 1398 Pathogenesis of Immune-Mediated Disorders, 1399 Primary versus Secondary Immune-Mediated Disorders, 1401 Organ Systems Involved in Autoimmune Disorders, 1401 99 Diagnostic Testing for Immune-Mediated Disease, 1402 Clinical Diagnostic Approach, 1402 Specific Diagnostic Tests, 1402 Slide Agglutination Test, 1402 Coombs Test (Direct Antiglobulin Test), 1403 Antiplatelet Antibodies, 1403 Megakaryocyte Direct Immunofluorescence, 1404 Antinuclear Antibody Test, 1404 Lupus Erythematosus Test, 1404 Rheumatoid Factor, 1404 Immunofluorescence and Immunohistochemistry, 1404 Autoimmune Panels, 1405 100â•… Treatment of Primary Immune-Mediated Diseases, 1407 Principles of Treatment of Immune-Mediated Diseases, 1407 Overview of Immunosuppressive Therapy, 1407 Glucocorticoids, 1408 Azathioprine, 1410 Cyclophosphamide, 1411 Chlorambucil, 1411 Cyclosporine (Ciclosporin), 1411 Vincristine, 1413 Human Intravenous Immunoglobulin, 1414 Pentoxifylline, 1415 Mycophenolate Mofetil, 1415 Leflunomide, 1415 Splenectomy, 1416 101 Common Immune-Mediated Diseases, 1417 Immune-Mediated Hemolytic Anemia, 1417 Prevention of Hemolysis, 1421 Blood Transfusion, 1423 Prevention of Thromboembolism, 1423 Supportive Care, 1423 Pure Red Cell Aplasia, 1424 Immune-Mediated Thrombocytopenia, 1424 Immunosuppression, 1428 Supportive Care, 1429

Contents

Feline Immune-Mediated Thrombocytopenia, 1429 Immune-Mediated Neutropenia, 1429 Idiopathic Aplastic Anemia, 1430 Polyarthritis, 1430 Systemic Lupus Erythematosus, 1433 Glomerulonephritis, 1434 Acquired Myasthenia Gravis, 1436

Immune-Mediated Myositis, 1437 Masticatory Myositis, 1437 Polymyositis, 1437 Dermatomyositis, 1438

Index, 1441

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PART ONE

Cardiovascular System Disorders Wendy A. Ware

C H A P T E R

1â•…

Clinical Manifestations of Cardiac Disease

SIGNS OF HEART DISEASE Several signs can indicate the presence of heart disease even if the animal is not clinically in “heart failure.” Objective signs of heart disease include cardiac murmurs, rhythm disturbances, jugular pulsations, and cardiac enlargement. Other clinical signs that can result from heart disease include syncope, excessively weak or strong arterial pulses, cough or respiratory difficulty, exercise intolerance, abdominal distention, and cyanosis. However, noncardiac diseases can cause these signs as well. Further evaluation using thoracic radiography, electrocardiography (ECG), echocardiography, and sometimes other tests is usually indicated when signs suggestive of cardiovascular disease are present.

SIGNS OF HEART FAILURE Cardiac failure occurs when the heart cannot adequately meet the body’s circulatory needs or can do so only with high filling (venous) pressures. Most clinical signs of heart failure (Box 1-1) relate to high venous pressure behind the heart (congestive signs) or inadequate blood flow out of the heart (low output signs). Congestive signs associated with right-sided heart failure stem from systemic venous hypertension and the resulting increases in systemic capillary pressure. High left-heart filling pressure causes venous engorgement and edema. Signs of biventricular failure develop in some animals. Chronic left-sided congestive heart failure can promote the development of right-sided congestive signs, especially when pulmonary arterial pressure rises secondary to pulmonary venous hypertension. Signs of low cardiac output are similar regardless of which ventricle is primarily affected, because output from the left heart is coupled to that from the right heart. Heart failure is discussed further in Chapter 3 and within the context of specific diseases.

WEAKNESS AND EXERCISE INTOLERANCE Animals with heart failure often cannot adequately raise cardiac output to sustain increased levels of activity. Furthermore, vascular and metabolic changes that occur over time impair skeletal muscle perfusion during exercise and contribute to reduced exercise tolerance. Increased pulmonary vascular pressure and edema also lead to poor exercise ability. Episodes of exertional weakness or collapse can relate to these changes or to an acute decrease in cardiac output caused by arrhythmias (Box 1-2). SYNCOPE Syncope is characterized by transient unconsciousness associated with loss of postural tone (collapse) from insufficient oxygen or glucose delivery to the brain. Various cardiac and noncardiac abnormalities can cause syncope and intermittent weakness (see Box 1-2). Syncope can be confused with seizure episodes. A careful description of the animal’s behavior or activity before the collapse event, during the event itself, and following the collapse, as well as a drug history, can help the clinician differentiate among syncopal attacks, episodic weakness, and true seizures. Syncope often is associated with exertion or excitement. The actual event may be characterized by rear limb weakness or sudden collapse, lateral recumbency, stiffening of the forelimbs with opisthotonos, and micturition (Fig. 1-1). Vocalization is common; however, tonic/clonic motion, facial fits, and defecation are not. An aura (which often occurs before seizure activity), postictal dementia, and neurologic deficits are generally not seen in dogs and cats with cardiovascular syncope. Sometimes profound hypotension or asystole causes hypoxic “convulsive syncope,” with seizure-like activity or twitching; these convulsive syncopal episodes are preceded by loss of muscle tone. Presyncope, where reduced brain perfusion (or substrate delivery) is not severe enough to cause unconsciousness, 1

2

PART Iâ•…â•… Cardiovascular System Disorders

BOX 1-1â•… Clinical Signs of Heart Failure

BOX 1-2â•… Causes of Syncope or Intermittent Weakness

Congestive Signs—Left (↑ Left Heart Filling Pressure)

Cardiovascular Causes

Pulmonary venous congestion Pulmonary edema (causes cough, tachypnea, ↑ respiratory effort, orthopnea, pulmonary crackles, tiring, hemoptysis, cyanosis) Secondary right-sided heart failure Cardiac arrhythmias

Bradyarrhythmias (second- or third-degree AV block, sinus arrest, sick sinus syndrome, atrial standstill) Tachyarrhythmias (paroxysmal atrial or ventricular tachycardia, reentrant supraventricular tachycardia, atrial fibrillation) Congenital ventricular outflow obstruction (pulmonic stenosis, subaortic stenosis) Acquired ventricular outflow obstruction (heartworm disease and other causes of pulmonary hypertension, hypertrophic obstructive cardiomyopathy, intracardiac tumor, thrombus) Cyanotic heart disease (tetralogy of Fallot, pulmonary hypertension, and “reversed” shunt) Impaired forward cardiac output (severe valvular insufficiency, dilated cardiomyopathy, myocardial infarction or inflammation) Impaired cardiac filling (e.g., cardiac tamponade, constrictive pericarditis, hypertrophic or restrictive cardiomyopathy, intracardiac tumor, thrombus) Cardiovascular drugs (diuretics, vasodilators) Neurocardiogenic reflexes (vasovagal, cough-syncope, other situational syncope)

Congestive Signs—Right (↑ Right Heart Filling Pressure)

Systemic venous congestion (causes ↑ central venous pressure, jugular vein distention) Hepatic ± splenic congestion Pleural effusion (causes ↑ respiratory effort, orthopnea, cyanosis) Ascites Small pericardial effusion Subcutaneous edema Cardiac arrhythmias Low Output Signs

Tiring Exertional weakness Syncope Prerenal azotemia Cyanosis (from poor peripheral circulation) Cardiac arrhythmias

Pulmonary Causes

Diseases causing hypoxemia Pulmonary hypertension Pulmonary thromboembolism Metabolic and Hematologic Causes

may appear as transient “wobbliness” or weakness, especially in the rear limbs. Testing to determine the cause of intermittent weakness or syncope usually includes ECG recordings (during rest, exercise, and/or after exercise or a vagal maneuver); complete blood count (CBC); serum biochemical analysis (including electrolytes and glucose); neurologic examination; thoracic radiographs; heartworm testing; and echocardiography. Other studies for neuromuscular or neurologic disease may also be valuable. Intermittent cardiac arrhythmias not apparent on resting ECG may be uncovered by ambulatory ECG monitoring, using a 24-hour Holter, event, or implantable loop recording device. In-hospital continuous ECG monitoring will reveal a culprit arrhythmia in some cases.

AV, Atrioventricular.

Cardiovascular Causes of Syncope Various arrhythmias, obstruction to ventricular outflow, cyanotic congenital heart defects, and acquired diseases that cause poor cardiac output are the usual causes of cardiovascular syncope. Activation of vasodepressor reflexes and excessive dosages of cardiovascular drugs can also induce syncope. Arrhythmias that provoke syncope are usually associated with either very fast or very slow heart rate and can occur with or without identifiable underlying organic heart disease. Ventricular outflow obstruction can provoke syncope or sudden weakness if cardiac output becomes inadequate

during exercise or if high systolic pressures activate ventricular mechanoreceptors, causing inappropriate reflex bradycardia and hypotension. Both dilated cardiomyopathy and severe mitral insufficiency can impair forward cardiac output, especially during exertion. Vasodilator and diuretic drugs may induce syncope if given in excess. Syncope caused by abnormal peripheral vascular and/or neurologic reflex responses is not well defined in animals but is thought to occur in some patients. Syncope during sudden bradycardia after a burst of sinus tachycardia has been

Hypoglycemia Hypoadrenocorticism Electrolyte imbalance (especially potassium, calcium) Anemia Sudden hemorrhage Neurologic Causes

Cerebrovascular accident Brain tumor (Seizures) Neuromuscular Disease

(Narcolepsy, cataplexy)

CHAPTER 1â•…â•… Clinical Manifestations of Cardiac Disease

3

BOX 1-3â•… Important Historic Information

FIG 1-1â•…

Syncope in a Doberman Pinscher with paroxysmal ventricular tachycardia. Note the extended head and neck with stiffened forelimbs. Involuntary micturition also occurred, followed shortly by return of consciousness and normal activity.

documented, especially in small breed dogs with advanced atrioventricular (AV) valve disease; excitement often precipitates such an episode. Doberman Pinschers and Boxers similarly may experience syncope from sudden bradycardia. Postural hypotension and hypersensitivity of carotid sinus receptors infrequently may provoke syncope by inappropriate peripheral vasodilation and bradycardia. Fainting associated with a coughing fit (cough syncope or “cough-drop”) occurs in some dogs with marked left atrial enlargement and bronchial compression, as well as in dogs with primary respiratory disease. Several mechanisms have been proposed, including an acute decrease in cardiac filling and output during the cough, peripheral vasodilation after the cough, and increased cerebrospinal fluid pressure with intracranial venous compression. Severe pulmonary diseases, anemia, certain metabolic abnormalities, and primary neurologic diseases can also cause collapse resembling cardiovascular syncope.

COUGH AND OTHER RESPIRATORY SIGNS Congestive heart failure (CHF) in dogs results in tachypnea, cough, and dyspnea. These signs also can be associated with the pulmonary vascular pathology and pneumonitis of heartworm disease in both dogs and cats. Noncardiac conditions, including diseases of the upper and lower airways, pulmonary parenchyma (including noncardiogenic pulmonary edema), pulmonary vasculature, and pleural space, as well as certain nonrespiratory conditions, also should be considered in patients with cough, tachypnea, or dyspnea (see Chapter 19). The cough caused by cardiogenic pulmonary edema in dogs is often soft and moist, but it sometimes sounds like gagging. In contrast, cough rarely occurs from pulmonary edema in cats. Tachypnea progressing to dyspnea occurs in both species. Pleural and pericardial effusions occasionally

Signalment (age, breed, gender)? Vaccination status? What is the diet? Have there been any recent changes in food or water consumption? Where was the animal obtained? Is the pet housed indoors or outdoors? How much time is spent outdoors? Supervised? What activity level is normal? Does the animal tire easily now? Has there been any coughing? When? Describe episodes. Has there been any excessive or unexpected panting or heavy breathing? Has there been any vomiting or gagging? Diarrhea? Have there been any recent changes in urinary habits? Have there been any episodes of fainting or weakness? Do the tongue/mucous membranes always look pink, especially during exercise? Have there been any recent changes in attitude or activity level? Are medications being given for this problem? What? How much? How often? Do they help? Have medications been used in the past for this problem? What? How much? Were they effective?

are associated with coughing as well. Mainstem bronchus compression caused by severe left atrial enlargement can stimulate a cough (often described as dry or hacking) in dogs with chronic mitral insufficiency, even in the absence of pulmonary edema or congestion. A heartbase tumor, enlarged hilar lymph nodes, or other masses that impinge on an airway can also mechanically stimulate coughing. When respiratory signs are caused by heart disease, other evidence, such as generalized cardiomegaly, left atrial enlargement, pulmonary venous congestion, lung infiltrates that resolve with diuretic therapy, and/or a positive heartworm test, is usually present. The findings on physical examination, thoracic radiographs, cardiac biomarker assays, echocardiography, and sometimes electrocardiography help the clinician differentiate cardiac from noncardiac causes of respiratory signs.

CARDIOVASCULAR EXAMINATION The medical history (Box 1-3) is an important part of the cardiovascular evaluation that can help guide the choice of diagnostic tests because it may suggest various cardiac or noncardiac diseases. The signalment is useful because some congenital and acquired abnormalities are more prevalent in certain breeds or life stages or because specific findings are common in individuals of a given breed (e.g., soft left basilar ejection murmur in normal Greyhounds and other sighthounds).

4

PART Iâ•…â•… Cardiovascular System Disorders

Physical evaluation of the dog or cat with suspected heart disease includes observation (e.g., attitude, posture, body condition, level of anxiety, respiratory pattern) and a general physical examination. The cardiovascular examination itself consists of evaluating the peripheral circulation (mucous membranes), systemic veins (especially the jugular veins), systemic arterial pulses (usually the femoral arteries), and the precordium (left and right chest wall over the heart); palpating or percussing for abnormal fluid accumulation (e.g., ascites, subcutaneous edema, pleural effusion); and auscultating the heart and lungs. Proficiency in the cardiovascular examination requires practice but is important for accurate patient assessment and monitoring.

OBSERVATION OF RESPIRATORY PATTERN Respiratory difficulty (dyspnea) usually causes the animal to appear anxious. Increased respiratory effort, flared nostrils, and often a rapid rate of breathing are evident (Fig. 1-2). Increased depth of respiration (hyperpnea) frequently results from hypoxemia, hypercarbia, or acidosis. Pulmonary edema (as well as other pulmonary infiltrates) increases lung stiffness; rapid and shallow breathing (tachypnea) results as an attempt to minimize the work of breathing. An increased resting respiratory rate is often an early indicator of pulmonary edema in the absence of primary lung disease. Lung stiffness also increases with pleural fluid or air accumulation; however, large-volume pleural effusion or pneumothorax generally causes exaggerated respiratory motions as the animal struggles to expand the collapsed lungs. It is important to note whether the respiratory difficulty is more intense during a particular phase of respiration. Prolonged, labored inspiration is usually associated with upper airway disorders (obstruction), whereas prolonged expiration occurs with

lower airway obstruction or pulmonary infiltrative disease (including edema). Animals with severely compromised ventilation may refuse to lie down; rather, they stand or sit with elbows abducted to allow maximal rib expansion, and they resist being positioned in lateral or dorsal recumbency (orthopnea). Cats with dyspnea often crouch in a sternal position with elbows abducted. Open-mouth breathing is usually a sign of severe respiratory distress in cats (Fig. 1-3). The increased respiratory rate associated with excitement, fever, fear, or pain can usually be differentiated from dyspnea by careful observation and physical examination.

MUCOUS MEMBRANES Mucous membrane color and capillary refill time (CRT) are used to evaluate peripheral perfusion. The oral mucosa is usually assessed, but caudal mucous membranes (prepuce or vagina) also can be evaluated. The CRT is determined by applying digital pressure to blanch the membrane; color should return within 2 seconds. Slower refill times occur as a result of dehydration or other causes of decreased cardiac output because of high peripheral sympathetic tone and vasoconstriction. Pale mucous membranes result from anemia or peripheral vasoconstriction. The CRT is normal in anemic animals unless hypoperfusion is also present. However, the CRT can be difficult to assess in severely anemic animals because of the lack of color contrast. The color of the caudal membranes should be compared with that of the oral membranes in polycythemic cats and dogs for evidence of differential cyanosis. If the oral membranes are pigmented, the ocular conjunctiva can be evaluated. Box 1-4 outlines causes for abnormal mucous membrane color. Petechiae in the mucous membranes may be noticed in dogs and cats with platelet disorders (see Chapter 85). In addition, oral and ocular mucous membranes are often areas where icterus (jaundice) is first detected. A yellowish cast to these membranes should prompt further evaluation for hemolysis (see Chapter 80) or hepatobiliary disease (see Chapter 35).

FIG 1-2â•…

Dyspnea in an older male Golden Retriever with advanced dilated cardiomyopathy and fulminant pulmonary edema. The dog appeared highly anxious, with rapid labored respirations and hypersalivation. Within minutes after this photograph, respiratory arrest occurred, but the dog was resuscitated and lived another 9 months with therapy for heart failure.

FIG 1-3â•…

Severe dyspnea is manifested in this cat by open-mouth breathing, infrequent swallowing (drooling saliva), and reluctance to lie down. Note also the dilated pupils associated with heightened sympathetic tone.

CHAPTER 1â•…â•… Clinical Manifestations of Cardiac Disease

5

BOX 1-4â•… Abnormal Mucous Membrane Color Pale Mucous Membranes

Anemia Poor cardiac output/high sympathetic tone Injected, Brick-Red Membranes

Polycythemia (erythrocytosis) Sepsis Excitement Other causes of peripheral vasodilation Cyanotic Mucous Membranes*

Pulmonary parenchymal disease Airway obstruction Pleural space disease Pulmonary edema Right-to-left shunting congenital cardiac defect Hypoventilation Shock Cold exposure Methemoglobinemia

FIG 1-4â•…

Prominent jugular vein distention is seen in this cat with signs of right-sided congestive heart failure from dilated cardiomyopathy.

Differential Cyanosis

Reversed patent ductus arteriosus (head and forelimbs receive normally oxygenated blood, but caudal part of body receives desaturated blood via the ductus, which arises from the descending aorta) Icteric Mucous Membranes

Hemolysis Hepatobiliary disease Biliary obstruction *Anemic animals may not appear cyanotic even with marked hypoxemia because 5╯g/dL of desaturated hemoglobin is necessary for visible cyanosis.

JUGULAR VEINS Systemic venous and right heart filling pressures are reflected at the jugular veins. These veins should not be distended when the animal is standing with its head in a normal position (jaw parallel to the floor). Persistent jugular vein distention occurs in patients with right-sided CHF (because of high right heart filling pressure), external compression of the cranial vena cava, or jugular vein or cranial vena cava thrombosis (Fig. 1-4). Jugular pulsations extending higher than one third of the way up the neck from the thoracic inlet also are abnormal. Sometimes the carotid pulse wave is transmitted through adjacent soft tissues, mimicking a jugular pulse in thin or excited animals. To differentiate a true jugular pulse from carotid transmission, the jugular vein is occluded lightly below the area of the visible pulse. If the pulse disappears, it is a true jugular pulsation; if the pulse continues, it is being transmitted from the carotid artery. Jugular pulse waves are

related to atrial contraction and filling. Visible pulsations occur in animals with tricuspid insufficiency (after the first heart sound, during ventricular contraction); conditions causing a stiff and hypertrophied right ventricle (just before the first heart sound, during atrial contraction); or arrhythmias that cause the atria to contract against closed AV valves (so-called cannon “a” waves). Specific causes of jugular vein distention and/or pulsations are listed in Box 1-5. Impaired right ventricular filling, reduced pulmonary blood flow, or tricuspid regurgitation can cause a positive hepatojugular reflux even in the absence of jugular distention or pulsations at rest. To test for this reflux, firm pressure is applied to the cranial abdomen while the animal stands quietly. This transiently increases venous return. Jugular distention that persists while abdominal pressure is applied constitutes a positive (abnormal) test. Normal animals have little to no change in the jugular vein with this maneuver.

ARTERIAL PULSES The strength and regularity of the peripheral arterial pressure waves and the pulse rate are assessed by palpating the femoral or other peripheral arteries (Box 1-6). Subjective evaluation of pulse strength is based on the difference between the systolic and diastolic arterial pressures (the pulse pressure). When the difference is wide, the pulse feels strong on palpation; abnormally strong pulses are termed hyperkinetic. When the pressure difference is small, the pulse feels weak (hypokinetic). If the rise to maximum systolic arterial pressure is prolonged, as with severe subaortic stenosis, the pulse also feels weak (pulsus parvus et tardus). Both femoral pulses should be palpated and compared; absence of pulse or a weaker pulse on one side may be caused by

6

PART Iâ•…â•… Cardiovascular System Disorders

BOX 1-5â•… Causes of Jugular Vein Distention/Pulsation Distention Alone

Pericardial effusion/tamponade Right atrial mass/inflow obstruction Dilated cardiomyopathy Cranial mediastinal mass Jugular vein/cranial vena cava thrombosis Pulsation ± Distention

Tricuspid insufficiency of any cause (degenerative, cardiomyopathy, congenital, secondary to diseases causing right ventricular pressure overload) Pulmonic stenosis Heartworm disease Pulmonary hypertension Ventricular premature contractions Complete (third-degree) heart block Constrictive pericarditis Hypervolemia

BOX 1-6â•… Abnormal Arterial Pulses Weak Pulses

Dilated cardiomyopathy (Sub)aortic stenosis Pulmonic stenosis Shock Dehydration Strong Pulses

Excitement Hyperthyroidism Fever Hypertrophic cardiomyopathy Very Strong, Bounding Pulses

Patent ductus arteriosus Fever/sepsis Severe aortic regurgitation

thromboembolism. Femoral pulses can be difficult to palpate in cats, even when normal. Often an elusive pulse can be found by gently working a fingertip toward the cat’s femur in the area of the femoral triangle, where the femoral artery enters the leg between the dorsomedial thigh muscles. The femoral arterial pulse rate should be evaluated simultaneously with the direct heart rate, which is obtained by chest wall palpation or auscultation. Fewer femoral pulses than heartbeats constitute a pulse deficit. Various cardiac arrhythmias induce pulse deficits by causing the heart to beat before adequate ventricular filling has occurred. Consequently, minimal or even no blood is ejected for those beats

FIG 1-5â•…

Abdominal distention caused by ascites from right heart failure in a 7-year-old Golden Retriever.

and a palpable pulse is absent. Other arterial pulse variations occur occasionally. Alternately weak then strong pulsations can result from severe myocardial failure (pulsus alternans) or from a normal heartbeat alternating with a premature beat (bigeminy), which causes reduced ventricular filling and ejection. An exaggerated decrease in systolic arterial pressure during inspiration occurs in association with cardiac tamponade; a weak arterial pulse strength (pulsus paradoxus) may be detectable during inspiration in those patients.

PRECORDIUM The precordium is palpated by placing the palm and fingers of each hand on the corresponding side of the animal’s chest wall over the heart. Normally the strongest impulse is felt during systole over the area of the left apex (located at approximately the fifth intercostal space near the costochondral junction). Cardiomegaly or a space-occupying mass within the chest can shift the precordial impulse to an abnormal location. Decreased intensity of the precordial impulse can be caused by obesity, weak cardiac contractions, pericardial effusion, intrathoracic masses, pleural effusion, or pneumothorax. The precordial impulse should be stronger on the left chest wall than on the right. A stronger right precordial impulse can result from right ventricular hypertrophy or displacement of the heart into the right hemithorax by a mass lesion, lung atelectasis, or chest deformity. Very loud cardiac murmurs cause palpable vibrations on the chest wall known as a precordial thrill. This feels like a buzzing sensation on the hand. A precordial thrill is usually localized to the area of maximal intensity of the murmur. EVALUATION FOR FLUID ACCUMULATION Right-sided CHF promotes abnormal fluid accumulation within body cavities (Fig. 1-5; see also Fig. 9-3) or, usually less noticeably, in the subcutis of dependent areas. Palpation and ballottement of the abdomen, percussion of the chest in

the standing animal, and palpation of dependent areas are used to detect effusions and subcutaneous edema. Fluid accumulation secondary to right-sided heart failure is usually accompanied by abnormal jugular vein distention and/or pulsations, unless the animal’s circulating blood volume is diminished by diuretic use or other cause. Hepatomegaly and/or splenomegaly may also be noted in cats and dogs with right-sided heart failure.

AUSCULTATION Thoracic auscultation is used to identify normal heart sounds, determine the presence or absence of abnormal sounds, assess heart rhythm and rate, and evaluate pulmonary sounds. Heart sounds are created by turbulent blood flow and associated vibrations in adjacent tissue during the cardiac cycle. Although many of these sounds are too low in frequency and/or intensity to be audible, others can be heard with the stethoscope or even palpated. Heart sounds are classified as transient sounds (those of short duration) and cardiac murmurs (longer sounds occurring during a normally silent part of the cardiac cycle). Cardiac murmurs and transient sounds are described using general characteristics of sound: frequency (pitch), amplitude of vibrations (intensity/loudness), duration, and quality (timbre). Sound quality is affected by the physical characteristics of the vibrating structures. Because many heart sounds are difficult to hear, a cooperative animal and a quiet room are important during auscultation. The animal should be standing, if possible, so that the heart is in its normal position. Panting in dogs is discouraged by holding the animal’s mouth shut. Respiratory noise can be decreased further by placing a finger over one or both nostrils for a short time. Purring in cats may be stopped by holding a finger over one or both nostrils (Fig. 1-6), gently pressing the cricothyroid ligament region with a fingertip, waving an alcohol-soaked cotton ball near the cat’s nose, or turning on a water faucet near the animal. Various other

FIG 1-6â•…

During cardiac auscultation, respiratory noise and purring can be decreased or eliminated by gently placing a finger over one or both nostrils for brief periods of time.

CHAPTER 1â•…â•… Clinical Manifestations of Cardiac Disease

7

artifacts can interfere with auscultation, including respiratory clicks, air movement sounds, shivering, muscle twitching, hair rubbing against the stethoscope, gastrointestinal sounds, and extraneous room noises. The traditional stethoscope has both a stiff, flat diaphragm and a bell on the chestpiece. The diaphragm, when applied firmly to the chest wall, allows better auscultation of higher-frequency heart sounds than those of low frequency. The bell, applied lightly to the chest wall, facilitates auscultation of lower-frequency sounds such as S3 and S4 (see the following section on Gallop Sounds). Stethoscopes with a single-sided chestpiece are designed to function as a diaphragm when used with firm pressure against the skin and as a bell when used with light pressure. Ideally the stethoscope should have short double tubing and comfortable eartips. The binaural eartubes should be angled rostrally to align with the examiner’s ear canals (Fig. 1-7). Both sides of the chest should be carefully auscultated, with special attention to the valve areas (Fig. 1-8). The stethoscope is moved gradually to all areas of the chest. The examiner should concentrate on the various heart sounds, correlating them to the events of the cardiac cycle, and listen for any abnormal sounds in systole and diastole successively. The normal heart sounds (S1 and S2) are used as a framework for timing abnormal sounds. The point of maximal intensity (PMI) of any abnormal sounds should be located. The examiner should focus on cardiac auscultation separately from pulmonary auscultation because full assimilation of sounds from both systems simultaneously is unlikely. Pulmonary auscultation is described further in Chapter 20.

Transient Heart Sounds The heart sounds normally heard in dogs and cats are S1 (associated with closure and tensing of the AV valves and associated structures at the onset of systole) and S2 (associated with closure of the aortic and pulmonic valves following ejection). The diastolic sounds (S3 and S4) are not audible in

FIG 1-7â•…

Note the angulation of the stethoscope binaurals for optimal alignment with the clinician’s ear canals (top of picture is rostral). The flat diaphragm of the chestpiece is facing left, and the concave bell is facing right.

8

PART Iâ•…â•… Cardiovascular System Disorders

Right

Left

P AM

T

FIG 1-8â•…

Approximate locations of various valve areas on chest wall. T, Tricuspid; P, pulmonic; A, aortic; M, mitral.

normal dogs and cats. Fig. 1-9 correlates the hemodynamic events of the cardiac cycle with the ECG and timing of the heart sounds. It is important to understand these events and identify the timing of systole (between S1 and S2) and diastole (after S2 until the next S1) in the animal. The precordial impulse occurs just after S1 (systole), and the arterial pulse occurs between S1 and S2. Sometimes the first (S1) and/or second (S2) heart sounds are altered in intensity. A loud S1 may be heard in dogs and cats with a thin chest wall, high sympathetic tone, tachycardia, systemic arterial hypertension, or shortened PR intervals. A muffled S1 can result from obesity, pericardial effusion, diaphragmatic hernia, dilated cardiomyopathy, hypovolemia/poor ventricular filling, or pleural effusion. A split or sloppy-sounding S1 may be normal, especially in large dogs, or it may result from ventricular premature contractions or an intraventricular conduction delay. The intensity of S2 is increased by pulmonary hypertension (e.g., from heartworm disease, a congenital shunt with Eisenmenger’s physiology, or cor pulmonale). Cardiac arrhythmias often cause variation in the intensity (or even absence) of heart sounds. Normal physiologic splitting of S2 can be heard in some dogs because of variation in stroke volume during the respiratory cycle. During inspiration, increased venous return to the right ventricle tends to delay closure of the pulmonic valve, while reduced filling of the left ventricle accelerates aortic closure. Pathologic splitting of S2 can result from delayed ventricular activation or prolonged right ventricular ejection secondary to ventricular premature beats, right bundle branch block, a ventricular or atrial septal defect, or pulmonary hypertension.

Gallop Sounds The third (S3) and fourth (S4) heart sounds occur during diastole (see Fig. 1-9) and are not normally audible in dogs

IC

Ejection IR

S1

S2

AP

LVP

LAP

LVV

Heart sounds S4

S3

ECG FIG 1-9â•…

Cardiac cycle diagram depicting relationships among great vessel, ventricular and atrial pressures, ventricular volume, heart sounds, and electrical activation. AP, Aortic pressure; ECG, electrocardiogram; IC, isovolumic contraction; IR, isovolumic relaxation; LAP, left atrial pressure; LVP, left ventricular pressure; LVV, left ventricular volume.

and cats. When an S3 or S4 sound is heard, the heart may sound like a galloping horse, hence the term gallop rhythm. This term can be confusing because the presence or absence of an audible S3 or S4 has nothing to do with the heart’s rhythm (i.e., the origin of cardiac activation and the intracardiac conduction process). Gallop sounds are usually heard best with the bell of the stethoscope (or by light pressure applied to a single-sided chestpiece) because they are of lower frequency than S1 and S2. At very fast heart rates, differentiation of S3 from S4 is difficult. If both sounds are present, they may be superimposed, which is called a summation gallop. The S3, also known as an S3 gallop or ventricular gallop, is associated with low-frequency vibrations at the end of the rapid ventricular filling phase. An audible S3 in the dog or cat usually indicates ventricular dilation with myocardial failure. The extra sound can be fairly loud or very subtle and is heard best over the cardiac apex. It may be the only auscultable abnormality in an animal with dilated cardiomyopathy. An S3 gallop may also be audible in dogs with advanced valvular heart disease and congestive failure. The S4 gallop, also called an atrial or presystolic gallop, is associated with low-frequency vibrations induced by blood flow into the ventricles during atrial contraction (just after the P wave of the ECG). An audible S4 in the dog or cat is usually associated with increased ventricular stiffness and hypertrophy, as with hypertrophic cardiomyopathy or hyperthyroidism in cats. A transient S4 gallop of unknown significance is sometimes heard in stressed or anemic cats.

Other Transient Sounds Other brief abnormal sounds are sometimes audible. Systolic clicks are mid-to-late systolic sounds that are usually heard best over the mitral valve area. These sounds have been associated with degenerative valvular disease (endocardiosis), mitral valve prolapse, and congenital mitral dysplasia; a concurrent mitral insufficiency murmur may be present. In dogs with degenerative valvular disease, a mitral click may be the first abnormal sound noted, with a murmur developing over time. An early systolic, high-pitched ejection sound at the left base may occur in animals with valvular pulmonic stenosis or other diseases that cause dilation of a great artery. The sound is thought to arise from either the sudden checking of a fused pulmonic valve or the rapid filling of a dilated vessel during ejection. Rarely, restrictive pericardial disease causes an audible pericardial knock. This diastolic sound is caused by sudden checking of ventricular filling by the restrictive pericardium; its timing is similar to the S3. Cardiac Murmurs Cardiac murmurs are described by their timing within the cardiac cycle (systolic or diastolic, or portions thereof); intensity; PMI on the precordium; radiation over the chest wall; quality; and pitch. Systolic murmurs can occur in early

CHAPTER 1â•…â•… Clinical Manifestations of Cardiac Disease

9

(protosystolic), middle (mesosystolic), or late (telesystolic) systole or throughout systole (holosystolic). Diastolic murÂ� murs generally occur in early diastole (protodiastolic) or throughout diastole (holodiastolic). Murmurs at the end of diastole are termed presystolic. Continuous murmurs begin in systole and extend through S2 into all or part of diastole. Murmur intensity is generally graded on a I to VI scale (Table 1-1). The PMI is usually indicated by the hemithorax (right or left) and intercostal space or valve area where it is located, or by the terms apex or base. Because murmurs can radiate extensively, the entire thorax, thoracic inlet, and carotid artery areas should be auscultated. The pitch and quality of a murmur relate to its frequency and subjective assessment. “Noisy” or “harsh” murmurs contain mixed frequencies. “Musical” murmurs are of essentially one frequency with its overtones. Murmurs are also described by phonocardiographic configuration (Fig. 1-10). A holosystolic (plateau-shaped) murmur begins at the time of S1 and is of fairly uniform

TABLE 1-1â•… Grading of Heart Murmurs GRADE

MURMUR

I

Very soft murmur; heard only in quiet surroundings after prolonged listening

II

Soft murmur but easily heard

III

Moderate-intensity murmur

IV

Loud murmur but no precordial thrill

V

Loud murmur with a palpable precordial thrill

VI

Very loud murmur with a precordial thrill; can be heard with the stethoscope lifted from the chest wall

Holosystolic (plateau, regurgitant) Crescendo-decrescendo (diamond-shaped, ejection) Systolic decrescendo Diastolic decrescendo Continuous (machinery) S1

S2

FIG 1-10â•…

S1

S2

The phonocardiographic shape (configuration) and the timing of different murmurs are illustrated in this diagram.

10

PART Iâ•…â•… Cardiovascular System Disorders

intensity throughout systole. Loud holosystolic murmurs may mask the S1 and S2 sounds. AV valve insufficiency and interventricular septal defects commonly cause this type of murmur because turbulent blood flour occurs throughout ventricular systole. A crescendo-decrescendo or diamond-shaped murmur starts softly, builds intensity in midsystole, and then diminishes; S1 and S2 can usually be heard clearly before and after the murmur. This type is also called an ejection murmur because it occurs during blood ejection, usually because of ventricular outflow obstruction. A decrescendo murmur tapers from its initial intensity over time; it may occur in systole or diastole. Continuous (machinery) murmurs occur throughout systole and diastole. Systolic murmurs.╇ Systolic murmurs can be decrescendo, holosystolic (plateau-shaped), or ejection (crescendodecrescendo) in configuration. It can be difficult to differentiate these by auscultation alone. However, the most important steps toward diagnosis include establishing that a murmur occurs in systole (rather than diastole), determining its PMI, and grading its intensity. Fig. 1-11 depicts the typical PMI of various murmurs over the chest wall. Functional murmurs usually are heard best over the left heartbase. They are usually soft to moderate in intensity and of decrescendo (or crescendo-decrescendo) configuration. Functional murmurs may have no apparent cardiovascular cause (e.g., “innocent” puppy murmurs) or can result from

an altered physiologic state (physiologic murmurs). Innocent puppy murmurs generally disappear by the time the animal is about 6 months old. Physiologic murmurs have been associated with anemia, fever, high sympathetic tone, hyperthyroidism, marked bradycardia, peripheral arteriovenous fistulae, hypoproteinemia, and athletic hearts. Aortic dilation (e.g., with hypertension) and dynamic right ventricular outflow obstruction are other conditions associated with systolic murmurs in cats. The murmur of mitral insufficiency is heard best at the left apex, in the area of the mitral valve. It radiates well dorsally and often to the left base and right chest wall. Mitral insufficiency characteristically causes a plateaushaped murmur (holosystolic timing), but in its early stages the murmur may be protosystolic, tapering to a decrescendo configuration. Occasionally this murmur has a musical or “whooplike” quality. With degenerative mitral valve disease, murmur intensity is usually related to disease severity. Systolic ejection murmurs are most often heard at the left base and are caused by ventricular outflow obstruction, usually from a fixed narrowing (e.g., subaortic or pulmonic valve stenosis) or dynamic muscular obstruction. Ejection murmurs become louder as cardiac output or contractile strength increases. The subaortic stenosis murmur is heard well at the low left base and also at the right base because the murmur radiates up the aortic arch, which curves toward the

Left

Right

TVI

MVI

SAS

SAS

VSD

AS PDA PS

A FIG 1-11â•…

B

The usual point of maximal intensity (PMI) and configuration for murmurs typical of various congenital and acquired causes are depicted on left (A) and right (B) chest walls. AS, Aortic (valvular) stenosis; MVI, mitral valve insufficiency; PDA, patent ductus arteriosus; PS, pulmonic stenosis; SAS, subaortic stenosis; TVI, tricuspid valve insufficiency; VSD, ventricular septal defect. (From Bonagura JD, Berkwitt L: Cardiovascular and pulmonary disorders. In Fenner W, editor: Quick reference to veterinary medicine, ed 2, Philadelphia, 1991, JB Lippincott.)

right. This murmur also radiates up the carotid arteries and occasionally can be heard on the calvarium. Soft (grade I-II/ VI), nonpathologic (functional) systolic ejection murmurs are common in sight hounds, Boxers, and certain other large breeds; these can be related to a large stroke volume, as well as breed-related left ventricular outflow tract characteristics. The murmur of pulmonic stenosis is best heard high at the left base. Relative pulmonic stenosis occurs when flow through a structurally normal valve is abnormally increased (e.g., with a large left-to-right shunting atrial or ventricular septal defect). Most murmurs heard on the right chest wall are holosystolic, plateau-shaped murmurs, except for the subaortic stenosis murmur (above). The tricuspid insufficiency murmur is loudest at the right apex over the tricuspid valve. Its pitch or quality may be noticeably different from a concurrent mitral insufficiency murmur, and it often is accompanied by jugular pulsations. Ventricular septal defects also cause holosystolic murmurs. The PMI is usually at the right sternal border, reflecting the direction of the intracardiac shunt. A large ventricular septal defect may also cause the murmur of relative pulmonic stenosis. In apparently healthy cats, the prevalence of systolic murmurs has been estimated at 15% to 34%. Although many of these appear related to subclinical structural cardiac disease, presence of a murmur alone was not a highly sensitive predictor of cardiomyopathy in one study. The murmur PMI is often in the parasternal region and associated with dynamic left (or right) ventricular outflow obstruction. Presence of left ventricular or septal hyper� trophy is variable. Congenital cardiac malformation is another potential cause. However, echocardiography is recommended to screen for structural disease in cats with a murmur. Diastolic murmurs.╇ Diastolic murmurs are uncommon in dogs and cats. Aortic insufficiency from infective endocarditis is the most common cause, although congenital malformation or degenerative aortic valve disease occasionally occurs. Clinically relevant pulmonic insufficiency is rare but would be more likely in the face of pulmonary hypertension. These diastolic murmurs begin at the time of S2 and are heard best at the left base. They are decrescendo in configuration and extend a variable time into diastole, depending on the pressure difference between the associated great vessel and ventricle. Some aortic insufficiency murmurs have a musical quality. Continuous murmurs.╇ As implied by the name, continuous (machinery) murmurs occur throughout the cardiac cycle. They indicate that a substantial pressure gradient exists continuously between two connecting areas (vessels). The murmur is not interrupted at the time of S2; instead, its intensity is often greater at that time. The murmur becomes softer toward the end of diastole, and at slow heart rates it can become inaudible. Patent ductus arteriosus (PDA) is by far the most common cause of a continuous murmur. The PDA murmur is loudest high at the left base above the pulmonic valve area; it tends to radiate

CHAPTER 1â•…â•… Clinical Manifestations of Cardiac Disease

11

cranially, ventrally, and to the right. The systolic component is usually louder and heard well all over the chest. The diastolic component is more localized to the left base in many cases. The diastolic component (and the correct diagnosis) may be missed if only the cardiac apical area is auscultated. Continuous murmurs can be confused with concurrent systolic ejection and diastolic decrescendo murmurs. However, with these so-called “to-and-fro” murmurs, the ejection (systolic) component tapers in late systole and the S2 can be heard as a distinct sound. The most common cause of to-and-fro murmurs is the combination of subaortic stenosis with aortic insufficiency. Rarely, stenosis and insufficiency of the pulmonic valve cause this type of murmur. Likewise, both a holosystolic and a diastolic decrescendo murmur can occur together on occasion (e.g., with a ventricular septal defect and aortic insufficiency from loss of aortic root support). This also is not considered a true “continuous” murmur. Suggested Readings Côté E et al: Assessment of the prevalence of heart murmurs in overtly healthy cats, J Am Vet Med Assoc 225:384, 2004. Dirven MJ et al: Cause of heart murmurs in 57 apparently healthy cats, Tijdschr Diergeneeskd 135:840, 2010. Fabrizio F et al: Left basilar systolic murmur in retired racing greyhounds, J Vet Intern Med 20:78, 2006. Fang JC, O’Gara PT: The history and physical examination. In Libby P, Bonow RO, Mann DL, Zipes DP, editors: Braunwald’s heart disease: a textbook of cardiovascular medicine, ed 8, Philadelphia, 2008, WB Saunders, p 125. Forney S: Dyspnea and tachypnea. In Ettinger SJ, Feldman EC, editors: Textbook of veterinary internal medicine, ed 7, Philadelphia, 2010, WB Saunders, p 253. Häggström J et al: Heart sounds and murmurs: changes related to severity of chronic valvular disease in the Cavalier King Charles Spaniel, J Vet Intern Med 9:75, 1995. Hamlin RL: Normal cardiovascular physiology. In Fox PR, Sisson DD, Moise NS, editors: Canine and feline cardiology, ed 2, New York, 1999, WB Saunders, p 25. Hoglund K et al: A prospective study of systolic ejection murmurs and left ventricular outflow tract in boxers, J Small Anim Pract 52:11, 2011. Koplitz SL et al: Echocardiographic assessment of the left ventricular outflow tract in the Boxer, J Vet Intern Med 20:904, 2006. Paige CF et al: Prevalence of cardiomyopathy in apparently healthy cats, J Am Vet Med Assoc 234:1398, 2009. Pedersen HD et al: Auscultation in mild mitral regurgitation in dogs: observer variation, effects of physical maneuvers, and agreement with color Doppler echocardiography and phonocardiography, J Vet Intern Med 13:56, 1999. Prosek R: Abnormal heart sounds and heart murmurs. In Ettinger SJ, Feldman EC, editors: Textbook of veterinary internal medicine, ed 7, Philadelphia, 2010, WB Saunders, p 259. Rishniw M, Thomas WP: Dynamic right ventricular outflow obstruction: a new cause of systolic murmurs in cats, J Vet Intern Med 16:547, 2002.

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Tidholm A: Pulse alterations. In Ettinger SJ, Feldman EC, editors: Textbook of veterinary internal medicine, ed 7, Philadelphia, 2010, WB Saunders, p 264. Wagner T et al: Comparison of auscultatory and echocardiographic findings in healthy adult cats, J Vet Cardiol 12:171, 2010. Ware WA: The cardiovascular examination. In Ware WA: Cardiovascular disease in small animal medicine, London, 2011, Manson Publishing, p 26.

Ware WA: Syncope or intermittent collapse. In Ware WA: Cardiovascular disease in small animal medicine, London, 2011, Manson Publishing, p 139. Yee K: Syncope. In Ettinger SJ, Feldman EC, editors: Textbook of veterinary internal medicine, ed 7, Philadelphia, 2010, WB Saunders, p 275.

C H A P T E R

2â•…

Diagnostic Tests for the Cardiovascular System

CARDIAC RADIOGRAPHY Thoracic radiographs are important for assessing overall heart size and shape, pulmonary vessels, and lung parenchyma, as well as surrounding structures. Both lateral and dorsoventral (DV) or ventrodorsal (VD) views should be obtained. On lateral view, the ribs should be aligned with each other dorsally. On DV or VD views, the sternum, vertebral bodies, and dorsal spinous processes should be superimposed. Consistency in views chosen is important because slight changes in cardiac shadow appearance occur with different positions. For example, the heart tends to look more elongated on VD view in comparison to its appearance on DV view. In general, the DV view yields better definition of the hilar area and caudal pulmonary arteries. High kilovoltage peak (kVp) and low milliampere (mA) radiographic technique is recommended for better resolution among soft tissue structures. Exposure is ideally made at the time of peak inspiration. On expiration, the lungs appear denser, the heart is relatively larger, the diaphragm may overlap the caudal heart border, and pulmonary vessels are poorly delineated. Use of exposure times short enough to minimize respiratory motion and proper, straight (not obliquely tilted) patient positioning are important for accurate interpretation of cardiac shape and size and pulmonary parenchyma. The radiographs should be examined systematically, beginning with assessment of the technique, patient positioning, presence of artifacts, and phase of respiration during exposure. Chest conformation should be considered when evaluating cardiac size and shape in dogs because normal cardiac appearance may vary from breed to breed. The cardiac shadow in dogs with a round or barrel-shaped chest has greater sternal contact on lateral view and an oval shape on DV or VD view. In contrast, the heart has an upright, elongated appearance on lateral view and a small, almost circular shape on DV or VD view in narrow- and deepchested dogs. Because of variations in chest conformation and the influences of respiration, cardiac cycle, and positioning on the apparent size of the cardiac shadow, mild cardiomegaly may be difficult to identify. Also, excess pericardial

fat may mimic the appearance of cardiomegaly. The cardiac shadow in puppies normally appears slightly large relative to thoracic size compared with that of adult dogs. The vertebral heart score (VHS) can be used as a means of quantifying the presence and degree of cardiomegaly in dogs and cats, because there is good correlation between body length and heart size regardless of chest conformation. Measurements for the VHS are obtained using the lateral view (Fig. 2-1) in adult dogs and puppies. The cardiac long axis is measured from the ventral border of the left mainstem bronchus to the most ventral aspect of the cardiac apex. This same distance is compared with the thoracic spine beginning at the cranial edge of T4; length is estimated to the nearest 0.1 vertebra. The maximum perpendicular short axis is measured in the central third of the heart shadow; the short axis is also measured in number of vertebrae (to the nearest 0.1) beginning with T4. Both measurements are added to yield the VHS. A VHS between 8.5 and 10.5 vertebrae (v) is considered normal for most breeds. However, some variation exists among breeds. In dogs with a short thorax (e.g., Miniature Schnauzer) an upper limit of 11╯v may be normal. The VHS in normal Greyhounds, Whippets, and some other breeds such as the Labrador Retriever may normally exceed 11╯v, and the VHS range in normal Boxers is thought to extend to 12.6╯v. In contrast, an upper limit of 9.5╯v may be normal in dogs with a long thorax (e.g., Dachshund). The cardiac silhouette on lateral view in cats is aligned more parallel to the sternum than in dogs; this parallel positioning may be accentuated in old cats. Radiographic positioning can influence the relative size, shape, and position of the heart because the feline thorax is so flexible. On lateral view the normal cat heart is less than or equal to two intercostal spaces (ICS) in width and less than 70% of the height of the thorax. On DV view the heart is normally no more than one half the width of the thorax. Measurement of VHS is useful in cats as well. From lateral radiographs in cats, mean VHS in normal cats is 7.3 to 7.5 vertebrae (range 6.7-8.1╯v). The mean short axis cardiac dimension taken from DV or VD view, compared with the thoracic spine beginning at T4 on lateral view, was 3.4 to 3.5 vertebrae. An upper limit of 13

14

PART Iâ•…â•… Cardiovascular System Disorders

BOX 2-1â•… Common Differential Diagnoses for Radiographic Signs of Cardiomegaly Generalized Enlargement of the Cardiac Shadow

L

T4

Dilated cardiomyopathy Mitral and tricuspid insufficiency Pericardial effusion Peritoneopericardial diaphragmatic hernia Tricuspid dysplasia Ventricular or atrial septal defect Patent ductus arteriosus

S

T

S L

FIG 2-1â•…

Diagram illustrating the vertebral heart score (VHS) measurement method using the lateral chest radiograph. The long-axis (L) and short-axis (S) heart dimensions are transposed onto the vertebral column and recorded as the number of vertebrae beginning with the cranial edge of T4. These values are added to obtain the VHS. In this example, L = 5.8 v, S = 4.6 v; therefore VHS = 10.4 v. T, Trachea. (Modified from Buchanan JW, Bücheler J: Vertebral scale system to measure canine heart size in radiographs, J Am Vet Med Assoc 206:194, 1995.)

Left Atrial Enlargement

Early mitral insufficiency Hypertrophic cardiomyopathy Early dilated cardiomyopathy (especially Doberman Pinschers) (Sub)aortic stenosis Left Atrial and Ventricular Enlargement

Dilated cardiomyopathy Hypertrophic cardiomyopathy Mitral insufficiency Aortic insufficiency Ventricular septal defect Patent ductus arteriosus (Sub)aortic stenosis Systemic hypertension Hyperthyroidism Right Atrial and Ventricular Enlargement

normal of 4 vertebrae was identified. In kittens, as in puppies, the relative size of the heart compared with that of the thorax is larger than in adults because of smaller lung volume. An abnormally small heart shadow (microcardia) results from reduced venous return (e.g., from shock or hypovolemia). The apex appears more pointed and may be elevated from the sternum. Radiographic suggestion of abnormal cardiac size or shape should be considered within the context of the physical examination and other test findings.

CARDIOMEGALY Generalized enlargement of the heart shadow on plain thoracic radiographs may indicate true cardiomegaly or pericardial distention. With cardiac enlargement, the contours of different chambers are usually still evident, although massive right ventricular (RV) and right atrial (RA) dilation can cause a round cardiac silhouette. Fluid, fat, or viscera within the pericardium tends to obliterate these contours and create a globoid heart shadow. Common differential diagnoses for cardiac enlargement patterns are listed in Box 2-1. CARDIAC CHAMBER ENLARGEMENT PATTERNS Most diseases that cause cardiac dilation or hypertrophy affect two or more chambers. For example, mitral

Advanced heartworm disease Chronic, severe pulmonary disease Tricuspid insufficiency Pulmonic stenosis Tetralogy of Fallot Atrial septal defect Pulmonary hypertension (with or without reversed shunting congenital defect) Mass lesion within the right heart

insufficiency leads to left ventricular (LV) and left atrial (LA) enlargement; pulmonic stenosis causes RV enlargement, a main pulmonary artery bulge, and often RA dilation. For descriptive purposes, however, specific chamber and great vessel enlargements are discussed later. Fig. 2-2 illustrates various patterns of chamber enlargement.

Left Atrium The left atrium (LA) is the most dorsocaudal chamber of the heart, although its auricular appendage extends to the left and craniad. An enlarged LA bulges dorsally and caudally on lateral view, elevating the left and sometimes right mainstem bronchi. Compression of the left mainstem bronchus occurs in patients with severe LA enlargement. In cats the caudal heart border is normally quite straight on lateral view; LA

15

CHAPTER 2â•…â•… Diagnostic Tests for the Cardiovascular System

enlargement causes subtle to marked convexity of the dorsocaudal heart border, with elevation of the mainstem bronchi. On DV or VD view, the mainstem bronchi are pushed laterally and curve slightly around a markedly enlarged LA (sometimes referred to as the “bowed-legged cowboy sign”). A bulge in the 2- to 3-o’clock position of the

cardiac silhouette is common in cats and dogs with concurrent left auricular enlargement. Massive LA enlargement sometimes appears as a large, rounded soft tissue opacity superimposed over the LV apical area on DV (VD) view (Fig. 2-3). LA size is influenced by the pressure or volume load imposed, as well as by its duration. For example, mitral Dorsal (LV)

Right

Left

MPA

MPA

Ao RA

LA

Ao RAu

LAu

LA

RV

RV

LV

A

B

FIG 2-2â•…

Common radiographic enlargement patterns. Diagrams indicating direction of enlargement of cardiac chambers and great vessels in the dorsoventral (A) and lateral (B) views. Ao, Aorta (descending); LA, left atrium; LAu, left auricle; LV, left ventricle; MPA, main pulmonary artery; RA, right atrium; RAu, right auricle; RV, right ventricle. (Modified from Bonagura JD, Berkwitt L: Cardiovascular and pulmonary disorders. In Fenner W, editor: Quick reference to veterinary medicine, ed 3, Philadelphia, 2000, JB Lippincott.)

A

B FIG 2-3â•…

Lateral (A) and dorsoventral (B) views from a dog with chronic mitral regurgitation. Marked left ventricular and atrial enlargement are evident. Dorsal displacement of the carina is seen in A; the caudal edge of the left atrium (arrows), superimposed over the ventricular shadow, and a prominent left auricular bulge (arrowhead) are seen in B.

LV

16

PART Iâ•…â•… Cardiovascular System Disorders

regurgitation of slowly increasing severity may cause massive LA enlargement without pulmonary edema if chamber dilation occurs slowly at relatively low pressures. Conversely, rupture of chordae tendinae can acutely cause severe valvular regurgitation; pulmonary edema with relatively normal LA size can occur because of a rapid and marked atrial pressure increase.

Left Ventricle LV enlargement is manifested on lateral view by a taller cardiac silhouette with elevation of the carina and caudal vena cava. The caudal heart border becomes convex, but cardiac apical sternal contact is maintained. On DV/VD view, rounding and enlargement occur in the 2- to 5-o’clock position. Some cats with hypertrophic cardiomyopathy maintain the apical point; concurrent atrial enlargement creates the classic “valentine-shaped” heart. Right Atrium RA enlargement expands the cranial heart border and widens the cardiac silhouette on lateral view. Tracheal elevation may occur over the cranial portion of the heart shadow. Bulging of the cardiac shadow on DV/VD view occurs in the 9- to 11-o’clock position. The right atrium (RA) is largely superimposed over the right ventricle (RV), so differentiation from RV enlargement is difficult; however, concurrent enlargement of both chambers is common. Right Ventricle RV enlargement (dilation or hypertrophy) usually causes increased convexity of the cranioventral heart border and elevation of the trachea over the cranial heart border on lateral view. With severe RV enlargement and relatively normal left heart size, the apex is elevated from the sternum. The carina and caudal vena cava are also elevated. The degree of sternal contact of the heart shadow is not, by itself, a reliable sign of RV enlargement because of breed variation in chest conformation. On DV/VD view, the heart tends to take on a reverse-D configuration, especially without concurrent left-sided enlargement. The apex may be shifted leftward, and the right heart border bulges to the right. INTRATHORACIC BLOOD VESSELS Great Vessels The aorta and main pulmonary artery dilate in response to chronic arterial hypertension or increased turbulence (poststenotic dilation). Subaortic stenosis causes dilation of the ascending aorta. Because of its location within the mediastinum, dilation here is not easily detected, although widening and increased opacity of the dorsocranial heart shadow may be observed. Patent ductus arteriosus causes a localized dilation in the descending aorta just caudal to the arch, where the ductus exits; this “ductus bump” is seen on DV or VD view. A prominent aortic arch is more common in cats than dogs. The thoracic aorta of older cats also may have an undulating appearance. Systemic hypertension should be a consideration in these cases.

Severe dilation of the main pulmonary trunk (usually associated with pulmonic stenosis or pulmonary hypertension) can be seen as a bulge superimposed over the trachea on lateral radiograph. On DV view in the dog, main pulmonary trunk enlargement causes a bulge in the 1- to 2-o’clock position. In the cat the main pulmonary trunk is slightly more medial and is usually obscured within the mediastinum. The caudal vena cava (CaVC) normally angles cranioventrally from the diaphragm to the heart. The width of the CaVC is approximately that of the descending thoracic aorta, although its size changes with respiration. The CaVCcardiac junction is pushed dorsally with enlargement of either ventricle. Persistent widening of the CaVC could indicate RV failure, cardiac tamponade, pericardial constriction, or other obstruction to right heart inflow. The following comparative findings suggest abnormal CaVC distention: CaVC/aortic diameter (at same ICS) greater than 1.5; CaVC/ length of the thoracic vertebra directly above the tracheal bifurcation greater than 1.3; and CaVC/width of right fourth rib (just ventral to the spine) greater than 3.5. A thin CaVC can indicate hypovolemia, poor venous return, or pulmonary overinflation.

Lobar Pulmonary Vessels Pulmonary arteries are located dorsal and lateral to their accompanying veins and bronchi. In other words, pulmonary veins are “ventral and central.” On lateral view, the cranial lobar vessels in the nondependent (“up-side”) lung are more ventral and larger than those in the dependent lung. The width of the cranial lobar vessels is measured where they cross the fourth rib in dogs or at the cranial heart border (fourth to fifth rib) in cats. These vessels are normally 0.5 to 1 times the diameter of the proximal one third of the fourth rib. The DV view is best for evaluating the caudal pulmonary vessels. The caudal lobar vessels should be 0.5 to 1 times the width of the ninth (dogs) or tenth (cats) rib at the point of intersection. Four pulmonary vascular patterns are usually described: overcirculation, undercirculation, prominent pulmonary arteries, and prominent pulmonary veins. An overcirculation pattern occurs when the lungs are hyperperfused, as in left-to-right shunts, overhydration, and other hyperdynamic states. Pulmonary arteries and veins are both prominent; the increased perfusion also generally increases lung opacity. Pulmonary undercirculation is characterized by thin pulmonary arteries and veins, along with increased pulmonary lucency. Severe dehydration, hypovolemia, obstruction to RV inflow, right-sided congestive heart failure, and tetralogy of Fallot can cause this pattern. Some animals with pulmonic stenosis appear to have pulmonary undercirculation. Overinflation of the lungs or overexposure of radiographs also minimizes the appearance of pulmonary vessels. Pulmonary arteries larger than their accompanying veins indicate pulmonary arterial hypertension. The pulmonary arteries become dilated, tortuous, and blunted, and

visualization of the terminal portions is lost. Heartworm disease often causes this pulmonary vascular pattern, in addition to patchy to diffuse interstitial pulmonary infiltrates. Prominent pulmonary veins are a sign of pulmonary venous congestion, usually from left-sided congestive heart failure. On lateral view, the cranial lobar veins are larger and denser than their accompanying arteries and may sag ventrally. Dilated, tortuous pulmonary veins may be seen entering the dorsocaudal aspect of the enlarged LA in dogs and cats with chronic pulmonary venous hypertension. But pulmonary venous dilation is not always visualized in patients with left-sided heart failure. In cats with acute cardiogenic pulmonary edema, enlargement of both pulmonary veins and arteries can be seen.

PATTERNS OF PULMONARY EDEMA Pulmonary interstitial fluid accumulation increases pulmonary opacity. Pulmonary vessels appear ill-defined, and bronchial walls look thick as interstitial fluid accumulates around vessels and bronchi. As pulmonary edema worsens, areas of fluffy or mottled fluid opacity progressively become more confluent. Alveolar edema causes greater opacity in the lung fields and obscures vessels and outer bronchial walls. The air-filled bronchi appear as lucent, branching lines surrounded by fluid density (air bronchograms). Interstitial and alveolar patterns of pulmonary infiltration can be caused by many pulmonary diseases, as well as by cardiogenic edema. The distribution of these pulmonary infiltrates is important, especially in dogs. Cardiogenic pulmonary edema in dogs is classically located in dorsal and perihilar areas and is often bilaterally symmetric. Nevertheless, some dogs develop an asymmetric or concurrent ventral distribution of cardiogenic edema. The distribution of cardiogenic edema in cats is usually uneven and patchy, although some cats have a diffuse, uniform pattern. The infiltrates can be distributed throughout the lung fields or concentrated in ventral, middle, or caudal zones. Both the radiographic technique and the phase of respiration influence the apparent severity of interstitial infiltrates. Other abnormalities on thoracic radiographs are discussed in Chapter 20.

CHAPTER 2â•…â•… Diagnostic Tests for the Cardiovascular System

NORMAL ECG WAVEFORMS The normal cardiac rhythm originates in the sinoatrial node. Specialized conduction pathways facilitate activation of the atria and ventricles (Fig. 2-4). The ECG waveforms, P-QRST, are generated as heart muscle is depolarized and then repolarized (Fig. 2-5 and Table 2-1). The QRS complex, as a AV node

SA node

LA

Left bundle branch

Bundle of His RV

Right bundle branch

FIG 2-4â•…

Schematic of cardiac conduction system. AV, Atrioventricular; LA, left atrium; RV, right ventricle; SA, sinoatrial. (Modified from Tilley LE: Essentials of canine and feline electrocardiography, ed 3, Philadelphia, 1992, Lea & Febiger.) 0.1 sec

0.02 sec

R

0.5 mV

0.1 mV

P S-T

Q

ELECTROCARDIOGRAPHY The electrocardiogram (ECG) graphically represents the electrical depolarization and repolarization of cardiac muscle. The ECG provides information on heart rate, rhythm, and intracardiac conduction; it may also suggest specific chamber enlargement, myocardial disease, ischemia, pericardial disease, certain electrolyte imbalances, and some drug toxicities. However, the ECG alone cannot be used to identify the presence of congestive heart failure, assess the strength (or even presence) of cardiac contractions, or predict whether the animal will survive an anesthetic or surgical procedure.

17

S

QRS

P-R interval FIG 2-5â•…

Baseline

T

Q-T interval

Normal canine P-QRS-T complex in lead II. Paper speed is 50╯mm/sec; calibration is standard (1╯cm = 1╯mV). Time intervals (seconds) are measured from left to right; waveform amplitudes (millivolts) are measured as positive (upward) or negative (downward) motion from baseline. (From Tilley LE: Essentials of canine and feline electrocardiography, ed 3, Philadelphia, 1992, Lea & Febiger.)

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PART Iâ•…â•… Cardiovascular System Disorders

TABLE 2-1â•… Normal Cardiac Waveforms WAVEFORM

EVENT

P

Activation of atrial muscle; normally is positive in leads II and aVF

PR interval

Time from onset of atrial muscle activation, through conduction over the AV node, bundle of His, and Purkinje fibers; also called PQ interval

QRS complex

Activation of ventricular muscle; by definition, Q is the first negative deflection (if present), R the first positive deflection, and S is the negative deflection after the R wave

J point

End of the QRS complex; junction of QRS and ST segment

ST segment

Represents the period between ventricular depolarization and repolarization (correlates with phase 2 of the action potential)

T wave

Ventricular muscle repolarization

QT interval

Total time of ventricular depolarization and repolarization

AV, Atrioventricular.

representation of ventricular muscle electrical activation, does not necessarily have individual Q, R, and S wave components (or variations thereof). The configuration of the QRS complex depends on the lead being recorded, as well as the animal’s intraventricular conduction characteristics.

LEAD SYSTEMS Various leads are used to evaluate the cardiac activation process. The orientation of a lead with respect to the heart is called the lead axis. Each lead has direction and polarity. If the myocardial depolarization or repolarization wave travels parallel to the lead axis, a relatively large deflection will be recorded in that lead. As the angle between the lead axis and the orientation of the activation wave increases toward 90 degrees, the ECG deflection for that lead becomes smaller; it becomes isoelectric when the activation wave is perpendicular to the lead axis. Each lead has a positive and a negative pole or direction. A positive deflection will be recorded in a lead if the cardiac activation wave travels toward the positive pole (electrode) of that lead. If the wave of depolarization travels away from the positive pole, a negative deflection will be recorded in that ECG lead. Both bipolar and unipolar ECG leads are used clinically. A bipolar lead records electrical potential differences between two electrodes on the body surface; the lead axis is oriented between these two points. (Augmented) unipolar leads have a recording (positive) electrode on the body surface. The negative

pole of unipolar leads is formed by “Wilson’s central terminal” (V), which is an average of all other electrodes and is analogous to zero. The standard limb lead system records cardiac electrical activity in the frontal plane (as depicted by a DV/VD radiograph). In this plane, left-to-right and cranial-to-caudal currents are recorded. Fig. 2-6 depicts the six standard frontal leads (hexaxial lead system) overlying the cardiac ventricles. Unipolar chest (precordial) leads “view” the heart from the transverse plane (Fig. 2-7). Box 2-2 lists common ECG lead systems.

APPROACH TO ECG INTERPRETATION Routine ECG recording is usually done with the animal placed in right lateral recumbency on a nonconducting surface. The proximal limbs are parallel to each other and perpendicular to the torso. Other body positions may change various waveform amplitudes and affect the calculated mean electrical axis (MEA). However, if only heart rate and rhythm are desired, any recording position can be used. Front limb electrodes are placed at the elbows or slightly below, not touching the chest wall or each other. Rear limb electrodes are placed at the stifles or hocks. With alligator clip or button/ plate electrodes, copious ECG paste or (less ideally) alcohol is used to ensure good contact. Communication between two electrodes via a bridge of paste or alcohol or by physical contact should be avoided. The animal is gently restrained in position to minimize movement artifacts. A relaxed and quiet patient produces a better quality tracing. Holding the mouth shut to discourage panting or placing a hand on the chest of a trembling animal may be helpful. A good ECG recording produces minimal artifact from patient movement, no electrical interference, and a clean baseline. The ECG complexes should be centered and totally contained within the background gridwork so that neither the top nor bottom of the QRS complex is clipped off. If the complexes are too large to fit entirely within the grid, the calibration should be adjusted (e.g., from standard [1╯cm = 1╯mV] to 1/2 standard [0.5╯cm = 1╯mV]). The calibration used during the recording must be known in order to accurately measure waveform amplitude. A calibration square wave (1╯mV amplitude) can be inscribed manually during recording if this is not done automatically. The paper or digital recording speed and lead(s) used also must be evident for interpretation. A consistent approach to ECG interpretation is recommended. First the recording speed, lead(s) used, and calibration are identified. Then the heart rate, heart rhythm, and MEA are determined. Finally, individual waveforms are measured. The heart rate is the number of complexes (or beats) per minute. This can be calculated by counting the number of complexes in 3 or 6 seconds and then multiplying by 20 or 10, respectively. If the heart rhythm is regular, 3000 divided by the number of small boxes (at paper/trace speed 50╯mm/sec) between successive RR intervals equals the instantaneous heart rate. Because variations in heart rate are so common (in dogs especially), determining an estimated

19

CHAPTER 2â•…â•… Diagnostic Tests for the Cardiovascular System

–90°

aVR –1 50 °

0° aVL

±180 °

I

+1 20 °

+1 20 ° III

B

aVF

A

+3

CAUDAL +6

II

+90°

° 50 +1

+6

III

LEFT

±180 °

+3

CAUDAL

0° aVL

–3

RIGHT

LEFT

° 50 +1

aVR –1 50 °

–3

RIGHT

–6

–6

° 20 –1

° 20 –1

–90°

+90°

II

aVF

FIG 2-6â•…

Frontal lead system: diagrams of six frontal leads over schematic of left and right ventricles within the thorax. Circular field is used for determining direction and magnitude of cardiac electrical activation. Each lead is labeled at its positive pole. Shaded area represents normal range for mean electrical axis. A, Dog. B, Cat. V10

BOX 2-2â•… Small Animal Electrocardiographic Lead Systems Standard Bipolar Limb Leads

Right

Left

I RA (−) compared with LA (+) II RA (−) compared with LL (+) III LA (−) compared with LL (+) Augmented Unipolar Limb Leads

V4 (CV6LU)

aVR RA (+) compared with average of LA and LL (−) aVL LA (+) compared with average of RA and LL (−) aVF LL (+) compared with average of RA and LA (−) Unipolar Chest Leads

rV2 (CV5RL)

V2 (CV6LL)

FIG 2-7â•…

Commonly used chest leads seen from cross-sectional view. CV5RL is located at right edge of the sternum in fifth intercostal space (ICS), CV6LL is near sternum at sixth ICS, CV6LU is at costochondral junction at sixth ICS, and V10 is located near seventh dorsal spinous process.

heart rate over several seconds is usually more accurate and practical than calculating an instantaneous heart rate. Heart rhythm is assessed by scanning the entire ECG recording for irregularities and identifying individual waveforms. The presence and pattern of P waves and QRS-T complexes are determined. The relationship between the

V1, rV2 (CV5RL) Fifth right ICS near sternum V2 (CV6LL) Sixth left ICS near sternum V3 Sixth left ICS, equidistant between V2 and V4 V4 (CV6LU) Sixth left ICS near costochondral junction V5 and V6 Spaced as for V3 to V4, continuing dorsally in sixth left ICS V10 Over dorsal spinous process of seventh thoracic vertebra Orthogonal Leads

X Lead I (right to left) in the frontal plane Y Lead aVF (cranial to caudal) in the midsagittal plane Z Lead V10 (ventral to dorsal) in the transverse plane ICS, Intercostal space; LA, left arm; LL, left leg; RA, right arm.

I

20

PART Iâ•…â•… Cardiovascular System Disorders

P waves and QRS-Ts is then evaluated. Calipers are often useful for evaluating the regularity and interrelationships of the waveforms. Estimation of MEA is described on page 28. Individual waveforms and intervals are usually measured using lead II. Amplitudes are recorded in millivolts and durations in seconds (or msec). Only one thickness of the inscribed pen/trace line should be included for each

measurement. At 25╯mm/sec recording speed, each small (1╯mm) box on the ECG gridwork is 0.04 second in duration (from left to right). At 50╯mm/sec recording speed, each small box equals 0.02 second. A deflection from baseline (up or down) of 10 small boxes (1╯cm) equals 1╯mV at standard calibration (0.1╯mV per small box). ECG reference ranges for cats and dogs (Table 2-2) are representative of

TABLE 2-2â•… Normal Electrocardiographic Reference Ranges for Dogs and Cats DOGS

CATS

Heart Rate

70-160 beats/min (adults)* to 220 beats/min (puppies)

120-240 beats/min

Mean Electrical Axis (Frontal Plane)

+40 to +100 degrees

0 to +160 degrees

Measurements (Lead II) P-wave duration (maximum)

0.04╯sec (0.05╯sec, giant breeds)

0.035-0.04╯sec

P-wave height (maximum)

0.4╯mV

0.2╯mV

PR interval

0.06-0.13╯sec

0.05-0.09╯sec

QRS complex duration (maximum)

0.05╯sec (small breeds) 0.06╯sec (large breeds)

0.04╯sec

R-wave height (maximum)

2.5╯mV (small breeds) 3╯mV (large breeds)†

0.9╯mV in any lead; QRS total in any lead < 1.2╯mV

ST segment deviation

100 beats/min). The QRS to QRS (RR) interval is most often regular, although some variation can occur. Nonconducted sinus P waves may be superimposed on or between the ventricular complexes, although they are unrelated to the VPCs because the AV node and/or ventricles are in the refractory period (physiologic AV dissociation). The term capture beat refers to the successful conduction of a

CHAPTER 2â•…â•… Diagnostic Tests for the Cardiovascular System

sinus P wave into the ventricles uninterrupted by another VPC (i.e., the sinus node has “recaptured” the ventricles). If the normal ventricular activation sequence is interrupted by a VPC, a “fusion” complex can result. A fusion complex represents a melding of the normal QRS configuration and that of the VPC (see Fig. 2-10, E). Fusion complexes are often observed at the onset or end of a paroxysm of ventricular tachycardia; they are preceded by a P wave and shortened PR interval. Identification of P waves (whether conducted or not) or fusion complexes helps in differentiating ventricular tachycardia from SVT with abnormal (aberrant) intraventricular conduction. Polymorphic ventricular tachycardia is characterized by QRS complexes that vary in size, polarity, and often rate; sometimes the QRS configuration appears as if it were rotating around the isoelectric baseline. Torsades de pointes is a specific form of polymorphic ventricular tachycardia associated with Q-T interval prolongation.

Accelerated Ventricular Rhythm Also called idioventricular tachycardia, accelerated ventricular rhythm is a ventricular-origin rhythm with a rate of about 60 to 100 beats/min in the dog (perhaps somewhat faster in the cat). Because the rate is slower than true ventricular tachycardia, it is usually a less serious rhythm disturbance. An accelerated ventricular rhythm may appear intermittently during sinus arrhythmia, as the sinus rate decreases; the ventricular rhythm is often suppressed as the sinus rate increases. This is common in dogs recovering from motor vehicle trauma. Often this rhythm disturbance has no deleterious effects, although it could progress to ventricular tachycardia, especially in clinically unstable patients.

FIG 2-11â•…

A

B

25

Atrial fibrillation. A, Uncontrolled atrial fibrillation (heart rate 220 beats/min) in a Doberman Pinscher with dilated cardiomyopathy (lead II, 25╯mm/sec). B, Slower ventricular response rate after therapy in a different Doberman Pinscher with dilated cardiomyopathy showing baseline fibrillation waves. Note lack of P waves and irregular RR intervals. Eighth complex from left superimposed on calibration mark. Lead II, 25╯mm/sec.

26

PART Iâ•…â•… Cardiovascular System Disorders

Ventricular Fibrillation Ventricular fibrillation is a lethal rhythm that is characterized by multiple reentrant circuits causing chaotic electrical activity in the ventricles; the ECG consists of an irregularly undulating baseline (Fig. 2-12). The ventricles cannot function effectively as a pump because the chaotic electrical activation produces incoordinated mechanical activation. Ventricular flutter, which appears as rapid sine-wave activity on the ECG, may precede fibrillation. “Course” ventricular fibrillation (VF) has larger ECG oscillations than “fine” VF. Escape Complexes Ventricular asystole is the absence of ventricular electrical (and mechanical) activity. Escape complexes and escape rhythms are protective mechanisms. An escape complex occurs after a pause in the dominant (usually sinus) rhythm. If the dominant rhythm does not resume, the escape focus continues to discharge at its own intrinsic rate. Escape rhythms are usually regular. Escape activity originates from automatic cells within the atria, the AV junction, or the ventricles (see Fig. 2-10, G). Ventricular escape rhythms (idioventricular rhythms) usually have an intrinsic rate of less than 40 to 50 beats/min in the dog and 100 beats/min in the cat, although higher ventricular escape rates can occur. Junctional escape rhythms usually range from 40 to 60 beats/min in the dog, with a faster rate expected in the cat. It is important to differentiate escape from premature complexes. Escape activity should never be suppressed with antiarrhythmic drugs. CONDUCTION DISTURBANCES Abnormal impulse conduction within the atria can occur at several sites. Sinoatrial (SA) block prevents impulse transmission from the SA node to the atrial muscle. Although this cannot reliably be differentiated from sinus arrest on the ECG, with SA block the interval between P waves is a multiple of the normal P–P interval. An atrial, junctional, or

FIG 2-12â•…

Ventricular fibrillation. Note chaotic baseline motion and absence of organized waveforms. A, Coarse fibrillation; B, fine fibrillation. Lead II, 25╯mm/sec, dog.

A

B

ventricular escape rhythm should take over after prolonged sinus arrest or block. Atrial standstill occurs when diseased atrial muscle prevents normal electrical and mechanical function, regardless of sinus node activity; consequently, a junctional or ventricular escape rhythm results and P waves are not seen. Because hyperkalemia interferes with normal atrial function, it can mimic atrial standstill.

Conduction Disturbances within the Atrioventricular Node Abnormalities of AV conduction can occur from excessive vagal tone; drugs (e.g., digoxin, xylazine, medetomidine, verapamil, anesthetic agents); and organic disease of the AV node and/or intraventricular conduction system. Three types of AV conduction disturbances are commonly described (Fig. 2-13). First-degree AV block, the mildest, occurs when conduction from the atria into the ventricles is prolonged. All impulses are conducted, but the PR interval is longer than normal. Second-degree AV block is characterized by intermittent AV conduction; some P waves are not followed by a QRS complex. When many P waves are not conducted, the patient has high-grade second-degree heart block. There are two subtypes of second-degree AV block. Mobitz type I (Wenckebach) is characterized by progressive prolongation of the PR interval until a nonconducted P wave occurs; it is frequently associated with disorders within the AV node itself and/or high vagal tone. Mobitz type II is characterized by uniform PR intervals preceding the blocked impulse and is thought to be more often associated with disease lower in the AV conduction system (e.g., bundle of His or major bundle branches). An alternative classification of second-degree AV block based on QRS configuration has been described. Patients with type A second-degree block have a normal, narrow QRS configuration; those with type B second-degree block have a wide or abnormal QRS configuration, which suggests diffuse disease lower in the ventricular conduction system. Mobitz type I AV block is usually type A, whereas Mobitz type II

CHAPTER 2â•…â•… Diagnostic Tests for the Cardiovascular System

A

27

B

C

D FIG 2-13â•…

Atrioventricular (AV) conduction abnormalities. A, First-degree AV block in a dog with digoxin toxicity (lead aVF, 25╯mm/sec). B, Second-degree AV block (Wenckebach) in an old cat under anesthesia. Note gradually prolonged PR interval with failed conduction of third (and seventh) P wave(s) followed by an escape complex. The fourth and eighth P waves (arrows) are not conducted because the ventricles are refractory (lead II, 25╯mm/ sec). C, Second-degree AV block in a comatose old dog with brainstem signs and seizures. Note the changing configuration of the P waves (wandering pacemaker) (lead II, 25╯mm/sec). D, Complete (third-degree) heart block in a Poodle. There is underlying sinus arrhythmia, but no P waves are conducted; a slow ventricular escape rhythm has resulted. Two calibration marks (half-standard, 0.5╯cm = 1╯mV) are seen. Lead II, 25╯mm/sec.

is frequently type B. Supraventricular or ventricular escape complexes are common during long pauses in ventricular activation. Third-degree or complete AV block is complete failure of AV conduction; no sinus (or supraventricular) impulses are conducted into the ventricles. Although a regular sinus rhythm or sinus arrhythmia is often evident, the P waves are not related to the QRS complexes, which result from a (usually) regular ventricular escape rhythm.

Intraventricular Conduction Disturbances Abnormal (aberrant) ventricular conduction occurs in association with slowed or blocked impulse transmission in a

major bundle branch or ventricular region. The right bundle branch or the left anterior or posterior fascicles of the left bundle branch can be affected singly or in combination. A block in all three major branches results in third-degree (complete) heart block. Activation of the myocardium served by the blocked pathway occurs relatively slowly, from myocyte to myocyte; therefore the QRS complexes appear wide and abnormal (Fig. 2-14). Right bundle branch block (RBBB) is sometimes identified in otherwise normal dogs and cats, although it can occur from disease or distention of the RV. Left bundle branch block (LBBB) is usually related to clinically relevant underlying LV disease. The left anterior

28

PART Iâ•…â•… Cardiovascular System Disorders

fascicular block (LAFB) pattern is common in cats with hypertrophic cardiomyopathy.

Ventricular Preexcitation Early activation (preexcitation) of part of the ventricular myocardium can occur when there is an accessory conduction pathway that bypasses the normal, more slowly conducting AV nodal pathway. Several types of preexcitation and accessory pathways have been described. Most cause a shortened PR interval. Wolff-Parkinson-White (WPW) preexcitation is also characterized by early widening and slurring of the QRS by a so-called delta wave (Fig. 2-15). This pattern occurs because the accessory pathway (Kent bundle) lies outside the AV node (extranodal) and allows early depolarization (represented by the delta wave) of a part of the ventricle distant to where normal ventricular activation begins. Other accessory pathways connect the atria or dorsal areas of the AV node directly to the bundle of His. These cause a short PR interval without early QRS widening. Preexcitation can be intermittent or concealed (not evident on ECG). The danger with preexcitation is that a reentrant supraventricular tachycardia can occur using the accessory pathway and AV node (also called AV reciprocating tachycardia). Usually the tachycardia impulses travel into the ventricles via the AV node (antegrade or orthodromic conduction) and then back to the atria via the accessory pathway, but sometimes the

direction is reversed. Rapid AV reciprocating tachycardia can cause weakness, syncope, congestive heart failure, and death. The presence of the WPW pattern on ECG in conjunction with reentrant supraventricular tachycardia that causes clinical signs characterizes the WPW syndrome.

MEAN ELECTRICAL AXIS The mean electrical axis (MEA) describes the average direction of the ventricular depolarization process in the frontal plane. It represents the summation of the various instantaneous vectors that occur from the beginning until the end of ventricular muscle activation. Major intraventricular conduction disturbances and/or ventricular enlargement patterns can shift the average direction of ventricular activation and therefore the MEA. By convention, only the six frontal plane leads are used to determine MEA. Either of the following methods can be used: 1. Find the lead (I, II, III, aVR, aVL, or aVF) with the largest R wave (note: the R wave is a positive deflection). The positive electrode of this lead is the approximate orientation of the MEA. 2. Find the lead (I, II, III, aVR, aVL, or aVF) with the most isoelectric QRS (positive and negative deflections are about equal). Then identify the lead perpendicular to this lead on the hexaxial lead diagram (see Fig. 2-6). If the

FIG 2-14â•…

Electrocardiogram from a dog that developed right bundle branch block and first-degree AV block after doxorubicin therapy. Sinus arrhythmia, leads I and II, 25╯mm/sec, 1╯cm = 1╯mV.

FIG 2-15â•…

Ventricular preexcitation in a cat. Note slowed QRS upstroke (delta wave; arrows) immediately following each P wave. Lead II, 50╯mm/sec, 1╯cm = 1╯mV.

CHAPTER 2â•…â•… Diagnostic Tests for the Cardiovascular System

QRS in this perpendicular lead is mostly positive, the MEA is toward the positive pole of this lead. If the QRS in the perpendicular lead is mostly negative, the MEA is oriented toward the negative pole. If all leads appear isoelectric, the frontal axis is indeterminate. Fig. 2-6 shows the normal MEA range for dogs and cats.

CHAMBER ENLARGEMENT AND BUNDLE BRANCH BLOCK PATTERNS Changes in the ECG waveforms can suggest enlargement or abnormal conduction within a particular cardiac chamber. However, enlargement does not always produce these changes. A widened P wave has been associated with LA enlargement (p mitrale); sometimes the P wave is notched, as well as wide. Tall, spiked P waves (p pulmonale) can accompany RA enlargement. With atrial enlargement, the usually obscure atrial repolarization (Ta) wave may be evident as a baseline shift in the opposite direction of the P wave. A right-axis deviation and an S wave in lead I are strong criteria for RV enlargement (or RBBB). Other ECG changes can usually be found as well. Three or more of the criteria listed in Box 2-4 are generally present when RV enlargement exists. RV enlargement (dilation or hypertrophy) is usually pronounced if it is evident on the ECG because LV activation forces are normally so dominant. LV dilation and eccentric hypertrophy often increase R-wave voltage in the caudal leads (II and aVF) and widen the QRS. LV concentric hypertrophy inconsistently produces a left-axis deviation. Conduction block in any of the major ventricular conduction pathways disturbs the normal activation process and alters QRS configuration. Electrical activation of ventricular muscle regions served by a diseased bundle branch occurs late and progresses slowly. This widens the QRS complex and shifts the terminal QRS orientation toward the area of delayed activation. Box 2-4 and Fig. 2-16 summarize ECG patterns associated with ventricular enlargement or conduction delay. Box 2-5 lists common clinical associations. Other QRS Abnormalities Small-voltage QRS complexes sometimes occur. Causes of reduced QRS amplitude include pleural or pericardial effusions, obesity, intrathoracic mass lesions, hypovolemia, and hypothyroidism. Small complexes are occasionally seen in dogs without identifiable abnormalities. Electrical alternans is an every-other-beat recurring alteration in QRS complex size or configuration. This is most often seen with large-volume pericardial effusions (see Chapter 9). ST-T ABNORMALITIES The ST segment extends from the end of the QRS complex (also called the J-point) to the onset of the T wave. In dogs and cats this segment tends to slope into the T wave that follows, without clear demarcation. Abnormal elevation (>0.15╯mV in dogs or >0.1╯mV in cats) or depression

29

BOX 2-4â•… Ventricular Chamber Enlargement and Conduction Abnormality Patterns Normal

Normal mean electrical axis No S wave in lead I R wave taller in lead II than in lead I Lead V2 R wave larger than S wave Right Ventricular Enlargement

Right-axis deviation S wave present in lead I S wave in V2-3 larger than R wave or > 0.8╯mV Q-S (W shape) in V10 Positive T wave in lead V10 Deep S wave in leads II, III, and aVF Right Bundle Branch Block (RBBB)

Same as right ventricular enlargement, with prolonged terminal portion of the QRS (wide, sloppy S wave) Left Ventricular Hypertrophy

Left-axis deviation R wave in lead I taller than R wave in leads II or aVF No S wave in lead I Left Anterior Fascicular Block (LAFB)

Same as left ventricular hypertrophy, possibly with wider QRS Left Ventricular Dilation

Normal frontal axis Taller than normal R wave in leads II, aVF, V2-3 Widened QRS; slurring and displacement of ST segment and T-wave enlargement may also occur Left Bundle Branch Block (LBBB)

Normal frontal axis Very wide and sloppy QRS Small Q wave may be present in leads II, III, and aVF (incomplete LBBB)

(>0.2╯mV in dogs or >0.1╯mV in cats) of the J point and ST segment from baseline in leads I, II, or aVF may be clinically significant. Myocardial ischemia and other types of myocardial injuries are possible causes. Atrial enlargement or tachycardia can cause pseudodepression of the ST segment because of prominent Ta waves. Other secondary causes of ST segment deviation include ventricular hypertrophy, slowed conduction, and some drugs (e.g., digoxin). The T wave represents ventricular muscle repolarization; it may be positive, negative, or biphasic in normal cats and dogs. Changes in size, shape, or polarity from previous recordings in a given animal are probably clinically important. Abnormalities of the T wave can be primary (i.e., not

30

PART Iâ•…â•… Cardiovascular System Disorders I

II/aVF

V3

V10

BOX 2-5â•… Clinical Associations of Electrocardiographic Enlargement Patterns

Normal

RVE (RBBB)

Left Atrial Enlargement

Mitral insufficiency (acquired or congenital) Cardiomyopathies Patent ductus arteriosus Subaortic stenosis Ventricular septal defect Right Atrial Enlargement

LV dilation (LPFB)

LV hypertrophy (LAFB)

Tricuspid insufficiency (acquired or congenital) Chronic respiratory disease Interatrial septal defect Pulmonic stenosis Left Ventricular Enlargement (Dilation)

Mitral insufficiency Dilated cardiomyopathy Aortic insufficiency Patent ductus arteriosus Ventricular septal defect Subaortic stenosis Left Ventricular Enlargement (Hypertrophy)

FIG 2-16â•…

Schematic of common ventricular enlargement patterns and conduction abnormalities. Electrocardiogram leads are listed across top. LAFB, Left anterior fascicular block; LPFB, left posterior fascicular block; LV, left ventricular; RBBB, right bundle branch block; RVE, right ventricular enlargement.

related to the depolarization process) or secondary (i.e., related to abnormalities of ventricular depolarization). Secondary ST-T changes tend to be in the opposite direction of the main QRS deflection. Box 2-6 lists some causes of ST-T abnormalities.

QT Interval The QT interval represents the total time of ventricular activation and repolarization. This interval varies inversely with average heart rate; faster rates have a shorter QT interval. Autonomic nervous tone, various drugs, and electrolyte disorders influence the duration of the QT interval (see Box 2-6). Inappropriate prolongation of the QT interval may facilitate development of serious reentrant arrhythmias when underlying nonuniformity in ventricular repolarization exists. Prediction equations for expected QT duration have been published for normal dogs and cats. ELECTROCARDIOGRAPHIC MANIFESTATIONS OF DRUG TOXICITY AND ELECTROLYTE IMBALANCE Digoxin, antiarrhythmic agents, and anesthetic drugs often alter heart rhythm and/or conduction either by their direct

Hypertrophic cardiomyopathy Subaortic stenosis Right Ventricular Enlargement

Pulmonic stenosis Tetralogy of Fallot Tricuspid insufficiency (acquired or congenital) Severe heartworm disease Severe pulmonary hypertension (of other cause)

electrophysiologic effects or by affecting autonomic tone (Box 2-7). Potassium has marked and complex influences on cardiac electrophysiology. Hypokalemia can increase spontaneous automaticity of cardiac cells, as well as nonuniformly slow repolarization and conduction; these effects predispose to both supraventricular and ventricular arrhythmias. Hypokalemia can cause progressive ST segment depression, reduced T-wave amplitude, and QT interval prolongation. Severe hypokalemia can also increase QRS and P-wave amplitudes and durations. In addition, hypokalemia exacerbates digoxin toxicity and reduces the effectiveness of class I antiarrhythmic agents (see Chapter 4). Hypernatremia and alkalosis worsen the effects of hypokalemia on the heart. Moderate hyperkalemia actually has an antiarrhythmic effect by reducing automaticity and enhancing uniformity and speed of repolarization. However, rapid or severe increases in serum potassium concentration are arrhythmogenic primarily because they slow conduction velocity and shorten the refractory period. A number of ECG changes

BOX 2-6â•… Causes of ST Segment, T Wave, and QT Abnormalities Depression of J Point/ST Segment

Myocardial ischemia Myocardial infarction/injury (subendocardial) Hyperkalemia or hypokalemia Cardiac trauma Secondary change (ventricular hypertrophy, conduction disturbance, VPCs) Digitalis (“sagging” appearance) Pseudodepression (prominent Ta) Elevation of the J Point/ST Segment

Pericarditis Left ventricular epicardial injury Myocardial infarction (transmural) Myocardial hypoxia Secondary change (ventricular hypertrophy, conduction disturbance, VPCs) Digoxin toxicity

Quinidine toxicity Ethylene glycol poisoning Secondary to prolonged QRS Hypothermia Central nervous system abnormalities Shortening of QT Interval

Hypercalcemia Hyperkalemia Digitalis toxicity Large T Waves

Myocardial hypoxia Ventricular enlargement Intraventricular conduction abnormalities Hyperkalemia Metabolic or respiratory diseases Normal variation

Prolongation of QT Interval

Tented T Waves

Hypocalcemia Hypokalemia

Hyperkalemia

VPC, Ventricular premature complex.

BOX 2-7â•… Electrocardiographic Changes Associated with Electrolyte Imbalance and Selected Drug Adverse Effects/Toxicity Hyperkalemia (see Fig. 2-17)

Quinidine/Procainamide

Peaked (tented) ± large T waves Short QT interval Flat or absent P waves Widened QRS ST segment depression

Atropine-like effects Prolonged QT interval AV block Ventricular tachyarrhythmias Widened QRS complex Sinus arrest

Hypokalemia

ST segment depression Small, biphasic T waves Prolonged QT interval Tachyarrhythmias

Lidocaine

Hypercalcemia

β-Blockers

Few effects Short QT interval Prolonged conduction Tachyarrhythmias

Sinus bradycardia Prolonged PR interval AV block

Hypocalcemia

Ventricular bigeminy

Prolonged QT interval Tachyarrhythmias Digoxin

PR prolongation Second- or third-degree AV block Sinus bradycardia or arrest Accelerated junctional rhythm Ventricular premature complexes Ventricular tachycardia Paroxysmal atrial tachycardia with block Atrial fibrillation with slow ventricular rate AV, Atrioventricular.

AV block Ventricular tachycardia Sinus arrest

Barbiturates/Thiobarbiturates

Halothane/Methoxyflurane

Sinus bradycardia Ventricular arrhythmias (increased sensitivity to catecholamines, especially halothane) Medetomidine/Xylazine

Sinus bradycardia Sinus arrest/sinoatrial block AV block Ventricular tachyarrhythmias (especially with halothane, epinephrine)

32

PART Iâ•…â•… Cardiovascular System Disorders

I

aVR

V3

I

aVR

V3

II

aVL

V6

II

aVL

V6

III

aVF

V10

III

aVF

V10

12/16

12/14

A

B FIG 2-17â•…

ECGs recorded in a female Poodle with Addison disease at presentation (A), (K+ = 10.2; Na+ = 132╯mEq/L), and 2 days later after treatment (B), (K+ = 3.5; Na+ = 144╯mEq/L). Note absence of P waves, accentuated and tented T waves (especially in chest leads), shortened QT interval, and slightly widened QRS complexes in A compared with B. Leads as marked, 25╯mm/sec, 1╯cm = 1╯mV.

may occur as serum potassium (K+) concentration rises; however, these may be only inconsistently observed in clinical cases, perhaps because of additional concurrent metabolic abnormalities. Observations from experimental studies indicate an early change, as serum rises to and above 6╯mEq/L, is a peaked (“tented”) T wave as the QT interval shortens. However, the characteristic symmetric “tented” T wave may be evident in only some leads and may be of small amplitude. In addition, progressive slowing of intraventricular conduction leads to widening of the QRS complexes. Experimentally, conduction through the atria slows as serum K+ nears 7╯mEq/L, and P waves flatten. P waves disappear as atrial conduction fails at about 8╯mEq/L. The sinus node is relatively resistant to the effects of hyperkalemia and continues to function, although the sinus rate may slow. Despite progressive atrial muscle unresponsiveness, specialized fibers transmit sinus impulses to the ventricles, producing a “sinoventricular” rhythm. Hyperkalemia should be a differential diagnosis for patients with a wide-QRS complex rhythm without P-waves, even if the heart rate is not slow. At extremely high serum K+ concentrations (>10╯mEq/L) an irregular ectopic ventricular rhythm, fibrillation, or asystole develop. Fig. 2-17 illustrates the electrocardiographic effects

of severe hyperkalemia and the response to therapy in a dog with Addison disease. Hypocalcemia, hyponatremia, and acidosis accentuate the electrocardiographic changes caused by hyperkalemia, whereas hypercalcemia and hypernatremia tend to counteract them. Marked ECG changes caused by other electrolyte disturbances are uncommon. Severe hypercalcemia or hypocalcemia could have noticeable effects (Table 2-3), but this is rarely seen clinically. Hypomagnesemia has no reported effects on the ECG, but it can predispose to digoxin toxicity and exaggerate the effects of hypocalcemia.

COMMON ARTIFACTS Fig. 2-18 illustrates some common ECG artifacts. Electrical interference can be minimized or eliminated by properly grounding the ECG machine. Turning off other electrical equipment or lights on the same circuit or having a different person restrain the animal may also help. Other artifacts are sometimes confused with arrhythmias; however, artifacts do not disturb the underlying cardiac rhythm. Conversely, ectopic complexes often disrupt the underlying rhythm; they are also followed by a T wave. Careful examination for these characteristics usually allows differentiation

CHAPTER 2â•…â•… Diagnostic Tests for the Cardiovascular System

33

TABLE 2-3â•… Echocardiographic Measurement Guidelines for Dogs* LVIDD (cm)

LVIDS (cm)

LVWD (cm)

LVWS (cm)

IVSD (cm)

IVSS (cm)

AO (cm)

LA† (M-mode; cm)

3

2.1 (1.8-2.6)

1.3 (1.0-1.8)

0.5 (0.4-0.8)

0.8 (0.6-1.1)

0.5 (0.4-0.8)

0.8 (0.6-1.0)

1.1 (0.9-1.4)

1.1 (0.9-1.4)

4

2.3 (1.9-2.8)

1.5 (1.1-1.9)

0.6 (0.4-0.8)

0.9 (0.7-1.2)

0.6 (0.4-0.8)

0.8 (0.6-1.1)

1.3 (1.0-1.5)

1.2 (1.0-1.6)

6

2.6 (2.2-3.1)

1.7 (1.2-2.2)

0.6 (0.4-0.9)

1.0 (0.7-1.3)

0.6 (0.4-0.9)

0.9 (0.7-1.2)

1.4 (1.2-1.8)

1.4 (1.1-1.8)

9

2.9 (2.4-3.4)

1.9 (1.4-2.5)

0.7 (0.5-1.0)

1.0 (0.8-1.4)

0.7 (0.5-1.0)

1.0 (0.7-1.3)

1.7 (1.3-2.0)

1.6 (1.3-2.1)

11

3.1 (2.6-3.7)

2.0 (1.5-2.7)

0.7 (0.5-1.0)

1.1 (0.8-1.5)

0.7 (0.5-1.1)

0.7 (0.5-1.1)

1.8 (1.4-2.2)

1.7 (1.3-2.2)

15

3.4 (2.8-4.1)

2.2 (1.7-3.0)

0.8 (0.5-1.1)

1.2 (0.9-1.6)

0.8 (0.6-1.1)

1.1 (0.8-1.5)

2.0 (1.6-2.4)

1.9 (1.6-2.5)

20

3.7 (3.1-4.5)

2.4 (1.8-3.2)

0.8 (0.6-1.2)

1.2 (0.9-1.7)

0.8 (0.6-1.2)

1.2 (0.9-1.6)

2.2 (1.7-2.7)

2.1 (1.7-2.7)

25

3.9 (3.3-4.8)

2.6 (2.0-3.5)

0.9 (0.6-1.3)

1.3 (1.0-1.8)

0.9 (0.6-1.3)

1.3 (0.9-1.7)

2.3 (1.9-2.9)

2.3 (1.8-2.9)

30

4.2 (3.5-5.0)

2.8 (2.1-3.7)

0.9 (0.6-1.3)

1.4 (1.0-1.9)

0.9 (0.7-1.3)

1.3 (1.0-1.8)

2.5 (2.0-3.1)

2.5 (1.9-3.1)

35

4.4 (3.6-5.3)

2.9 (2.2-3.9)

1.0 (0.7-1.4)

1.4 (1.1-1.9)

1.0 (0.7-1.4)

1.4 (1.0-1.9)

2.6 (2.1-3.2)

2.6 (2.0-3.3)

40

4.5 (3.8-5.5)

3.0 (2.3-4.0)

1.0 (0.7-1.4)

1.5 (1.1-2.0)

1.0 (0.7-1.4)

1.4 (1.0-1.9)

2.7 (2.2-3.4)

2.7 (2.1-3.5)

50

4.8 (4.0-5.8)

3.3 (2.4-4.3)

1.0 (0.7-1.5)

1.5 (1.1-2.1)

1.1 (0.7-1.5)

1.5 (1.1-2.0)

3.0 (2.4-3.6)

2.9 (2.3-3.7)

60

5.1 (4.2-6.2)

3.5 (2.6-4.6)

1.1 (0.7-1.6)

1.6 (1.2-2.2)

1.1 (0.8-1.6)

1.5 (1.1-2.1)

3.2 (2.5-3.9)

3.1 (2.4-4.0)

70

5.3 (4.4-6.5)

3.6 (2.7-4.8)

1.1 (0.8-1.6)

1.6 (1.2-2.2)

1.1 (0.8-1.6)

1.6 (1.2-2.2)

3.3 (2.7-4.1)

3.3 (2.6-4.2)

BW (kg)

FS (25-) 27% to 40 (-47)% EPSS ≤ 6╯mm Guidelines for approximate normal canine M-mode measurements based on allometric scaling to body weight (kg) to the 13 power (BW1/3). Values may not be accurate for dogs that are extremely obese or thin, old or young, or athletic. *Normal M-Mode Average Measurement Values and 95% Prediction Intervals for Dogs. † Note that M-mode LA measurement does not reflect maximum LA diameter (see text, p. 42). LA size should be assessed from appropriate 2-D frames (see pp. 36-37). AO, Aortic root; BW, body weight; EPSS, mitral E-point septal separation; FS, fractional shortening; IVSD, interventricular septal thickness in diastole; IVSS, interventricular septal thickness in systole; LA, left atrium; LVIDD, left ventricular diameter in diastole; LVIDS, left ventricular diameter in systole; LVWD, left ventricular free wall thickness in diastole; LVWS, left ventricular free wall thickness in systole. (From Cornell CC et╯al: Allometric scaling of M-mode cardiac measurements in normal adult dogs, J Vet Intern Med 18:311, 2004.)

between intermittent artifacts and arrhythmias. When multiple leads can be recorded simultaneously, comparison of the rhythm and complex configurations in all leads available is helpful.

AMBULATORY ELECTROCARDIOGRAPHY Holter Monitoring Holter monitoring allows the continuous recording of cardiac electrical activity during normal daily activities (except swimming), strenuous exercise, and sleep. This is

useful for detecting and quantifying intermittent cardiac arrhythmias and therefore helps identify cardiac causes of syncope and episodic weakness. Holter monitoring is also used to assess the efficacy of antiarrhythmic drug therapy and to screen for arrhythmias associated with cardiomyopathy or other diseases. The Holter monitor is a small batterypowered digital (or analog) recorder worn by the patient, typically for 24 hours. Two or three ECG channels are recorded from modified chest leads using adhesive patch electrodes. During the recording period, the animal’s

34

PART Iâ•…â•… Cardiovascular System Disorders

A

B

C

D

E FIG 2-18â•…

Common electrocardiogram artifacts. A, 60╯Hz electrical interference; Lead III, 25╯mm/ sec, dog. B, Baseline movement caused by panting; Lead II, 25╯mm/sec, dog. C, Respiratory motion artifact; Lead V3, 50╯mm/sec, dog. D, Severe muscle tremor artifact; Lead V3, 50╯mm/sec, cat. E, Intermittent, rapid baseline spikes caused by purring in cat; a calibration mark is seen just left of the center of the strip. Lead aVF, 25╯mm/sec.

activities are noted in a patient diary for later correlation with simultaneous ECG events. An event button on the Holter recorder can be pressed to mark the time a syncopal or other episode is witnessed. The recording is analyzed using computer algorithms that classify the recorded complexes. Evaluation and editing by a trained Holter technician experienced with veterinary recordings are important for accurate analysis. Fully

automated computer analysis can result in significant misclassification of QRS complexes and artifacts from dog and cat recordings. A summary report is generated, and selected portions of the recording are enlarged for examination by the clinician. Evaluation of a full disclosure display of the entire recording is also helpful for comparison with the technician-selected ECG strips and the times of clinical signs and/or activities noted in the patient diary (see Suggested

Readings for more information). A Holter monitor, hook-up supplies, and analysis can be obtained from some commercial human Holter scanning services, as well as many veterinary teaching hospitals and cardiology referral centers. Wide variation in heart rate is seen throughout the day in normal animals. In dogs maximum heart rates of up to 300 beats/min have been recorded with excitement or activity. Episodes of bradycardia (75╯mm╯Hg; TRmax > 4.3╯m/sec). Likewise, pulmonary diastolic pressure can be estimated from pulmonary regurgitant (PR) jet velocity at end-diastole. The calculated enddiastolic pressure gradient between the pulmonary artery and the RV, plus the estimated RV diastolic pressure, represents pulmonary arterial diastolic pressure. Pulmonary hypertension is also suggested by a peak PR velocity of greater than 2.2╯m/sec.

Color Flow Mapping Color flow (CF) mapping is a form of PW Doppler that combines the M-mode or 2-D modality with blood flow imaging. However, instead of one sample volume along one scan line, many sample volumes are analyzed along multiple scan lines. The mean frequency shifts obtained from multiple sample volumes are color coded for direction (in relation to the transducer) and velocity. Most systems code blood flow toward the transducer as red and blood flow away from the transducer as blue. Zero velocity is indicated by black, meaning either no flow or flow that is perpendicular to the angle of incidence. Differences in relative velocity of flow can be accentuated, and the presence of multiple velocities and directions of flow (turbulence) can be indicated by different display maps that use variations in brightness and color. Aliasing occurs often, even with normal blood flows, because of low Nyquist limits. Signal aliasing is displayed as a reversal of color (e.g., red shifting to blue; Fig. 2-33). Turbulence produces multiple velocities and directions of flow in an area, resulting in a mixing of color; this display can be enhanced using a variance map, which adds shades of yellow or green to the red/blue display (Fig. 2-34). The severity of valve regurgitation is sometimes estimated by the size and shape of the regurgitant jet during CF imaging. Although technical and hemodynamic factors confound the accuracy of such assessment, wide and long

FIG 2-33â•…

Example of color flow aliasing in a dog with mitral valve stenosis and atrial fibrillation. Diastolic flow toward the narrowed mitral orifice (arrow) accelerates beyond the Nyquist limit, causing red-coded flow (blood moving toward transducer) to alias to blue, then again to red, and once more to blue. Turbulent flow is seen within the left ventricle at the top of the two-dimensional image.

regurgitant jets are generally associated with more severe regurgitation than narrow jets. Other methods for quantifying valve regurgitation have been described as well. Maxi� mum regurgitant jet velocity is not a good indicator of severity, especially with mitral regurgitation. Changes in chamber size provide a better indication of severity with chronic regurgitation.

CHAPTER 2â•…â•… Diagnostic Tests for the Cardiovascular System

47

TRANSESOPHAGEAL ECHOCARDIOGRAPHY Transesophageal echocardiography (TEE) uses specialized transducers mounted on a flexible, steerable endoscope tip to image cardiac structures through the esophageal wall. TEE can provide clearer images of some cardiac structures (especially those at or above the AV junction) compared with transthoracic echocardiography because chest wall and lung interference is avoided. This technique can be particularly useful for defining some congenital cardiac defects and identifying thrombi, tumors, or endocarditis lesions, as well as guiding cardiac interventional procedures (Fig. 2-35). The need for general anesthesia and the expense of the endoscopic transducers are the main disadvantages of TEE. Complications related to the endoscopy procedure appear to be minimal.

FIG 2-34â•…

Systolic frame showing turbulent regurgitant flow into the enlarged LA of a dog with chronic mitral valve disease. The regurgitant jet curves around the dorsal aspect of the LA. Imaged from the right parasternal long axis, four chamber view. LA, Left atrium; LV, left ventricle; RA, right atrium; RV, right ventricle.

A

OTHER ECHOCARDIOGRAPHIC MODALITIES Doppler Tissue Imaging Doppler tissue imaging (DTI) is a modality used to assess the motion of tissue, rather than blood cells, by altering the signal processing and filtering of returning echoes. Myocardial velocity patterns can be assessed with color flow and pulsed wave spectral DTI techniques. Spectral DTI provides

B FIG 2-35â•…

A, Two-dimensional transesophageal echo (TEE) image at the heartbase from a 5-year-old English Springer Spaniel shows a patent ductus arteriosus (arrow) between the descending aorta (D Ao) and pulmonary artery (PA). B, Color flow Doppler image in diastole from the same orientation demonstrates flow acceleration toward the ductal opening in the D Ao and the turbulent ductal flow into the PA.

48

PART Iâ•…â•… Cardiovascular System Disorders

greater temporal resolution and quantifies velocity of myocardial motion at specific locations, such as the lateral or septal aspects of the mitral annulus (Fig. 2-36). Color DTI methods display mean myocardial velocities from different regions. Other techniques used to assess regional myocardial function and synchrony can be derived from DTI methods; these include myocardial velocity gradients, myocardial strain, and strain rate. Myocardial strain and strain rate indices may be helpful in assessing subclinical myocardial wall motion abnormalities and ventricular dyssynchrony. Strain is a measure of myocardial deformation, or percent change from its original dimension. Strain rate describes the temporal rate of deformation. A significant limitation of Doppler-based techniques is their angle dependence, complicated by cardiac translational motion. More recently, a “speckle tracking” modality, based on 2-D echocardiography rather than Doppler tissue imaging, has been described as a potentially more accurate way to assess regional myocardial motion, strain, and strain rate. This modality relies on tracking the motion of gray scale “speckles” within the myocardium as they move throughout the cardiac cycle. More information can be found in the Suggested Readings.

Three-Dimensional Echocardiography The ability to generate and manipulate three-dimensional (3-D) ultrasound images of the heart and other structures is becoming more available as a way to evaluate cardiac structure and function. Anatomic and blood flow abnormalities can be viewed from any angle by rotating or bisecting the 3-D images. Acquisition of sufficient data for 3-D

FIG 2-36â•…

PW Doppler tissue image from a cat. The mitral annulus moves toward the left apex (and transducer) in systole (S). Early diastolic filling (Ea) shifts the annulus away from the apex as the LV expands. Additional motion occurs with late diastolic filling from atrial contraction (Aa).

reconstruction of the entire heart generally requires several cardiac cycles.

OTHER TECHNIQUES CENTRAL VENOUS PRESSURE MEASUREMENT Central venous pressure (CVP) is the fluid pressure within the RA and by extension the intrathoracic cranial vena cava. It is influenced by intravascular volume, venous compliance, and cardiac function. CVP measurement helps in differentiating high right heart filling pressure (as from right heart failure or pericardial disease) from other causes of pleural or peritoneal effusion. However, it is important to note that pleural effusion itself can increase intrapleural pressure and raise CVP even in the absence of cardiac disease. Therefore CVP should be measured after thoracocentesis in patients with moderate- to large-volume pleural effusion. CVP is sometimes used to monitor critical patients receiving large intravenous fluid infusions. However, CVP is not an accurate reflection of left heart filling pressure and thus is not a reliable way to monitor for cardiogenic pulmonary edema. The CVP in normal dogs and cats usually ranges from 0 to 8 (up to 10) cm H2O. Fluctuations in CVP that parallel those of intrapleural pressure occur during respiration. CVP is measured via a large-bore jugular catheter that extends into or close to the RA. The catheter is placed aseptically and connected by extension tubing and a three-way stopcock to a fluid administration set and bag of crystalloid fluid. Free flow of fluid through this catheter system into the patient should be verified (stopcock side-port turned off). A water manometer is attached to the stopcock and positioned vertically, with the stopcock (representing 0╯cm H2O) placed at the same horizontal level as the patient’s RA. Usually the patient is placed in lateral or sternal recumbency for CVP measurement. The stopcock is turned off to the animal, allowing the manometer to fill with fluid; then the stopcock is turned off to the fluid reservoir so that the fluid column in the manometer equilibrates with the patient’s CVP. Repeated measurements are more consistent when taken with the animal and manometer in the same position and during the expiratory phase of respiration. Small fluctuations in the manometer’s fluid meniscus occur with the heartbeat, and slightly larger movement is associated with respiration. Marked change in the height of the fluid column associated with the heartbeat suggests either severe tricuspid insufficiency or that the catheter tip is within the RV. BIOCHEMICAL MARKERS Certain cardiac biomarkers have potential diagnostic and prognostic utility in dogs and cats, especially the cardiac troponins and natriuretic peptides. Cardiac troponins are regulatory proteins attached to the cardiac actin (thin) contractile filaments. Myocyte injury allows their leakage into the cytoplasm and extracellular fluid. Cardiac troponins are more sensitive for detecting myocardial injury than

cardiac-specific creatine kinase (CK-MB) and other biochemical markers of muscle damage. Circulating concentrations of cardiac troponin I (cTnI) and cardiac troponin T (cTnT) provide a specific indicator of myocardial injury or necrosis, although the pattern and degree of their release can depend on the type and severity of myocyte injury. After acute myocardial injury, circulating cTnI concentration peaks in 12 days and dissipates within 2 weeks, having a half-life in dogs of about 6 hours. Persistent increase usually indicates ongoing myocardial damage. The cTn release profile is less clear in patients with chronic disease but may relate to myocardial remodeling. Myocardial inflammation, trauma, various acquired and congenital cardiac diseases, and congestive heart failure, as well as gastric dilation/volvulus and several other noncardiac diseases, have been associated with increased cTn concentrations. Normal Greyhounds have higher cTnI concentration as a breed-related variation. Persistently increased cTn may be more useful as a prognostic indicator rather than in specific diagnosis; it has been negatively associated with survival. Increases in cTnI appear to occur earlier and more frequently than for cTnT. Human assays for cTnI and cTnT can be used in dogs and cats, but because methodology is not standardized among various cTnI assays, the cut-off values for normal may vary. Furthermore, cTn values that indicate clinically relevant myocardial disease or damage in animals are unclear. The natriuretic peptides—atrial (ANP) and brain (BNP) natriuretic peptide—or their precursors are useful biomarkers for the presence and possibly prognosis of heart disease and failure. Increase in circulating concentrations of these occurs with vascular volume expansion, decreased renal clearance, and when their production is stimulated (as with atrial stretch, ventricular strain and hypertrophy, hypoxia, tachyarrhythmias, and occasionally from ectopic noncardiac production). The natriuretic peptides help regulate blood volume and pressure and antagonize the renin-angiotensinaldosterone axis, among other effects. They are synthesized as preprohormones, then cleaved to a prohormone, and finally to their inactive amino terminal (NTproBNP and NTproANP) and active carboxyterminal BNP fragments. The N-terminal fragments remain in circulation longer and reach higher plasma concentrations than the active hormone molecules. NTproBNP elevation correlates with cardiac disease severity and can help the clinician differentiate congestive heart failure from noncardiac causes of dyspnea in both dogs and cats. However, elevation of NTproBNP and NTproANP also occurs with azotemia. Similar to cTn, natriuretic peptides are better used as functional markers of cardiac disease rather than of specific pathology. Although ANP and NT-proANP amino acid sequences are somewhat conserved among people, dogs, and cats, significant differences between canine and feline BNP and human BNP preclude the use of human BNP assays. Canine and feline NTproBNP measurement is commercially available (IDEXX Cardiopet proBNP). Plasma concentrations of less than

CHAPTER 2â•…â•… Diagnostic Tests for the Cardiovascular System

49

900╯ pmol/L (dogs) and less than 50╯ pmol/L (cats) are considered normal. Values greater than 1800╯ pmol/L (dogs) and greater than 100╯ pmol/L (cats) are elevated and highly suggestive of heart disease and/or failure; further cardiac diagnostic testing should be pursued in these cases. Interestingly, normal Greyhounds have high NT-proBNP concentrations when using this method. Also commercially available is an assay for canine BNP (ANTECH CardioBNP); the manufacturer reports a cutoff value of 6╯ pg/ mL as being highly sensitive and specific for congestive heart failure in dyspneic dogs. For both of these assays, plasma should be shipped in specialized tubes obtained from the respective laboratory. Although NT-proBNP and NT-proANP are clearly elevated in cats with severe hypertrophic cardiomyopathy, there are conflicting findings related to differentiating mild and moderate degrees of hypertrophy in asymptomatic cats. Variable peptide concentration elevations are seen in dogs with heart diseases, arrhythmias, and heart failure, but overlap in concentrations with those of dogs without heart disease can sometimes occur. Other biomarkers are currently being evaluated. The endothelin (ET) system is activated in dogs and cats with heart failure and in those with pulmonary hypertension, so assays for plasma ET–like immunoreactivity may be useful. Tumor necrosis factor (TNFα) or other proinflammatory cytokines such as C-reactive protein or various interleukins may also become useful markers of cardiac disease progression but are not cardiac specific.

ANGIOCARDIOGRAPHY Nonselective angiocardiography can be used to diagnose several acquired and congenital diseases, including cardiomyopathy and heartworm disease in cats, severe pulmonic or (sub)aortic stenosis, patent ductus arteriosus, and tetralogy of Fallot. Intracardiac septal defects and valvular regurgitation cannot be reliably identified. The quality of such studies is higher with rapid injection of radiopaque agents via a large-bore catheter and with smaller patient size. In most cases, echocardiography provides similar information more safely. However, evaluation of the pulmonary vasculature is better accomplished using nonselective angiocardiography. Selective angiocardiography is performed by advancing cardiac catheters into specific areas of the heart or great vessels. Injection of contrast material is generally preceded by the measurement of pressures and oxygen saturations. This technique allows identification of anatomic abnormalities and the path of blood flow. Doppler echocardiography may provide comparable diagnostic information noninvasively. However, selective angiography is a necessary component of many cardiac interventional procedures. CARDIAC CATHETERIZATION Cardiac catheterization allows measurement of pressure, cardiac output, and blood oxygen concentration from specific intracardiac locations. Specialized catheters are selectively placed into different areas of the heart and vasculature

50

PART Iâ•…â•… Cardiovascular System Disorders

via the jugular vein, carotid artery, or femoral vessels. Congenital and acquired cardiac abnormalities can be identified and assessed with these procedures in combination with selective angiocardiography. The advantages of Doppler echocardiography often outweigh those of cardiac catheterization, especially in view of the good correlation between certain Doppler- and catheterization-derived measurements. However, cardiac catheterization is necessary for balloon valvuloplasty, ductal occlusion, and other interventional procedures. Pulmonary capillary wedge pressure (PCWP) monitoring is done rarely to measure left heart filling pressure in dogs with heart failure. A Swan-Ganz (end-hole, balloon-tipped) monitoring catheter is passed into the main pulmonary artery. When the balloon is inflated the catheter tip becomes wedged in a smaller pulmonary artery, occluding flow in that vessel. The pressure measured at the catheter tip reflects pulmonary capillary pressure, which is essentially equivalent to LA pressure. This invasive technique allows differentiation of cardiogenic from noncardiogenic pulmonary edema and provides a means of monitoring the effectiveness of heart failure therapy. However, its use requires meticulous, aseptic catheter placement, and continuous patient monitoring.

Endomyocardial Biopsy Small samples of endocardium and adjacent myocardium can be obtained using a special bioptome passed into the RV via a jugular vein. Routine histopathology and other techniques to evaluate myocardial metabolic abnormalities can be done on the samples. Endomyocardial biopsy is sometimes used for myocardial disease research but rarely in clinical veterinary practice. OTHER IMAGING TECHNIQUES Pneumopericardiography Pneumopericardiography may help delineate the cause of pericardial effusions when echocardiography is unavailable. This technique and pericardiocentesis are described in Chapter 9. Nuclear Cardiology Radionuclide, or nuclear, methods of evaluating cardiopulmonary function are available at some veterinary referral centers. These techniques can provide noninvasive assessment of cardiac output, ejection fraction, and other measures of cardiac performance, as well as myocardial blood flow and metabolism. Cardiac Computed Tomography and Magnetic Resonance Imaging Cardiac computed tomography (CT) and magnetic resonance imaging (MRI) are now more widely available in veterinary practice. CT combines multiple radiographic image slices to produce detailed cross-sectional images from reconstructed 3-D orientations. MRI uses radio waves and a magnetic field to create detailed tissue images. These techniques can allow greater differentiation between cardiovascular

structures, different tissue types, and the blood pool. Because cardiac movement during the imaging sequence reduces image quality, physiologic (electrocardiographic) gating is used for optimal cardiac imaging. Identification of pathologic morphology, such as congenital malformations or cardiac mass lesions, is a major application. Evaluation of myocardial function, perfusion, or valve function studies may also be done. Different cardiac MRI imaging sequences are used depending on the application or type of inforÂ� mation desired. For example, “black blood” MRI scans allow better assessment of anatomical details and abnormalities, whereas “bright blood” sequences are used to evaluate cardiac function. Suggested Readings Radiography Bavegems V et al: Vertebral heart size ranges specific for Whippets, Vet Radiol Ultrasound 46:400, 2005. Benigni L et al: Radiographic appearance of cardiogenic pulmonary oedema in 23 cats, J Small Anim Pract 50:9, 2009. Buchanan JW, Bücheler J: Vertebral scale system to measure canine heart size in radiographs, J Am Vet Med Assoc 206:194, 1995. Coulson A, Lewis ND: An atlas of interpretive radiographic anatomy of the dog and cat, Oxford, 2002, Blackwell Science. Ghadiri A et al: Radiographic measurement of vertebral heart size in healthy stray cats, J Feline Med Surg 10:61, 2008. Lamb CR et al: Use of breed-specific ranges for the vertebral heart scale as an aid to the radiographic diagnosis of cardiac disease in dogs, Vet Rec 148:707, 2001. Lehmkuhl LB et al: Radiographic evaluation of caudal vena cava size in dogs, Vet Radiol Ultrasound 38:94, 1997. Litster AL, Buchanan JW: Vertebral scale system to measure heart size in radiographs of cats, J Am Vet Med Assoc 216:210, 2000. Marin LM et al: Vertebral heart size in retired racing Greyhounds, Vet Radiol Ultrasound 48:332, 2007. Sleeper MM, Buchanan JW: Vertebral scale system to measure heart size in growing puppies, J Am Vet Med Assoc 219:57, 2001. Electrocardiography Bright JM, Cali JV: Clinical usefulness of cardiac event recording in dogs and cats examined because of syncope, episodic collapse, or intermittent weakness: 60 cases (1997-1999), J Am Vet Med Assoc 216:1110, 2000. Calvert CA et al: Possible late potentials in four dogs with sustained ventricular tachycardia, J Vet Intern Med 12:96, 1998. Calvert CA, Wall M: Evaluation of stability over time for measures of heart-rate variability in overtly healthy Doberman Pinschers, Am J Vet Res 63:53, 2002. Constable PD et al: Effects of endurance training on standard and signal-averaged electrocardiograms of sled dogs, Am J Vet Res 61:582, 2000. Finley MR et al: Structural and functional basis for the long QT syndrome: relevance to veterinary patients, J Vet Intern Med 17:473, 2003. Hanas S et al: Twenty-four hour Holter monitoring of unsedated healthy cats in the home environment, J Vet Cardiol 11:17, 2009. Harvey AM et al: Effect of body position on feline electrocardiographic recordings, J Vet Intern Med 19:533, 2005. Holzgrefe HH et al: Novel probabilistic method for precisely correcting the QT interval for heart rate in telemetered dogs and cynomolgus monkeys, J Pharmacol Toxicol Methods 55:159, 2007.

MacKie BA et al: Retrospective analysis of an implantable loop recorder for evaluation of syncope, collapse, or intermittent weakness in 23 dogs (2004-2008), J Vet Cardiol 12:25, 2010. Meurs KM et al: Use of ambulatory electrocardiography for detection of ventricular premature complexes in healthy dogs, J Am Vet Med Assoc 218:1291, 2001. Miller RH et al: Retrospective analysis of the clinical utility of ambulatory electrocardiographic (Holter) recordings in syncopal dogs: 44 cases (1991-1995), J Vet Intern Med 13:111, 1999. Nakayama H, Nakayama T, Hamlin RL: Correlation of cardiac enlargement as assessed by vertebral heart size and echocardiographic and electrocardiographic findings in dogs with evolving cardiomegaly due to rapid ventricular pacing, J Vet Intern Med 15:217, 2001. Norman BC et al: Wide-complex tachycardia associated with severe hyperkalemia in three cats, J Feline Med Surg 8:372, 2006. Perego M et al: Isorhythmic atrioventricular dissociation in Labrador Retrievers, J Vet Intern Med 26:320, 2012. Rishniw M et al: Effect of body position on the 6-lead ECG of dogs, J Vet Intern Med 16:69, 2002. Santilli RA et al: Utility of 12-lead electrocardiogram for differentiating paroxysmal supraventricular tachycardias in dogs, J Vet Intern Med 22:915, 2008. Stern JA et al: Ambulatory electrocardiographic evaluation of clinically normal adult Boxers, J Am Vet Med Assoc 236:430, 2010. Tag TL et al: Electrocardiographic assessment of hyperkalemia in dogs and cats, J Vet Emerg Crit Care 18:61, 2008. Tattersall ML et al: Correction of QT values to allow for increases in heart rate in conscious Beagle dogs in toxicology assessment, J Pharmacol Toxicol Methods 53:11, 2006. Tilley LP: Essentials of canine and feline electrocardiography, ed 3, Philadelphia, 1992, Lea & Febiger. Ulloa HM, Houston BJ, Altrogge DM: Arrhythmia prevalence during ambulatory electrocardiographic monitoring of beagles, Am J Vet Res 56:275, 1995. Ware WA, Christensen WF: Duration of the QT interval in healthy cats, Am J Vet Res 60:1426, 1999. Ware WA: Twenty-four hour ambulatory electrocardiography in normal cats, J Vet Intern Med 13:175, 1999. Echocardiography Abbott JA, MacLean HN: Two-dimensional echocardiographic assessment of the feline left atrium, J Vet Intern Med 20:111, 2006. Adin DB, McCloy K: Physiologic valve regurgitation in normal cats, J Vet Cardiol 7:9, 2005. Borgarelli M et al: Anatomic, histologic, and two-dimensional echocardiographic evaluation of mitral valve anatomy in dogs, Am J Vet Res 72:1186, 2011. Campbell FE, Kittleson MD: The effect of hydration status on the echocardiographic measurements of normal cats, J Vet Intern Med 21:1008, 2007. Chetboul V: Advanced techniques in echocardiography in small animals, Vet Clin North Am Small Anim Pract 40:529, 2010. Concalves AC et al: Linear, logarithmic, and polynomial models of M-mode echocardiographic measurements in dogs, Am J Vet Res 63:994, 2002. Cornell CC et al: Allometric scaling of M-mode cardiac measurements in normal adult dogs, J Vet Intern Med 18:311, 2004. Culwell NM et al: Comparison of echocardiographic indices of myocardial strain with invasive measurements of left ventricular systolic function in anesthetized healthy dogs, Am J Vet Res 72:650, 2011.

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Cunningham SM et al: Echocardiographic ratio indices in overtly healthy Boxer dogs screened for heart disease, J Vet Intern Med 22:924, 2008. Feigenbaum H et al: Feigenbaum’s echocardiography, ed 6, Philadelphia, 2005, Lippincott Williams & Wilkins. Fox PR et al: Echocardiographic reference values in healthy cats sedated with ketamine HCl, Am J Vet Res 46:1479, 1985. Gavaghan BJ et al: Quantification of left ventricular diastolic wall motion by Doppler tissue imaging in healthy cats and cats with cardiomyopathy, Am J Vet Res 60:1478, 1999. Griffiths LG et al: Echocardiographic assessment of interventricular and intraventricular mechanical synchrony in normal dogs, J Vet Cardiol 13:115, 2011. Jacobs G, Knight DV: M-mode echocardiographic measurements in nonanesthetized healthy cats: effects of body weight, heart rate, and other variables, Am J Vet Res 46:1705, 1985. Kittleson MD, Brown WA: Regurgitant fraction measured by using the proximal isovelocity surface area method in dogs with chronic myxomatous mitral valve disease, J Vet Intern Med 17:84, 2003. Koch J et al: M-mode echocardiographic diagnosis of dilated cardiomyopathy in giant breed dogs, Zentralbl Veterinarmed A 43:297, 1996. Koffas H et al: Peak mean myocardial velocities and velocity gradients measured by color M-mode tissue Doppler imaging in healthy cats, J Vet Intern Med 17:510, 2003. Koffas H et al: Pulsed tissue Doppler imaging in normal cats and cats with hypertrophic cardiomyopathy, J Vet Intern Med 20:65, 2006. Ljungvall I et al: Assessment of global and regional left ventricular volume and shape by real-time 3-dimensional echocardiography in dogs with myxomatous mitral valve disease, J Vet Intern Med 25:1036, 2011. Loyer C, Thomas WP: Biplane transesophageal echocardiography in the dog: technique, anatomy and imaging planes, Vet Radiol Ultrasound 36:212, 1995. MacDonald KA et al: Tissue Doppler imaging and gradient echo cardiac magnetic resonance imaging in normal cats and cats with hypertrophic cardiomyopathy, J Vet Intern Med 20:627, 2006. Margiocco ML et al: Doppler-derived deformation imaging in unsedated healthy adult dogs, J Vet Cardiol 11:89, 2009. Morrison SA et al: Effect of breed and body weight on echocardiographic values in four breeds of dogs of differing somatotype, J Vet Intern Med 6:220, 1992. Quintavalla C et al: Aorto-septal angle in Boxer dogs with subaortic stenosis: an echocardiographic study, Vet J 185:332, 2010. Rishniw M, Erb HN: Evaluation of four 2-dimensional echocardiographic methods of assessing left atrial size in dogs, J Vet Intern Med 14:429, 2000. Schober KE et al: Comparison between invasive hemodynamic measurements and noninvasive assessment of left ventricular diastolic function by use of Doppler echocardiography in healthy anesthetized cats, Am J Vet Res 64:93, 2003. Schober KE, Maerz I: Assessment of left atrial appendage flow velocity and its relation to spontaneous echocardiographic contrast in 89 cats with myocardial disease, J Vet Intern Med 20:120, 2006. Schober KE et al: Detection of congestive heart failure in dogs by Doppler echocardiography, J Vet Intern Med 24:1358, 2010. Simak J et al: Color-coded longitudinal interventricular septal tissue velocity imaging, strain and strain rate in healthy Doberman Pinschers, J Vet Cardiol 13:1, 2011.

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Sisson DD et al: Plasma taurine concentrations and M-mode echocardiographic measures in healthy cats and in cats with dilated cardiomyopathy, J Vet Intern Med 5:232, 1991. Snyder PS, Sato T, Atkins CE: A comparison of echocardiographic indices of the non-racing, healthy greyhound to reference values from other breeds, Vet Radiol Ultrasound 36:387, 1995. Stepien RL et al: Effect of endurance training on cardiac morphology in Alaskan sled dogs, J Appl Physiol 85:1368, 1998. Thomas WP et al: Recommendations for standards in transthoracic two-dimensional echocardiography in the dog and cat, J Vet Intern Med 7:247, 1993. Tidholm A et al: Comparisons of 2- and 3-dimensional echocardiographic methods for estimation of left atrial size in dogs with and without myxomatous mitral valve disease, J Vet Intern Med 24:1414, 2011. Wess G et al: Assessment of left ventricular systolic function by strain imaging echocardiography in various stages of feline hypertrophic cardiomyopathy, J Vet Intern Med 24:1375, 2010. Wess G et al: Comparison of pulsed wave and color Doppler myocardial velocity imaging in healthy dogs, J Vet Intern Med 24:360, 2010. Other Techniques Adin DB et al: Comparison of canine cardiac troponin I concentrations as determined by 3 analyzers, J Vet Intern Med 20:1136, 2006. Boddy KN et al: Cardiac magnetic resonance in the differentiation of neoplastic and nonneoplastic pericardial effusion, J Vet Intern Med 25:1003, 2011. Chetboul V et al: Diagnostic potential of natriuretic peptides in occult phase of Golden Retriever muscular dystrophy cardiomyopathy, J Vet Intern Med 18:845, 2004. Connolly DJ et al: Assessment of the diagnostic accuracy of circulating cardiac troponin I concentration to distinguish between cats with cardiac and non-cardiac causes of respiratory distress, J Vet Cardiol 11:71, 2009. DeFrancesco TC et al: Prospective clinical evaluation of an ELISA B-type natriuretic peptide assay in the diagnosis of congestive heart failure in dogs presenting with cough or dyspnea, J Vet Intern Med 21:243, 2007. Ettinger SJ et al: Evaluation of plasma N-terminal pro-B-type natriuretic peptide concentrations in dogs with and without cardiac disease, J Am Vet Med Assoc 240:171, 2012.

Fine DM et al: Evaluation of circulating amino terminal-pro-Btype natriuretic peptide concentration in dogs with respiratory distress attributable to congestive heart failure or primary pulmonary disease, J Am Vet Med Assoc 232:1674, 2008. Fox PR et al: Multicenter evaluation of plasma N-terminal probrain natriuretic peptide (NT-pro BNP) as a biochemical screening test for asymptomatic (occult) cardiomyopathy in cats, J Vet Intern Med 25:1010, 2011. Gookin JL, Atkins CE: Evaluation of the effect of pleural effusion on central venous pressure in cats, J Vet Intern Med 13:561, 1999. Herndon WE et al: Cardiac troponin I in feline hypertrophic cardiomyopathy, J Vet Intern Med 16:558, 2002. MacDonald KA et al: Brain natriuretic peptide concentration in dogs with heart disease and congestive heart failure, J Vet Intern Med 17:172, 2003. Oyama MA, Sisson D: Cardiac troponin-I concentration in dogs with cardiac disease, J Vet Intern Med 18:831, 2004. Prosek R et al: Distinguishing cardiac and noncardiac dyspnea in 48 dogs using plasma atrial natriuretic factor, B-type natriuretic factor, endothelin, and cardiac troponin-I, J Vet Intern Med 21:238, 2007. Prosek R et al: Biomarkers of cardiovascular disease. In Ettinger SJ, Feldman EC, editors: Textbook of veterinary internal medicine, ed 7, Philadelphia, 2010, WB Saunders, p 1187. Raffan E et al: The cardiac biomarker NT-proBNP is increased in dogs with azotemia. J Vet Intern med 23:1184, 2009. Shaw SP, Rozanski EA, Rush JE: Cardiac troponins I and T in dogs with pericardial effusion, J Vet Intern Med 18:322, 2004. Singh MK et al: NT-proBNP measurement fails to reliably identify subclinical hypertrophic cardiomyopathy in Maine Coon cats, J Feline Med Surg 12:942, 2010. Sisson DD: Neuroendocrine evaluation of cardiac disease, Vet Clin North Am: Small Anim Pract 34:1105, 2004. Spratt DP et al: Cardiac troponin I: evaluation of a biomarker for the diagnosis of heart disease in the dog, J Small Anim Pract 46:139, 2005. Wells SM, Sleeper M: Cardiac troponins, J Vet Emerg Crit Care 18:235, 2008. Wess G et al: Utility of measuring plasma N-terminal pro-brain natriuretic peptide in detecting hypertrophic cardiomyopathy and differentiating grades of severity in cats, Vet Clin Pathol 40:237, 2011.

C H A P T E R

3â•…

Management of Heart Failure

OVERVIEW OF HEART FAILURE Heart failure entails abnormalities of cardiac systolic or diastolic function, or both. These can occur without evidence of abnormal fluid accumulation (congestion), especially in the initial stages of disease. Congestive heart failure (CHF) is characterized by high cardiac filling pressure, which leads to venous congestion and tissue fluid accumulation. It is a complex clinical syndrome rather than a specific etiologic diagnosis. The pathophysiology of heart failure is complex. It involves structural and functional changes within the heart and vasculature, as well as other organs. The process of progressive cardiac remodeling inherent to heart failure can develop secondary to cardiac injury or stress from valvular disease, genetic mutations, acute inflammation, ischemia, increased systolic pressure load, and other causes.

CARDIAC RESPONSES Cardiac remodeling refers to the changes in myocardial size, shape, and stiffness that occur in response to various mechanical, biochemical, and molecular signals induced by the underlying injury or stress. These changes include myocardial cell hypertrophy, cardiac cell drop-out or self-destruction (apoptosis), excessive interstitial matrix formation, fibrosis, and destruction of normal collagen binding between individual myocytes. The latter, resulting from effects of myocardial collagenases or matrix metalloproteinases, can cause dilation or distortion of the ventricle from myocyte slippage. Stimuli for remodeling include mechanical forces (e.g., increased wall stress from volume or pressure overload) and the effects of various neurohormones (such as angiotensin II, norepinephrine, endothelin, aldosterone) and proinflammatory cytokines (including tumor necrosis factor [TNF]-α), as well as other cytokines (such as osteopontin and cardiotrophin-1). Contributing biochemical abnormalities related to cellular energy production, calcium fluxes, protein synthesis, and catecholamine metabolism have been variably identified in different models of heart failure and in clinical patients. Myocyte hypertrophy and reactive fibrosis increase total cardiac mass by eccentric

and, in some cases, concentric patterns of hypertrophy. Ventricular hypertrophy can increase chamber stiffness, impair relaxation, and increase filling pressures; these abnormalities of diastolic function can also contribute to systolic failure. Ventricular remodeling also promotes the development of arrhythmias. The initiating stimulus underlying chronic cardiac remodeling may occur years before clinical evidence of heart failure appears. Acute increases in ventricular filling (preload) induce greater contraction force and blood ejection. This response, known as the Frank-Starling mechanism, allows beat-to-beat adjustments that balance the output of the two ventricles and increase overall cardiac output in response to acute increases in hemodynamic load. In the short term, the Frank-Starling effect helps normalize cardiac output under conditions of increased pressure and/or volume loading, but these conditions also increase ventricular wall stress and oxygen consumption. Ventricular wall stress is directly related to ventricular pressure and internal dimensions and inversely related to wall thickness (Laplace’s law). Myocardial hypertrophy can reduce wall stress. The pattern of hypertrophy that develops depends on underlying disease conditions. A ventricular systolic pressure load induces “concentric” hypertrophy; myocardial fibers and ventricular walls thicken as contractile units are added in parallel. With severe hypertrophy, capillary density and myocardial perfusion may be inadequate; chronic myocardial hypoxia or ischemia stimulates further fibrosis and dysfunction. Chronic volume loading increases diastolic wall stress and leads to “eccentric” hypertrophy; myocardial fiber elongation and chamber dilation occur as new sarcomeres are laid down in series. Reductions in the extracellular collagen matrix and intercellular support structure have been shown in dogs with chronic volume overloading due to mitral insufficiency. Compensatory hypertrophy lessens the importance of the Frank-Starling mechanism in stable, chronic heart failure. Although volume loads are better tolerated because myocardial oxygen demand is not as severe, both abnormal pressure and volume loading impair cardiac performance over time. 53

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PART Iâ•…â•… Cardiovascular System Disorders

Eventually, decompensation and myocardial failure develop. In patients with primary myocardial diseases, initial cardiac pressure and volume loads are normal but intrinsic defects of the heart muscle lead to the hypertrophy and dilation observed. Cardiac hypertrophy and other remodeling begin long before heart failure becomes manifest. Biochemical abnormalities involving cell energy production, calcium fluxes, and contractile protein function can develop. Clinical heart failure can be considered a state of decompensated hypertrophy; ventricular function progressively deteriorates as contractility and relaxation become more deranged. Continued exposure to increased sympathetic stimulation reduces cardiac sensitivity to catecholamines. Downregulation (reduced number) of myocardial β1-receptors and other changes in cellular signaling may help protect the myocardium against the cardiotoxic and arrhythmogenic effects of catecholamines. β-Blocking agents can reverse β1-receptor downregulation but may worsen heart failure. Cardiac β2- and α1-receptors are also present but are not downregulated; these are thought to contribute to myocardial remodeling and arrhythmogenesis. Another cardiac receptor subtype (β3-receptors) may promote myocardial function deterioration through a negative inotropic effect.

SYSTEMIC RESPONSES Neurohormonal Mechanisms Neurohormonal (NH) responses contribute to cardiac remodeling and also have more far-reaching effects. Over time, excessive activation of neurohormonal “compensatory” mechanisms leads to the clinical syndrome of CHF. Although these mechanisms support circulation in the face of acute hypotension and hypovolemia, their chronic activation accelerates further deterioration of cardiac function. Major neurohormonal changes in heart failure include increases in sympathetic nervous tone, attenuated vagal tone, activation of the renin-angiotensin-aldosterone system, and increased release of antidiuretic hormone (ADH-vasopressin) and endothelin. These neurohormonal systems work independently and interact together to increase vascular volume (by sodium and water retention and increased thirst) and vascular tone (Fig. 3-1). Although increased lymphatic flow helps moderate the rise in venous pressures, eventually excessive volume retention results in edema and effusions. Prolonged systemic vasoconstriction increases the workload on the heart, can reduce forward cardiac output, and may exacerbate valvular regurgitation. The extent to which these mechanisms are activated varies with the severity and etiology of heart failure. In general, as failure worsens, neurohormonal activation increases. Increased production of endothelins and proinflammatory cytokines, as well as altered expression of vasodilatory and natriuretic factors, also contribute to the complex interplay among these NH mechanisms and their consequences. The effects of sympathetic stimulation (e.g., increased contractility, heart rate, and venous return) can increase cardiac output initially, but over time these effects become

detrimental by increasing afterload stress and myocardial oxygen requirements, contributing to cellular damage and myocardial fibrosis, and enhancing the potential for cardiac arrhythmias. Normal feedback regulation of sympathetic nervous and hormonal systems depends on arterial and atrial baroreceptor function. Baroreceptor responsiveness becomes attenuated in chronic heart failure, which contributes to sustained sympathetic and hormonal activation and reduced inhibitory vagal effects. Baroreceptor function can improve with reversal of heart failure, increased myocardial contractility, decreased cardiac loading conditions, or inhibition of angiotensin II and aldosterone (which directly attenuate baroreceptor sensitivity). Digoxin has a positive effect on baroreceptor sensitivity. The renin-angiotensin system has far-reaching effects. Whether systemic renin-angiotensin-aldosterone activation always occurs before overt congestive failure is unclear and may depend on the underlying etiology. Renin release from the renal juxtaglomerular apparatus occurs secondary to low renal artery perfusion pressure, renal β-adrenergic receptor stimulation, and reduced Na+ delivery to the macula densa of the distal renal tubule. Stringent dietary salt restriction and diuretic or vasodilator therapy can promote renin release. Renin facilitates conversion of the precursor peptide angiotensinogen to angiotensin I (an inactive form). Angiotensin-converting enzyme (ACE), found in the lung and elsewhere, converts angiotensin I to the active angiotensin II and is involved in the degradation of certain vasodilator kinins. There are also alternative pathways for angiotensin II generation. Angiotensin II has several important effects, including potent vasoconstriction and stimulation of aldosterone release from the adrenal cortex. Additional effects of angiotensin II include increased thirst and salt appetite, facilitation of neuronal norepinephrine synthesis and release, blockade of neuronal norepinephrine reuptake, stimulation of antidiuretic hormone (vasopressin) release, and increased adrenal epinephrine secretion. Inhibition of ACE can reduce NH activation and promote vasodilation and diuresis. Local production of angiotensin II also occurs in the heart, vasculature, adrenal glands, and other tissues in dogs and cats. Local activity affects cardiovascular structure and function by enhancing sympathetic effects and promoting tissue remodeling that can include hypertrophy, inflammation, and fibrosis. Tissue chymase is thought to be more important in the conversion to active angiotensin II than ACE in the myocardium and extracellular matrix. Aldosterone promotes sodium and chloride reabsorption, as well as potassium and hydrogen ion secretion in the renal collecting tubules; the concurrent water reabsorption augments vascular volume. Increased aldosterone concentration can promote hypokalemia, hypomagnesemia, and impaired baroreceptor function. It can potentiate the effects of catecholamines by blocking NE reuptake. Aldosterone receptors are also found in the heart and vasculature; aldosterone produced locally in the cardiovascular system mediates

CHAPTER 3â•…â•… Management of Heart Failure

Heart disease

55

Cellular signaling and biochemical abnormalities, local NH activation, and cytokine release

Cardiac remodeling

Progressive cardiac dysfunction

ONSET OF HF ↓ Cardiac output ↓ Blood pressure and baroreceptor unloading

Signals to brain

↑ Adrenergic nerve traffic and circulating NE

↓ Renal perfusion

↑ Heart rate, contractility, and remodeling

↑ Renin secretion ↑ Adrenal EPI release ↑ AT I

↑ Endothelin production

↑ Vasopressin/ ADH release

ACE

Constriction of efferent arterioles ↑ Cardiac remodeling

↑ Filtration fraction

↑ AT II

↑ Aldosterone ↑ Thirst ↓ Baroreceptor sensitivity Vasoconstriction ↑ H2O resorption

↑ Na resorption ↑ Venous pressure

↑ Preload edema and effusions

↑ Afterload and blood redistribution

FIG 3-1â•…

Important neurohormonal mechanisms leading to volume retention and increased afterload in congestive heart failure (CHF). Note: Additional mechanisms and interactions also contribute. Endogenous vasodilatory and natriuretic mechanisms also become activated during the evolution of CHF. ACE, Angiotensin-converting enzyme; ADH, antidiuretic hormone; AT, angiotensin; EPI, epinephrine; HF, heart failure; NE, norepinephrine.

inflammation and fibrosis. Chronic exposure contributes to pathologic remodeling and myocardial fibrosis. Antidiuretic hormone (ADH, arginine vasopressin) is released from the posterior pituitary gland. This hormone directly causes vasoconstriction and also promotes free water

reabsorption in the distal nephrons. Although increased plasma osmolality or reduced blood volume are the normal stimuli for ADH release, reduced effective circulating volume and other nonosmotic stimuli (including sympathetic stimulation and angiotensin II) cause continued release of ADH

56

PART Iâ•…â•… Cardiovascular System Disorders

in patients with heart failure. The continued release of ADH contributes to the dilutional hyponatremia sometimes found in patients with heart failure. Increased circulating concentrations of other substances that play a role in abnormal cardiovascular hypertrophy and/ or fibrosis, including cytokines (e.g., TNFα) and endothelins, have also been detected in animals with severe heart failure. Endothelin is a potent vasoconstrictor whose precursor peptide is produced by vascular endothelium. Endothelin production is stimulated by hypoxia and vascular mechanical factors but also by angiotensin II, ADH, norepinephrine, cytokines (including TNFα and interleukin-I), and other factors. Endogenous mechanisms that oppose the vasoconstrictor responses are also activated. These include natriuretic peptides, adrenomedullin, nitric oxide, and vasodilator prostaglandins. Normally, a balance between vasodilator and vasoconstrictor effects maintains circulatory homeostasis, as well as renal solute excretion. As heart failure progresses, the influence of the vasoconstrictor mechanisms predominates despite increased activation of vasodilator mechanisms. Natriuretic peptides are synthesized in the heart and play an important role in regulation of blood volume and pressure. Atrial natriuretic peptide (ANP) is synthesized by atrial myocytes as a prohormone, which is then cleaved to the active peptide after release stimulated by mechanical stretch of the atrial wall. Brain natriuretic peptide (BNP) is also synthesized in the heart, mainly by the ventricles in response to myocardial dysfunction or ischemia. Natriuretic peptides cause diuresis, natriuresis, and peripheral vasodilation. They act to antagonize the effects of the renin-angiotensin system and can also alter vascular permeability and inhibit growth of smooth muscle cells. Natriuretic peptides are degraded by neutral endopeptidases. Circulating concentrations of ANP, BNP, and their precursor peptides (such as NT-proBNP) increase in patients with heart failure. This increase has been correlated with pulmonary capillary wedge pressure and severity of heart failure in both dogs and people. Adrenomedullin is another natriuretic and vasodilatory peptide produced in the adrenal medulla, heart, lung, and other tissues that is thought to play a role in heart failure. Nitric oxide (NO), produced in vascular endothelium in response to endothelial-nitric oxide synthetase (NOS), is a functional antagonist of endothelin and angiotensin II. This response is impaired in patients with heart failure. At the same time, myocardial inducible–NOS expression is enhanced; myocardial NO release has negative effects on myocyte function. Intrarenal vasodilator prostaglandins oppose the action of angiotensin II on the renal vasculature. The use of prostaglandin synthesis inhibitors in dogs or cats with severe heart failure could potentially reduce glomerular filtration (by increasing afferent arteriolar resistance) and enhance sodium retention.

Renal Effects Renal efferent glomerular arteriolar constriction, mediated by sympathetic stimulation and angiotensin II, helps

maintain glomerular filtration in the face of reduced cardiac output and renal blood flow. Higher oncotic and lower hydrostatic pressures develop in the peritubular capillaries, enhancing the reabsorption of tubular fluid and sodium. Angiotensin II–mediated aldosterone release further promotes sodium and water retention. Continued activation of these mechanisms leads to clinical edema and effusions. Afferent arteriolar vasodilation mediated by endogenous prostaglandins and natriuretic peptides can partially offset the effects of efferent vasoconstriction, but progressive impairment of renal blood flow leads to renal insufficiency. Diuretics cannot only magnify azotemia and electrolyte loss but also further reduce cardiac output and activate the neurohormonal (NH) mechanisms.

Other Effects Reduced exercise capacity occurs in patients with heart failure. Although cardiac output may be fairly normal at rest, the ability to increase cardiac output in response to exercise is impaired. Poor diastolic filling, inadequate forward output, and pulmonary edema or pleural effusion can interfere with exercise ability. Furthermore, impaired peripheral vasodilation during exercise contributes to inadequate skeletal muscle perfusion and fatigue. Excessive peripheral sympathetic tone, angiotensin II (both circulating and locally produced), and vasopressin can contribute to impaired skeletal muscle vasodilatory capacity in patients with CHF. Increased vascular wall sodium content and interstitial fluid pressure stiffen and compress vessels. Other mechanisms can include impaired endothelium-dependent relaxation, increased endothelin concentration, and vascular wall changes induced by the growth factor effects of various NH vasoconstrictors. ACE inhibitor (ACEI) therapy, with or without spironolactone, may improve endothelial vasomotor function and exercise capacity. Pulmonary endothelial function is improved by ACEIs in dogs with CHF. GENERAL CAUSES OF HEART FAILURE The causes of heart failure are quite diverse; it can be useful to think of them in terms of underlying pathophysiology. In most cases of heart failure, the major initiating abnormality is myocardial (systolic pump) failure, systolic pressure overload, volume overload, or reduced ventricular compliance (impaired filling). Nevertheless, several pathophysiologic abnormalities often coexist; both systolic and diastolic function abnormalities are common in patients with advanced failure. Myocardial failure is characterized by poor ventricular contractile function, and it is most commonly secondary to idiopathic dilated cardiomyopathy; valvular insufficiency may or may not be present initially but usually develops as the affected ventricle dilates. Persistent tachyarrhythmias, some nutritional deficiencies, and other cardiac insults also can lead to myocardial failure (see Chapters 7 and 8). Diseases that cause a volume or flow overload to the heart usually involve a primary “plumbing” problem (e.g., a leaky valve or abnormal systemic-to-pulmonary connection).

Cardiac pump function is often maintained at a near-normal level for a prolonged time, but myocardial contractility does eventually deteriorate (see Chapters 5 and 6). Pressure overload results when the ventricle must generate higherthan-normal systolic pressure to eject blood. Concentric hypertrophy increases ventricular wall thickness and stiffness and can predispose to myocardial ischemia. Excessive pressure loads eventually lead to a decline in myocardial contractility. Myocardial pressure overload results from ventricular outflow obstruction (congenital or acquired) and systemic or pulmonary hypertension (see Chapters 5, 10, and 11). Diseases that restrict ventricular filling impair diastolic function. These include hypertrophic and restrictive myocardial disease and pericardial diseases (see Chapters 8 and 9). Contractile ability is usually normal initially, but high filling pressure leads to congestion behind the ventricle(s) and may diminish cardiac output. Uncommon causes of impaired filling include congenital atrioventricular (AV) valve stenosis, cor triatriatum, and intracardiac mass lesions. Table 3-1 lists common diseases according to their major initiating pathophysiology and typical clinical CHF manifestations.

APPROACH TO TREATING HEART FAILURE Current perspectives on CHF management are based on not only mitigating the results of excessive NH activation (especially sodium and water retention) but also modifying or blocking the activation process itself with the aim of minimizing progression of myocardial remodeling and dysfunction. Diuretics, dietary salt restriction, and some vasodilators help control signs of congestion, whereas ACEIs and alÂ� dosterone and sympathetic antagonists modulate NH responses. Treatment strategies center on controlling edema and effusions, improving cardiac output, reducing cardiac workload, supporting myocardial function, and managing concurrent arrhythmias. The approach to these goals varies somewhat with different diseases, most notably those causing restriction to ventricular filling. Classification of Severity Guidelines for clinical staging of heart failure (based on the American Heart Association and American College of Cardiology [AHA/ACC] system) are being increasingly applied to veterinary patients (Table 3-2). These describe disease progression through four stages over time. This system emphasizes the importance of patient screening and early diagnosis. It is recommended as a guide in coordinating appropriate (and ideally, evidence-based) treatment to the severity of the clinical signs at each stage of disease. It also deemphasizes the term “congestive” in congestive heart failure because volume overload is not consistently present at all stages. Nevertheless, attention to the patient’s fluid status is highly important. The clinical severity of heart failure is also sometimes described according to a modified New York Heart Association (NYHA) classification scheme or the International

CHAPTER 3â•…â•… Management of Heart Failure

57

  TABLE 3-1â•… Common Causes of Congestive Heart Failure (CHF) MAJOR PATHOPHYSIOLOGY

TYPICAL CHF MANIFESTATION*

Myocardial Failure

Idiopathic dilated cardiomyopathy

Either L- or R-CHF

Myocardial ischemia/infarction

L-CHF

Drug toxicities (e.g., doxorubicin)

L-CHF

Infective myocarditis

Either L- or R-CHF

Volume-Flow Overload

Mitral valve regurgitation (degenerative, congenital, infective)

L-CHF

Aortic regurgitation (infective endocarditis, congenital)

L-CHF

Ventricular septal defect

L-CHF

Patent ductus arteriosus

L-CHF

Tricuspid valve regurgitation (degenerative, congenital, infective)

R-CHF

Tricuspid endocarditis

R-CHF

Chronic anemia

Either L- or R-CHF

Thyrotoxicosis

Either L- or R-CHF

Pressure Overload

(Sub)aortic stenosis

L-CHF

Systemic hypertension

L-CHF (rare)

Pulmonic stenosis

R-CHF

Heartworm disease

R-CHF

Pulmonary hypertension

R-CHF

Impaired Ventricular Filling

Hypertrophic cardiomyopathy

L-(±R-) CHF

Restrictive cardiomyopathy

L-(±R-) CHF

Cardiac tamponade

R-CHF

Constrictive pericardial disease

R-CHF

*L-CHF, Left-sided congestive heart failure signs (pulmonary edema as main congestive sign); R-CHF, right-sided congestive heart failure signs (pleural effusion and/or ascites as main congestive signs). Weakness and other low-output signs can occur with any of these diseases, especially those associated with arrhythmias.

Small Animal Cardiac Health Council (ISACHC) criteria. These systems group patients into functional categories on the basis of clinical observations rather than underlying cardiac disease or myocardial function. Such classification can still be helpful conceptually and for categorizing study patients, as well as complement the previously described staging system. Regardless of the clinical classi� fication scheme, identifying the underlying etiology and

58

PART Iâ•…â•… Cardiovascular System Disorders

  TABLE 3-2â•… Classification Systems for Heart Failure Severity CLASSIFICATION

DEGREE OF SEVERITY

Modified AHA/ACC Heart Failure Staging System

A

Patient “at risk” for the development of heart failure, but apparent cardiac structural abnormality not yet identified

B B1 B2

Structural cardiac abnormality is evident (such as a murmur), but no clinical signs of heart failure â•… No radiographic or echo evidence for cardiac remodeling/chamber enlargement â•… Chamber enlargement has developed in response to the underlying cardiac disease and hemodynamic abnormality

C

Structural cardiac abnormality, with past or present clinical signs of heart failure

D

Persistent or end-stage heart failure signs, refractory to standard therapy

Modified NYHA Functional Classification

I

Heart disease is present but no evidence of heart failure or exercise intolerance; cardiomegaly is minimal to absent

II

Heart disease present but clinical signs of failure only with strenuous exercise; radiographic cardiomegaly is usually present

III

Signs of heart failure with normal activity or mild exercise (e.g., cough, orthopnea); radiographic signs of cardiomegaly and pulmonary edema or pleural/abdominal effusion

IV

Severe clinical signs of heart failure at rest or with minimal activity; marked radiographic signs of CHF and cardiomegaly

International Small Animal Cardiac Health Council Functional Classification

I

Asymptomatic patient

Ia

Signs of heart disease without cardiomegaly

Ib

Signs of heart disease and evidence of compensation (cardiomegaly)

II

Mild to moderate heart failure; clinical signs of failure evident at rest or with mild exercise and adversely affect quality of life

III

Advanced heart failure; clinical signs of CHF are immediately obvious

IIIa

Home care is possible

IIIb

Hospitalization recommended (cardiogenic shock, life-threatening edema, large pleural effusion, refractory ascites)

AHA/ACC, American Heart Association and American College of Cardiology; CHF, congestive heart failure.

pathophysiology, as well as the clinical severity, is important for individualized therapy.

TREATMENT FOR ACUTE CONGESTIVE HEART FAILURE GENERAL CONSIDERATIONS Fulminant CHF is characterized by severe cardiogenic pulmonary edema, with or without pleural and/or abdominal effusions or poor cardiac output. It can occur in stage C or D patients. Therapy is aimed at rapidly clearing pulmonary edema, improving oxygenation, and optimizing cardiac output (Box 3-1). Thoracocentesis should be performed expediently if marked pleural effusion exists. Likewise, largevolume ascites should be drained to improve ventilation.

Animals with severe CHF are greatly stressed. Physical activity must be maximally restricted to reduce total oxygen consumption; cage confinement is preferred. Environmental stresses such as excess heat and humidity or extreme cold should be avoided. When transported, the animal should be placed on a cart or carried. Unnecessary patient handling and use of oral medications should be avoided, when possible.

SUPPLEMENTAL OXYGEN Oxygen administered by face mask or improvised hood, nasal catheter, endotracheal tube, or oxygen cage is beneficial as long as the method chosen does not increase the patient’s distress. An oxygen cage with temperature and humidity controls is preferred; a setting of 65° F is recommended for normothermic animals. Oxygen flow of 6 to 10╯L/min is

CHAPTER 3â•…â•… Management of Heart Failure

59

  BOX 3-1â•… Acute Treatment of Decompensated Congestive Heart Failure Minimize patient stress and excitement! Cage rest/transport on gurney (no activity allowed) Avoid excessive heat and humidity Improve oxygenation: Ensure airway patency Give supplemental O2 (avoid > 50% for > 24 hours) Postural support if needed (help maintain sternal recumbency, head elevation) If frothing evident, suction airways Intubate and mechanically ventilate if necessary Thoracocentesis if pleural effusion suspected/ documented Diuresis: Furosemide (dogs: 2-5[-8] mg/kg, IV or IM, q1-4h until respiratory rate decreases, then 1-4╯mg/kg q6-12h, or 0.6-1╯mg/kg/h CRI [see text]; cats: 1-2[-4] mg/ kg, IV or IM, q1-4h until respiratory rate decreases, then q6-12h) Provide access to water after diuresis begins Support cardiac pump function (inodilator) Pimobendan (dogs 0.25-0.3╯mg/kg PO q12h; begin as soon as possible) Reduce anxiety: Butorphanol (dogs: 0.2-0.3╯mg/kg IM; cats: 0.20.25╯mg/kg IM); or Morphine (dogs: 0.025-0.1╯mg/kg IV boluses q2-3min to effect, or 0.1-0.5╯mg/kg single IM or SC dose) Acepromazine (cats: 0.05-0.2╯mg/kg SC; or 0.050.1╯mg/kg IM with butorphanol), or Diazepam (cats: 2-5╯mg IV; dogs: 5-10╯mg IV) ±Strategies to redistribute blood volume: Vasodilators (sodium nitroprusside, if able to monitor BP closely: 0.5-1╯µg/kg/min CRI in D5W, titrate upward as needed to 5-15╯µg/kg/min; or 2% nitroglycerin ointment—Dogs: 12 to 112 inch cutaneously q6h; cats: 14 to 12 inch cutaneously q6h) ±Morphine (dogs only) ±Phlebotomy (6-10╯mL/kg) ±Further afterload reduction (especially for mitral regurgitation): Hydralazine (if not using nitroprusside; dogs: 0.5-1╯mg/kg PO repeated in 2-3 hours [until systolic

arterial pressure is 90-110╯mm Hg], then q12h; see text); or Enalapril (0.5╯mg/kg PO q12-24h) or other ACEI— avoid nitroprusside; or Amlodipine (dogs: 0.05-0.1╯mg/kg initially (-0.3╯mg/ kg) PO q12-24h; see text) ±Additional inotropic support (if myocardial failure or persistent hypotension present): Dobutamine* (1-10╯µg/kg/min CRI; start low), or dopamine† (dogs: 1-10╯µg/kg/min CRI; cats: 1-5╯µg/kg/min CRI; start low) Amrinone (1-3╯mg/kg IV; 10-100╯µg/kg/min CRI), or milrinone (50╯µg/kg IV over 10 minutes initially; 0.375-0.75╯µg/kg/min CRI [human dose]) Digoxin PO (see Table 3-3); (digoxin loading dose [see text for indications]: PO—1 or 2 doses at twice calculated maintenance; dog IV: 0.01-0.02╯mg/ kg—give 14 of this total dose in slow boluses over 2-4 hours to effect; cat IV: 0.005╯mg/kg—give 12 of total, then 1-2 hours later give 14 dose bolus(es), if needed) ±Minimize bronchoconstriction: Aminophylline (dogs: 4-8╯mg/kg slow IV, IM, SC, or 6-10╯mg/kg PO q6-8h; cats: 4-8╯mg/kg IM, SC, PO q8-12h) or similar drug Monitor and address abnormalities as possible: Respiratory rate, heart rate and rhythm, arterial pressure, O2 saturation, body weight, urine output, hydration, attitude, serum biochemistry and blood gas analyses, and pulmonary capillary wedge pressure (if available) Diastolic dysfunction (e.g., cats with hypertrophic cardiomyopathy): General recommendations, O2 therapy, and furosemide as above ±Nitroglycerin and mild sedation Begin enalapril or benazepril as soon as possible Consider IV esmolol (0.1-0.5╯mg/kg IV over 1 minute, followed by 0.025-0.2╯mg/kg/min CRI) or diltiazem (0.15-0.25╯mg/kg over 2-3 minutes IV) to reduce heart rate, and dynamic outflow obstruction (esmolol) if present

*Dilution of 250╯mg dobutamine into 500╯mL of D5W or lactated Ringer’s solution yields a solution of 500╯µg/mL; CRI of 0.6╯mL/kg/h provides 5╯µg/kg/min. † Dilution of 40╯mg of dopamine into 500╯mL of D5W or lactated Ringer’s solution yields a solution of 80╯µg/mL; a volume of 0.75╯mL/kg/h provides 1╯µg/kg/min. ACE, Angiotensin-converting enzyme; CRI, constant rate infusion; D5W, 5% dextrose in water.

usually adequate. Concentrations of 50% to 100% oxygen may be necessary initially, but this should be reduced within a few hours to 40% to avoid lung injury. When a nasal tube is used, humidified O2 is delivered at a rate of 50 to 100╯mL/ kg/min. Extremely severe pulmonary edema with respiratory

failure may respond to endotracheal or tracheotomy tube placement, airway suctioning, and mechanical ventilation. Positive end-expiratory pressure helps clear small airways and expand alveoli. Positive airway pressures can adversely affect hemodynamics, however, and chronic high oxygen

60

PART Iâ•…â•… Cardiovascular System Disorders

concentrations (>70%) can injure lung tissue (see Suggested Readings for more information). Continuous monitoring is essential for intubated animals.

DRUG THERAPY Diuresis Rapid diuresis can be achieved with intravenous (IV) furosemide; effects begin within 5 minutes, peak by 30 minutes, and last about 2 hours. This route also provides a mild venodilating effect. Some patients require aggressive initial doses or cumulative doses administered at frequent intervals (see Box 3-1). Furosemide can be given by constant rate infusion (CRI), which may provide greater diuresis than bolus injection. The veterinary formulation (50╯mg/mL) can be diluted to 10╯mg/mL for CRI using 5% dextrose in water (D5W), lactated Ringer’s solution (LRS), or sterile water. Dilution to 5╯mg/mL in D5W or sterile water is also described. The patient’s respiratory rate, as well as other parameters (discussed in more detail later), guide the intensity of continued furosemide therapy. Once diuresis has begun and respiration improves, the dosage is reduced to prevent excessive volume contraction or electrolyte depletion. An ancillary approach that has been described for patients with fulminant cardiogenic edema is phlebotomy (up to 25% of total blood volume), but this is not generally done. Vasodilation Vasodilator drugs can reduce pulmonary edema by increasing systemic venous capacitance, lowering pulmonary venous pressure, and reducing systemic arterial resistance. Although ACE inhibitors are a mainstay of chronic CHF management, more immediate afterload reduction is often desirable for animals with acute pulmonary edema. The initial dose of an arteriolar vasodilator should be low, with subsequent titration upward as needed on the basis of blood pressure and clinical response. Arteriolar vasodilation is not recommended for heart failure caused by diastolic dysfunction or ventricular outflow obstruction. Sodium nitroprusside is a potent arteriolar and venous dilator, with direct action on vascular smooth muscle. It is given by IV infusion because of its short duration of action. Blood pressure must be closely monitored when using this drug. The dose is titrated to maintain mean arterial pressure at about 80╯mm╯Hg (at least > 70╯mm╯Hg) or systolic blood pressure between 90 and 110╯mm╯Hg. Nitroprusside CRI is usually continued for 12 to 24 hours. Dosage adjustments may be necessary because drug tolerance develops rapidly. Profound hypotension is the major adverse effect. Cyanide toxicity can result from excessive or prolonged use (e.g., longer than 48 hours). Nitroprusside should not be infused with other drugs and should be protected from light. Hydralazine, a pure arteriolar dilator, is an alternative to nitroprusside. It is useful for refractory pulmonary edema caused by mitral regurgitation (MR; and sometimes dilated cardiomyopathy) because it can reduce regurgitant flow and lower left atrial (LA) pressure. An initial dose of 0.5 to 1╯mg/

kg is given orally, followed by repeated doses every 2 to 3 hours until the systolic blood pressure is between 90 and 110╯mm╯Hg or clinical improvement is obvious. If blood pressure cannot be monitored, an initial dose of 1╯mg/kg is repeated in 2 to 4 hours if sufficient clinical improvement has not been observed. The addition of 2% nitroglycerin ointment may provide beneficial venodilating effects. An ACE inhibitor or amlodipine, with or without nitroglycerin ointment, is an alternative to hydralazine/ nitroglycerin. The onset of action is slower and the effects are less pronounced, but this regimen can still be helpful. Nitroglycerin (and other orally or transcutaneously administered nitrates) acts mainly on venous smooth muscle to increase venous capacitance and reduce cardiac filling pressure. The major indication for nitroglycerin is acute cardiogenic pulmonary edema. Nitroglycerin ointment (2%) is usually applied to the skin of the groin, axillary area, or ear pinna, although the efficacy of this in heart failure is unclear. An application paper or glove is used to avoid skin contact by the person applying the drug.

Inotropic Support The inodilator pimobendan is a useful component of therapy for dogs with acute CHF from chronic mitral valve disease, as well as those with dilated cardiomyopathy. Despite oral administration, its onset of action is fairly rapid. The initial dose is usually given as soon as practicable, with subsequent doses continued as part of long-term HF management (see p. 65 and Table 3-3). Other positive inotropic therapy may also be indicated when heart failure is caused by poor myocardial contractility or when persistent hypotension occurs. Treatment for 1 to 3 days with an IV sympathomimetic (catecholamine) or phosphodiesterase (PDE) inhibitor drug can help support arterial pressure, forward cardiac output, and organ perfusion when myocardial failure or hypotension is severe. Catecholamines enhance contractility via a cAMPmediated increase in intracellular Ca++. They can provoke arrhythmias and increase pulmonary and systemic vascular resistance (potentially exacerbating edema formation). Their short half-life ( 22╯kg, 0.22╯mg/m2 or 0.003-0.005╯mg/kg q12h. Decrease by 10% for elixir. Maximum: 0.5╯mg/day or 0.375╯mg/day for Doberman Pinschers. (See Box 3-1 for loading doses)

0.007╯mg/kg (or 14 of 0.125╯mg tab) PO q48h (see Box 3-1 for IV dose)

Positive Inotropes

CRI, Constant rate infusion.

ventricular arrhythmias. Adverse effects are more likely in cats; these include nausea and seizures at relatively low doses. Dopamine at low doses ( male

Subaortic stenosis

Newfoundland, Golden Retriever, Rottweiler, Boxer, German Shepherd Dog, Great Dane, German Short-Haired Pointer, Bouvier des Flandres, Samoyed; (valvular aortic stenosis: Bull Terrier)

Pulmonic stenosis

English Bulldog (male > female), Mastiff, Samoyed, Miniature Schnauzer, West Highland White Terrier, Cocker Spaniel, Beagle, Labrador Retriever, Basset Hound, Newfoundland, Airedale Terrier, Boykin Spaniel, Chihuahua, Scottish Terrier, Boxer, Chow Chow, Miniature Pinscher, other terriers & spaniels

Ventricular septal defect

English Bulldog, English Springer Spaniel, Keeshond, West Highland White Terrier; cats

Atrial septal defect

Samoyed, Doberman Pinscher, Boxer

Tricuspid dysplasia

Labrador Retriever, German Shepherd Dog, Boxer, Weimaraner, Great Dane, Old English Sheepdog, Golden Retriever; other large breeds; (male > female?); cats

Mitral dysplasia

Bull Terrier, German Shepherd Dog, Great Dane, Golden Retriever, Newfoundland, Mastiff, Dalmatian, Rottweiler(?); cats; (male > female)

Tetralogy of Fallot

Keeshond, English Bulldog

Persistent right aortic arch

German Shepherd Dog, Great Dane, Irish Setter

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PART Iâ•…â•… Cardiovascular System Disorders

are caused by an aorticopulmonary window (a communication between the ascending aorta and pulmonary artery) or some other functionally similar communication in the hilar region.

PATENT DUCTUS ARTERIOSUS Etiology and Pathophysiology The ductus normally constricts to become functionally closed within hours of birth. Structural changes and permanent closure occur over the ensuing weeks. The ductal wall in animals with an inherited PDA is histologically abnormal and contains less smooth muscle and a greater proportion of elastic fibers, similar to the aortic wall. It is therefore unable to constrict effectively. When the ductus fails to close, blood shunts through it from the descending aorta into the pulmonary artery. Because aortic pressure is normally higher than pulmonic pressure throughout the cardiac cycle, shunting occurs during both systole and diastole. This left-to-right shunt causes a volume overload of the pulmonary circulation, left atrium (LA), and left ventricle (LV). The shunt volume is directly related to the pressure difference (gradient) between the two circulations and the diameter of the ductus. Hyperkinetic arterial pulses are characteristic of PDA. Blood runoff from the aorta into the pulmonary system allows diastolic aortic pressure to rapidly decrease below normal. The widened pulse pressure (systolic minus diastolic pressure) causes palpably stronger arterial pulses (Fig. 5-2). Compensatory mechanisms that promote increased heart rate and volume retention maintain adequate systemic blood flow. However, the LV is subjected to a great hemodynamic burden, especially when the ductus is large, because the

FIG 5-2â•…

increased stroke volume is pumped into the relatively high pressure aorta. Left ventricular (LV) and mitral annulus dilation in turn cause mitral regurgitation and further volume overload. Excess fluid retention, declining myocardial contractility stemming from the chronic volume overload, and arrhythmias contribute to the development of congestive heart failure (CHF). In some cases, excessive pulmonary blood flow from a large ductus causes pulmonary vascular changes, abnormally high resistance, and pulmonary hypertension (see p. 110). As pulmonary artery pressure rises toward aortic pressure, progressively less blood shunting occurs. If pulmonary artery pressure exceeds aortic pressure, shunt reversal (right-to-left flow) occurs. Approximately 15% of dogs with inherited PDA develop a reversed shunt. Clinical Features The left-to-right shunting PDA is by far the most common form; clinical features of reversed PDA are described on page 110. The prevalence of PDA is higher in certain breeds of dogs; a polygenic inheritance pattern is thought to exist. The prevalence is two or more times greater in female than male dogs. Reduced exercise ability, tachypnea, or cough is present in some cases, but many animals are asymptomatic when first diagnosed. A continuous murmur heard best high at the left base (see p. 9), often with a precordial thrill, is typical for a left-to-right PDA; sometimes only a systolic murmur is heard more caudally, near the mitral valve area. Other findings include hyperkinetic (bounding, “waterhammer”) arterial pulses and pink mucous membranes. Diagnosis Radiographs usually show cardiac elongation (left heart dilation), left atrial (LA) and auricular enlargement, and

Continuous femoral artery pressure recording during surgical ligation of a patent ductus arteriosus in a Poodle. The wide pulse pressure (left side of trace) narrows as the ductus is closed (right side of trace). Diastolic arterial pressure rises because blood runoff into the pulmonary artery is curtailed. (Courtesy Dr. Dean Riedesel.)

CHAPTER 5â•…â•… Congenital Cardiac Disease

99

  TABLE 5-2â•… Radiographic Findings in Common Congenital Heart Defects DEFECT

HEART

PULMONARY VESSELS

OTHER

PDA

LAE, LVE; left auricular bulge; ±increased cardiac width

Overcirculated

Bulge(s) in descending aorta + pulmonary trunk; ±pulmonary edema

SAS

±LAE, LVE

Normal

Wide cranial cardiac waist (dilated ascending aorta)

PS

RAE, RVE; reverse D

Normal to undercirculated

Pulmonary trunk bulge

VSD

LAE, LVE; ±RVE

Overcirculated

±Pulmonary edema; ±pulmonary trunk bulge (large shunts)

ASD

RAE, RVE

±Overcirculated

±Pulmonary trunk bulge

T dys

RAE, RVE; ±globoid shape

Normal

Caudal cava dilation; ±pleural effusion, ascites, hepatomegaly

M dys

LAE, LVE

±Venous hypertension

±Pulmonary edema

T of F

RVE, RAE; reverse D

Undercirculated; ±prominent Normal to small pulmonary trunk; ±cranial aortic bronchial vessels bulge on lateral view

PRAA

Normal

Normal

Focal leftward and ventral tracheal deviation ± narrowing cranial to heart; wide cranial mediastinum; megaesophagus; (±aspiration pneumonia)

ASD, Atrial septal defect; LAE, left atrial enlargement; LVE, left ventricular enlargement; M dys, mitral dysplasia; PDA, patent ductus arteriosus; PRAA, persistent right aortic arch; PS, pulmonic stenosis; RVE, right ventricular enlargement; RAE, right atrial enlargement; SAS, subaortic stenosis; T dys, tricuspid dysplasia; T of F, tetralogy of Fallot; VSD, ventricular septal defect.

pulmonary overcirculation (Table 5-2). A bulge is often evident in the descending aorta (“ductus bump”) or main pulmonary trunk, or both (Fig. 5-3). The triad of all three bulges (i.e., pulmonary trunk, aorta, and left auricle), located in that order from the 1 to 3 o’clock position on a dorsoventral (DV) radiograph, is a classic finding but not always seen. There is also evidence of pulmonary edema in animals with left-sided heart failure. Characteristic ECG findings include wide P waves, tall R waves, and often deep Q waves in leads II, aVF, and CV6LL. Changes in the ST-T segment secondary to LV enlargement may occur. However, the ECG is normal in some animals with PDA. Echocardiography also shows left heart enlargement and pulmonary trunk dilation. LV fractional shortening can be normal or decreased, and the E point–septal separation is often increased. The ductus itself may be difficult to visualize because of its location between the descending aorta and pulmonary artery; angulation from the left cranial short axis view is usually most helpful. Doppler interrogation documents continuous, turbulent flow into the pulmonary artery (Fig. 5-4). The maximum aortic-to-pulmonary artery pressure gradient should be estimated. Cardiac catheterization is generally unnecessary for diagnosis, although it is important during interventional procedures. Catheterization findings include higher oxygen content in the pulmonary artery compared with the right ventricle (RV)—oxygen “step-up”—and a wide aortic pressure pulse. Angiocardiography shows leftto-right shunting through the ductus (see Fig. 5-3, C).

Treatment and Prognosis Closure of the left-to-right ductus is recommended as soon as is feasible in almost all cases, either by surgical or transcatheter methods. Surgical ligation is successful in most cases. Although a perioperative mortality of about 10% has been reported, a much lower rate is expected in uncomplicated cases with an experienced surgeon. Several methods of transcatheter PDA occlusion are available and involve placement of a vascular occluding device such as the Amplatz canine ductal occluder or wire coils (with attached thrombogenic tufts) within the ductus. Vascular access is usually via the femoral artery, although some have used a venous approach to the ductus. Where available, transcatheter PDA occlusion offers a much less invasive alternative to surgical ligation. Complications can occur (including aberrant coil embolization and residual ductal flow, among others), and not all cases are suitable for transcatheter occlusion. A normal life span can be expected after uncomplicated ductal closure. Concurrent mitral regurgitation usually resolves after ductal closure if the valve is structurally normal. Animals with CHF are treated with furosemide, an angiotensin-converting enzyme inhibitor (ACEI), rest, and dietary sodium restriction (see Chapter 3). Because contractility tends to decline over time, pimobendan (or digoxin) may be indicated as well. Arrhythmias are treated as needed. If the ductus is not closed, prognosis depends on its size and the level of pulmonary vascular resistance. CHF is the eventual outcome for most patients that do not undergo

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A

B

C FIG 5-3â•…

Lateral (A) and dorsoventral (DV) (B) radiographs from a dog with a patent ductus arteriosus. Note the large and elongated heart and prominent pulmonary vasculature. A large bulge is seen in the descending aorta on the DV view (arrowheads in B). C, Angiocardiogram obtained using a left ventricular injection outlines the left ventricle, aorta, patent ductus (arrowheads), and pulmonary artery.

ductal closure. More than 50% of affected dogs die within the first year. In animals with pulmonary hypertension and shunt reversal, ductal closure is contraindicated because the ductus acts as a “pop-off ” valve for the high right-sided pressures. Ductal ligation in animals with reversed PDA produces no improvement and can lead to right ventricular (RV) failure.

VENTRICULAR OUTFLOW OBSTRUCTION Ventricular outflow obstruction can occur at the semilunar valve, just below the valve (subvalvular), or above the valve

in the proximal great vessel (supravalvular). SAS and PS are most common in dogs and cats. Stenotic lesions impose a pressure overload on the affected ventricle, requiring higher systolic pressure and a slightly longer time to eject blood across the narrowed outlet. A systolic pressure gradient is generated across the stenotic region, as downstream pressure is normal. The magnitude of this gradient is related to the severity of the obstruction and strength of ventricular contraction. Concentric myocardial hypertrophy typically develops in response to a systolic pressure overload; some dilation of the affected ventricle can also occur. Ventricular hypertrophy can

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SUBAORTIC STENOSIS Etiology and Pathophysiology

A

B FIG 5-4â•…

Continuous turbulent flow into the pulmonary artery from the area of the patent ductus (arrow) is illustrated by systolic (A) and diastolic (B) color flow Doppler frames from the left cranial parasternal position, in an adult female Springer Spaniel. Ao, Ascending aorta; PA, main pulmonary artery; RV, right ventricle.

impede diastolic filling (by increasing ventricular stiffness) or lead to secondary AV valve regurgitation. Heart failure results when ventricular diastolic and atrial pressures are elevated. Cardiac arrhythmias can contribute to the onset of CHF. Furthermore, the combination of outflow obstruction, paroxysmal arrhythmias, and/or inappropriate bradycardia reflexly triggered by ventricular baroreceptor stimulation can result in signs of low cardiac output. These are more often associated with severe outflow tract obstruction and include exercise intolerance, syncope, and sudden death.

Subvalvular narrowing caused by a fibrous or fibromuscular ring is the most common type of LV outflow stenosis in dogs. Certain larger breeds of dog are predisposed to this defect. SAS is thought to be inherited as an autosomal dominant trait with modifying genes that influence its phenotypic expression. SAS also occurs occasionally in cats; supravalvular lesions have been reported in this species as well. Valvular aortic stenosis is reported in Bull Terriers. The spectrum of SAS severity varies widely; three grades of SAS have been described in Newfoundland dogs. The mildest (grade I) causes no clinical signs or murmur and only subtle subaortic fibrous tissue ridging seen on postmortem examination. Moderate (grade II) SAS causes mild clinical and hemodynamic evidence of the disease, with an incomplete fibrous ring below the aortic valve found at postmortem. Dogs with grade III SAS have severe disease and a complete fibrous ring around the outflow tract. Some cases have an elongated, tunnel-like obstruction. Malformation of the mitral valve apparatus may exist as well. Outflow tract narrowing and dynamic obstruction with or without a discrete subvalvular ridge have been described in some Golden Retrievers. A component of dynamic LV outflow tract obstruction may be important in other dogs, too. The obstructive lesion of SAS develops during the first several months of life, and there may be no audible murmur at an early age. In some dogs no murmur is detected until 1 to 2 years of age, and the obstruction may continue to worsen beyond that. Murmur intensity usually increases with exercise or excitement. Because of such factors, as well as the presence of physiologic murmurs in some animals, definitive diagnosis and genetic counseling to breeders can be difficult. The severity of the stenosis determines the degree of LV pressure overload and resulting concentric hypertrophy. Coronary perfusion is easily compromised in animals with severe LV hypertrophy. Capillary density may become inadequate as hypertrophy progresses. Furthermore, the high systolic wall tension, along with coronary narrowing, can cause systolic flow reversal in small coronary arteries. These factors contribute to intermittent myocardial ischemia and secondary fibrosis. Clinical sequelae include arrhythmias, syncope, and sudden death. Many animals with SAS also have aortic or mitral valve regurgitation because of related malformations or secondary changes; this imposes an additional volume overload on the LV. Left-sided CHF develops in some cases. Animals with SAS are thought to be at higher risk for aortic valve endocarditis because of jet lesion injury to the underside of the valve (see p. 123 and Fig. 6-4). Clinical Features Historical signs of fatigue, exercise intolerance or exertional weakness, syncope, or sudden death occur in about a third of dogs with SAS. Low-output signs can result from severe outflow obstruction, tachyarrhythmias, or sudden reflex

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bradycardia and hypotension resulting from the activation of ventricular mechanoreceptors. Signs of left-sided CHF can develop, usually in conjunction with concurrent mitral or aortic regurgitation, other cardiac malformations, or acquired endocarditis. Dyspnea is the most commonly reported sign in cats with SAS. Characteristic physical examination findings in dogs with moderate to severe stenosis include weak and late-rising femoral pulses (pulsus parvus et tardus) and a precordial thrill low at the left heartbase. A harsh systolic ejection murmur is heard at or below the aortic valve area on the left hemithorax. This murmur often radiates equally or more loudly to the right heartbase because of the orientation of the aortic arch. The murmur is frequently heard over the carotid arteries, and it may even radiate to the calvarium. In mild cases a soft, poorly radiating ejection murmur at the left and sometimes right heartbase may be the only abnormality found on physical examination. Functional LV outflow murmurs that are not associated with SAS are common in normal Greyhounds, other sight hounds, and Boxers. Aortic regurgitation can produce a diastolic murmur at the left base or may be inaudible. Severe aortic regurgitation can increase the arterial pulse strength. There may be evidence of pulmonary edema or arrhythmias. Diagnosis Radiographic abnormalities (see Table 5-2) can be subtle, especially in animals with mild SAS. The LV can appear normal or enlarged; mild to moderate LA enlargement is more likely with severe SAS or concurrent MR. Poststenotic dilation in the ascending aorta can cause a prominent cranial waist in the cardiac silhouette (especially on a lateral view) and cranial mediastinal widening. The ECG is often normal, although evidence of LV hypertrophy (left axis deviation) or enlargement (tall complexes) can be present. Depression of the ST segment in leads II and aVF can occur from myocardial ischemia or secondary to hypertrophy; exercise induces further ischemic ST-segment changes in some animals. Ventricular tachyarrhythmias are common. Echocardiography reveals the extent of LV hypertrophy and subaortic narrowing. A discrete tissue ridge below the aortic valve is evident in many animals with moderate to severe disease (Fig. 5-5). Increased LV subendocardial echogenicity (probably from fibrosis) is common in animals with severe obstruction; systolic anterior motion of the anterior mitral leaflet and midsystolic partial aortic valve closure suggest concurrent dynamic LV outflow obstruction. Ascending aorta dilation, aortic valve thickening, and LA enlargement with hypertrophy may also be seen. In mildly affected animals 2-D and M-mode findings may be unremarkable. Doppler echocardiography reveals systolic turbulence originating below the aortic valve and extending into the aorta, as well as high peak systolic outflow velocity (Fig. 5-6). Some degree of aortic or mitral regurgitation is common. Spectral Doppler studies are used to estimate the stenosis severity. Doppler-estimated systolic pressure gradients in unanesthetized animals are usually 40% to 50%

FIG 5-5â•…

Echocardiogram from a 6-month-old German Shepherd Dog with severe subaortic stenosis. Note the discrete ridge of tissue (arrow) below the aortic valve, creating a fixed outflow tract obstruction. A, Aorta; LV, left ventricle; RV, right ventricle.

FIG 5-6â•…

Color flow Doppler frame of the left ventricular outflow region in systole from a 2-year-old female Rottweiler with severe subaortic stenosis. Note the turbulent flow pattern originating below the aortic valve, as well as the thickened septum, papillary muscle, and left ventricular free wall. Right parasternal long axis view; Ao, Aorta; LA, left atrium; LV, left ventricle; RA, right atrium.

higher than those recorded during cardiac catheterization under anesthesia. Severe SAS is associated with peak estimated gradients greater than 100 to 125╯mm╯Hg. The LV outflow tract should be interrogated from more than one position to achieve the best possible alignment with blood flow. The subcostal (subxiphoid) position usually yields the

highest-velocity signals, although the left apical position is optimal in some animals. The Doppler-estimated aortic outflow velocity may be only equivocally high in animals with mild SAS, especially with suboptimal Doppler beam alignment. With optimal alignment, aortic root velocities of less than 1.7╯m/sec are typical in normal unsedated dogs; velocities over approximately 2.25╯m/sec are generally considered abnormal. Peak velocities in the equivocal range between these values may indicate the presence of mild SAS, especially if there is other evidence of disease such as a subaortic ridge, disturbed flow in the outflow tract or ascending aorta with an abrupt increase in velocity, and aortic regurgitation. This is mainly of concern when selecting animals for breeding. In some breeds (e.g., Boxer, Golden Retriever, Greyhound), outflow velocities in this equivocal range (1.8-2.25╯m/sec) are common. This may reflect breedspecific variation in LV outflow tract anatomy or response to sympathetic stimulation, rather than SAS. A limitation of using the estimated pressure gradient to assess outflow obstruction severity is that this gradient depends on blood flow. Factors causing sympathetic stimulation and increased cardiac output (e.g., excitement, exercise, fever) will increase outflow velocities, whereas myocardial failure, cardiodepressant drugs, and other causes of reduced stroke volume will decrease recorded velocities. Cardiac catheterization and angiocardiography are rarely used now to diagnose or quantify SAS, except in conjunction with balloon dilation of the stenotic area. Treatment and Prognosis Several palliative surgical techniques have been tried in dogs with severe SAS. Although some have reduced the LV systolic pressure gradient and possibly improved exercise ability, because of high complication rates, expense, and lack of a long-term survival advantage, surgery is not recommended. Likewise, transvascular balloon dilation of the stenotic area can reduce the measured gradient in some dogs, but significant survival benefit has not been documented with this procedure. Medical therapy with a β-blocker is advocated in patients with moderate to severe SAS to reduce myocardial oxygen demand and minimize the frequency and severity of arrhythmias. Animals with a high pressure gradient, marked ST-segment depression, frequent ventricular premature beats, or a history of syncope may be more likely to benefit from this therapy. Whether β-blockers prolong survival is unclear. Exercise restriction is advised for animals with moderate to severe SAS. Prophylactic antibiotic therapy is recommended for animals with SAS before the performance of any procedures with the potential to cause bacteremia (e.g., dentistry), although the efficacy of this in preventing endocarditis is unclear. The prognosis in dogs and cats with severe stenosis (catheterization pressure gradient > 80╯mm╯Hg or Doppler gradient > 100-125╯mm╯Hg) is guarded. More than half of dogs with severe SAS die suddenly within their first 3 years. The overall prevalence of sudden death in dogs with SAS appears

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to be just over 20%. Infective endocarditis and CHF may be more likely to develop after 3 years of age. Atrial and ventricular arrhythmias and worsened mitral regurgitation are complicating factors. Dogs with mild stenosis (e.g., catheterization gradient < 35╯mm╯Hg or Doppler gradient < 60-70╯mm╯Hg) are more likely to survive longer and without clinical signs.

PULMONIC STENOSIS Etiology and Pathophysiology PS is more common in small breeds of dogs. Some cases of valvular PS result from simple fusion of the valve cusps, but valve dysplasia is more common. Dysplastic valve leaflets are variably thickened, asymmetric, and partially fused, with a hypoplastic valve annulus. RV pressure overload leads to concentric hypertrophy, as well as secondary dilation of the RV. Severe ventricular hypertrophy promotes myocardial ischemia and its sequelae. Excessive muscular hypertrophy in the infundibular region below the valve can create a dynamic subvalvular component to the stenosis. Other variants of PS, including supravalvular stenosis and RV muscular partition (double-chamber RV), occur rarely. Turbulence caused by high-velocity flow across the stenotic orifice leads to poststenotic dilation in the main pulmonary trunk. Right atrial (RA) dilation from secondary tricuspid insufficiency and high RV filling pressure predisposes to atrial tachyarrhythmias and CHF. The combination of PS and a patent foramen ovale or ASD can allow rightto-left shunting at the atrial level. A single anomalous coronary artery has been described in some Bulldogs and Boxers with PS and is thought to contribute to the outflow obstruction. In such cases, palliative surgical procedures and balloon valvuloplasty may cause death secondary to transection or avulsion of the major left coronary branch. Clinical Features Many dogs with PS are asymptomatic when diagnosed, although right-sided CHF or a history of exercise intolerance or syncope may exist. Clinical signs may not develop until the animal is several years old, even in those with severe stenosis. Physical examination findings characteristic of moderate to severe stenosis include a prominent right precordial impulse; a thrill high at the left base; normal to slightly diminished femoral pulses; pink mucous membranes; and, in some cases, jugular pulses. A systolic ejection murmur is heard best high at the left base on auscultation. The murmur can radiate cranioventrally and to the right in some cases but is usually not heard over the carotid arteries. An early systolic click is sometimes identified; this is probably caused by abrupt checking of a fused valve at the onset of ejection. A murmur of tricuspid insufficiency or arrhythmias can be heard in some cases. Ascites and other signs of right-sided CHF are present in some cases. Occasionally, cyanosis accompanies right-to-left shunting through a concurrent atrial or ventricular septal defect.

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A

B

C FIG 5-7â•…

Lateral (A) and dorsoventral (DV) (B) radiographs from a dog with pulmonic stenosis, showing right ventricular enlargement (apex elevation on lateral view [arrowhead in A] and reverse D configuration on DV view) along with a pulmonary trunk bulge (arrowheads in B) seen on a DV view. C, Angiocardiogram using a selective right ventricular injection demonstrates poststenotic dilation of the main pulmonary trunk and pulmonary arteries. The thickened pulmonic valve is closed in this diastolic frame.

Diagnosis Radiographic findings typically seen with PS are outlined in Table 5-2 on page 99. Marked RV hypertrophy shifts the cardiac apex dorsally and to the left. The heart may appear as a “reverse D” shape on a DV or ventrodorsal (VD) view. A variably sized pulmonary trunk bulge (poststenotic dilation) is best seen at the 1 o’clock position on a DV or VD view (Fig. 5-7). The size of the poststenotic dilation does not necessarily correlate with the severity of the pressure gradient. Diminutive peripheral pulmonary vasculature and/or a dilated caudal vena cava may be apparent. ECG changes are more common with moderate to severe stenosis. These include an RV hypertrophy pattern, right axis

deviation, and sometimes an RA enlargement pattern or tachyarrhythmias. Echocardiographic findings characteristic of moderate to severe stenosis include RV concentric hypertrophy and enlargement. The interventricular septum appears flattened when pressure in the RV exceeds that in the LV and pushes it toward the left (Fig. 5-8, A). Secondary RA enlargement is common as well, especially with concurrent tricuspid regurgitation (TR). A thickened, asymmetric, or otherwise malformed pulmonic valve usually can be identified (see Fig. 5-8, B), although the outflow region may be narrow and difficult to clearly visualize. Poststenotic dilation of the main pulmonary trunk is expected. Pleural effusion and marked right heart dilation generally accompany

CHAPTER 5â•…â•… Congenital Cardiac Disease

A

105

B FIG 5-8â•…

Echocardiograms from two dogs with severe pulmonic stenosis. (A) Right parasternal short-axis view at the ventricular level in a 4-month-old male Samoyed shows right ventricular hypertrophy (arrows) and enlargement; high right ventricular pressure flattens the septum toward the left in this diastolic frame. (B) Thickened, partially fused leaflets of the malformed pulmonary valve (arrows) are seen in a 5-month-old male Pomeranian. Ao, Aortic root; LA, left atrium; RVOT, right ventricular outflow tract; RVW, right ventricular wall.

secondary CHF. Paradoxical septal motion is likely in such cases as well. Doppler evaluation along with anatomic findings provides an estimate of PS severity. Cardiac catheterization and angiocardiography can also be used to assess the pressure gradient across the stenotic valve, the right heart filling pressure, and other anatomic features. Dopplerestimated systolic pressure gradients in unanesthetized animals are usually 40% to 50% higher than those recorded during cardiac catheterization. PS is generally considered mild if the Doppler-derived gradient is less than 50╯mm╯Hg and severe if it is greater than 80 to 100╯mm╯Hg. Treatment and Prognosis Balloon valvuloplasty is recommended for palliation of severe (and sometimes moderate) stenosis, especially if infundibular hypertrophy is not excessive. This procedure can reduce or eliminate clinical signs and appears to improve long-term survival in severely affected animals. Balloon valvuloplasty, done in conjunction with cardiac catheterization and angiocardiography, involves passing a specially designed balloon catheter across the valve and inflating the balloon to enlarge the stenotic orifice. Pulmonary valves with mild to moderate thickening and simple fusion of the leaflets are likely to be easier to effectively dilate. Dysplastic valves can be more difficult to dilate effectively, but good results

are possible in some cases. A recent retrospective study (Locatelli et╯al, 2011) found that balloon valvuloplasty resulted in postprocedure Doppler gradients of 50 mm Hg or less in 58% of dogs with PS. Although 62% of dogs with mild to moderate valve leaflet thickening and fusion and normal annulus size (“type A” PS) achieved this outcome, compared with only 41% of dogs with severe valve thickening and/or annulus hypoplasia (“type B” PS), this difference did not reach significance. The only independent predictor of suboptimal postballooning result in this study was a higher prevalvuloplasty Doppler gradient. Various surgical procedures have also been used to palliate moderate to severe PS in dogs. Balloon valvuloplasty is usually attempted before a surgical procedure because it is less risky. Animals with a single anomalous coronary artery generally should not undergo balloon or surgical dilation procedures because of increased risk of death, although conservative ballooning has reportedly been palliative in a few cases. Coronary anatomy can be verified using echocardiography or angiography. Exercise restriction is advised for animals with moderate to severe stenosis. β-Blocker therapy may be helpful, especially in those with prominent RV infundibular hypertrophy. Signs of CHF are managed medically (see Chapter 3). The prognosis in patients with PS is variable and depends on the

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severity of the lesion and any complicating factors. Life span can be normal in those with mild to moderate PS, whereas animals with severe PS often die within 3 years of diagnosis. Sudden death occurs in some; development of CHF is more common. The prognosis is considerably worse in animals with tricuspid regurgitation, atrial fibrillation or other tachyarrhythmias, or CHF.

INTRACARDIAC SHUNT Blood flow volume across an intracardiac shunt depends on the size of the defect and the pressure gradient across it. In most cases, flow direction is from left to right, causing pulmonary overcirculation. Compensatory increases in blood volume and cardiac output occur in response to the partial diversion of blood away from the systemic circulation. A volume overload is imposed on the side of the heart doing the most work. If right heart pressures increase as a result of increased pulmonary resistance or a concurrent PS, shunt flow may equilibrate or reverse (i.e., become right to left).

VENTRICULAR SEPTAL DEFECT Etiology and Pathophysiology Most VSDs are located in the membranous part of the septum, just below the aortic valve and beneath the septal tricuspid leaflet (infracristal VSD). VSDs also occur spora� dically in other septal locations, including the muscular septum, and just below the pulmonary valve (supracristal VSD). A VSD may be accompanied by other AV septal (endocardial cushion) malformations, especially in cats. Usually, VSDs cause volume overloading of the pulmonary circulation, LA, LV, and RV outflow tract. Small defects may be clinically unimportant. Moderate to large defects tend to cause left heart dilation and can lead to left-sided CHF. A very large VSD causes the ventricles to function as a common chamber and induces RV dilation and hypertrophy. Pulmonary hypertension secondary to overcirculation is more likely to develop with large shunts. Some animals with VSD also have aortic regurgitation, with diastolic prolapse of a valve leaflet. Presumably this occurs because the deformed septum provides inadequate support for the aortic root. Aortic regur� gitation places an additional volume load on the LV. Clinical Features The most common clinical manifestations of VSD are exercise intolerance and signs of left-sided CHF, but many animals are asymptomatic at the time of diagnosis. The characteristic auscultatory finding is a holosystolic murmur, heard loudest at the cranial right sternal border (which corresponds to the usual direction of shunt flow). A large shunt volume can produce a murmur of relative or functional PS (systolic ejection murmur at the left base). With concurrent aortic regurgitation, a corresponding diastolic decrescendo murmur may be audible at the left base.

Diagnosis Radiographic findings associated with VSD vary with the size of the defect and the shunt volume (see Table 5-2). Large shunts typically cause left heart enlargement and pulmonary overcirculation. However, large shunts that increase pulmonary vascular resistance and pressure lead to RV enlargement. A large shunt volume (with or without pulmonary hypertension) can also increase main pulmonary trunk size. The ECG may be normal or suggest LA or LV enlargement. In some cases, disturbed intraventricular conduction is suggested by “fractionated” or splintered QRS complexes. An RV enlargement pattern usually indicates a large defect, pulmonary hypertension, or a concurrent RV outflow tract obstruction, although sometimes a right bundle-branch block causes this pattern. Echocardiography reveals left heart dilation (with or without RV dilation) when the shunt is large. The defect can often be visualized just below the aortic valve in the right parasternal long-axis LV outflow view. The septal tricuspid leaflet is located to the right of the defect. Because echo “dropout” at the thin membranous septum can mimic a VSD, the area of a suspected defect should be visualized in more than one plane. Supporting clinical evidence and a murmur typical of a VSD should also be present before the diagnosis is made. Doppler (or echo-contrast) studies usually demonstrate the shunt flow (Fig. 5-9). Spectral Doppler assessment of shunt flow peak velocity is used to estimate the systolic pressure gradient between the LV and RV. Small (restrictive or resistive) VSDs cause a high-velocity shunt flow (≈4.5-5 m/sec) because of the normally large systolic

FIG 5-9â•…

Color flow Doppler frame in systole showing turbulent flow (from left to right) through a small membranous ventricular septal defect just below the aortic root in a 1-year-old male terrier. Right parasternal long axis view; AO, aortic root; LV, left ventricle.

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pressure difference between the ventricles. Lower peak shunt velocity usually implies increased RV systolic pressure, either from PS or pulmonary hypertension. Cardiac catheterization, oximetry, and angiocardiography allow measurement of intracardiac pressures, indicate the presence of an oxygen step-up at the level of the RV outflow tract, and show the pathway of abnormal blood flow.

is expected across the ASD, although large left-to-right shunts can cause a murmur of relative PS. Fixed splitting (i.e., with no respiratory variation) of the second heart sound (S2) is the classic auscultatory finding, caused by delayed pulmonic and early aortic valve closures. Rarely, a soft diastolic murmur of relative tricuspid stenosis might be audible. Large ASDs can lead to signs of right-sided CHF.

Treatment and Prognosis A small to moderate defect usually allows a relatively normal life span. In some cases, the defect closes spontaneously within the first 2 years of life. Closure can result from myocardial hypertrophy around the VSD or a seal formed by the septal tricuspid leaflet or a prolapsed aortic leaflet. Left-sided CHF is more likely in animals with a large septal defect, although in some cases pulmonary hypertension with shunt reversal develops instead, usually at an early age. Definitive therapy for VSD usually requires cardiopulmonary bypass or hypothermia and intracardiac surgery, although transcatheter delivery of an occlusion device has been successful in some cases. Large left-to-right shunts sometimes have been palliated by surgically placing a constrictive band around the pulmonary trunk to create a mild supravalvular PS. This raises RV systolic pressure in response to the increased outflow resistance. Consequently, less blood shunts from the LV to RV. However, an excessively tight band can cause right-to-left shunting (functionally analogous to a T of F). Left-sided CHF is managed medically. Palliative surgery should not be attempted in the presence of pulmonary hypertension and shunt reversal.

Diagnosis Right heart enlargement, with or without pulmonary trunk dilation, is found radiographically in patients with larger shunt volumes (see Table 5-2). The pulmonary circulation may appear increased unless pulmonary hypertension has developed. Left heart enlargement is not evident unless another defect such as mitral insufficiency is present. The ECG may be normal or show evidence of RV and RA enlargement. Cats with an AV septal defect may have RV enlargement and a left axis deviation. Echocardiography is likely to show RA and RV dilation, with or without paradoxical interventricular septal motion. Larger ASDs can be visualized. Care must be taken not to confuse the thinner fossa ovalis region of the interatrial septum with an ASD because echo dropout also occurs here. Doppler echocardiography allows identification of smaller shunts that cannot be clearly visualized on 2-D examination, but venous inflow streams may complicate this. Cardiac catheterization shows an oxygen step-up at the level of the right atrium (RA). Abnormal flow through the shunt may be evident after the injection of contrast material into the pulmonary artery.

ATRIAL SEPTAL DEFECT

Treatment and Prognosis Large shunts can be treated surgically, similarly to VSDs. Otherwise, animals are managed medically if CHF develops. The prognosis is variable and depends on shunt size, concurrent defects, and the level of pulmonary vascular resistance.

Etiology and Pathophysiology Several types of ASD exist. Those located in the region of the fossa ovalis (ostium secundum defects) are more common in dogs. An ASD in the lower interatrial septum (ostium primum defect) is likely to be part of the AV septal (endocardial cushion or common AV canal) defect complex, especially in cats. Sinus venosus–type defects are rare; these are located high in the atrial septum near the entry of the cranial vena cava. Animals with ASD commonly have other cardiac malformations as well. In most cases of ASD, blood shunts from the LA to RA and results in a volume overload to the right heart. However, if PS or pulmonary hypertension is present, right-to-left shunting and cyanosis may occur. Patent foramen ovale, where embryonic atrial septation has occurred normally but the overlap between the septum primum and septum secundum does not seal closed, is not considered a true ASD. Nevertheless, if RA pressure becomes abnormally high, right-to-left shunting can occur here also. Clinical Features The clinical history in animals with an ASD is usually nonspecific. Physical examination findings associated with an isolated ASD are often unremarkable. Because the pressure difference between right and left atria is minimal, no murmur

ATRIOVENTRICULAR VALVE MALFORMATION MITRAL DYSPLASIA Congenital malformations of the mitral valve apparatus include shortened, fused, or overly elongated chordae tendineae; direct attachment of the valve cusp to a papillary muscle; thickened or cleft or shortened valve cusps; prolapse of valve leaflets; abnormally positioned or malformed papillary muscles; and excessive dilation of the valve annulus. Mitral valve dysplasia (MD) is most common in large-breed dogs and also occurs in cats. Valvular regurgitation is the predominant functional abnormality, and it may be severe; the pathophysiology and sequelae resemble those of acquired mitral regurgitation (see p. 115). Mitral valve stenosis occurs uncommonly; the ventricular inflow obstruction increases LA pressure and can precipitate the development of pulmonary edema. Mitral regurgitation usually accompanies stenosis.

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Clinical signs associated with MD are similar to those seen with degenerative mitral valve disease, except for the younger patient age. Reduced exercise tolerance, respiratory signs of left-sided CHF, inappetence, and atrial arrhythmias (especially atrial fibrillation) are common in affected animals. Mitral regurgitation typically causes a holosystolic murmur heard best at the left apex. Animals with severe MD, especially those with stenosis, may also develop syncope with exertion, pulmonary hypertension, and signs of right- in addition to left-sided CHF. Radiographic, ECG, echocardiographic, and catheterization findings are similar to those of patients with acquired mitral insufficiency. Echocardiography can depict the specific mitral apparatus malformations, as well as the degree of chamber enlargement and functional changes. Animals with mitral stenosis have a typical mitral inflow pattern with prolonged high velocity, reflecting the diastolic pressure gradient. Therapy consists of medical management for CHF. Animals with mild to moderate mitral valve dysfunction may do well clinically for years. However, for those with severe mitral regurgitation or stenosis, the prognosis is poor. Surgical valve reconstruction or replacement may be possible in some cases.

RV and occasionally RA enlargement patterns are seen on ECG. A splintered QRS complex configuration may be seen. Atrial fibrillation or other atrial tachyarrhythmias occur commonly. Evidence for ventricular preexcitation is seen in some cases. Echocardiography reveals right heart dilation, which can be massive. Malformations of the valve apparatus may be clear in several views (Fig. 5-10), although the left apical four-chamber view is especially useful. Doppler flow patterns are similar to those of MD. Intracardiac electrocardiography is necessary to confirm an Ebstein anomaly, which is suggested by ventral displacement of the tricuspid valve annulus; a ventricular electrogram recorded on the RA side of the valve is diagnostic. CHF and arrhythmias are managed medically. Periodic thoracocentesis may be necessary in animals with pleural effusion that cannot be controlled with medication and diet. The prognosis is guarded to poor, especially when cardiomegaly is marked. Nevertheless, some dogs survive for several years. Surgical replacement of the tricuspid valve with a bioprosthesis, by means of cardiopulmonary bypass, has been described in a small number of dogs. Balloon dilation has occasionally been successful for treating tricuspid stenosis.

TRICUSPID DYSPLASIA Animals with tricuspid dysplasia (TD) have malformations of the tricuspid valve and related structures that are similar to those of MD. The tricuspid valve can be displaced ventrally into the ventricle (an Ebstein-like anomaly) in some cases; ventricular preexcitation may be more likely in these animals. Tricuspid dysplasia is identified most frequently in large-breed dogs, particularly in Labrador Retrievers, and in males. Cats are also affected. The pathophysiologic features of TD are the same as those of acquired tricuspid regurgitation. Severe cases result in marked enlargement of the right heart chambers. Progressive increase in RA and RV end-diastolic pressures eventually result in right-sided CHF. Tricuspid stenosis is rare. The historical signs and clinical findings likewise are similar to those of degenerative tricuspid disease. Initially, the animal may be asymptomatic or mildly exercise intolerant. However, exercise intolerance, abdominal distention resulting from ascites, dyspnea resulting from pleural effusion, anorexia, and cardiac cachexia often develop. The murmur of tricuspid regurgitation is characteristic. However, not all cases have an audible murmur because the dysplastic leaflets may gap so widely in systole that there is little resistance to backflow and therefore minimal turbulence. Jugular pulsations are common. Additional signs that accompany CHF include jugular vein distention, muffled heart and lung sounds, and ballotable abdominal fluid. Radiographs demonstrate RA and RV enlargement. The round appearance of the heart shadow in some cases is similar to that seen in patients with pericardial effusion or dilated cardiomyopathy. A distended caudal vena cava, pleural or peritoneal effusion, and hepatomegaly are common.

CARDIAC ANOMALIES CAUSING CYANOSIS Malformations that allow deoxygenated blood to reach the systemic circulation result in hypoxemia. Visible cyanosis occurs when the desaturated hemoglobin concentration is greater than 5╯g/dL, which becomes more likely in patients with erythrocytosis. Arterial hypoxemia stimulates increased red blood cell production, which increases oxygen carrying capacity. However, blood viscosity and resistance to flow also rise with the increase in PCV. Severe erythrocytosis (PCV ≥ 65%) can lead to microvascular sludging, poor tissue oxygenation, intravascular thrombosis, hemorrhage, and cardiac arrhythmias. Erythrocytosis can become extreme, with a PCV of greater than 80% in some animals. Hyperviscosity is thought to underlie many of the clinical signs in affected animals, including progressive weakness, syncope, metabolic and hemostatic abnormalities, seizures, and cerebrovascular accidents. The possibility of a venous embolus crossing the shunt to the systemic circulation poses another danger in these cases. Anomalies that most often cause cyanosis in dogs and cats are T of F and pulmonary arterial hypertension secondary to a large PDA, VSD, or ASD. Other complex but uncommon anomalies such as transposition of the great vessels or truncus arteriosus also send deoxygenated blood to the systemic circulation. Some collateral blood flow to the lungs develops from the bronchial arteries of the systemic circulation. These small tortuous vessels may increase the overall radiographic opacity of the central pulmonary fields. Physical exertion tends to exacerbate right-to-left shunting and cyanosis, as peripheral vascular resistance

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B FIG 5-10â•…

Right parasternal long-axis echo images from a 1-year-old male Labrador Retriever with tricuspid valve dysplasia in diastole (A) and systole (B). The valve annulus appears to be ventrally displaced; the leaflet tips are tethered to a malformed, wide papillary muscle (arrows in A). Wide leaflet tip separation in systole (B) caused severe tricuspid regurgitation and clinical congestive heart failure. LA, Left atrium; LV, left ventricle; RA, right atrium; RV, right ventricle.

decreases and blood flow to skeletal muscle increases. Despite the pressure overload on the right heart, CHF is rare; the shunt provides an alternate pathway for high pressure flow.

TETRALOGY OF FALLOT Etiology and Pathophysiology The four components of the T of F are a VSD, PS, a dextropositioned aorta, and RV hypertrophy. The VSD can be quite large. The PS can involve the valve or infundibular area; in some cases, the pulmonary artery is hypoplastic or not open at all (atretic). The large aortic root extends over the right side of the interventricular septum and facilitates RV-toaortic shunting. Aortic anomalies exist in some animals as well. RV hypertrophy occurs in response to the pressure overload imposed by the PS and systemic arterial circulation. The volume of blood shunted from the RV into the aorta depends on the balance of outflow resistance caused by the fixed PS compared with systemic arterial resistance, which can vary. Exercise and other causes of decreased arterial resistance increase right-to-left shunt volume. Dynamic RV outflow obstruction from extensive infundibular hypertrophy also exacerbates right-to-left shunting in some cases. Pulmonary vascular resistance is generally normal in animals with T of F. A polygenic inheritance pattern for T of F has been identified in the Keeshond. The defect also occurs in other dog breeds and in cats. Clinical Features Exertional weakness, dyspnea, syncope, cyanosis, and stunted growth are common in the history. Physical examination

findings are variable, depending on the relative severity of the malformations. Cyanosis is seen at rest in some animals. Others have pink mucous membranes, although cyanosis usually becomes evident with exercise. The precordial impulse is usually of equal intensity or stronger on the right chest wall than on the left. Inconsistently, a precordial thrill may be palpable at the right sternal border or left basilar area. Jugular pulsation may be noted. A holosystolic murmur at the right sternal border consistent with a VSD, or a systolic ejection murmur at the left base compatible with PS, or both may be heard on auscultation. However, some animals have no audible murmur because hyperviscosity associated with erythrocytosis diminishes blood turbulence and therefore murmur intensity. Diagnosis Thoracic radiographs depict variable cardiomegaly, usually of the right heart (see Table 5-2). The main pulmonary artery may appear small, although a bulge is evident in some cases. Reduced pulmonary vascular markings are common, although a compensatory increase in bronchial circulation can increase the overall pulmonary opacity. The malpositioned aorta can create a cranial bulge in the heart shadow on lateral view. RV hypertrophy displaces the left heart dorsally and can simulate left heart enlargement. The ECG typically suggests RV enlargement, although a left axis deviation has been seen in some affected cats. Echocardiography depicts the VSD, a large aortic root shifted rightward and overriding the ventricular septum, some degree of PS, and RV hypertrophy. Doppler studies reveal the right-to-left shunt and high-velocity stenotic

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pulmonary outflow jet. An echo-contrast study can also document the right-to-left shunt. Typical clinicopathologic abnormalities include increased PCV and arterial hypoxemia. Treatment and Prognosis Definitive repair of T of F requires open-heart surgery. Palliative surgical procedures can increase pulmonary blood flow by creating a left-to-right shunt. Anastomosis of a subclavian artery to the pulmonary artery and the creation of a window between the ascending aorta and pulmonary artery are two techniques that have been used successfully. Severe erythrocytosis and clinical signs associated with hyperviscosity (e.g., weakness, shortness of breath, seizures) can be treated with periodic phlebotomy (see p. 111) or, alternatively, hydroxyurea (see p. 111). The goal is to maintain PCV at a level where clinical signs are minimal; further reduction of PCV (into the normal range) can exacerbate signs of hypoxia. A β-blocker may help reduce clinical signs in some dogs with T of F. Decreased sympathetic tone, RV contractility, RV (muscular) outflow obstruction, and myocardial oxygen consumption, along with increased peripheral vascular resistance, are potential benefits, although the exact mechanism is not clear. Exercise restriction is also advised. Drugs with systemic vasodilator effects should not be given. Supplemental O2 has negligible benefit in patients with T of F. The prognosis for animals with T of F depends on the severity of PS and erythrocytosis. Mildly affected animals and those that have had a successful palliative surgical shunting procedure may survive well into middle age. Nevertheless, progressive hypoxemia, erythrocytosis, and sudden death at an earlier age are common.

PULMONARY HYPERTENSION WITH SHUNT REVERSAL Etiology and Pathophysiology Pulmonary hypertension develops in a relatively small percentage of dogs and cats with shunts. The defects usually associated with development of pulmonary hypertension are PDA, VSD, AV septal defect or common AV canal, ASD, and aorticopulmonary window. The low-resistance pulmonary vascular system normally can accept a large increase in blood flow without marked rise in pulmonary arterial pressure. It is not clear why pulmonary hypertension develops in some animals, although the defect size in affected animals is usually quite large. Possibly the high fetal pulmonary resistance may not regress normally in these animals or their pulmonary vasculature may react abnormally to an initially large left-to-right shunt flow. In any case, irreversible histologic changes occur in the pulmonary arteries that increase vascular resistance. These include intimal thickening, medial hypertrophy, and characteristic plexiform lesions. As pulmonary vascular resistance increases, pulmonary artery pressure rises and the extent of left-to-right shunting diminishes. If right heart and pulmonary pressures exceed

those of the systemic circulation, the shunt reverses direction and deoxygenated blood flows into the aorta. These changes appear to develop at an early age (probably by 6 months), although exceptions are possible. The term Eisenmenger syndrome refers to the severe pulmonary hypertension and shunt reversal that develop. Right-to-left shunts that result from pulmonary hypertension cause pathophysiologic and clinical sequelae similar to those resulting from T of F. The major difference is that the impediment to pulmonary flow occurs at the level of the pulmonary arterioles rather than at the pulmonic valve. Hypoxemia, RV hypertrophy and enlargement, erythrocytosis and its consequences, increased shunting with exercise, and cyanosis can occur. Likewise, right-sided CHF is uncommon but can develop in response to secondary myocardial failure or tricuspid insufficiency. The right-to-left shunt potentially allows venous emboli to cross into the systemic arterial system and cause stroke or other arterial embolization. Clinical Features The history and clinical presentation of animals with pulmonary hypertension and shunt reversal are similar to those associated with T of F. Exercise intolerance, shortness of breath, syncope (especially in association with exercise or excitement), seizures, and sudden death are common. Cough and hemoptysis can also occur. Cyanosis may be evident only during exercise or excitement. Intracardiac shunts cause equally intense cyanosis throughout the body. Cyanosis of the caudal mucous membranes alone (differential cyanosis) is typically caused by a reversed PDA. Here, normally oxygenated blood flows to the cranial body via the brachycephalic trunk and left subclavian artery (from the aortic arch); because the ductus is located in the descending aorta, the caudal body receives desaturated blood (Fig. 5-11). Rear limb weakness is common in animals with reversed PDA. A murmur typical of the underlying defect(s) may be heard, but in many cases no murmur or only a soft systolic murmur is audible because high blood viscosity minimizes turbulence. There is no continuous murmur in patients with reversed PDA. Pulmonary hypertension often causes a loud and “snapping” or split S2 sound. A gallop sound is occasionally heard. Other physical examination findings can include a pronounced right precordial impulse and jugular pulsations. Diagnosis Thoracic radiographs typically reveal right heart enlargement; a prominent pulmonary trunk; and tortuous, proximally widened pulmonary arteries. A bulge in the descending aorta is common in dogs with reversed PDA. In animals with a reversed PDA or VSD, the left heart may be enlarged as well. The ECG usually suggests RV and sometimes RA enlargement, with a right axis deviation. Echocardiography reveals the RV hypertrophy and intracardiac anatomic defects (and sometimes a large ductus), as well as pulmonary trunk dilation. Doppler or echo-contrast study can confirm an intracardiac right-to-left shunt. Reversed PDA flow can be shown by imaging the abdominal

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B FIG 5-11â•…

Angiocardiograms from an 8-month-old female Cocker Spaniel with patent ductus arteriosus, pulmonary hypertension, and shunt reversal. Left ventricular injection (A) shows dorsal displacement of the left ventricle by the enlarged right ventricle. Note the dilution of radiographic contrast solution in the descending aorta (from mixing with nonopacified blood from the ductus) and the prominent right coronary artery. Right ventricular injection (B) illustrates right ventricular hypertrophy and pulmonary trunk dilation secondary to severe pulmonary hypertension. Opacified blood courses through the large ductus into the descending aorta.

aorta during venous echo-contrast injection. Peak RV (and in the absence of PS, pulmonary artery) pressure can be estimated by measuring the peak velocity of a tricuspid regurgitation jet. Pulmonary insufficiency flow can be used to estimate diastolic pulmonary artery pressure. Cardiac catheterization can also confirm the diagnosis and quantify the pulmonary hypertension and systemic hypoxemia. Treatment and Prognosis Therapy is aimed at managing secondary erythrocytosis to minimize signs of hyperviscosity and attempting to reduce pulmonary arterial pressure, if possible. Exercise restriction is also advised. Erythrocytosis can be managed by periodic phlebotomy or use of oral hydroxyurea (see later). Ideally the PCV is maintained at a level where the patient’s signs of hyperviscosity (e.g., rear limb weakness, shortness of breath, lethargy) are minimal. A PCV of about 62% has been recommended, but this may not be optimal for all cases. Surgical closure of the shunt is contraindicated. The prognosis is generally poor in animals with pulmonary hypertension and shunt reversal, although some patients do well for years with medical management. Phlebotomy is done when necessary. One method is to remove 5 to 10╯mL blood/kg body weight and administer an

equal volume of isotonic fluid. Another technique (Cote et╯al, 2001) involves initially removing 10% of the patient’s circulating blood volume without giving replacement fluid. The circulating blood volume (mL) is calculated as 8.5% × body weight (kg) × 1000╯g/kg × 1╯mL/g. After 3 to 6 hours of cage rest, an additional volume of blood is removed if the patient’s initial PCV was greater than 60%. This additional volume would be 5% to 10% of the circulating blood volume if initial PCV was 60% to 70%, or an additional 10% to 18% if initial PCV was greater than 70%. Hydroxyurea therapy (40-50╯mg/kg by mouth q48h or 3×/week) can be a useful alternative to periodic phlebotomy in some patients with secondary erythrocytosis. A complete blood cell count and platelet count should be monitored weekly or biweekly to start. Possible adverse effects of hydroxyurea include anorexia, vomiting, bone marrow hypoplasia, alopecia, and pruritus. Depending on the patient’s response, the dose can be divided q12h on treatment days, administered twice weekly, or administered at less than 40╯mg/kg. Sildenafil citrate is a selective phosphodiesterase-5 inhibitor that may reduce pulmonary resistance via nitric oxide– dependent pulmonary vasodilation. It can improve clinical signs and exercise tolerance in some dogs with pulmonary

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hypertension, although the capacity for pulmonary arteriolar dilation is limited in most cases. Doses of 1 to 2 (or 3) mg/kg q12h or q8h are generally well tolerated and may produce some reduction in Doppler-estimated pulmonary artery pressure. Lower initial doses are suggested, with gradual up-titration. The drug can be compounded for easier dosing in small animals. Use of “generic” sildenafil citrate is not recommended because potency may be suboptimal. Adverse effects of sildenafil can include possible nasal congestion, hypotension, or sexual adverse effects, especially in intact animals. Other vasodilator drugs tend to produce systemic effects that are similar to or greater than those on the pulmonary vasculature; therefore they are of little benefit and possibly detrimental. Low-dose aspirin (e.g., 5╯mg/kg) therapy may also be useful in animals with pulmonary hypertension and reversed shunt, but this is not well studied.

OTHER CARDIOVASCULAR ANOMALIES VASCULAR RING ANOMALIES Various vascular malformations originating from the embryonic aortic arch system can occur. These can entrap the esophagus and sometimes the trachea within a vascular ring at the dorsal heartbase. Persistent right aortic arch is the most common vascular ring anomaly in the dog. This developmental malformation surrounds the esophagus dorsally and to the right with the aortic arch, to the left with the ligamentum arteriosum, and ventrally with the base of the heart. Different vascular ring anomalies can occur as well. In addition, other vascular malformations such as a left cranial vena cava or PDA may accompany a vascular ring anomaly. Vascular ring anomalies are rare in cats. The vascular ring prevents solid food from passing normally through the esophagus. Clinical signs of regurgitation and stunted growth commonly develop within 6 months of weaning. Esophageal dilation occurs cranial to the ring; food may be retained in this area. Sometimes the esophagus dilates caudal to the stricture as well, indicating that altered esophageal motility coexists. The animal’s body condition score may be normal initially, but progressive debilitation ensues. A palpably dilated cervical esophagus (containing food or gas) is evident at the thoracic inlet in some cases. Fever and respiratory signs including coughing, wheezing, and cyanosis usually signal secondary aspiration pneumonia. However, in some cases a double aortic arch can cause stridor and other respiratory signs secondary to tracheal stenosis. Vascular ring anomalies by themselves do not result in abnormal cardiac sounds. Thoracic radiographs show a leftward tracheal deviation near the cranial heart border on DV view. Other common signs include a widened cranial mediastinum, focal narrowing and/or ventral displacement of the trachea, air or food in the cranial thoracic esophagus, and sometimes evidence of aspiration pneumonia. A barium swallow allows visualization of the esophageal stricture over the heartbase and

cranial esophageal dilation (with or without caudal esophageal dilation). Surgical division of the ligamentum arteriosum (or other vessel if the anomaly is not a persistent right aortic arch) is the recommended therapy. In some cases a retroesophageal left subclavian artery or left aortic arch is also present and must be divided to free the esophagus. Medical management consists of frequent small, semisolid, or liquid meals eaten in an upright position. This feeding method may be necessary indefinitely. Persistent regurgitation occurs in some dogs despite successful surgery, suggesting a permanent esophageal motility disorder.

COR TRIATRIATUM Cor triatriatum is an uncommon malformation caused by an abnormal membrane that divides either the right (dexter) or the left (sinister) atrium into two chambers. Cor triatriatum dexter occurs sporadically in dogs; cor triatriatum sinister has been described only rarely. Cor triatriatum dexter results from failure of the embryonic right sinus venosus valve to regress. The caudal vena cava and coronary sinus empty into the RA caudal to the intra-atrial membrane; the tricuspid orifice is within the cranial RA “chamber.” Obstruction to venous flow through the opening in the abnormal membrane elevates vascular pressure in the caudal vena cava and the structures that drain into it. Large- to medium-size breeds of dog are most often affected. Persistent ascites that develops at an early age is the most prominent clinical sign. Exercise intolerance, lethargy, distended cutaneous abdominal veins, and sometimes diarrhea are reported as well. Neither a cardiac murmur nor jugular venous distention is a feature of this anomaly. Thoracic radiographs indicate caudal vena caval distention without generalized cardiomegaly. The diaphragm may be displaced cranially by massive ascites. The ECG is usually normal. Echocardiography reveals the abnormal membrane and prominence of the caudal RA chamber and vena cava. Doppler studies show the flow disturbance within the RA and allow estimation of the intra-RA pressure gradient. Successful therapy requires enlarging the membrane orifice or excising the abnormal membrane to remove flow obstruction. A surgical approach using inflow occlusion, with or without hypothermia, can be used to excise the membrane or break it down using a valve dilator. A much less invasive option is percutaneous balloon dilation of the membrane orifice. This works well as long as a sufficiently large balloon is used. Several balloon dilation catheters placed simultaneously may be necessary for effective dilation in larger dogs. ENDOCARDIAL FIBROELASTOSIS Diffuse fibroelastic thickening of the LV and LA endocardium, with dilation of the affected chambers, characterizes the congenital abnormality endocardial fibroelastosis. It has been reported occasionally in cats, especially Burmese and Siamese, as well as in dogs. Left-sided or biventricular heart failure commonly develops early in life. A mitral

regurgitation murmur may be present. Criteria for LV and LA enlargement are seen on radiographs, ECG, and echocardiogram. Evidence for reduced LV myocardial function may be present. Definitive antemortem diagnosis is difficult.

OTHER VASCULAR ANOMALIES A number of venous anomalies have been described. Many are not clinically relevant. The persistent left cranial vena cava is a fetal venous remnant that courses lateral to the left AV groove and empties into the coronary sinus of the caudal RA. Although it causes no clinical signs, its presence may complicate surgical exposure of other structures at the left heartbase. Portosystemic venous shunts are common and can lead to hepatic encephalopathy, as well as other signs. These malformations are thought to be more prevalent in the Yorkshire Terrier, Pug, Miniature and Standard Schnauzers, Maltese, Pekingese, Shih Tzu, and Lhasa Apso breeds and are discussed in Chapter 38. Suggested Readings General References Buchanan JW: Prevalence of cardiovascular disorders. In Fox PR, Sisson D, Moise NS, editors: Textbook of canine and feline cardiology, ed 2, Philadelphia, 1999, Saunders, p 457. Oliveira P et al: Retrospective review of congenital heart disease in 976 dogs, J Vet Intern Med 25:477, 2011. Oyama MA et al: Congenital heart disease. In Ettinger SJ, Feldman EC, editors: Textbook of veterinary internal medicine, ed 7, St Louis, 2010, Saunders Elsevier, p 1250. Ventricular Outflow Obstruction Belanger MC et al: Usefulness of the indexed effective orifice area in the assessment of subaortic stenosis in the dog, J Vet Intern Med 15:430, 2001. Buchanan JW: Pathogenesis of single right coronary artery and pulmonic stenosis in English bulldogs, J Vet Intern Med 15:101, 2001. Bussadori C et al: Balloon valvuloplasty in 30 dogs with pulmonic stenosis: effect of valve morphology and annular size on initial and 1-year outcome, J Vet Intern Med 15:553, 2001. Estrada A et al: Prospective evaluation of the balloon-to-annulus ratio for valvuloplasty in the treatment of pulmonic stenosis in the dog, J Vet Intern Med 20:862, 2006. Falk T, Jonsson L, Pedersen HD: Intramyocardial arterial narrowing in dogs with subaortic stenosis, J Small Anim Pract 45:448, 2004. Fonfara S et al: Balloon valvuloplasty for treatment of pulmonic stenosis in English Bulldogs with aberrant coronary artery, J Vet Intern Med 24:354, 2010. Jenni S et al: Use of auscultation and Doppler echocardiography in Boxer puppies to predict development of subaortic or pulmonary stenosis. J Vet Intern Med 23:81, 2009. Kienle RD, Thomas WP, Pion PD: The natural history of canine congenital subaortic stenosis, J Vet Intern Med 8:423, 1994. Koplitz SL et al: Aortic ejection velocity in healthy Boxers with soft cardiac murmurs and Boxers without cardiac murmurs: 201 cases (1997-2001), J Am Vet Med Assoc 222:770, 2003. Locatelli C et al: Independent predictors of immediate and longterm results after pulmonary balloon valvuloplasty in dogs, J Vet Cardiol 13:21, 2011.

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Meurs KM, Lehmkuhl LB, Bonagura JD: Survival times in dogs with severe subvalvular aortic stenosis treated with balloon valvuloplasty or atenolol, J Am Vet Med Assoc 227:420, 2005. Orton EC et al: Influence of open surgical correction on intermediate-term outcome in dogs with subvalvular aortic stenosis: 44 cases (1991-1998), J Am Vet Med Assoc 216:364, 2000. Pyle RL: Interpreting low-intensity cardiac murmurs in dogs predisposed to subaortic stenosis (editorial), J Am Anim Assoc 36:379, 2000. Schrope DP: Primary pulmonic infundibular stenosis in 12 cats: natural history and the effects of balloon valvuloplasty, J Vet Cardiol 10:33, 2008. Stafford Johnson M et al: Pulmonic stenosis in dogs: balloon dilation improves clinical outcome, J Vet Intern Med 18:656, 2004. Cardiac Shunts Birchard SJ, Bonagura JD, Fingland RB: Results of ligation of patent ductus arteriosus in dogs: 201 cases (1969-1988), J Am Vet Med Assoc 196:2011, 1990. Blossom JE et al: Transvenous occlusion of patent ductus arteriosus in 56 consecutive dogs, J Vet Cardiol 12:75, 2010. Buchanan JW, Patterson DF: Etiology of patent ductus arteriosus in dogs, J Vet Intern Med 17:167, 2003. Bureau S, Monnet E, Orton EC: Evaluation of survival rate and prognostic indicators for surgical treatment of left-to-right patent ductus arteriosus in dogs: 52 cases (1995-2003), J Am Vet Med Assoc 227:1794, 2005. Campbell FE et al: Immediate and late outcomes of transarterial coil occlusion of patent ductus arteriosus in dogs, J Vet Intern Med 20:83, 2006. Chetboul V et al: Retrospective study of 156 atrial septal defects in dogs and cats (2001-2005), J Vet Med 53:179, 2006. Cote E, Ettinger SJ: Long-term clinical management of right-to-left (“reversed”) patent ductus arteriosus in 3 dogs, J Vet Intern Med 15:39, 2001. Fujii Y et al: Transcatheter closure of congenital ventricular septal defects in 3 dogs with a detachable coil, J Vet Intern Med 18:911, 2004. Fujii Y et al: Prevalence of patent foramen ovale with right-to-left shunting in dogs with pulmonic stenosis, J Vet Intern Med 26:183, 2012. Goodrich KR et al: Retrospective comparison of surgical ligation and transarterial catheter occlusion for treatment of patent ductus arteriosus in two hundred and four dogs (1993-2003), Vet Surg 36:43, 2007. Gordon SG et al: Transcatheter atrial septal defect closure with the Amplatzer atrial septal occlude in 13 dogs: short- and mid-term outcome, J Vet Intern Med 23:995, 2009. Gordon SG et al: Transarterial ductal occlusion using the Amplatz Canine Duct Occluder in 40 dogs, J Vet Cardiol 12:85, 2010. Guglielmini C et al: Atrial septal defect in five dogs, J Small Anim Pract 43:317, 2002. Hogan DF et al: Transarterial coil embolization of patent ductus arteriosus in small dogs with 0.025 inch vascular occlusion coils: 10 cases, J Vet Intern Med 18:325, 2004. Moore KW, Stepien RL: Hydroxyurea for treatment of polycythemia secondary to right-to-left shunting patent ductus arteriosus in 4 dogs, J Vet Intern Med 15:418, 2001. Nguyenba TP et al: Minimally invasive per-catheter patent ductus arteriosus occlusion in dogs using a prototype duct occluder, J Vet Intern Med 22:129, 2008.

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Orton EC et al: Open surgical repair of tetralogy of Fallot in dogs, J Am Vet Med Assoc 219:1089, 2001. Saunders AB et al: Pulmonary embolization of vascular occlusion coils in dogs with patent ductus arteriosus, J Vet Intern Med 18:663, 2004. Saunders AB et al: Echocardiographic and angiocardiographic comparison of ductal dimensions in dogs with patent ductus arteriosus, J Vet Intern Med 21:68, 2007. Schneider M et al: Transvenous embolization of small patent ductus arteriosus with single detachable coils in dogs, J Vet Intern Med 15:222, 2001. Schneider M et al: Transthoracic echocardiographic measurement of patent ductus arteriosus in dogs, J Vet Intern Med 21:251, 2007. Singh MK et al: Occlusion devices and approaches in canine patent ductus arteriosus: comparison and outcomes, J Vet Intern Med 26:85, 2012. Stafford Johnson M et al: Management of cor triatriatum dexter by balloon dilatation in three dogs, J Small Anim Pract 45:16, 2004. Stokhof AA, Sreeram N, Wolvekamp WTC: Transcatheter closure of patent ductus arteriosus using occluding spring coils, J Vet Intern Med 14:452, 2000. Van Israel N et al: Review of left-to-right shunting patent ductus arteriosus and short term outcome in 98 dogs, J Small Anim Pract 43:395, 2002.

Other Anomalies Adin DB, Thomas WP: Balloon dilation of cor triatriatum dexter in a dog, J Vet Intern Med 13:617, 1999. Arai S et al: Bioprosthesis valve replacement in dogs with congenital tricuspid valve dysplasia: technique and outcome, J Vet Cardiol 13:91, 2011. Buchanan JW: Tracheal signs and associated vascular anomalies in dogs with persistent right aortic arch, J Vet Intern Med 18:510, 2004. Famula TR et al: Evaluation of the genetic basis of tricuspid valve dysplasia in Labrador Retrievers, Am J Vet Res 63:816, 2002. Isakow K, Fowler D, Walsh P: Video-assisted thoracoscopic division of the ligamentum arteriosum in two dogs with persistent right aortic arch, J Am Vet Med Assoc 217:1333, 2000. Kornreich BG, Moise NS: Right atrioventricular valve malformation in dogs and cats: an electrocardiographic survey with emphasis on splintered QRS complexes, J Vet Intern Med 11:226, 1997. Lehmkuhl LB, Ware WA, Bonagura JD: Mitral stenosis in 15 dogs, J Vet Intern Med 8:2, 1994. Muldoon MM, Birchard SJ, Ellison GW: Long-term results of surgical correction of persistent right aortic arch in dogs: 25 cases (1980-1995), J Am Vet Med Assoc 210:1761, 1997.

C H A P T E R

6â•…

Acquired Valvular and Endocardial Disease

DEGENERATIVE ATRIOVENTRICULAR VALVE DISEASE Chronic degenerative atrioventricular (AV) valve disease is the most common cause of heart failure in the dog; it is estimated to cause more than 70% of the cardiovascular disease recognized in this species. Yet almost all small-breed dogs develop some degree of valve degeneration as they age. Degenerative valve disease is also known as endocardiosis, mucoid or myxomatous valvular degeneration, chronic valvular fibrosis, and other names. Because clinically relevant degenerative valve disease is rare in cats, this chapter focuses on canine chronic valvular disease. The mitral valve is affected most often and to a greater degree, but degenerative lesions also involve the tricuspid valve in many dogs. However, isolated degenerative disease of the tricuspid valve is uncommon. Thickening of the aortic and pulmonic valves is sometimes observed in older animals but rarely causes more than mild insufficiency. Etiology and Pathophysiology Although the specific pathogenic processes are unclear, mechanical valve stress and multiple chemical stimuli are thought to be involved. Serotonin (5-hydroxytryptamine) and transforming growth factor β signaling pathways, as well as developmental regulatory pathways common to valve, bone, and cartilage tissue have all been implicated in the pathogenesis of degenerative valve lesions in dogs and people. Normal valve interstitial cells, which maintain a normal extracellular matrix, are transformed into active myofibroblast-type cells that play an integral role in the degenerative process. Characteristic valve changes include collagen degeneration and disorganization, fragmentation of valve elastin, and excess deposition of proteoglycan and glucosaminoglycan (mucopolysaccharide), all of which thicken and weaken the valve apparatus. The histologic changes have been described as myxomatous degeneration. Middle-aged and older small to mid-size breeds are most often affected, and a strong hereditary basis is thought to exist. Disease prevalence and severity increase with age.

About a third of small-breed dogs older than 10 years of age are affected. Commonly affected breeds include Cavalier King Charles Spaniels, Toy and Miniature Poodles, Miniature Schnauzers, Chihuahuas, Pomeranians, Fox Terriers, Cocker Spaniels, Pekingese, Dachshunds, Boston Terriers, Miniature Pinschers, and Whippets. An especially high prevalence and an early onset of degenerative mitral valve disease (MVD) occurs in Cavalier King Charles Spaniels, in which inheritance is thought to be polygenic, with gender and age influencing expression. The overall prevalence of mitral regurgitation (MR) murmurs and degenerative valve disease appears similar in male and female dogs, but males have earlier onset and faster disease progression. Some largebreed dogs are also affected, and the prevalence may be higher in German Shepherd Dogs. Pathologic valve changes develop gradually with age. Early lesions consist of small nodules on the free margins of the valve. Over time these become larger, coalescing plaques that thicken and distort the valve. This myxomatous interstitial degeneration causes valvular nodular thickening and deformity. It also weakens the valve and its chordae tendineae. Redundant tissue between chordal attachments often bulges (prolapses) like a parachute toward the atrium. Mitral valve prolapse may be important in the pathogenesis of the disease, at least in some breeds. In severely affected regions, the valve surface also becomes damaged and endothelial cells are lost in some areas. Despite loss of valvular endothelial integrity, however, thrombosis and endocarditis are rare complications. Affected valves gradually begin to leak because their edges do not coapt properly. Regurgitation usually develops slowly over months to years. Pathophysiologic changes relate to volume overload on the affected side of the heart after the valve or valves become incompetent. Mean atrial pressure usually remains fairly low during this time, unless a sudden increase in regurgitant volume (e.g., ruptured chordae) occurs. As valve degeneration worsens, a progressively larger volume of blood moves ineffectually back and forth between the ventricle and atrium, diminishing the forward flow to the aorta. Compensatory mechanisms augment blood 115

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volume in an attempt to meet the circulatory needs of the body (see Chapter 3), including increased sympathetic activity and renin-angiotensin-aldosterone system (RAAS) activation. Atrial jet lesions and endocardial fibrosis develop as secondary lesions. In patients with advanced disease, partialor even full-thickness atrial tears can form. Remodeling of the affected ventricle (and atrium) gradually occurs in response to growing end-diastolic wall stress. A multitude of changes in left ventricular (LV) gene expression have been shown, many related to upregulated proinflammatory responses, collagen degradation, and reduced interstitial matrix production. The LV remodeling process is characterized by degradation and loss of the normal collagen weave between the cardiomyocytes, thought largely due to increased production of matrix metalloproteinases and chymase from mast cells. Chymase, rather than angiotensin-converting enzyme (ACE), is the enzyme responsible for interstitial production of angiotensin II in the myocardium, which contributes to continued ventricular remodeling. The interstitial collagen loss allows myocardial fiber slippage and, along with myocardial cell elongation and hypertrophy and changes in LV geometry, produces the typical progressive eccentric (dilation) hypertrophy pattern of chronic volume overloading. Stretching of the valve annulus as the ventricle dilates contributes to further valve regurgitation and volume overload. The compensatory changes in heart size and blood volume allow most dogs to remain asymptomatic for a prolonged period. Left atrial (LA) enlargement may become massive before any signs of decompensation appear, and some dogs never show clinical signs of heart failure. The rate at which the regurgitation worsens, as well as the degree of atrial distensibility and ventricular contractility, influences how well the disease is tolerated. A gradual increase in atrial, pulmonary venous, and capillary hydrostatic pressures stimulates compensatory increases in pulmonary lymphatic flow. Overt pulmonary edema develops when the capacity of the pulmonary lymphatic system is exceeded. Pulmonary hypertension secondary to chronically increased LA pressure and worsening tricuspid regurgitation (TR) lead to right-sided congestive heart failure (CHF) signs in many advanced cases. In addition to pulmonary venous hypertension, other factors contributing to increases in pulmonary vascular resistance may include hypoxic pulmonary arteriolar vasoconstriction, impaired endothelium-dependent vasodilation, and chronic neurohumoral activation. Ventricular pump function is usually maintained fairly well until late in the disease, even in the face of severe congestive signs. Nevertheless, studies of isolated myocardial cells from dogs with early, subclinical mitral regurgitation show reduced contractility, abnormal Ca++ kinetics, and evidence of oxidative stress. Progressive myocardial dysfunction exacerbates ventricular dilation and valve regurgitation and therefore can worsen CHF. Assessment of LV contractility in animals with MR is complicated by the fact that the commonly used clinical indices (echocardiographic fractional shortening or ejection fraction) overestimate contractility

because they are obtained during ejection and are therefore affected by the reduced ventricular afterload caused by MR. Estimation of the end-systolic volume index and some other echo/Doppler indices can also be helpful in assessing LV systolic and diastolic function (see p. 41). Chronic valvular disease is also associated with intramural coronary arteriosclerosis, microscopic intramural myocardial infarctions, and focal myocardial fibrosis. The extent to which these changes cause clinical myocardial dysfunction is not clear because senior dogs without valvular disease also have similar vascular lesions. Complicating Factors Although this disease usually progresses slowly, certain complicating events can precipitate acute clinical signs in dogs with previously compensated disease (Box 6-1). For example,

  BOX 6-1â•… Potential Complications of Chronic Atrioventricular Valve Disease Causes of Acutely Worsened Pulmonary Edema

Arrhythmias Frequent atrial premature complexes Paroxysmal atrial/supraventricular tachycardia Atrial fibrillation Frequent ventricular tachyarrhythmias Rule out drug toxicity (e.g., digoxin) Ruptured chordae tendineae Iatrogenic volume overload Excessive volumes of IV fluids or blood High-sodium fluids Erratic or improper medication administration Insufficient medication for stage of disease Increased cardiac workload Physical exertion Anemia Infections/sepsis Hypertension Disease of other organ systems (e.g., pulmonary, renal, liver, endocrine) Hot, humid environment Excessively cold environment Other environmental stresses High salt intake Myocardial degeneration and poor contractility Causes of Reduced Cardiac Output or Weakness

Arrhythmias (see above) Ruptured chordae tendineae Cough-syncope Left atrial tear Intrapericardial bleeding Cardiac tamponade Increased cardiac workload (see above) Secondary right-sided heart failure Myocardial degeneration and poor contractility

tachyarrhythmias may be severe enough to cause decompensated CHF, syncope, or both. Frequent atrial premature contractions, paroxysmal atrial tachycardia, or atrial fibrillation can reduce ventricular filling time and cardiac output, increase myocardial oxygen needs, and worsen pulmonary congestion and edema. Ventricular tachyarrhythmias also occur but are less common. Acute rupture of diseased chordae tendineae acutely increases regurgitant volume and can quickly precipitate fulminant pulmonary edema and signs of low cardiac output in asymptomatic or previously compensated dogs. Ruptured minor chordae tendineae can be an incidental finding in some dogs. Marked LA enlargement itself may compress the left mainstem bronchus and stimulate persistent coughing, even in the absence of CHF; however, this mechanism has been called into question. Concurrent airway inflammatory disease and bronchomalacia are common in small-breed dogs with chronic MR. Massive left (or right) atrial distention can result in partial- or full-thickness tearing. Atrial wall rupture can cause acute cardiac tamponade or an acquired atrial septal defect. There appears to be a higher prevalence of this complication in male Cocker Spaniels, Dachshunds, and possibly Miniature Poodles. In Cavalier King Charles Spaniels, the prevalence seems to be similar between females and males. Severe valve disease, marked atrial enlargement, atrial jet lesions, and ruptured first-order chordae tendineae are common findings in these cases. Clinical Features Degenerative AV valve disease may cause no clinical signs for years, and some dogs never develop signs of heart failure. In those that do, the signs usually relate to decreased exercise tolerance and manifestations of pulmonary congestion and edema. Diminished exercise capacity and cough or tachÂ� ypnea with exertion are common initial owner complaints. As pulmonary congestion and interstitial edema worsen, the resting respiratory rate increases. Coughing tends to occur at night and early morning, as well as in association with activity. Severe edema results in obvious respiratory distress and usually a moist cough. Signs of severe pulmonary edema can develop gradually or acutely. Intermittent episodes of symptomatic pulmonary edema interspersed with periods of compensated heart failure occurring over months to years are also common. Episodes of transient weakness or acute collapse (syncope) are more common in dogs with advanced disease. These may occur secondary to tachyarrhythmias, an acute vasovagal response, pulmonary hypertension, or an atrial tear. Coughing spells may precipitate syncope, as can exercise or excitement. Signs of TR are often overshadowed by those of MR but include ascites and respiratory distress from pleural effusion; subcutaneous edema is rare. Splanchnic congestion may precipitate gastrointestinal signs. The cough caused by mainstem bronchus compression is often described as “honking.” A holosystolic murmur heard best in the area of the left apex (left fourth to sixth intercostal space) is typical in

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patients with MR. The murmur can radiate in any direction. Mild regurgitation may be inaudible or cause a murmur only in early systole (protosystolic). Exercise and excitement often increase the intensity of soft MR murmurs. Louder murmurs have been associated with more advanced disease, but in dogs with massive regurgitation and severe heart failure the murmur can be soft or even inaudible. Occasionally, the murmur sounds like a musical tone or whoop. Some dogs with early MVD have an audible mid- to late-systolic click, with or without a soft murmur. In dogs with advanced disease and myocardial failure, an S3 gallop may be audible at the left apex. TR typically causes a holosystolic murmur best heard at the right apex. Features that aid in differentiating a TR murmur from radiation of an MR murmur to the right chest wall include jugular vein pulsations, a precordial thrill over the right apex, and a different quality to the murmur heard over the tricuspid region. Pulmonary sounds can be normal or abnormal. Accentuated, harsh breath sounds and end-inspiratory crackles (especially in ventral lung fields) develop as pulmonary edema worsens. Fulminant pulmonary edema causes widespread inspiratory, as well as expiratory, crackles and wheezes. Some dogs with chronic MR have abnormal lung sounds caused by underlying pulmonary or airway disease rather than CHF. Although not a pathognomonic finding, dogs with CHF often have sinus tachycardia, while marked sinus arrhythmia is common in those with chronic pulmonary disease. Pleural effusion may cause diminished pulmonary sounds ventrally. Other physical examination findings may be normal or noncontributory. Peripheral capillary perfusion and arterial pulse strength are usually good, although pulse deficits may be present in dogs with tachyarrhythmias. A palpable precordial thrill accompanies loud (grade 5-6/6) murmurs. Jugular vein distention and pulsations are not expected in dogs with MR alone. In animals with TR, jugular pulses occur during ventricular systole; these are more evident after exercise or in association with excitement. Jugular venous distention results from elevated right heart filling pressures. Jugular pulsations and distention are more evident with cranial abdominal compression (positive hepatojugular reflux). Ascites or hepatomegaly may be evident in dogs with right-sided CHF. Diagnosis

RADIOGRAPHY Thoracic radiographs typically show some degree of LA and LV enlargement (see p. 15), which progresses over months to years (Fig. 6-1). Dorsal elevation of the carina and, as LA size increases, dorsal main bronchus displacement occurs. Severe LA enlargement can cause the appearance of carina and left mainstem bronchus compression. Fluoroscopy may demonstrate dynamic airway collapse (of the left main bronchus or other regions) during coughing or even quiet breathing because concurrent airway disease is common in these cases. Extreme dilation of the LA can result over time, even without

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A

B FIG 6-1â•…

Lateral (A) and dorsoventral (B) radiographs from a Poodle with advanced mitral valve insufficiency. Note marked left ventricular and atrial enlargement and narrowing of left mainstem bronchus (arrowheads in A).

clinical heart failure. Variable right heart enlargement occurs with chronic TR, but this may be masked by left heart and pulmonary changes associated with concurrent MVD. Pulmonary venous congestion and interstitial edema occur with the onset of left-sided CHF; progressive interstitial and alveolar pulmonary edema may follow. However, visibly distended pulmonary veins are not always appreciable. Radiographic findings associated with early pulmonary edema can appear similar to those caused by chronic airway or pulmonary disease. Although cardiogenic pulmonary edema in dogs typically has a hilar, dorsocaudal, and bilaterally symmetric pattern, an asymmetric distribution is seen in some dogs. The presence and severity of pulmonary edema do not necessarily correlate with the degree of cardiomegaly. Acute, severe MR (e.g., with rupture of the chordae tendineae) can cause severe edema in the presence of minimal LA enlargement. Conversely, slowly worsening MR can produce massive LA enlargement with no evidence of CHF. Early signs of right-sided heart failure include caudal vena caval distention, pleural fissure lines, and hepatomegaly. Overt pleural effusion and ascites occur with advanced failure.

ELECTROCARDIOGRAPHY The electrocardiogram (ECG) may suggest LA or biatrial enlargement and LV dilation (see p. 20), although the tracing is often normal. An RV enlargement pattern is occasionally seen in dogs with severe TR. Arrhythmias, especially sinus tachycardia, supraventricular premature complexes, paroxysmal or sustained supraventricular tachycardias, ventricular premature complexes, and atrial fibrillation are common in dogs with advanced disease. These arrhythmias may be associated with decompensated CHF, weakness, or syncope.

FIG 6-2â•…

Sample M-mode echocardiogram from male Maltese with advanced mitral valve insufficiency and left-sided heart failure. Note accentuated septal and left ventricular posterior wall motion (fractional shortening = 50%) and lack of mitral valve E point–septal separation (arrows).

ECHOCARDIOGRAPHY Echocardiography shows the atrial and ventricular chamber dilation secondary to chronic AV valve insufficiency. Depending on the degree of volume overload, this enlargement can be severe. Vigorous LV wall and septal motion are seen with MR when contractility is normal (Fig. 6-2); fractional shortening is high, and there is little to no E point–septal separation. Although ventricular diastolic dimension is increased, systolic dimension remains normal until myocardial failure ensues. Calculation of end-systolic volume index may help

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B

A

C FIG 6-3â•…

A, Thick, mildly prolapsing mitral valve and left atrial enlargement are seen from the left apical position in an older Dachshund with severe degenerative atrioventricular valve disease. The tricuspid valve is also thick. B, Chorda tendineae rupture is evident by the flail segment (arrow) seen in the enlarged left atrium of an older mixed-breed dog. C, A large jet of mitral regurgitation causes a wide area of flow disturbance in another mixed breed dog on color flow echo. Note the left atrial and left ventricular enlargement. LA, Left atrium; LV, left ventricle; RA, right atrium.

in assessing myocardial function. Ventricular wall thickness is typically normal in dogs with chronic AV valve disease. With severe TR, paradoxical septal motion may occur along with marked right ventricular (RV) and right atrial (RA) dilation. Mild pericardial effusion can accompany signs of right-sided CHF. Pericardial fluid (blood) is also seen after an LA tear; clots within the fluid and/or evidence for cardiac tamponade may be evident. A search for other potential causes of cardiac tamponade (e.g., cardiac tumor) is warranted in such cases as well. Affected valve cusps are thickened and may appear knobby. Smooth thickening is characteristic of degenerative

disease (endocardiosis). Conversely, rough and irregular vegetative valve lesions are characteristic of bacterial endocarditis; however, clear differentiation between these by echocardiography alone may be impossible. Systolic prolapse involving one or both valve leaflets is common in patients with degenerative AV valve disease (Fig. 6-3, A). A ruptured chorda tendinea or leaflet tip is sometimes seen flailing into the atrium during systole (see Fig. 6-3, B). The direction and extent of flow disturbance can be seen with color-flow Doppler (see Fig. 2-34). Although the size of the disturbed flow area provides a rough estimate of regurgitation severity, there are technical limitations with this. The proximal

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isovelocity surface area (PISA) method is considered by some to be a more accurate way to estimate MR severity. However, two-dimensional assessment of LA size is a more straightforward and simple indicator of chronic MR severity (see pp. 36–37 in Chapter 2). Other Doppler techniques can be used to evaluate systolic and diastolic ventricular function. Maximal TR jet velocity indicates whether pulmonary hypertension is present and its severity. Clinicopathologic Findings Clinicopathologic data may be normal or reflect changes associated with CHF or concurrent extracardiac disease. Other diseases produce signs similar to those of CHF

resulting from degenerative AV valve disease, including tracheal collapse, chronic bronchitis, bronchiectasis, pulmonary fibrosis, pulmonary neoplasia, pneumonia, pharyngitis, heartworm disease, dilated cardiomyopathy, and bacterial endocarditis. Plasma brain natriuretic peptide measurement can help differentiate CHF as a cause of respiratory distress, as opposed to noncardiac causes (see p. 56 in Chapter 3). Treatment and Prognosis In dogs with stage C heart disease (see p. 57 in Chapter 3), medical therapy is used to control signs of CHF and support cardiac function and modulate the excessive neurohormonal activation that contributes to the disease process (Box 6-2).

  BOX 6-2â•… Treatment Guidelines for Chronic Atrioventricular Valve Disease Asymptomatic (Stage B)

Client education (about disease process and early heart failure signs) Routine health maintenance Blood pressure measurement Baseline chest radiographs (±echocardiogram) and yearly rechecks Maintain normal body weight/condition Regular mild to moderate exercise Avoid excessively strenuous activity Heartworm testing and prophylaxis in endemic areas Manage other medical problems Avoid high-salt foods; consider moderately salt-restricted diet Consider angiotensin-converting enzyme (ACE) inhibitor if marked increase in LA ± LV enlargement occurs; additional therapies aimed against neurohormonal activation may or may not be clinically useful Mild to Moderate Congestive Heart Failure Signs (Stage C, Chronic/Outpatient Care [Stage C2])*

Considerations as above Furosemide, as needed Pimobendan ACE inhibitor ±Spironolactone ± digoxin (indicated with atrial tachyarrhythmias, including fibrillation) Other antiarrhythmic therapy if necessary Complete exercise restriction until signs abate Moderate dietary salt restriction Resting respiratory (±heart) rate monitoring at home Severe Congestive Heart Failure Signs (Stage C, Acute/ Hospitalized [Stage C1])*

Supplemental O2 Cage rest and minimal patient handling Furosemide (more aggressive doses, parenteral) Vasodilator therapy Consider intravenous (IV) nitroprusside or Oral hydralazine or amlodipine ± topical nitroglycerin *See Tables 3-2 and 3-3 and Box 3-1 for further details and doses.

±Butorphanol or morphine Antiarrhythmic therapy, if necessary Pimobendan (continue or add when oral administration possible) ±Other (IV) positive inotropic drug if persistent hypotension or myocardial failure (see Box 3-1) After patient stabilized, ±digoxin therapy ±Bronchodilator Thoracocentesis, if moderate- to large-volume pleural effusion Chronic Recurrent or Refractory Heart Failure Strategies (Stage D; In-Hospital [Stage D1] or Outpatient [Stage D2] as Needed)*

Ensure that therapies for stage C are being given at optimal doses and intervals, including furosemide, ACE inhibitor, pimobendan, spironolactone Rule out systemic arterial hypertension, arrhythmias, anemia, and other complications Increase furosemide dose/frequency as needed; may be able to decrease again in several days after signs abate Enforced rest until signs abate Increase ACE inhibitor frequency to q12h (if not already done) Add digoxin, if not currently prescribed; monitor serum concentration; increase dose only if subtherapeutic concentration documented Add (or increase dose of) second diuretic (e.g., spironolactone, hydrochlorothiazide) Additional afterload reduction (e.g., amlodipine or hydralazine); monitor blood pressure Further restrict dietary salt intake; verify that drinking water is low in sodium Thoracocentesis (or abdominocentesis) as needed Manage arrhythmias, if present (see Chapter 4) Consider sildenafil for secondary pulmonary hypertension (e.g., 1-3╯mg/kg PO q8-12h) Consider bronchodilator trial or cough suppressant

Drugs that decrease LV size (e.g., diuretics, vasodilators, positive inotropic agents) may reduce the regurgitant volume by decreasing mitral annulus size. Drugs that promote arteriolar vasodilation enhance forward cardiac output and reduce regurgitant volume by decreasing systemic arteriolar resistance. Frequent reevaluation and medication adjustment become necessary as the disease progresses. In many dogs with chronic heart failure from advanced MR, clinical compensation can be maintained for months to years using appropriate therapy. Although initial or recurrent congestive signs develop gradually in some dogs, severe pulmonary edema or episodes of syncope appear acutely in others. Intermittent episodes of decompensation in dogs on long-term CHF therapy can often be successfully managed. Therapy must be guided by the patient’s clinical status and the nature of complicating factors. Surgical procedures such as mitral annuloplasty, other valve repair techniques, or mitral valve replacement may be treatment options in some patients.

Asymptomatic Atrioventricular Valve Regurgitation Dogs that have shown no clinical signs of disease (stage B) are generally not given drug therapy. Convincing evidence that angiotensin-converting enzyme inhibitor (ACEI) or other therapy delays time to CHF onset in asymptomatic dogs is presently lacking. Whether dogs with marked cardiomegaly might benefit from therapy to modulate pathologic remodeling is unclear. Experimental studies show that β-blocker treatment in early MR can improve myocyte function, mitigate changes in LV geometry, and perhaps delay onset of clinical signs. However, clinical trials in dogs with stage B disease so far have not shown a significant delay in onset of CHF or improved survival with β-blocker therapy. Client education about the disease process and early signs of CHF is important. Owners can observe their pet’s resting respiratory rate to establish the normal baseline. Periodic monitoring for persistent increases in resting rate (of about 20% or more) may signal the onset of pulmonary edema. It is probably prudent to discourage high-salt foods, pursue weight reduction for obese dogs, and avoid prolonged strenuous exercise. A diet moderately reduced in salt may be helpful. Periodic reevaluation (e.g., every 6-12 months, or more frequently if indicated) to assess cardiac size (and possibly function), as well as blood pressure, is advised. The greatest rate of change and degree of cardiac enlargement occurs within 4 to 12 months of CHF onset; measurement of radiographic (VHS) and echocardiographic (LA/Ao, LV diastolic and systolic diameters, and other) parameters are useful. Other disease conditions are managed as appropriate. Mild to Moderate Congestive Heart Failure When clinical signs of CHF occur in association with exercise or activity, several treatment modalities are instituted (see Box 6-2, Table 3-3, and Box 3-1). This is stage C heart

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failure; dogs stable enough for outpatient (home) therapy can be categorized as stage C2. The severity of clinical signs and the nature of any complicating factors influence the aggressiveness of therapy. Furosemide is used for dogs with radiographic evidence of pulmonary edema and/or more severe clinical signs. Higher and more frequent doses are used when edema is severe. Patients needing hospitalization for CHF therapy (see below and Chapter 3) are considered in stage C1 heart failure. After signs of failure are controlled, the dose and frequency of furosemide administration are gradually reduced to the lowest effective levels for chronic therapy. Furosemide alone (e.g., without an ACEI or other agent) is not recommended for the long-term treatment of heart failure. When it is unclear whether respiratory signs are caused by early CHF or a noncardiac cause, a therapeutic trial of furosemide (e.g., 1-2╯mg/kg by mouth q8-12h) and/ or NT-proBNP measurement can be helpful. Cardiogenic pulmonary edema usually responds rapidly to furosemide. An ACEI is generally recommended for dogs with early signs of failure (see Chapter 3). The ability of ACEIs to modulate neurohormonal responses to heart failure is thought to be their main advantage. Chronic ACEI therapy can improve exercise tolerance, cough, and respiratory effort, although the issue of enhanced survival is unclear. Pimobendan is also indicated once stage C heart failure has developed (see Chapter 3). This drug has positive inotropic, vasodilator, and other actions. Its beneficial effects on survival exceed those of an ACEI (benazepril), and it is most often used together with an ACEI. Spironolactone, as an aldosterone antagonist, appears to confer clinical benefits when used in the therapy of CHF. Therefore, it is also often added to the “triple” therapy described earlier for dogs with stage C heart failure. Moderate dietary salt restriction is usually recommended initially (see p. 69 in Chapter 3). Dogs with overt signs of CHF should not be allowed to exercise. Mild to moderate, regular activity (not causing undue respiratory effort) may be resumed once pulmonary edema has resolved. Strenuous exercise is not recommended. Antitussive therapy can be helpful in dogs without pulmonary edema but with persistent cough caused by mechanical mainstem bronchus compression (e.g., hydrocodone bitartrate, 0.25╯mg/kg PO q8-12h; or butorphanol, 0.5╯mg/kg PO q6-12h).

Severe, Acute Congestive Heart Failure Severe pulmonary edema and shortness of breath at rest require urgent treatment (see Chapter 3, Box 3-1). Aggressive diuresis with parenteral furosemide, supplemental oxygen, and cage rest are instituted as soon as possible. Gentle handling is important because added stress may precipitate cardiopulmonary arrest. Thoracic radiographs and other diagnostic procedures may need to be postponed until the animal’s respiratory condition is more stable. Vasodilator therapy is also indicated. If adequate monitoring facilities are available, intravenous (IV) nitroprusside infusion may be used for rapid arteriolar and venous

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dilation. Blood pressure must be closely monitored to avoid hypotension. Oral hydralazine can be used instead; its direct and rapid arteriolar vasodilating effect increases forward flow and decreases regurgitation. Amlodipine is an alternative arteriolar vasodilator, but with a slower onset of action. Topical nitroglycerin may help reduce pulmonary venous pressure by direct venodilation. Pimobendan is administered as soon as possible, as acute dyspnea begins to subside. For dogs with uncontrolled atrial fibrillation or frequent paroxysmal atrial tachycardia, IV diltiazem is recommended to control heart rate (see p. 81 in Chapter 4). For chronic therapy, PO digoxin with diltiazem or a β-blocker (see Table 4-2) can be used (see Chapter 4). Dogs that have persistent hypotension can be given an IV inotropic agent (e.g., dobutamine, see Box 3-1). Other ancillary therapy including mild sedation to reduce anxiety or a bronchodilator may be useful and is described in Chapter 3. Thoracocentesis is indicated to improve pulmonary function in dogs with moderate- to large-volume pleural effusion. Ascites that impedes respiration should also be drained. Close monitoring is important for titrating therapy and identifying complications (e.g., azotemia, electrolyte abnormalities, hypotension, arrhythmias). Once the patient’s condition is stabilized, medications are adjusted over several days to weeks to determine optimal long-term therapy. Furosemide is titrated to the lowest dose (and longest interval) that controls signs of CHF. If not already prescribed, an ACEI is added for ongoing therapy; hydralazine or amlodipine may be discontinued or may be continued for dogs approaching stage D heart failure.

Chronic Management of Advanced Disease As CHF worsens, therapy is intensified or modified according to individual patient needs. Progressively higher or more frequent doses of furosemide are usually necessary. Meanwhile, ACEI, pimobendan, and spironolactone doses are increased to their maximum recommended dosage, if tolerated. Patients requiring about 6╯mg/kg or more of furosemide in addition to other combination therapy are considered to be in stage D heart failure. Some of these dogs (stage D1) require in-hospital treatment for severe recurrent CHF signs, but others (stage D2) can be managed on an outpatient basis. Additional strategies for managing this chronic refractory heart failure are outlined on page 71 in Chapter 3. Digoxin is often added to the chronic therapy of CHF from advanced MR. Digoxin’s sensitizing effect on baroreceptors may be more advantageous than its modest positive inotropic effect (see Chapter 3). Marked LV dilation, evidence for reduced myocardial contractility, or recurrent episodes of pulmonary edema despite increasing furosemide doses and other treatment are rational indications for adding digoxin. Digoxin is also indicated for heart rate control in dogs with atrial fibrillation and for its antiarrhythmic effect in some cases of frequent atrial premature beats or supraventricular tachycardia. Conservative doses and measurement of serum concentrations are recommended to prevent toxicity (see p. 67).

Intermittent tachyarrhythmias can promote decompensated CHF and episodes of transient weakness or syncope. Cough-induced syncope, pulmonary hypertension, atrial rupture, or other causes of reduced cardiac output may also occur. Pulmonary hypertension associated with chronic MR is usually of mild to moderate severity but is occasionally severe. Signs of pulmonary hypertension are similar to other signs of advanced disease, including exercise intolerance, cough, dyspnea, syncope, cyanosis, and signs of right-sided CHF. The addition of sildenafil (1-3╯mg/kg q8-12h PO) to other CHF therapy can be helpful in dogs that develop syncope and/or right-sided CHF signs in association with marked pulmonary hypertension.

Patient Monitoring and Reevaluation Client education regarding the disease process, the clinical signs of failure, and the drugs used to control them is essential for long-term therapy to be successful. As the disease progresses, the need for medication readjustment (different dosages of currently used drugs and/or additional drugs) is expected. Several common potential complications of chronic degenerative AV valve disease can cause decompensation (see Box 6-1). At-home monitoring is important to detect early signs of decompensation. Respiratory (± heart) rate should be monitored periodically when the dog is quietly resting or sleeping (see p. 71); a persistent increase in either can signal early decompensation. Asymptomatic dogs should be reevaluated at least yearly in the context of a routine preventive health program. The frequency of reevaluation in dogs receiving medication for heart failure depends on the disease severity and whether any complicating factors are present. Dogs with recently diagnosed or decompensated CHF should be evaluated more frequently (within several days to a week or so) until their condition is stable. Those with chronic heart failure that appears well controlled can be reevaluated less frequently but usually several times per year. The specific drugs and doses being administered, medication supply, owner’s compliance, and patient’s attitude, activity level, and diet should be reviewed with the owner at each visit. A general physical examination with particular attention to cardiovascular parameters and patient’s respiratory rate and pattern is important at each visit. An ECG is indicated if an arrhythmia or unexpectedly low or high heart rate is found. When an arrhythmia is suspected but not documented on routine ECG, ambulatory electrocardiography (e.g., 24-hour Holter or event monitoring) can be helpful. Thoracic radiographs are warranted if abnormal pulmonary sounds are heard or if the owner reports coughing, other respiratory signs, or an increased resting respiratory rate. Other causes of cough should be considered if neither pulmonary edema nor venous congestion is seen radiographically and if the resting respiratory rate has not increased. Main bronchus compression or collapse can stimulate a dry cough. As discussed earlier, cough suppressants are helpful but should be prescribed only after other causes of cough are ruled out.

Echocardiography may show evidence of chordal rupture, progressive cardiomegaly, or worsened myocardial function. Frequent monitoring of serum electrolyte concentrations and renal function is important. Other routine blood and urine tests are also done periodically. Dogs receiving digoxin should have a serum concentration measured 7 to 10 days after treatment initiation or a dosage change. Additional measurements are recommended if signs consistent with toxicity (including appetite reduction or other gastrointestinal signs) appear or if renal disease or electrolyte imbalance (hypokalemia) is suspected. The prognosis in dogs that have developed clinical signs of degenerative valve disease is variable. Although CHF is the most common cardiac cause of death, sudden death occasionally occurs. Some dogs die during an initial episode of fulminant pulmonary edema. Survival for most symptomatic dogs ranges from several months to a few years. However, with appropriate CHF therapy and attentive management of complications, some dogs live well for more than 4 years after the signs of heart failure first appear. Important indicators of increased mortality risk include the degree of LA and LV enlargement, which reflect the severity of chronic MR, and also the level of circulating natriuretic peptides.

INFECTIVE ENDOCARDITIS Etiology and Pathophysiology Bacteremia, either persistent or transient, is necessary in order for endocardial infection to occur. The likelihood of a cardiac infection becoming established is increased when organisms are highly virulent or the bacterial load is heavy. Recurrent bacteremia may occur with infections of the skin, mouth, urinary tract, prostate, lungs, or other organs. Dentistry procedures are known to cause a transient bacteremia. Other procedures that are presumed to cause transient bacteremia sometimes include endoscopy, urethral catheterization, anal surgery, and other so-called “dirty” procedures. A predisposing cause is never identified in some cases of infective endocarditis. The endocardial surface of the valve is infected directly from the blood flowing past it. Previously normal valves may be invaded by virulent bacteria, causing acute bacterial endocarditis. Subacute bacterial endocarditis is thought to result from infection of previously damaged or diseased valves after a persistent bacteremia. Such damage may result from mechanical trauma (such as jet lesions from turbulent blood flow or catheter-induced endocardial injury). However, chronic degenerative MVD has not been associated with a higher risk for infective endocarditis of the mitral valve. The lesions of endocarditis are typically located downstream from the disturbed blood flow; common sites include the ventricular side of the aortic valve in patients with subaortic stenosis, the RV side of a ventricular septal defect, and the atrial surface of a regurgitant mitral valve. Bacterial clumping caused by the action of an agglutinating antibody may facilitate attachment to the valves. Alternatively, chronic

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stress and mechanical trauma can predispose to the development of nonbacterial thrombotic endocarditis, a sterile accumulation of platelets and fibrin on the valve surface. Nonseptic emboli may break off from such vegetations and cause infarctions elsewhere. Bacteremia can also cause a secondary infective endocarditis at these sites. The most common organisms identified in dogs with endocarditis have been Staphylococcus spp., Streptococcus spp., Corynebacterium (Arcanobacterium) spp., and Escherichia coli. Bartonella vinsonii subsp. berkhoffii and other Bartonella spp. have increasingly been identified in dogs with endocarditis. In one study, Bartonella spp. was identified as the causative agent in 45% of dogs with infective endocarditis but with a negative blood culture and in 20% of the overall population. Organisms isolated infrequently from infected valves have included Pasteurella spp., Pseudomonas aeruginosa, Erysipelothrix rhusiopathiae (E. tonsillaris), and others, including anaerobic Propionibacterium and Fusobacterium spp. The most common organisms identified in cats with endocarditis are Bartonella spp.; others include Staphylococcus spp., Streptococcus spp., E. coli, and anaerobes. Culture-negative endocarditis may be caused by fastidious organisms or by Bartonella spp., which enter endothelial and red blood cells. The mitral and aortic valves are most commonly affected in dogs and cats. Microbial colonization leads to ulceration of the valve endothelium. Subendothelial collagen exposure stimulates platelet aggregation and activation of the coagulation cascade, leading to the formation of vegetations. Vegetations consist mainly of aggregated platelets, fibrin, blood cells, and bacteria. Newer vegetations are friable, but with time the lesions become fibrous and may calcify. As additional fibrin is deposited over bacterial colonies, they become protected from normal host defenses and many antibiotics. Although vegetations usually involve the valve leaflets, lesions may extend to the chordae tendineae, sinuses of Valsalva, mural endocardium, or adjacent myocardium. Vegetations cause valve deformity, including perforations or tearing of the leaflet(s), and result in valve insufficiency. Rarely, large vegetations may cause the valve to become stenotic. Streptococcus spp. appear to more commonly affect the mitral valve. Bartonella spp. infect the aortic valve most often, causing somewhat different lesions of fibrosis, mineralization, endothelial proliferation, and neovascularization. Valve insufficiency and subsequent volume overload commonly lead to CHF. Because the mitral and/or aortic valve is usually affected, left-sided CHF signs of pulmonary congestion and edema are usual. Clinical heart failure develops rapidly in patients with severe valve destruction, rupture of chordae tendineae, and multiple valve involvement, or when other predisposing factors are present. Cardiac function can be compromised by myocardial injury resulting from coronary arterial embolization with myocardial infarction and abscess formation or from direct extension of the infection into the myocardium. Reduced contractility and atrial or ventricular tachyarrhythmias often result. Aortic valve endocarditis lesions may extend into the AV node and

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cause partial or complete AV block. Arrhythmias may cause weakness, syncope, and sudden death or contribute to the development of CHF. Fragments of vegetative lesions often break loose. Embolization of other body sites can cause infarction or metastatic infection, which results in diverse clinical signs. Larger and more mobile vegetations (based on echocardiographic appearance) are associated with a higher incidence of embolic events in people; the same may occur in animals. Emboli can be septic or bland (containing no infectious organisms). Septic arthritis, diskospondylitis, urinary tract infections, and renal and splenic infarctions are common in affected animals. Local abscess formation resulting from septic thromboemboli contributes to recurrent bacteremia and fever. Hypertrophic osteopathy has also been associated with bacterial endocarditis. Circulating immune complexes and cell-mediated responses contribute to the disease syndrome. Sterile polyarthritis, glomerulonephritis, vasculitis, and other forms of immune-mediated organ damage are common. Rheumatoid factor and antinuclear antibody test (ANA) results may be positive. Clinical Features The prevalence of bacterial endocarditis is relatively low in dogs and even lower in cats. Male dogs are affected more commonly than females. An increased prevalence of endocarditis has been noted in association with age. German Shepherd Dogs and other large-breed dogs (especially Boxers, Golden and Labrador Retrievers, and Rottweilers) may be at greater risk. Subaortic stenosis is a known risk factor for aortic valve endocarditis. There may be a relationship between severe periodontal disease and risk of endocarditis or cardiomyopathy. However, small breeds of dog, which are often affected with severe periodontal disease and degenerative mitral valve disease, have a low prevalence of endocarditis. Neutropenic and otherwise immunocompromised animals may be at greater risk for endocarditis. The clinical signs of endocarditis are variable. Some affected animals have evidence of past or concurrent infections, although often a clear history of predisposing factors is absent. The presenting signs can result from left-sided CHF or arrhythmias, but cardiac signs may be overshadowed by signs of systemic infarction, infection, immune-mediated disease (including polyarthritis), or a combination of these. Nonspecific signs of lameness or stiffness (possibly shifting from one limb to another), lethargy, trembling, recurrent fever, weight loss, inappetence, vomiting, diarrhea, and weakness may be the predominant complaints. A cardiac murmur is heard in most dogs with endocarditis; murmur characteristics depend on the valve involved. Ventricular tachyarrhythmias are reported most commonly, but supraventricular tachyarrhythmias or AV block (especially with aortic valve infection) also occur. Infective endocarditis often mimics immune-mediated disease. Dogs with endocarditis are commonly evaluated for a “fever of unknown origin.” Some of the consequences of infectious endocarditis are outlined in Box 6-3. Endocarditis

has been nicknamed “the great imitator”; therefore, maintaining an index of suspicion for this disease is important. Infective valve damage may be heralded by signs of CHF in an unexpected clinical setting or in an animal with a murmur of recent onset, especially if other suggestive signs are present. However, a “new” murmur can be a manifestation of noninfective acquired disease (e.g., degenerative valve disease, cardiomyopathy); previously undiagnosed congenital disease; or physiologic alterations (e.g., fever, anemia). Conversely, endocarditis may develop in an animal known to have a murmur caused by another cardiac disease. Although a change in murmur quality or intensity over a short time frame may indicate active valve damage, physiologic causes of murmur variation are common. The onset of a diastolic murmur at the left heartbase is suspicious for aortic valve endocarditis, especially if fever or other signs are present. Diagnosis It may be difficult to obtain a definitive antemortem diagnosis. Presumptive diagnosis of infective endocarditis is made on the basis of positive findings in two or more blood cultures (or positive Bartonella testing), in addition to either echocardiographic evidence of vegetations or valve destruction or the documented recent appearance of a regurgitant murmur. Endocarditis is likely even when blood culture results are negative or intermittently positive if there is echocardiographic evidence of vegetations or valve destruction along with a combination of other criteria (Box 6-4). A new diastolic murmur, hyperkinetic pulses, and fever are strongly suggestive of aortic valve endocarditis. Preparation for blood culture sampling includes shaving and surgical scrub of the area. Several samples of at least 10╯mL (or 5╯mL in small dogs and cats) of blood should be aseptically collected for bacterial blood culture, with more than 1 hour elapsing between collections. Ideally, different venipuncture sites should be used for each sample; alternatively, samples can be obtained from a freshly and aseptically placed jugular catheter. Use of peripheral catheters is not recommended for collection. Larger sample volumes (e.g., 20-30╯mL) increase culture sensitivity. Antibiotic therapy should be discontinued (or delayed) before sampling whenever possible; use of antibacterial removal devices may be helpful in some cases. In critical patients where 24-hour delay in instituting antimicrobial therapy is deemed inadvisable, collection of two to three blood culture samples can be done over a 10- to 60-minute period. The size of blood culture collection bottle can be important; a blood-toculture broth ratio of 1â•›:â•›10 has been recommended to minimize inherent bactericidal effects of the patient’s serum. Before transferring the blood sample into the collection bottle, disinfect the top of the bottle and place a new needle on the collection syringe. Avoid injecting air while transÂ� ferring the blood, and then gently invert the bottle several times to mix. Both aerobic and anaerobic cultures have been recommended, although the value of routine anaerobic culture is questionable. Prolonged incubation (3 weeks) is

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  BOX 6-3â•… Potential Sequelae of Infective Endocarditis Heart

Valve insufficiency or stenosis Murmur Congestive heart failure Coronary embolization (aortic valve*) Myocardial infarction Myocardial abscess Myocarditis Decreased contractility (segmental or global) Arrhythmias Myocarditis (direct invasion by microorganisms) Arrhythmias Atrioventricular conduction abnormalities (aortic valve*) Decreased contractility Pericarditis (direct invasion by microorganisms) Pericardial effusion Cardiac tamponade (?) Kidney

Infarction Reduced renal function Abscess formation and pyelonephritis Reduced renal function Urinary tract infection Renal pain Glomerulonephritis (immune mediated) Proteinuria Reduced renal function Musculoskeletal

Septic arthritis Joint swelling and pain Lameness Immune-mediated polyarthritis Shifting-leg lameness Joint swelling and pain

Septic osteomyelitis Bone pain Lameness Myositis Muscle pain Brain and Meninges

Abscesses Associated neurologic signs Encephalitis and meningitis Associated neurologic signs Vascular System in General

Vasculitis Thrombosis Petechiae and small hemorrhages (e.g., eye, skin) Obstruction Ischemia of tissues served, with associated signs Lung

Pulmonary emboli (tricuspid or pulmonic valves, rare*) Pneumonia (tricuspid or pulmonic valves, rare*) Nonspecific

Sepsis Fever Anorexia Malaise and depression Shaking Vague pain Inflammatory leukogram Mild anemia ±Positive antinuclear antibody test ±Positive blood cultures

*Diseased valve most commonly associated with abnormality.

recommended because some bacteria are slow growing. Although blood culture results are positive in many dogs with endocarditis, negative culture results have occurred in more than half of dogs with confirmed infective endocarditis. Blood culture results may be negative in the setting of chronic endocarditis, recent antibiotic therapy, intermittent bacteremia, and infection with fastidious or slow-growing organisms, as well as noninfective endocarditis. In dogs with negative blood cultures, polymerase chain reaction (PCR) or serologic testing may reveal underlying Bartonella spp. infection; seropositive dogs may also be seroreactive to (other) tick-borne diseases. Because the kidneys are a possible source of primary and secondary bacterial infection, culturing the urine is also recommended. Echocardiography is especially supportive if oscillating vegetative lesions and abnormal valve motion can be identified (Fig. 6-4). The visualization

of lesions depends on their size and location, the image resolution, and the proficiency of the echocardiographer. Because false-negative and false-positive “lesions” may be found, cautious interpretation of images is important. Mild valve thickening and/or enhanced echogenicity can occur in patients with early valve damage. Vegetative lesions appear as irregular dense masses. Increased echogenicity of more chronic lesions may result from dystrophic calcification. As valve destruction progresses, ruptured chordae, flail leaflet tips, or other abnormal valve motion can be seen. Differentiation of mitral vegetations from degenerative thickening may be impossible, however, especially in the early stages. Nevertheless, vegetative endocarditis classically causes rough, raggedlooking valve thickening; degenerative disease is associated with smooth valvular thickening. Poor or marginal-quality images or suboptimal resolution from use of lower-frequency

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  BOX 6-4â•… Criteria for Diagnosis of Infectious Endocarditis* Definite Endocarditis by Pathologic Criteria

Pathologic (postmortem) lesions of active endocarditis with evidence of microorganisms in vegetation (or embolus) or intracardiac abscess Definite Endocarditis by Clinical Criteria

Two major criteria (below), or One major and three minor criteria, or Five minor criteria Possible Endocarditis

Findings consistent with infectious endocarditis that fall short of “definite” but not “rejected” Rejected Diagnosis of Endocarditis

Firm alternative diagnosis for clinical manifestations Resolution of manifestations of infective endocarditis with 4 or fewer days of antibiotic therapy No pathologic evidence of infective endocarditis at surgery or necropsy after 4 or fewer days of antibiotic therapy Major Criteria

Positive blood cultures Typical microorganism for infective endocarditis from two separate blood cultures

Persistently positive blood cultures for organism consistent with endocarditis (samples drawn > 12 hours apart or three or more cultures drawn ≥ 1 hour apart) Evidence of endocardial involvement Positive echocardiogram for infective endocarditis (oscillating mass on heart valve or supportive structure or in path of regurgitant jet or evidence of cardiac abscess) New valvular regurgitation (increase or change in preexisting murmur not sufficient evidence) Minor Criteria

Predisposing heart condition (see p. 123) Fever Vascular phenomena: major arterial emboli, septic infarcts Immunologic phenomena: glomerulonephritis, positive antinuclear antibody or rheumatoid factor tests Medium to large dog† Bartonella titer > 1â•›:â•›1024† Microbiologic evidence: positive blood culture not meeting major criteria above Echocardiogram consistent with infective endocarditis but not meeting major criteria above (Rare in dogs and cats: repeated nonsterile IV drug administration)

*Adapted from Duke criteria for endocarditis. In Durack DT et╯al: New criteria for diagnosis of infective endocarditis: utilization of specific echocardiographic findings, Am J Med 96:200, 1994. † Proposed minor criteria.

transducers can prevent identification of some vegetations. Secondary effects of valve dysfunction include chamber enlargement from volume overload and flail or otherwise abnormal valve leaflet motion. Myocardial dysfunction and arrhythmias may also be evident. Aortic insufficiency can cause fluttering of the anterior mitral valve leaflet during diastole as the regurgitant jet makes contact with this leaflet. Spontaneous contrast within the left heart chambers is observed occasionally, probably related to hyperfibrogenemia and increased erythrocyte sedimentation. Doppler studies illustrate flow disturbances (Fig. 6-5). The ECG may be normal or document premature ectopic complexes or tachycardia, conduction disturbances, or evidence of myocardial ischemia. Radiographic findings are unremarkable in some cases; however, in others, evidence of left-sided CHF or other organ involvement (e.g., diskospondylitis) is seen. Cardiomegaly is minimal early in the disease but progresses over time as a result of valve insufficiency. Clinicopathologic findings usually reflect an inflammatory process. Neutrophilia with a left shift is typical of acute endocarditis, whereas mature neutrophilia with or without monocytosis usually develops with chronic disease. However, sometimes an inflammatory leukogram is absent.

Nonregenerative anemia has been associated with about half of canine cases, and thrombocytopenia is also common. Biochemical abnormalities are variable. Azotemia, hyperglobulinemia, hypoalbuminemia, hematuria, pyuria, and proteinuria are common. Increased liver enzyme activities and hypoglycemia may also be seen in animals with bac� teremia. The ANA results may be positive in dogs with subacute or chronic bacterial endocarditis. About 75% of dogs with Bartonella vinsonii infection reportedly have positive ANA test results. Treatment and Prognosis Aggressive therapy with bactericidal antibiotics capable of penetrating fibrin and supportive care are indicated for infective endocarditis. Ideally, drug choice is guided by culture and in vitro susceptibility test results. Because treatment delay while waiting for these results can be harmful, broad-spectrum combination therapy is usually begun immediately after blood culture samples are obtained. Dosages at the higher end of the recommended range are used. Therapy can be altered, if necessary, when culture results are available. Culture-negative cases should be continued on the broad-spectrum regimen. An initial

FIG 6-4â•…

Right parasternal short-axis echocardiogram at the aortic-left atrial level in a 2-year-old male Vizsla with congenital subaortic stenosis and pulmonic stenosis. Note the aortic valve vegetation (arrows) caused by endocarditis. A, Aorta; LA, left atrium; RA, right atrium; RVOT, right ventricular outflow tract.

FIG 6-5â•…

Right parasternal long axis, color flow Doppler image taken during diastole from the same dog as in Fig. 6-4. The “flamelike” jet of aortic regurgitation extends from the closed aortic valve into the left ventricular outflow tract. A, Aorta; LV, left ventricle.

combination of a cephalosporin or a synthetic penicillin derivative (e.g., ampicillin, ticarcillin, piperacillin) with an aminoglycoside (gentamicin or amikacin) or a fluoroquinolone (e.g., enrofloxacin) is commonly used. This can be effective against the organisms most often associated with

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infective endocarditis. Alternate strategies include azithromycin or ticarcillin-clavulanate. Clindamycin, metronidazole, or cefoxitin provides added anaerobic efficacy. An alternative combination for unknown bacterial etiology when renal function is impaired is enrofloxacin with clindamycin (although the latter is bacteriostatic). Nevertheless, growing bacterial resistance is a concern. Most coagulasepositive Staphylococcus spp. are resistant to ampicillin (and penicillin). Extended-spectrum penicillins (ticarcillin, piperacillin, carbenicillin) may be more effective and also have some gram-negative activity, but many Staphylococcus spp. are also resistant to them. Ticarcillin-clavulanate may have better effectiveness against β-lactamase–producing Staphylococcus. First-generation cephalosporins are often effective against Staphylococcus, Streptococcus, and some gramnegative agents, although resistance is increasing. Secondand third-generation cephalosporins are more effective against gram-negative organisms and some anaerobes. In cats, a first-generation cephalosporin with piperacillin or clindamycin has been recommended against likely gramnegative or anaerobic infections. Optimal treatment for Bartonella spp. is not clear. Azithromycin or possibly enrofloxacin or high-dose doxycycline has been suggested for Bartonella. Dogs in critical condition from Bartonella endocarditis may benefit from aggressive aminoglycoside therapy, depending on their renal function and tolerance for IV fluid therapy. Antibiotics are administered intravenously (or at least intramuscularly) for the first week or longer to obtain higher and more predictable blood concentrations. Oral therapy is often used thereafter for practical reasons, although parenteral administration is probably better. Appropriate antimicrobial therapy is continued for at least 6 to 8 weeks and usually longer. Some clinicians advocate antimicrobial treatment for a year. However, aminoglycosides are discontinued after 1 week or sooner if renal toxicity develops. Close monitoring of the urine sediment is indicated to detect early aminoglycoside nephrotoxicity. For documented or suspected B. vinsonii (berkhoffii) infection, repeat serologic or PCR testing is recommended a month after antibiotic therapy. A reduced titer is expected with effective therapy. Supportive care includes management for CHF (see Chapter 3) and arrhythmias (see Chapter 4) if present. Complications related to the primary source of infection, embolic events, or immune responses are addressed to the extent possible. Attention to hydration status, nutritional support, and general nursing care is also important. Corticosteroids are contraindicated. In people, aspirin and clopidogrel (but not oral anticoagulants) have reduced vegetative lesion size, bacterial dissemination, and risk of embolic events. For animals with positive blood (or urine) cultures, repeat cultures in 1 to 2 weeks and also a couple of weeks after completion of antibiotic therapy are recommended. Echocardiographic reevaluation during and following the treatment period is useful to monitor the affected valve’s function, as well as other cardiac parameters. Radiographs, complete blood cell counts, serum chemistries, and other tests are repeated as indicated for the individual patient.

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Long-term prognosis is generally guarded to poor. Echocardiographic evidence of vegetations (especially of the aortic valve) and volume overload suggests a poor prognosis. Other negative prognostic indicators include Bartonella or gram-negative infections, renal or cardiac complications that respond poorly to treatment, septic embolization, and thrombocytopenia. Glucocorticoid therapy and inadequate antibiotic therapy can contribute to a poor outcome. Aggressive therapy may be successful if valve dysfunction is not severe and large vegetations are absent. CHF is the most common cause of death, although sepsis, systemic embolization, arrhythmias, or renal failure may be the proximate cause. The use of prophylactic antibiotics is controversial. Experience in people indicates that most cases of infective endocarditis are not preventable. The risk of endocarditis from a specific (e.g., dental) procedure in humans is low compared with the cumulative risk associated with normal daily activities. However, because endocarditis appears to have a higher prevalence in patients with certain cardiovascular malformations, antimicrobial prophylaxis is recommended before dental or other “dirty” procedures (e.g., involving the oral cavity or intestinal or urogenital systems) in these cases. Subaortic stenosis is a well-recognized predisposing lesion; endocarditis has also been associated with ventricular septal defect, patent ductus arteriosus, and cyanotic congenital heart disease. Antimicrobial prophylaxis is recommended for animals with an implanted pacemaker or other device or with a history of endocarditis. Prophylaxis should be considered for immunocompromised animals as well. Various recommendations have included the administration of high-dose ampicillin, amoxicillin, ticarcillin, or a firstgeneration cephalosporin 1 hour before and 6 hours after an oral or upper respiratory procedure, as well as ampicillin with an aminoglycoside (IV, 30 minutes before and 8 hours after a gastrointestinal or urogenital procedure). Clindamycin has also been recommended in dogs before dental procedures. Suggested Readings Degenerative AV Valve Disease Atkins C et al: Guidelines for the diagnosis and treatment of canine chronic valvular heart disease (ACVIM Consensus Statement), J Vet Intern Med 23:1142, 2009. Atkins CE, Haggstrom J: Pharmacologic management of myxoÂ� matous mitral valve disease in dogs, J Vet Cardiol 14:165, 2012. Atkins CE et al: Results of the veterinary enalapril trial to prove reduction in onset of heart failure in dogs chronically treated with enalapril alone for compensated, naturally occurring mitral valve insufficiency, J Am Vet Med Assoc 231:1061, 2007. Atkinson KJ et al: Evaluation of pimobendan and N-terminal probrain natriuretic peptide in the treatment of pulmonary hypertension secondary to degenerative mitral valve disease in dogs, J Vet Intern Med 23:1190, 2009. Aupperle H, Disatian A: Pathology, protein expression and signalling in myxomatous mitral valve degeneration: comparison of dogs and humans, J Vet Cardiol 14:59, 2012.

Bernay F et al: Efficacy of spironolactone on survival in dogs with naturally occurring mitral regurgitation caused by myxomatous mitral valve disease, J Vet Intern Med 24:331, 2010. Borgarelli M, Buchanan JW: Historical review, epidemiology and natural history of degenerative mitral valve disease, J Vet Cardiol 14:93, 2012. Borgarelli M et al: Survival characteristics and prognostic variables of dogs with preclinical chronic degenerative mitral valve disease attributable to myxomatous valve disease, J Vet Intern Med 26:69, 2012. Chetboul V et al: Association of plasma N-terminal Pro-B-type natriuretic peptide concentration with mitral regurgitation severity and outcome in dogs with asymptomatic degenerative mitral valve disease, J Vet Intern Med 23:984, 2009. Chetboul V, Tissier R: Echocardiographic assessment of canine degenerative mitral valve disease, J Vet Cardiol 14:127, 2012. Diana A et al: Radiographic features of cardiogenic pulmonary edema in dogs with mitral regurgitation: 61 cases (1998-2007), J Am Vet Med Assoc 235:1058, 2009. Dillon AR et al: Left ventricular remodeling in preclinical experimental mitral regurgitation of dogs, J Vet Cardiol 14:7392, 2012. Falk T, Jonsson L, Olsen LH, et al: Arteriosclerotic changes in the myocardium, lung, and kidney in dogs with chronic congestive heart failure and myxomatous mitral valve disease, Cardiovasc Pathol 15:185, 2006. Fox PR: Pathology of myxomatous mitral valve disease in the dog, J Vet Cardiol 14:103, 2012. Gordon SG et al: Retrospective review of carvedilol administration in 38 dogs with preclinical chronic valvular heart disease, J Vet Cardiol 14:243, 2012. Gouni V et al: Quantification of mitral valve regurgitation in dogs with degenerative mitral valve disease by use of the proximal isovelocity surface area method, J Am Vet Med Assoc 231:399, 2007. Haggstrom J et al: Effect of pimobendan or benazepril hydrochloride on survival times in dogs with congestive heart failure caused by naturally occurring myxomatous mitral valve disease: the QUEST study, J Vet Intern Med 22:1124, 2008. Hezzell MJ et al: The combined prognostic potential of serum highsensitivity cardiac troponin I and N-terminal pro-B-type natriuretic peptide concentrations in dogs with degenerative mitral valve disease, J Vet Intern Med 26:302, 2012. Hezzell MJ et al: Selected echocardiographic variables change more rapidly in dogs that die from myxomatous mitral valve disease, J Vet Cardiol 14:269, 2012. Kellihan HB, Stepien RL: Pulmonary hypertension in canine degenerative mitral valve disease, J Vet Cardiol 14:149, 2012. Kittleson MD, Brown WA: Regurgitant fraction measured by using the proximal isovelocity surface area method in dogs with chronic myxomatous mitral valve disease, J Vet Intern Med 17:84, 2003. Kvart C et al: Efficacy of enalapril for prevention of congestive heart failure in dogs with myxomatous valve disease and asymptomatic mitral regurgitation, J Vet Intern Med 16:80, 2002. Ljungvall I et al: Assessment of global and regional left ventricular volume and shape by real-time 3-dimensional echocardiography in dogs with myxomatous mitral valve disease, J Vet Intern Med 25:1036, 2011. Ljungvall I et al: Cardiac troponin I is associated with severity of myxomatous mitral valve disease, age, and C-reactive protein in dogs, J Vet Intern Med 24:153, 2010.

Lombard CW, Jöns O, Bussadori CM: Clinical efficacy of pimobendan versus benazepril for the treatment of acquired atrioventricular valvular disease in dogs, J Am Anim Hosp Assoc 42:249, 2006. Lord PF et al: Radiographic heart size and its rate of increase as tests for onset of congestive heart failure in Cavalier King Charles Spaniels with mitral valve regurgitation, J Vet Intern Med 25:1312, 2011. Marcondes-Santos M et al: Effects of carvedilol treatment in dogs with chronic mitral valvular disease, J Vet Intern Med 21:996, 2007. Moesgaard SG et al: Flow-mediated vasodilation measurements in Cavalier King Charles Spaniels with increasing severity of myxomatous mitral valve disease, J Vet Intern Med 26:61, 2012. Moonarmart W et al: N-terminal pro B-type natriuretic peptide and left ventricular diameter independently predict mortality in dogs with mitral valve disease, J Small Anim Pract 51:84, 2010. Muzzi RAL et al: Regurgitant jet area by Doppler color flow mapping: quantitative assessment of mitral regurgitation severity in dogs, J Vet Cardiol 5:33, 2003. Orton EC et al: Technique and outcome of mitral valve replacement in dogs, J Am Vet Med Assoc 226:1508, 2005. Orton EC, Lacerda CMR, MacLea HB: Signaling pathways in mitral valve degeneration, J Vet Cardiol 14:7, 2012. Orton C: Transcatheter mitral valve implantation (TMVI) for dogs. In Proceedings, 2012 ACVIM Forum, New Orleans, LA, 2012, p 185. Oyama MA: Neurohormonal activation in canine degenerative mitral valve disease: implications on pathophysiology and treatment, J Small Anim Pract 50:3, 2009. Reineke EL, Burkett DE, Drobatz KJ: Left atrial rupture in dogs: 14 cases (1990-2005), J Vet Emerg Crit Care 18:158, 2008. Schober KE et al: Effects of treatment on respiratory rate, serum natriuretic peptide concentration, and Doppler echocardiographic indices of left ventricular filling pressure in dogs with congestive heart failure secondary to degenerative mitral valve disease and dilated cardiomyopathy, J Am Vet Med Assoc 239:468, 2011. Serres F et al: Chordae tendineae rupture in dogs with degenerative mitral valve disease: prevalence, survival, and prognostic factors (114 cases, 2001-2006), J Vet Intern Med 21:258, 2007. Singh MK et al: Bronchomalacia in dogs with myxomatous mitral valve degeneration, J Vet Intern Med 26:312, 2012.

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Smith PJ et al: Efficacy and safety of pimobendan in canine heart failure caused by myxomatous mitral valve disease, J Small Anim Pract 46:121, 2005. Tarnow I et al: Predictive value of natriuretic peptides in dogs with mitral valve disease, Vet J 180:195, 2009. Uechi M: Mitral valve repair in dogs, J Vet Cardiol 14:185, 2012. Infective Endocarditis Breitschwerdt EB et al: Bartonellosis: an emerging infectious disease of zoonotic importance to animals and human beings, J Vet Emerg Crit Care 20:8, 2010. Calvert CA, Thomason JD: Cardiovascular infections. In Greene CE, editor: Infectious diseases of the dog and cat, ed 4, St Louis, 2012, Elsevier Saunders, p 912. Glickman LT et al: Evaluation of the risk of endocarditis and other cardiovascular events on the basis of the severity of periodontal disease in dogs, J Am Vet Med Assoc 234:486, 2009. MacDonald KA: Infective endocarditis. In Bonagura JD, Twedt DC, editors: Kirk’s current veterinary therapy XIV, St Louis, 2009, Elsevier Saunders, p 786. Meurs KM et al: Comparison of polymerase chain reaction with bacterial 16s primers to blood culture to identify bacteremia in dogs with suspected bacterial endocarditis, J Vet Intern Med 25:959, 2011. Miller MW, Fox PR, Saunders AB: Pathologic and clinical features of infectious endocarditis, J Vet Cardiol 6:35, 2004. Peddle G, Sleeper MM: Canine bacterial endocarditis: a review, J Am Anim Hosp Assoc 43:258, 2007. Peddle GD et al: Association of periodontal disease, oral procedures, and other clinical findings with bacterial endocarditis in dogs, J Am Vet Med Assoc 234:100, 2009. Pesavento PA et al: Pathology of Bartonella endocarditis in six dogs, Vet Pathol 42:370, 2005. Smith BE, Tompkins MB, Breitschwerdt EB: Antinuclear antibodies can be detected in dog sera reactive to Bartonella vinsonii subsp. berkhoffii, Ehrlichia canis, or Leishmania infantum antigens, J Vet Intern Med 18:47, 2004. Sykes JE et al: Evaluation of the relationship between causative organisms and clinical characteristics of infective endocarditis in dogs: 71 cases (1992-2005), J Am Vet Med Assoc 228:1723, 2006. Sykes JE et al: Clinicopathologic findings and outcome in dogs with infective endocarditis: 71 cases (1992-2005), J Am Vet Med Assoc 228:1735, 2006. Tou SP, Adin DB, Castleman WL: Mitral valve endocarditis after dental prophylaxis in a dog, J Vet Intern Med 19:268, 2005.

C H A P T E R

7â•…

Myocardial Diseases of the Dog

Heart muscle disease that leads to contractile dysfunction and cardiac chamber enlargement is an important cause of heart failure in dogs. Idiopathic or primary dilated cardiomyopathy (DCM) is most common and mainly affects the larger breeds. Secondary and infective myocardial diseases (see pp. 138 and 140) occur less often. Arrhythmogenic right ventricular cardiomyopathy (ARVC), also known as Boxer cardiomyopathy, is an important myocardial disease in Boxers. ARVC is uncommon in other breeds. Hypertrophic cardiomyopathy (HCM) is recognized infrequently in dogs (see p. 140).

DILATED CARDIOMYOPATHY Etiology and Pathophysiology DCM is a disease characterized by poor myocardial contractility, with or without arrhythmias. Although considered idiopathic, DCM as an entity probably represents the endstage of different pathologic processes or metabolic defects involving myocardial cells or the intercellular matrix rather than a single disease. A genetic basis is thought to exist for many cases of idiopathic DCM, especially in breeds with a high prevalence or a familial occurrence of the disease. Large and giant breeds are most commonly affected, including Doberman Pinschers, Great Danes, Saint Bernards, Scottish Deerhounds, Irish Wolfhounds, Boxers, Newfoundlands, Afghan Hounds, and Dalmatians. Some smaller breeds such as Cocker Spaniels and Bulldogs are also affected. The disease is rarely seen in dogs that weigh less than 12╯kg. Doberman Pinschers appear to have the highest prevalence of DCM and an autosomal dominant pattern of inheritance. Two genetic mutations have been associated with DCM in Doberman Pinschers; one (on chromosome 14) has greater association with poor systolic function, whereas the other (on chromosome 5) has greater association with severe ventricular tachyarrhythmias and sudden death. Testing for the former mutation is commercially available (North Carolina State University Veterinary Cardiac Genetics Laboratory; http://www.cvm.ncsu.edu/vhc/csds/vcgl/index.html). 130

Multiple other mutations associated with DCM may also exist in Dobermans and other breeds. Boxers with ventricular arrhythmias also have an autosomal dominant inheritance pattern with variable penetrance; a mutation on the striatin gene has been identified (see later). In at least some Great Danes, DCM appears to be an X-linked recessive trait. DCM in Irish Wolfhounds appears to be familial, with an autosomal recessive inheritance with sex-specific alleles. The familial DCM affecting young Portuguese Water Dogs has an autosomal recessive inheritance pattern and is rapidly fatal in puppies that are homozygous for the mutation. Various biochemical defects, nutritional deficiencies, toxins, immunologic mechanisms, and infectious agents may be involved in the pathogenesis of DCM in different cases. Impaired intracellular energy homeostasis and decreased myocardial adenosine triphosphate (ATP) concentrations were found in myocardial biochemical studies of affected Doberman Pinschers. Abnormal gene expression related to cardiac ryanodine receptor regulation and intracardiac Ca++ release have been reported in Great Danes with DCM. Idiopathic DCM has also been associated with prior viral infections in people. However, on the basis of polymerase chain reaction (PCR) analysis of myocardial samples from a small number of dogs with DCM, viral agents do not seem to be commonly associated with DCM in this species. Decreased ventricular contractility (systolic dysfunction) is the major functional defect in dogs with DCM. Progressive cardiac chamber dilation (remodeling) develops as systolic pump function and cardiac output worsen and compensatory mechanisms become activated. Poor cardiac output can cause weakness, syncope, and ultimately cardiogenic shock. Increased diastolic stiffness also contributes to the development of higher end-diastolic pressures, venous congestion, and congestive heart failure (CHF). Cardiac enlargement and papillary muscle dysfunction often cause poor systolic apposition of mitral and tricuspid leaflets with valve insufficiency. Although severe degenerative atrioventricular (AV) valve disease is not typical in dogs with DCM, some have

mild to moderate valvular disease, which exacerbates valve insufficiency. As cardiac output decreases, sympathetic, hormonal, and renal compensatory mechanisms become activated. These mechanisms increase heart rate, peripheral vascular resistance, and volume retention (see Chapter 3). Chronic neurohormonal activation is thought to contribute to progressive myocardial damage, as well as to CHF. Coronary perfusion can be compromised by poor forward blood flow and increased ventricular diastolic pressure; myocardial ischemia further impairs myocardial function and predisposes to development of arrhythmias. Signs of low-output heart failure and right- or left-sided CHF (see Chapter 3) are common in dogs with DCM. Atrial fibrillation (AF) often develops in dogs with DCM. Atrial contraction contributes importantly to ventricular filling, especially at faster heart rates. The loss of the “atrial kick” associated with AF reduces cardiac output and can cause acute clinical decompensation. Persistent tachycardia associated with AF probably also accelerates disease progression. Ventricular tachyarrhythmias are common as well and can cause sudden death. In Doberman Pinschers serial Holter recordings have documented the appearance of ventricular premature complexes (VPCs) months to more than a year before early echocardiographic abnormalities of DCM were identified. Once left ventricular (LV) function begins to deteriorate, the frequency of tachyarrhythmias increases. Excitement-induced bradyarrhythmias have also been associated with low-output signs in Doberman Pinschers. Dilation of all cardiac chambers is typical in dogs with DCM, although left atrial (LA) and LV enlargement usually predominate. The ventricular wall thickness may appear decreased compared with the lumen size. Flattened, atrophic papillary muscles and endocardial thickening also occur. Concurrent degenerative changes of the AV valves are generally only mild to moderate, if present at all. Histopathologic findings include scattered areas of myocardial necrosis, degeneration, and fibrosis, especially in the left ventricle (LV). Narrowed (attenuated) myocardial cells with a wavy appearance may be a common finding. Inflammatory cell infiltrates, myocardial hypertrophy, and fatty infiltration (mainly in Boxers and some Doberman Pinschers) are inconsistent features. Clinical Findings The prevalence of DCM increases with age, although most dogs with CHF are 4 to 10 years old. Males appear to be affected more often than females. However, in Boxers and Doberman Pinschers there may be no gender predilection once dogs with occult disease are included. Cardiomyopathy in Boxers is described in more detail later (see p. 136). Male Doberman Pinschers generally show signs at an earlier age than females. DCM appears to develop slowly, with a prolonged preclinical (occult) stage that may evolve over several years before clinical signs become evident. Further cardiac evaluation is indicated for dogs with a history of reduced exercise

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tolerance, weakness, or syncope or in those in which an arrhythmia, murmur, or gallop sound is detected on routine physical examination. Occult DCM is often recognized through the use of echocardiography. Some giant-breed dogs with mild to moderate LV dysfunction are relatively asymptomatic, even in the presence of AF. Clinical signs of DCM may seem to develop rapidly, especially in sedentary dogs in which early signs may not be noticed. Sudden death before CHF signs develop is relatively common. Presenting complaints include any or all of the following: weakness, lethargy, tachypnea or dyspnea, exercise intolerance, cough (sometimes described as “gagging”), anorexia, abdominal distention (ascites), and syncope (see Fig. 1-1). Loss of muscle mass (cardiac cachexia), accentuated along the dorsal midline, may be severe in advanced cases. Physical examination findings vary with the degree of cardiac decompensation. Dogs with occult disease may have normal physical examination findings. Others have a soft murmur of mitral or tricuspid regurgitation or an arrhythmia. Dogs with advanced disease and poor cardiac output have increased sympathetic tone and peripheral vasoconstriction, with pale mucous membranes and slowed capillary refill time. The femoral arterial pulse and precordial impulse are often weak and rapid. Uncontrolled AF and frequent VPCs cause an irregular and usually rapid heart rhythm, with frequent pulse deficits and variable pulse strength (see Fig. 4-1). Signs of left- and/or right-sided CHF include tachypnea, increased breath sounds, pulmonary crackles, jugular venous distention or pulsations, pleural effusion or ascites, and/or hepatosplenomegaly. Heart sounds may be muffled because of pleural effusion or poor cardiac contractility. An audible third heart sound (S3 gallop) is a classic finding, although it may be obscured by an irregular heart rhythm. Soft to moderate-intensity systolic murmurs of mitral and/or tricuspid regurgitation are common. Diagnosis

RADIOGRAPHY The stage of disease, chest conformation, and hydration status influence the radiographic findings. Dogs with early occult disease are likely to be radiographically normal. Generalized cardiomegaly is usually evident in those with advanced DCM, although left heart enlargement may predominate (Fig. 7-1). In Doberman Pinschers the heart may appear minimally enlarged, except for the left atrium (LA). In other dogs cardiomegaly may be severe and can mimic the globoid cardiac silhouette typical of large pericardial effusions. Distended pulmonary veins and pulmonary interstitial or alveolar opacities, especially in the hilar and dorsocaudal regions, accompany left heart failure with pulmonary edema. The distribution of pulmonary edema infiltrates may be asymmetric or widespread. Pleural effusion, caudal vena cava distention, hepatomegaly, and ascites usually accompany right-sided CHF.

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A

B

C

D FIG 7-1â•…

Radiographic examples of dilated cardiomyopathy in dogs. Lateral (A) and dorsoventral (B) views showing generalized cardiomegaly in a male Labrador Retriever. Note the cranial pulmonary vein is slightly larger than the accompanying artery in (A). Lateral (C) and dorsoventral (D) views of Doberman Pinscher depicting the prominent left atrial and relatively moderate ventricular enlargements commonly found in affected dogs of this breed. There is mild peribronchial pulmonary edema as well.

ELECTROCARDIOGRAPHY The electrocardiogram (ECG) findings in dogs with DCM are also variable. Sinus rhythm is usually the underlying rhythm, although AF is often documented instead, especially in Great Danes and other giant breeds (see Fig. 2-11). Other

atrial tachyarrhythmias, paroxysmal or sustained ventricular tachycardia, fusion complexes, and multiform VPCs are common. The QRS complexes may be tall (consistent with LV dilation), normal in size, or small. Myocardial disease often causes a widened QRS complex with a slowed R-wave

descent and slurred ST segment. A bundle-branch block pattern or other intraventricular conduction disturbance may be observed. The P waves in dogs with sinus rhythm are frequently widened and notched, suggesting LA enlargement. Twenty-four-hour Holter monitoring is useful for documenting the presence and frequency of ventricular ectopy and can be used as a screening tool for cardiomyopathy in Doberman Pinschers and Boxers (see p. 137). The presence of more than 50╯VPCs/day or any couplets or triplets is thought to predict future overt DCM in Doberman Pinschers. Some dogs with fewer than 50╯VPCs/day on initial evaluation also develop DCM after several years. The frequency and complexity of ventricular tachyarrhythmias appear to be negatively correlated with fractional shortening; sustained ventricular tachycardia has been associated with increased risk of sudden death. Variability in the number of VPCs between repeated Holter recordings in the same dog can be high. If available, the technique of signal-averaged electrocardiography can reveal the presence of ventricular late potentials, which may suggest an increased risk for sudden death in Doberman Pinschers with occult DCM.

ECHOCARDIOGRAPHY Echocardiography is used to assess cardiac chamber dimensions and myocardial function and differentiate pericardial effusion or chronic valvular insufficiency from DCM. Dilated cardiac chambers and poor systolic ventricular wall and septal motion are characteristic findings in dogs with DCM. In severe cases only minimal wall motion is evident. All chambers are usually affected, but right atrial (RA) and right ventricular (RV) dimensions may appear normal, especially in Doberman Pinschers and Boxers. LV systolic (as well as diastolic) dimension is increased compared with normal ranges for the breed, and the ventricle appears more spherical. Fractional shortening and ejection fraction are decreased (Fig. 7-2). Other common features are a wide mitral valve E point–septal separation and reduced aortic root motion. LV free-wall and septal thicknesses are normal to decreased. The calculated end-systolic volume index (see p. 41) is generally greater than 80╯mL/m2 in dogs with overt DCM (42╯kg), LVIDs greater than 3.8╯cm, or VPCs during initial examination, and/or mitral valve E point–septal separation

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FIG 7-2â•…

M-mode echocardiogram from a dog with dilated cardiomyopathy at the chordal (left side of figure) and mitral valve (right side of figure) levels. Note attenuated wall motion (fractional shortening = 18%) and the wide mitral valve E point–septal separation (28╯mm).

FIG 7-3â•…

Mild mitral regurgitation is indicated by a relatively small area of disturbed flow in this systolic frame from a Standard Poodle with dilated cardiomyopathy. Note the LA and LV dilation. Right parasternal long axis view, optimized for the left ventricular inflow tract. LA, Left atrium; LV, left ventricle.

greater than 0.8╯cm (LVID, left ventricular internal diameter; d, diastole; s, systole).

CLINICOPATHOLOGIC FINDINGS Circulating concentrations of the natriuretic peptide (BNP, ANP) and cardiac troponin biomarkers rise as CHF develops. Studies in Doberman Pinschers have shown high levels of these biomarkers in occult DCM as well. Although BNP (as measured by NT-proBNP) appears to have better sensitivity and specificity for DCM, the wide range of measured values in normal dogs, overlapping with results from occult and clinical DCM dogs, indicate this test should not replace Holter monitoring and echocardiography for screening

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individual dogs. Other clinicopathologic findings are noncontributory in most cases, although prerenal azotemia from poor renal perfusion or mildly increased liver enzyme activities from passive hepatic congestion often occur. Severe CHF may be associated with hypoproteinemia, hyponatremia, and hyperkalemia. Hypothyroidism with associated hypercholesterolemia occurs in some dogs with DCM. Others have a reduced serum thyroid hormone concentration without hypothyroidism (sick euthyroid); normal TSH and free T4 concentrations are common. Increased circulating neurohormones (e.g., norepinephrine, aldosterone, endothelin, in addition to the natriuretic peptides) occur mainly in DCM dogs with overt CHF. Treatment

OCCULT DILATED CARDIOMYOPATHY An angiotensin-converting enzyme inhibitor (ACEI) is thought to be helpful for dogs with LV dilation or reduced FS. Preliminary evidence in Doberman Pinschers suggests this may delay the onset of CHF. It is unclear whether this is true for all cases of DCM. Other therapy aimed at modulating early neurohormonal responses and ventricular remodeling processes have theoretical appeal, but their clinical usefulness is not clear. Further study of this using certain β-blockers (e.g., carvedilol, metoprolol), spironolactone, pimobendan, and other agents is ongoing. The decision to use antiarrhythmic drug therapy in dogs with ventricular tachyarrhythmias is influenced by whether they result in clinical signs (e.g., episodic weakness, syncope), as well as the arrhythmia frequency and complexity seen on Holter recording. Various antiarrhythmic agents have been used, but the most effective regimen(s) and when to institute therapy are still not clear. A regimen that increases ventricular fibrillation threshold and decreases arrhythmia frequency and severity is desirable. Sotalol, amiodarone, and the combination of mexiletine and atenolol or procainamide with atenolol may be most useful (see Chapter 4). CLINICALLY EVIDENT DILATED CARDIOMYOPATHY Therapy is aimed at improving the animal’s quality of life and prolonging survival to the extent possible by controlling signs of CHF, optimizing cardiac output, and managing arrhythmias. Pimobendan, an ACEI, and furosemide (dosed as needed) are used for most dogs (Box 7-1). Spironolactone is advocated as well. Antiarrhythmic drugs are used on the basis of individual need. Dogs with acute CHF are treated as outlined in Box 3-1, with parenteral furosemide, supplemental oxygen, inotropic support, cautious use of a vasodilator, and other medications on the basis of individual patient needs. Thoracocentesis is indicated if pleural effusion is suspected or identified. Dogs with poor contractility, persistent hypotension, or fulminant CHF can benefit from additional inotropic support provided by intravenous (IV) infusion of dobutamine or dopamine for 2 (to 3) days. An IV phosphodiesterase

inhibitor (amrinone or milrinone) may be helpful for acute stabilization in some dogs if oral pimobendan has not yet been initiated and can be used concurrently with a catecholamine. Long-term use of strong positive inotropic drugs is thought to have detrimental effects on the myocardium. During infusion of these drugs, the animal must be observed closely for worsening tachycardia or arrhythmias (especially VPCs). If arrhythmias develop, the drug is discontinued or infused at up to half the original rate. In dogs with AF, catecholamine infusion is likely to increase the ventricular response rate because of enhanced AV conduction. So if dopamine or dobutamine is deemed necessary in a dog with AF, diltiazem (IV or oral loading) can be used to slow heart rate. Digoxin, either orally or by cautious IV loading doses, is an alternative. Clinical status in dogs with DCM can deteriorate rapidly, so close patient monitoring is important. Respiratory rate and character, lung sounds, pulse quality, heart rate and rhythm, peripheral perfusion, rectal temperature, body weight, renal function, mentation, pulse oximetry, and blood pressure should be monitored. Because ventricular contractility is abysmal in many dogs with severe DCM, these patients have little cardiac reserve; diuretic and vasodilator therapy can lead to hypotension and even cardiogenic shock.

Long-Term Therapy Pimobendan has essentially replaced digoxin for oral inotropic support, and it offers several advantages over digoxin (see p. 65). Pimobendan (Vetmedin, Boehringer Ingelheim Vetmedica) is a phosphodiesterase III inhibitor that increases contractility through a Ca++-sensitizing effect; the drug also has vasodilator and other beneficial effects. However, digoxin, with its neurohormonal modulating and antiarrhythmic effects, may still be useful and can be given in conjunction with pimobendan. Digoxin is mainly indicated in dogs with AF to help slow the ventricular response rate. It can also suppress some other supraventricular tachyarrhythmias. If digoxin is used, it is generally initiated with oral maintenance doses. Toxicity seems to develop at relatively low dosages in some dogs, especially Doberman Pinschers. A total maximum daily dose of 0.5╯mg is generally used for large and giant-breed dogs, except for Doberman Pinschers, which are given a total maximum dose of 0.25 to 0.375╯mg/ day. Serum digoxin concentration should be measured 7 to 10 days after digoxin therapy is initiated or the dose is changed (see p. 67). For dogs with AF and a ventricular rate exceeding 200 beats/min, initial therapy with IV or rapid oral diltiazem (see p. 81) is thought to be safer than rapid digitalization. However, if not available, twice the digoxin oral maintenance dose (or cautious use of IV digoxin—see Box 3-1) could be given on the first day to more rapidly achieve effective blood concentrations. If oral digoxin alone does not adequately control the heart rate, diltiazem or a β-blocker is added for chronic management (see Table 4-2). Because these agents can have negative inotropic effects, a low initial dose and gradual dosage titration to effect or a maximum

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  BOX 7-1â•… Treatment Outline for Dogs with Dilated Cardiomyopathy Occult CM (Stage B)

Client education (about disease process and early heart failure signs) Routine health maintenance Manage other medical problems Consider ACE inhibitor Consider β-blocker titration (e.g., carvedilol or metoprolol) Consider pimobendan Antiarrhythmic therapy, if indicated (see Chapter 4) Avoid high-salt foods; consider moderately salt-restricted diet Monitor for early signs of CHF (e.g., resting respiratory rate, activity level) Mild to Moderate Signs of CHF (Stage C, Chronic/ Outpatient Care)*

Furosemide, as needed Pimobendan ACE inhibitor Consider adding spironolactone Antiarrhythmic therapy, if indicated (see Chapter 4) Client education and manage concurrent problems, as above Complete exercise restriction until signs abate Moderate dietary salt restriction Consider dietary supplement (fish oil, ±taurine or carnitine, if indicated) Resting respiratory (±heart) rate monitoring at home Severe CHF Signs (Stage C, Acute/Hospitalized Care)*

Supplemental O2 Cage rest and minimal patient handling Furosemide (more aggressive doses, parenteral) Antiarrhythmic therapy, if necessary (e.g., IV diltiazem for uncontrolled AF, lidocaine for ventricular tachycardia)

Pimobendan (continue or add when oral administration possible) Consider other (IV) positive inotropic drug, especially if persistent hypotension (see Box 3-1) ACE inhibitor Consider cautious use of other vasodilator if necessary (beware hypotension) Thoracocentesis, if moderate- to large-volume pleural effusion Chronic Recurrent or Refractory Heart Failure Strategies (Stage D; In-Hospital [Stage D1] or Outpatient [Stage D2] as Needed)*

Ensure that therapies for stage C are being given at optimal doses and intervals, including furosemide, ACE inhibitor, pimobendan, spironolactone Rule out complicating factors: arrhythmias, renal or other metabolic abnormalities, systemic arterial hypertension, anemia, and other complications Increase furosemide dose/frequency as needed (as renal function allows) Enforced rest until signs abate Increase ACE inhibitor frequency to q12h (if not already done) Consider adding digoxin, if not currently prescribed; monitor serum concentration; increase dose only if subtherapeutic concentration documented Add (or increase dose of) diuretic (e.g., spironolactone, hydrochlorothiazide); monitor renal function and electrolytes Consider additional afterload reduction (e.g., amlodipine or hydralazine); monitor blood pressure Further restrict dietary salt intake; verify that drinking water is low in sodium Thoracocentesis (or abdominocentesis) as needed Manage arrhythmias, if present (see Chapter 4)

*See text, Chapter 3, Tables 3-2 and 3-3 and Box 3-1 for further details and doses. ACE, Angiotensin-converting enzyme; AF, atrial fibrillation; CHF, congestive heart failure; IV, intravenous.

recommended level is advised. Heart rate control in dogs with AF is important. A maximum ventricular rate of 140 to 150 beats/min in the hospital (i.e., stressful) setting is the recommended target; lower heart rates (e.g., ≈100 beats/min or less) are expected at home. Because heart rate assessment by auscultation or chest palpation in dogs with AF is usually highly inaccurate, an ECG recording is recommended. Femoral pulses should not be used to assess heart rate in the presence of AF. Furosemide is used at the lowest effective oral dosage for long-term therapy (see Table 3-3). Hypokalemia and alkalosis are uncommon sequelae, unless anorexia or vomiting occurs. Potassium supplementation should be based on documentation of hypokalemia and should be used cautiously, because concurrent ACEI and/or spironolactone (see Table

3-3 and p. 64) use can predispose to hyperkalemia, especially if renal disease is present. An ACEI should be used in the chronic treatment of DCM and may attenuate progressive ventricular dilation and secondary mitral regurgitation. ACEIs have a positive effect on survival in patients with myocardial failure. These drugs minimize clinical signs and increase exercise tolerance. Enalapril or benazepril are used most commonly, but other ACEIs have similar effects. Spironolactone is thought to be useful because of its aldosterone-antagonist, as well as potential mild diuretic effects. Aldosterone is known to promote cardiovascular fibrosis and abnormal remodeling and, as such, contributes to the progression of cardiac disease. Therefore spironolactone is advocated as adjunctive therapy in combination with

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an ACEI, furosemide, and pimobendan (±digoxin) for chronic DCM therapy. Amlodipine or hydralazine (see Table 3-3) could also be useful as adjunct therapy for dogs with refractory CHF, although arterial blood pressure should be carefully monitored in such animals. Hydralazine is more likely to precipitate hypotension and therefore reflex tachycardia and further neurohormonal activation. Any vasodilator must be used cautiously in dogs with a low cardiac reserve because of the increased potential for hypotension. Therapy is initiated at a low dose; if this is well tolerated, the next dose is increased to a low maintenance level. The patient should be evaluated for several hours after each incremental dose, ideally by blood pressure measurement. Signs of worsening tachycardia, weakened pulses, or lethargy can also indicate the presence of hypotension. The jugular venous PO2 can be used to estimate directional changes in cardiac output; a venous PO2 greater than 30╯mm╯Hg is desirable. A number of other therapies may be useful in certain dogs with DCM, although additional studies are necessary to define optimal recommendations. These include omega-3 fatty acids, l-carnitine (in dogs with low myocardial carnitine concentrations), taurine (in dogs with low plasma concentrations), long-term β-blocker therapy (e.g., carvedilol or metoprolol), and possibly others (see Chapter 3, p. 70). Several palliative surgical therapies for DCM have been described in dogs but are not currently advocated. Biventricular pacing to better synchronize ventricular contraction has improved clinical status in people with myocardial dysfunction, but there is little clinical experience with resynchronization therapy in dogs with DCM.

Monitoring Owner education regarding the purpose, dosage, and adverse effects of each drug used is important. Monitoring the dog’s resting respiratory (and heart) rate at home helps in assessing how well the CHF is controlled. The time frame for reevaluation visits depends on the patient’s status. Recheck visits once or twice a week may be necessary initially. Dogs with stable heart failure can be rechecked every 2 or 3 months. Current medications, diet, and any owner concerns should be reviewed. Patient activity level, appetite, and attitude, along with serum electrolyte and creatinine (or BUN) concentrations, heart rate and rhythm, pulmonary status, blood pressure, body weight, and other appropriate factors should be evaluated, and therapy adjusted as needed. Prognosis The prognosis for dogs with DCM is generally guarded to poor. Historically, most dogs do not survive longer than 3 months after clinical manifestations of CHF appear, although an estimated 25% to 40% of affected dogs live longer than 6 months if initial response to therapy is good. A QRS duration greater than 0.06 second has been associated with shortened survival. The probability of survival for 2 years has been estimated at 7.5% to 28%. However, more recent

therapeutic advances may be changing this bleak picture. Pleural effusion and possibly ascites and pulmonary edema have been identified as independent indicators of poorer prognosis. Sudden death may occur even in the occult stage, before heart failure is apparent. Sudden death occurs in about 20% to 40% of affected Doberman Pinschers. Although ventricular tachyarrhythmias are thought to precipitate cardiac arrest most commonly, bradyarrhythmias may be responsible in some dogs. Doberman Pinschers with occult DCM often experience deterioration within 6 to 12 months. Dobermans in overt CHF when initially presented generally have not lived long, with a reported median survival of less than 7 weeks. The prognosis is worse if AF is also present. Most symptomatic dogs are between 5 and 10 years old at the time of death. In each case, however, it is reasonable to assess the animal’s response to initial treatment before pronouncing an unequivocally dismal prognosis. Early diagnosis may help prolong life.

ARRHYTHMOGENIC RIGHT VENTRICULAR CARDIOMYOPATHY CARDIOMYOPATHY IN BOXERS The prevalence of ventricular arrhythmias and syncope is high in Boxers with myocardial disease. Boxer cardiomyopathy has similar features to those of people with ARVC. Histologic changes in the myocardium are more extensive than those in dogs of other breeds with cardiomyopathy and include atrophy of myofibers, fibrosis, and fatty infiltration, especially in the RV wall. Focal areas of myocytolysis, necrosis, hemorrhage, and mononuclear cell infiltration are also common. Ultrastructural abnormalities, including reduced numbers of myocardial gap junctions and desmosomes, appear to differ between Boxer and human ARVC. The disease is more prevalent in some blood lines and appears to have an autosomal dominant inheritance pattern, although genetic penetrance seems variable. A mutation in the striatin gene on chromosome 17, which encodes for a protein involved in cell-to-cell adhesion, has been associated with Boxer ARVC. However, as in people, there may be a number of gene mutations associated with ARVC in different bloodlines. Some dogs have ventricular tachyarrhythmia without clinical signs. Others have syncope or weakness associated with paroxysmal or sustained ventricular tachycardia, despite normal heart size and LV function. Some affected Boxers have poor myocardial function and CHF, as well as ventricular tachyarrhythmias. Dogs with mild echocardiographic changes and those with syncope or weakness may later develop poor LV function and CHF. There appears to be geographic variation in the prevalence of the various clinical presentations (e.g., tachyarrhythmias with normal LV function are typical in affected U.S. Boxers, whereas LV dysfunction appears to be more common in parts of Europe).

CHAPTER 7â•…â•… Myocardial Diseases of the Dog

Clinical Findings Signs may appear at any age, but the mean age reportedly is 8.5 years (range younger than 1-15 years). Syncope is the most common clinical complaint. Ventricular tachyarrhythmias underlie most instances of syncope in Boxers with ARVC. However, syncope has been associated with bradycardia in some cases; this is thought to be a neurocardiogenic syncope, triggered by a sudden surge in sympathetic (with reflex vagal stimulation) or parasympathetic activity, and potentially exacerbated by use of sotolol or (other) β-blocker therapy. The physical examination may be normal, although a soft left basilar systolic murmur is common in Boxers, whether ARVC is present or not. In many Boxers this is a breedrelated physiologic murmur, or it may be associated with underlying subaortic stenosis. In some dogs a cardiac arrhythmia is found on physical examination or ECG; in others the resting heart rhythm is normal. When CHF occurs, left-sided signs are more common than ascites or other signs of right-sided heart failure; a mitral insufficiency murmur may be present as well. The radiographic findings are variable. Many Boxers have no visible abnormalities. Those with congestive signs generally show evidence of cardiomegaly and pulmonary edema. Echocardiographic findings also vary. Many Boxers have normal cardiac size and function; others show reduced fractional shortening and variable chamber dilation, similar to other dogs with DCM. The characteristic ECG finding is ventricular ectopy. VPCs occur singly, in pairs, in short runs, or as sustained ventricular tachycardia. Most ectopic ventricular complexes appear upright in leads II and aVF (Fig. 7-4). However, some Boxers have multiform VPCs. Usually an underlying sinus rhythm exists. AF is less common. Supraventricular tachycardia, conduction abnormalities, and evidence of chamber enlargement are also sometimes seen on ECG. Twenty-four-hour Holter monitoring is used to quantify the frequency and complexity of ventricular tachyarrhythmias and as a screening tool for Boxer ARVC. It is also

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recommended to evaluate the efficacy of antiarrhythmic drug therapy and especially in dogs that experience an increase in syncope after an antiarrhythmic drug is prescribed. Frequent VPCs and/or complex ventricular arrhythmias are characteristic findings in affected dogs. Although absolute criteria for separating normal from abnormal Boxers is not totally clear, more than 50 to 100╯VPCs/24hour period, or periods of couplets, triplets, or runs of VT are abnormal and consistent with the disease, especially in dogs with clinical signs. Other rhythm abnormalities may be found as well. The occurrence of ventricular arrhythmias appears to be widely distributed throughout the day, but there can be enormous variability in the number of VPCs between repeated Holter recordings in the same dog. Despite this, affected dogs are expected to show more ventricular ectopy over a number of years. Annual Holter recordings are recommended, especially for dogs that may be used for breeding. Even though diagnostic criteria are not totally clarified, a recommendation against breeding dogs with syncope, signs of CHF, or runs of VT on resting or Holter ECG is prudent. Frequent VPCs or episodes of ventricular tachycardia are thought to signal an increased risk for syncope and sudden death. The biomarkers cardiac troponin I and BNP do not reliably discriminate between normal and affected dogs without concurrent CHF. Genetic testing for the striatin gene mutation is available (North Carolina State University Veterinary Cardiac Genetics Laboratory; http:// www.cvm.ncsu.edu/vhc/csds/vcgl/index.html). Treatment Boxers with clinical signs from tachyarrhythmias, but with normal heart size and LV function, are treated with antiarrhythmic drugs. Asymptomatic dogs found to have ventricular tachycardia, more than 1000╯VPCs/day, or close coupling of VPCs to the preceding QRS on Holter monitoring are usually given antiarrhythmic therapy as well. However, the best regimen(s) and when to institute therapy are still not clear. Antiarrhythmic drug therapy that is apparently successful in reducing VPC number on the basis of Holter

Paroxysmal ventricular tachycardia at a rate of almost 300 beats/min in a Boxer with arrhythmogenic right ventricular cardiomyopathy. Note the typical upright (left bundle branch block–like) appearance of the ventricular ectopic complexes in the caudal leads. Lead II, 25╯mm/sec.

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recording may still not prevent sudden death or increase survival time, although the number of syncopal episodes may improve. Sotalol and mexiletine have each shown efficacy in reducing VPC frequency and complexity. The combination of mexiletine (or procainamide) with a β-blocker or use of amiodarone may be effective in some dogs (see Chapter 4). The addition of a fish oil supplement may also reduce VPC frequency. Some dogs require treatment for persistent supraventricular tachyarrhythmias. Therapy for CHF is similar to that described for dogs with idiopathic DCM. Myocardial carnitine deficiency has been documented in some Boxers with DCM and heart failure. Some of these dogs have responded to oral l-carnitine supplementation. Digoxin is generally avoided in animals with frequent ventricular tachyarrhythmias. Prognosis The prognosis for affected Boxers is guarded. Survival is often less than 6 months in those with CHF. Asymptomatic dogs with ARVC may have a more optimistic future, but sudden death is common. Ventricular tachyarrhythmias often worsen with time and may be refractory to drug therapy. Dogs that survive longer eventually may develop ventricular dilation and poor contractility.

ARRHYTHMOGENIC RIGHT VENTRICULAR CARDIOMYOPATHY IN NONBOXER DOGS A form of cardiomyopathy that mainly affects the right ventricle (RV) has been observed rarely in dogs. It appears similar to ARVC described in people and cats (see p. 157). Pathologic changes are characterized by widespread fibrous and fatty tissue replacement in the RV myocardium. In certain geographic areas, trypanosomiasis is a possible differential diagnosis. Clinical manifestations are largely related to right-sided CHF and severe ventricular tachyarrhythmias. Marked right heart dilation is typical. Sudden death is a common outcome in people with ARVC.

SECONDARY MYOCARDIAL DISEASE Poor myocardial function can result from a variety of identifiable insults and nutritional deficiencies. Myocardial infections (see p. 140), inflammation, trauma (see p. 142), ischemia, neoplastic infiltration, and metabolic abnormalities can impair normal contractile function. Hyperthermia, irradiation, electric shock, certain drugs, and other insults can also damage the myocardium. Some substances are known cardiac toxins.

MYOCARDIAL TOXINS Doxorubicin The antineoplastic drug doxorubicin induces both acute and chronic cardiotoxicity. Histamine, secondary catecholamine release, and free-radical production appear to be involved in the pathogenesis of myocardial damage, which leads to

decreased cardiac output, arrhythmias, and degeneration of myocytes. Doxorubicin-induced cardiotoxicity is directly related to the peak serum concentration of the drug; administering the drug diluted (0.5╯mg/mL) over 20 to 40 minutes minimizes the risk of developing cardiotoxicity. Progressive myocardial damage and fibrosis have developed in association with cumulative doses of greater than 160╯mg/m2 and sometimes as low as 100╯mg/m2. In dogs that have normal pretreatment cardiac function, clinical cardiotoxicity is uncommon. For example, one busy oncology service that administers 15 to 20 doses of doxorubicin per week diagnoses only 1 to 2 dogs per year with doxorubicin cardiomyopathy. Although predicting whether and when clinical cardiotoxicity will occur is difficult, it is more likely when the cumulative dose of doxorubicin exceeds 240╯mg/m2. Increases in circulating cardiac troponin concentrations can be seen, but the utility of this in monitoring dogs for doxorubicin-induced myocardial injury is unclear. Cardiac conduction defects (infranodal AV block and bundle branch block), as well as ventricular and supraventricular tachyarrhythmias, can develop in affected dogs. ECG changes do not necessarily precede clinical heart failure. Dogs with underlying cardiac abnormalities and those of breeds with a higher prevalence of idiopathic DCM are thought to be at greater risk for doxorubicin-induced cardiotoxicity. Carvedilol has been shown to decrease the risk for doxorubicin-induced cardiotoxicity in humans; there are similar anecdotal experiences in dogs. Clinical features of this cardiomyopathy are similar to those of idiopathic DCM.

Other Toxins Ethyl alcohol, especially if given IV for the treatment of ethylene glycol intoxication, can cause severe myocardial depression and death; slow administration of a diluted (≤20%) solution is advised. Other cardiac toxins include plant toxins (e.g., Taxus, foxglove, black locust, buttercups, lily-of-the-valley, gossypol); cocaine; anesthetic drugs; cobalt; catecholamines; and ionophores such as monensin. METABOLIC AND NUTRITIONAL DEFICIENCY L-carnitine l-carnitine is an essential component of the mitochondrial membrane transport system for fatty acids, which are the heart’s most important energy source. It also transports potentially toxic metabolites out of the mitochondria in the form of carnitine esters. l-carnitine–linked defects in myocardial metabolism have been found in some dogs with DCM. Rather than simple l-carnitine deficiency, one or more underlying genetic or acquired metabolic defects are suspected. There may be an association between DCM and carnitine deficiency in some families of Boxers, Doberman Pinschers, Great Danes, Irish Wolfhounds, Newfoundlands, and Cocker Spaniels. l-carnitine is mainly present in foods of animal origin. DCM has developed in some dogs fed strict vegetarian diets.

Plasma carnitine concentration is not a sensitive indicator of myocardial carnitine deficiency. Most dogs with myocardial carnitine deficiency, diagnosed via endomyocardial biopsy, have had normal or high plasma carnitine concentrations. Furthermore, the response to oral carnitine supplementation is inconsistent. Subjective improvement may occur, but few dogs have echocardiographic evidence of improved function. Dogs that do respond show clinical improvement within the first month of supplementation; there may be some degree of improvement in echo parameters after 2 to 3 months. l-carnitine supplementation does not suppress preexisting arrhythmias or prevent sudden death. See p. 70 for supplementation guidelines.

Taurine Although most dogs with DCM are not taurine deficient, low plasma taurine concentration is found in some. Low taurine, and sometimes carnitine, concentrations occur in Cocker Spaniels with DCM. Oral supplementation of these amino acids can improve LV size and function, as well as reduce the need for heart failure medications in this breed. Low plasma taurine concentrations have also been found in some Golden Retrievers, Labrador Retrievers, Saint Bernards, Dalmatians, and other dogs with DCM. A normally adequate taurine content is found in the diets of some such cases, although others have been fed low-protein, lamb and rice, or vegetarian diets. The role of taurine supplementation is unclear. Although taurine-deficient dogs may show some echocardiographic improvement after supplementation, there is questionable effect on survival time. Nevertheless, measurement of plasma taurine or a trial of supplemental taurine for at least 4 months may be useful, especially in an atypical breed affected with DCM (see p. 70 for supplementation guidelines). Plasma taurine concentrations less than 25 (to 40) nmol/mL and blood taurine concentrations less than 200 (or 150) nmol/mL are generally considered deficient. Specific collection and submission guidelines should be obtained from the laboratory used. Other Factors Myocardial injury induced by free radicals may play a role in a number of diseases. Evidence for increased oxidative stress has been found in dogs with CHF and myocardial failure, but the clinical ramifications of this are unclear. Diseases such as hypothyroidism, pheochromocytoma, and diabetes mellitus have been associated with reduced myocardial function, but clinical heart failure is unusual in dogs secondary to these conditions alone. Excessive sympathetic stimulation stemming from brain or spinal cord injury results in myocardial hemorrhage, necrosis, and arrhythmias (brainheart syndrome). Muscular dystrophy of the fasciohumoral type (reported in English Springer Spaniels) may result in atrial standstill and heart failure. Canine X-linked (Du� chenne) muscular dystrophy in Golden Retrievers and other breeds has also been associated with myocardial fibrosis and mineralization. Rarely, nonneoplastic (e.g., glycogen storage disease) and neoplastic (metastatic and primary) infiltrates

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interfere with normal myocardial function. Immunologic mechanisms may also play an important role in the pathogenesis of myocardial dysfunction in some dogs with myocarditis.

ISCHEMIC MYOCARDIAL DISEASE Acute myocardial infarction resulting from coronary embolization is uncommon. An underlying disease associated with increased risk for thromboembolism, such as bacterial endocarditis, neoplasia, severe renal disease, immune-mediated hemolytic anemia, acute pancreatitis, disseminated intravascular coagulopathy, and/or corticosteroid use, underlies most cases. Sporadic reports of myocardial infarction have been associated with congenital ventricular outflow obstruction, patent ductus arteriosus, hypertrophic cardiomyopathy, and mitral insufficiency. Atherosclerosis of the major coronary arteries, which can accompany severe hypothyroidism in dogs, rarely leads to acute myocardial infarction. Clinical signs of acute major coronary artery obstruction are likely to include arrhythmias, pulmonary edema, marked ST segment change on ECG, and evidence of regional or global myocardial contractile dysfunction on echocardiogram. High circulating cardiac troponin concentrations and possibly creatine kinase activity occur after myocardial injury and necrosis. Disease of small coronary vessels is recognized as well. Non-atherosclerotic narrowing of small coronary arteries could be more clinically important than previously assumed. Hyalinization of small coronary vessels and intramural myocardial infarctions have been described in dogs with chronic degenerative AV valve disease, but they can occur in older dogs without valve disease as well. Fibromuscular arteriosclerosis of small coronary vessels is also described. These changes in the walls of the small coronary arteries cause luminal narrowing and can impair resting coronary blood flow, as well as vasodilatory responses. Small myocardial infarctions and secondary fibrosis lead to reduced myocardial function. Various arrhythmias can occur. Eventual CHF is a cause of death in many cases with intramural coronary arteriosclerosis. Sudden death is a less common sequela. Larger breeds of dog may be predisposed, although Cocker Spaniels and Cavalier King Charles Spaniels appear to be commonly affected smaller breeds. TACHYCARDIA-INDUCED CARDIOMYOPATHY The term tachycardia-induced cardiomyopathy (TICM) refers to the progressive myocardial dysfunction, activation of neurohormonal compensatory mechanisms, and CHF that result from rapid, incessant tachycardias. The myocardial failure may be reversible if the heart rate can be normalized in time. TICM has been described in several dogs with AV nodal reciprocating tachycardias associated with accessory conduction pathways that bypass the AV node (e.g., WolffParkinson-White; see p. 78). Rapid artificial pacing (e.g., >200 beats/min) is a common model for inducing experimental myocardial failure that simulates DCM.

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HYPERTROPHIC CARDIOMYOPATHY In contrast to cats, hypertrophic cardiomyopathy (HCM) is uncommon in dogs. A genetic basis is suspected in some, although the cause is unknown. The pathophysiology is similar to that of HCM in cats (see Chapter 8). Abnormal, excessive myocardial hypertrophy increases ventricular stiffness and leads to diastolic dysfunction. The LV hypertrophy is usually symmetric, but regional variation in wall or septal thickness can occur. Compromised coronary perfusion is likely with severe ventricular hypertrophy. This leads to myocardial ischemia, which exacerbates arrhythmias, delays ventricular relaxation, and further impairs filling. High LV filling pressure predisposes to pulmonary venous congestion and edema. Besides diastolic dysfunction, systolic dynamic LV outflow obstruction occurs in some dogs. Malposition of the mitral apparatus may contribute to systolic anterior mitral valve motion and LV outflow obstruction, as well as to mitral regurgitation. In some dogs asymmetric septal hypertrophy also contributes to outflow obstruction. LV outflow obstruction increases ventricular wall stress and myocardial oxygen requirement while also impairing coronary blood flow. Heart rate elevations magnify these abnormalities. Clinical Features HCM is most commonly diagnosed in young to middle-age large-breed dogs, although there is a wide age distribution. Various breeds are affected. There may be a higher prevalence of HCM in males. Clinical signs of CHF, episodic weakness, and/or syncope occur in some dogs. Sudden death is the only sign in some cases. Ventricular arrhythmias secondary to myocardial ischemia are presumed to cause the lowoutput signs and sudden death. A systolic murmur, related to either LV outflow obstruction or mitral insufficiency, may be heard on auscultation. The systolic ejection murmur of ventricular outflow obstruction becomes louder when ventricular contractility is increased (e.g., with exercise or excitement) or when afterload is reduced (e.g., from vasodilator use). An S4 gallop sound is heard in some affected dogs. Diagnosis Echocardiography is the best diagnostic tool for HCM. An abnormally thick LV, with or without narrowing of the LV outflow tract area or asymmetric septal hypertrophy, and LA enlargement are characteristic findings. Mitral regurgitation may be evident on Doppler studies. Systolic anterior motion of the mitral valve may result from dynamic outflow obstruction causes. Partial systolic aortic valve closure may be seen as well. Other causes of LV hypertrophy to be ruled out include congenital subaortic stenosis, hypertensive renal disease, thyrotoxicosis, and pheochromocytoma. Thoracic radiographs may indicate LA and LV enlargement, with or without pulmonary congestion or edema. Some cases appear radiographically normal. ECG findings may include ventricular tachyarrhythmias and conduction abnormalities, such as complete heart block, first-degree AV block, and

fascicular blocks. Criteria for LV enlargement are variably present. Treatment The general goals of HCM treatment are to enhance myocardial relaxation and ventricular filling, control pulmonary edema, and suppress arrhythmias. A β-blocker (see p. 89) or Ca++-channel blocker (see p. 93) may lower heart rate, prolong ventricular filling time, reduce ventricular conÂ� tractility, and minimize myocardial oxygen requirement. β-blockers can also reduce dynamic LV outflow obstruction and may suppress arrhythmias induced by heightened sympathetic activity, whereas Ca++-blockers may facilitate myocardial relaxation. Diltiazem has a lesser inotropic effect and would be less useful against dynamic outflow obstruction, especially in view of its vasodilating effect. Because β- and Ca++-channel blockers can worsen AV conduction abnormalities, they may be relatively contraindicated in certain animals. A diuretic and ACEI are indicated if congestive signs are present. Digoxin should not be used because it may increase myocardial oxygen requirements, worsen outflow obstruction, and predispose to the development of ventricular arrhythmias. Likewise, there is no indication for pimobendan unless myocardial failure develops and LV outflow obstruction is absent. Exercise restriction is advised in dogs with HCM.

MYOCARDITIS A wide variety of agents can affect the myocardium, although disease manifestations in other organ systems may overshadow the cardiac involvement. The heart can be injured by direct invasion of the infective agent, by toxins it elaborates, or by the host’s immune response. Noninfective causes of myocarditis include cardiotoxic drugs and drug hypersensitivity reactions. Myocarditis can cause persistent cardiac arrhythmias and progressively impair myocardial function.

INFECTIVE MYOCARDITIS Etiology and Pathophysiology

Viral Myocarditis Lymphocytic myocarditis has been associated with acute viral infections in experimental animals and in people. CardioÂ� tropic viruses can play an important role in the pathogenesis of myocarditis and subsequent cardiomyopathy in several species, but this is not recognized commonly in dogs. The host animal’s immune responses to viral and nonviral antigens contribute to myocardial inflammation and damage. A syndrome of parvoviral myocarditis was recognized in the late 1970s and early 1980s. It is characterized by a peracute necrotizing myocarditis and sudden death (with or without signs of acute respiratory distress) in apparently healthy puppies about 4 to 8 weeks old. Cardiac dilation with pale streaks in the myocardium, gross evidence of congestive

failure, large basophilic or amorphophilic intranuclear inclusion bodies, myocyte degeneration, and focal mononuclear cell infiltrates are typical necropsy findings. This syndrome is uncommon now, probably as a result of maternal antibody production in response to virus exposure and vaccination. Parvovirus may cause a form of DCM in young dogs that survive neonatal infection; viral genetic material has been identified in some canine ventricular myocardial samples in the absence of classic intranuclear inclusion bodies. Canine distemper virus may cause myocarditis in young puppies, but multisystemic signs usually predominate. Histologic changes in the myocardium are mild compared with those in the classic form of parvovirus myocarditis. Experimental herpesvirus infection of pups during gestation also causes necrotizing myocarditis with intranuclear inclusion bodies leading to fetal or perinatal death. West Nile virus has been reported to cause severe lymphocytic and neutrophilic myocarditis and vasculitis, with areas of myocardial hemorrhage and necrosis. Vague clinical signs can include lethargy, poor appetite, arrhythmias, neurologic signs, and fever. Immunohistochemistry, RT-PCR, serology, and virus isolation have been used in diagnosis.

Bacterial Myocarditis Bacteremia and bacterial endocarditis or pericarditis can cause focal or multifocal suppurative myocardial inflammation or abscess formation. Localized infections elsewhere in the body may be the source of the organisms. Clinical signs include malaise, weight loss, and, inconsistently, fever. Arrhythmias and cardiac conduction abnormalities are common, but murmurs are rare unless concurrent valvular endocarditis or another underlying cardiac defect is present. Serial bacterial (or fungal) blood cultures, serology, or PCR may allow identification of the organism. Bartonella vinsonii subspecies have been associated with cardiac arrhythmias, myocarditis, endocarditis, and sudden death. Lyme Carditis Lyme disease is more prevalent in certain geographic areas, especially the northeastern, western coastal, and north central United States, as well as in Japan and Europe, among other areas. The spirochete Borrelia burgdorferi (or related species) is transmitted to dogs by ticks (especially Ixodes genus) and possibly other biting insects (see Chapter 71). Third-degree (complete) and high-grade second-degree AV block has been identified in dogs with Lyme disease. Syncope, CHF, reduced myocardial contractility, and ventricular arrhythmias are also reported in affected dogs. Pathologic findings of Lyme myocarditis include infiltrates of plasma cells, macrophages, neutrophils, and lymphocytes, with areas of myocardial necrosis. These are similar to findings in human Lyme carditis. A presumptive diagnosis is made on the basis of the finding of positive (or increasing) serum titers or a positive SNAP test and concurrent signs of myocarditis, with or without other systemic signs. If

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endomyocardial biopsy is available, findings may be helpful in confirming the diagnosis. Treatment with an appropriate antibiotic should be instituted pending diagnostic test results. Cardiac drugs are used as needed. Resolution of AV conduction block may not occur in dogs despite appropriate antimicrobial therapy.

Protozoal Myocarditis Trypanosoma cruzi, Toxoplasma gondii, Neosporum caninum, Babesia canis, Hepatozoon americanum, and Leishmania spp. are known to affect the myocardium (see p. 1378). Trypanosomiasis (Chagas disease) has occurred mainly in young dogs in Texas, Louisiana, Oklahoma, Virginia, and other southern states in the United States. The possibility for human infection should be recognized; this is an important cause of human myocarditis and subsequent cardiomyopathy in Central and South America. The organism is transmitted by bloodsucking insects of the family Reduviidae and is enzootic in wild animals of the region. Amastigotes of T. cruzi cause myocarditis with a mononuclear cell infiltrate and disruption and necrosis of myocardial fibers. Acute, latent, and chronic phases of Chagas myocarditis have been described. Lethargy, depression, and other systemic signs, as well as various tachyarrhythmias, AV conduction defects, and sudden death, are seen in dogs with acute trypanosomiasis. Clinical signs are sometimes subtle. The disease is diagnosed in the acute stage by finding trypomastigotes in thick peripheral blood smears; the organism can be isolated in cell culture or by inoculation into mice. Animals that survive the acute phase enter a latent phase of variable duration. During this phase the parasitemia is resolved, and antibodies develop against the organism, as well as cardiac antigens. Chronic Chagas disease is characterized by progressive right-sided or generalized cardiomegaly and various arrhythmias. Ventricular tachyarrhythmias are most common, but supraventricular tachyarrhythmias may occur. Right bundle branch block and AV conduction disturbances are also reported. Ventricular dilation and reduced myocardial function are usually evident echocardiographically. Clinical signs of biventricular failure are common. Antemortem diagnosis in chronic cases may be possible through serologic testing. Therapy in the acute stage is aimed at eliminating the organism and minimizing myocardial inflammation; several treatments have been tried with variable success. The therapy for chronic Chagas disease is aimed at supporting myocardial function, controlling congestive signs, and suppressing arrhythmias. A cysteine protease inhibitor may be effective in reducing the severity of the cardiac abnormalities. Toxoplasmosis and neosporiosis can cause clinical myocarditis in conjunction with generalized systemic infection, especially in the immunocompromised animal. The organism becomes encysted in the heart and various other body tissues after the initial infection. With rupture of these cysts, expelled bradyzoites induce hypersensitivity reactions and tissue necrosis. Other systemic signs often overshadow signs of myocarditis. Immunosuppressed dogs with chronic toxoplasmosis (or neosporiosis) may be prone to active disease,

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including clinically relevant myocarditis, pneumonia, chorioretinitis, and encephalitis. Antiprotozoal therapy may be successful. Babesiosis can be associated with cardiac lesions in dogs, including myocardial hemorrhage, inflammation, and necrosis. Pericardial effusion and variable ECG changes are also noted in some cases. A correlation between plasma cardiac troponin I (cTnI) concentration and clinical severity, survival, and cardiac histopathologic findings was shown in dogs with babesiosis. Hepatozoon americanum, identified as a new species distinct from Hepatozoon canis, was originally found in dogs along the Texas coast but has a much wider range. Coyotes, rodents, and other wildlife are an important wild reservoir. Dogs become infected by ingesting the organism’s tick host (Amblyomma maculatum) or through predation. Skeletal and cardiac muscles are the main tissues affected by H. americanum. A severe inflammatory reaction to merozoites released from ruptured tissue cysts leads to pyogranulomatous myositis. Clinical signs include stiffness, anorexia, fever, neutrophilia, periosteal new bone reaction, muscle atrophy, and often death. Leishmaniosis, endemic in certain regions, has caused myocarditis, various arrhythmias, and epicarditis with cardiac tamponade, as well as other systemic and cutaneous signs.

blood cultures may be useful. Serologic screening for specific infective causes may be helpful in some cases. Histopathologic criteria for a diagnosis of myocarditis include inflammatory infiltrates with myocyte degeneration and necrosis. Endomyocardial biopsy specimens are currently the only means of obtaining a definitive antemortem diagnosis, but if the lesions are focal, the findings may not be diagnostic. Treatment Unless a specific etiologic agent can be identified and treated, therapy for suspected myocarditis is largely supportive. Strict rest, antiarrhythmic drugs (see Chapter 4), therapy to support myocardial function and manage CHF signs (see Chapter 3), and other supportive measures are used as needed. Corticosteroids are not proven to be clinically beneficial in dogs with myocarditis and, considering the possible infective cause, are not recommended as nonspecific therapy. Exceptions would be confirmed immune-mediated disease, drug-related or eosinophilic myocarditis, or confirmed nonresolving myocarditis.

Other Causes Rarely, fungi (Aspergillus, Cryptococcus, Coccidioides, Blas� tomyces, Histoplasma, Paecilomyces); rickettsiae (Rickettsia rickettsii, Ehrlichia canis, Bartonella elizabethae); algaelike organisms (Prototheca spp.); and nematode larval migration (Toxocara spp.) cause myocarditis. Affected animals are usually immunosuppressed and have systemic signs of disease. Rocky Mountain spotted fever (R. rickettsii) occasionally causes fatal ventricular arrhythmias, along with necrotizing vasculitis, myocardial thrombosis, and ischemia. Angiostrongylus vasorum infection in association with immune-mediated thrombocytopenia has rarely caused myocarditis, thrombosing arteritis, and sudden death.

NONINFECTIVE MYOCARDITIS Myocardial inflammation can result from the effects of drugs, toxins, or immunologic responses. Although there is little clinical documentation for many of these in dogs, a large number of potential causes have been identified in people. Besides the well-known toxic effects of doxoÂ� rubicin and catecholamines, other potential causes of noninfective myocarditis include heavy metals (e.g., arsenic, lead, mercury); antineoplastic drugs (cyclophosphamide, 5-fluorouracil, interleukin-2, α-interferon); other drugs (e.g., thyroid hormone, cocaine, amphetamines, lithium); and toxins (wasp or scorpion stings, snake venom, spider bites). Immune-mediated diseases and pheochromocytoma can cause myocarditis as well. Hypersensitivity reactions to many antiinfective agents and other drugs have also been identified as causes of myocarditis in people. Drug-related myocarditis is usually characterized by eosinophilic and lymphocytic infiltrates.

Clinical Findings and Diagnosis Unexplained onset of arrhythmias or heart failure after a recent episode of infective disease or drug exposure is the classic clinical presentation of acute myocarditis. However, definitive diagnosis can be difficult because clinical and clinicopathologic findings are usually nonspecific and inconsistent. A database including complete blood count, serum biochemical profile with creatine kinase activity, serum cardiac troponin I (and NT-proBNP) concentration, thoracic and abdominal radiographs, and urinalysis are usually obtained. ECG changes could include an ST segment shift, T-wave or QRS voltage changes, AV conduction abnormalities, and various other arrhythmias. Echocardiographic signs of poor regional or global wall motion, altered myocardial echogenicity, or pericardial effusion may be evident. In dogs with persistent fever, serial bacterial (or fungal)

TRAUMATIC MYOCARDITIS Nonpenetrating or blunt trauma to the chest and heart is more common than penetrating wounds. Cardiac arrhythmias are frequently observed after such trauma, especially in dogs. Cardiac damage can result from impact against the chest wall, compression, or acceleration-deceleration forces. Other possible mechanisms of myocardial injury and arrhythmogenesis include an autonomic imbalance, is� chemia, reperfusion injury, and electrolyte and acid-base disturbances. Thoracic radiographs, serum biochemistries, circulating cardiac troponin concentrations, ECG, and echocardiography are recommended in the assessment of these cases. Echocardiography can define preexisting heart disease, global myocardial function, and unexpected cardiovascular findings, but it may not identify small areas of myocardial injury.

Arrhythmias usually appear within 24 to 48 hours after trauma, although they can be missed on intermittent ECG recordings. VPCs, ventricular tachycardia, and accelerated idioventricular rhythm (with rates of 60-100 beats/min or slightly faster) are more common than supraventricular tachyarrhythmias or bradyarrhythmias in these patients. An accelerated idioventricular rhythm is usually manifested only when the sinus rate slows or pauses; this rhythm is benign in most dogs with normal underlying heart function and disappears with time (generally within a week or so). Antiarrhythmic therapy for accelerated idioventricular rhythm in this setting is usually unnecessary. The patient and ECG rhythm should be monitored closely. More serious arrhythmias (e.g., with a faster rate) or hemodynamic deterioration may require antiarrhythmic therapy (see Chapter 4). Traumatic avulsion of a papillary muscle, septal perforation, and rupture of the heart or pericardium have also been reported. Traumatic papillary muscle avulsion causes acute volume overload with acute onset of CHF. Signs of lowoutput failure and shock, as well as arrhythmias, can develop rapidly after cardiac trauma. Suggested Readings Noninfective Myocardial Disease Baumwart RD et al: Clinical, echocardiographic, and electrocardiographic abnormalities in Boxers with cardiomyopathy and left ventricular systolic dysfunction: 48 cases (1985-2003), J Am Vet Med Assoc 226:1102, 2005. Baumwart RD, Orvalho J, Meurs KM: Evaluation of serum cardiac troponin I concentration in boxers with arrhythmogenic right ventricular cardiomyopathy, Am J Vet Res 68:524, 2007. Borgarelli M et al: Prognostic indicators for dogs with dilated cardiomyopathy, J Vet Intern Med 20:104, 2006. Calvert CA et al: Results of ambulatory electrocardiography in overtly healthy Doberman Pinschers with echocardiographic abnormalities, J Am Vet Med Assoc 217:1328, 2000. Dukes-McEwan J et al: Proposed guidelines for the diagnosis of canine idiopathic dilated cardiomyopathy, J Vet Cardiol 5:7, 2003. Falk T, Jonsson L: Ischaemic heart disease in the dog: a review of 65 cases, J Small Anim Pract 41:97, 2000. Fascetti AJ et al: Taurine deficiency in dogs with dilated cardiomyopathy: 12 cases (1997-2001), J Am Vet Med Assoc 223:1137, 2003. Fine DM, Tobias AH, Bonagura JD: Cardiovascular manifestations of iatrogenic hyperthyroidism in two dogs, J Vet Cardiol 12:141, 2010. Freeman LM et al: Relationship between circulating and dietary taurine concentration in dogs with dilated cardiomyopathy, Vet Therapeutics 2:370, 2001. Maxson TR et al: Polymerase chain reaction analysis for viruses in paraffin-embedded myocardium from dogs with dilated cardiomyopathy or myocarditis, Am J Vet Res 62:130, 2001. Meurs KM et al: Genome-wide association identifies a deletion in the 3′ untranslated region of striatin in a canine model of arrhythmogenic right ventricular cardiomyopathy, Hum Genet 128:315, 2010. Meurs KM et al: A prospective genetic evaluation of familial dilated cardiomyopathy in the Doberman Pinscher, J Vet Intern Med 21:1016, 2007.

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Meurs KM, Miller MW, Wright NA: Clinical features of dilated cardiomyopathy in Great Danes and results of a pedigree analysis: 17 cases (1990-2000), J Am Vet Med Assoc 218:729, 2001. O’Grady MR et al: Effect of pimobendan on case fatality rate in Doberman Pinschers with congestive heart failure caused by dilated cardiomyopathy, J Vet Intern Med 22:897, 2008. O’Sullivan ML, O’Grady MR, Minors SL: Plasma big endothelin-1, atrial natriuretic peptide, aldosterone, and norepinephrine concentrations in normal Doberman Pinschers and Doberman Pinschers with dilated cardiomyopathy, J Vet Intern Med 21:92, 2007. O’Sullivan ML, O’Grady MR, Minors SL: Assessment of diastolic function by Doppler echocardiography in normal Doberman Pinschers and Doberman Pinschers with dilated cardiomyopathy, J Vet Intern Med 21:81, 2007. Oxford EM et al: Ultrastructural changes in cardiac myocytes from Boxer dogs with arrhythmogenic right ventricular cardiomyopathy, J Vet Cardiol 13:101, 2011. Oyama MA, Chittur SV, Reynolds CA: Decreased triadin and increased calstabin2 expression in Great Danes with dilated cardiomyopathy, J Vet Intern Med 23:1014, 2009. Oyama MA et al: Carvedilol in dogs with dilated cardiomyopathy, J Vet Intern Med 21:1272, 2007. Palermo V et al: Cardiomyopathy in Boxer dogs: a retrospective study of the clinical presentation, diagnostic findings and survival, J Vet Cardiol 13:45, 2011. Pedro BM et al: Association of QRS duration and survival in dogs with dilated cardiomyopathy: a retrospective study of 266 clinical cases, J Vet Cardiol 13:243, 2011. Scansen BA et al: Temporal variability of ventricular arrhythmias in Boxer dogs with arrhythmogenic right ventricular cardiomyopathy, J Vet Intern Med 23:1020, 2009. Sleeper MM et al: Dilated cardiomyopathy in juvenile Portuguese water dogs, J Vet Intern Med 16:52, 2002. Smith CE et al: Omega-3 fatty acids in Boxers with arrhythmogenic right ventricular cardiomyopathy, J Vet Intern Med 21:265, 2007. Stern JA et al: Ambulatory electrocardiographic evaluation of clinically normal adult Boxers, J Am Vet Med Assoc 236:430, 2010. Thomason JD et al: Bradycardia-associated syncope in seven Boxers with ventricular tachycardia (2002-2005), J Vet Intern Med 22:931, 2008. Vollmar AC et al: Dilated cardiomyopathy in juvenile Doberman Pinscher dogs, J Vet Cardiol 5:23, 2003. Wess G et al: Cardiac troponin I in Doberman Pinschers with cardiomyopathy, J Vet Intern Med 24:843, 2010. Wess G et al: Evaluation of N-terminal pro-B-type natriuretic peptide as a diagnostic marker of various stages of cardiomyopathy in Doberman Pinschers, Am J Vet Res 72:642, 2011. Wright KN et al: Radiofrequency catheter ablation of atrioventricular accessory pathways in 3 dogs with subsequent resolution of tachycardia-induced cardiomyopathy, J Vet Intern Med 13:361, 1999. Myocarditis Barr SC et al: A cysteine protease inhibitor protects dogs from cardiac damage during infection by Trypanosoma cruzi, Antimicrob Agents Chemother 49:5160, 2005. Bradley KK et al: Prevalence of American trypanosomiasis (Chagas disease) among dogs in Oklahoma, J Am Vet Med Assoc 217:1853, 2000.

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Breitschwerdt EB et al: Bartonellosis: an emerging infectious disease of zoonotic importance to animal and human beings, J Vet Emerg Crit Care 20:8, 2010. Calvert CA, Thomason JD: Cardiovascular infections. In Greene CE, editor: Infectious diseases of the dog and cat, ed 4, St Louis, 2012, Elsevier Saunders, p 912. Cannon AB et al: Acute encephalitis, polyarthritis, and myocarditis associated with West Nile virus infection in a dog, J Vet Intern Med 20:1219, 2006.

Dvir E et al: Electrocardiographic changes and cardiac pathology in canine babesiosis, J Vet Cardiol 6:15, 2004. Fritz CL, Kjemtrup AM: Lyme borreliosis, J Am Vet Med Assoc 223:1261, 2003. Kjos SA et al: Distribution and characterization of canine Chagas disease in Texas, Vet Parasit 152:249, 2007. Schmiedt C et al: Cardiovascular involvement in 8 dogs with Blastomyces dermatitidis infection, J Vet Intern Med 20:1351, 2006.

C H A P T E R

8â•…

Myocardial Diseases of the Cat

Myocardial disease in cats encompasses a diverse collection of idiopathic and secondary processes affecting the myocar­ dium. The spectrum of anatomic and pathophysiologic features is wide. Disease characterized by myocardial hyper­ trophy is most common, although features of multiple pathophysiologic categories coexist in some cats. Restrictive pathophysiology develops often. Classic dilated cardiomy­ opathy (DCM) is now uncommon in cats; its features are similar to those of DCM in dogs (see Chapter 7). Myocardial disease in some cats does not fit neatly into the categories of hypertrophic, dilated, or restrictive cardiomyopathy and therefore is considered indeterminate or unclassified cardio­ myopathy. Rarely, arrhythmogenic right ventricular (RV) cardiomyopathy is identified in cats. Arterial thrombo­ embolism is a major complication in cats with myocardial disease.

Testing for these mutations is available (contact http:// www.cvm.ncsu.edu/vhc/csds/vcgl/). In addition to mutations of genes that encode for myo­ cardial contractile or regulatory proteins, possible causes of the disease include an increased myocardial sensitivity to or excessive production of catecholamines; an abnormal hyper­ trophic response to myocardial ischemia, fibrosis, or trophic factors; a primary collagen abnormality; and abnormalities of the myocardial calcium-handling process. Myocardial hypertrophy with foci of mineralization occurs in cats with hypertrophic feline muscular dystrophy, an X-linked reces­ sive dystrophin deficiency similar to Duchenne muscular dystrophy in people; however, congestive heart failure (CHF) is uncommon in these cats. Some cats with HCM have high serum growth hormone concentrations. It is not clear whether viral myocarditis has a role in the pathogenesis of feline cardiomyopathy.

HYPERTROPHIC CARDIOMYOPATHY

Pathophysiology Abnormal sarcomere function is thought to underlie activa­ tion of abnormal cell signaling processes that eventually pro­ duces myocyte hypertrophy and disarray, as well as increased collagen synthesis. Thickening of the left ventricular (LV) wall and/or interventricular septum is the characteristic result, but the extent and distribution of hypertrophy in cats with HCM are variable. Many cats have symmetric hyper­ trophy, but some have asymmetric septal thickening and a few have hypertrophy limited to the free wall or papillary muscles. The LV lumen usually appears small. Focal or diffuse areas of fibrosis occur within the endocardium, con­ duction system, or myocardium. Narrowing of small intra­ mural coronary arteries may also be noted and probably contributes to ischemia-related fibrosis. Areas of myocardial infarction and myocardial fiber disarray may be present. Cats with pronounced systolic anterior motion (SAM) of the anterior mitral leaflet may have a fibrous patch on the interventricular septum where repeated valve contact has occurred. Myocardial hypertrophy and the accompanying changes increase ventricular wall stiffness. Additionally, early active

Etiology The cause of primary or idiopathic hypertrophic cardio­ myopathy (HCM) in cats is unknown, but a heritable abnormality is likely in many cases. Autosomal dominant inheritance has been identified in the Maine Coon, Ragdoll, and American Shorthair breeds. Incomplete penetrance occurs in Maine Coon cats; some genetically abnormal car­ riers may be phenotypically normal. Disease prevalence is high in other breeds as well, including British Shorthairs, Norwegian Forest Cats, Scottish Folds, Bengals, and Rex. There also are reports of HCM in litter mates and other closely related domestic shorthair cats. In human familial HCM, many different gene mutations are known to exist, although several common human gene mutations have not yet been found in feline HCM. Two mutations in the cardiac myosin binding protein C gene have been found, one in Maine Coon cats and one in Ragdoll cats with HCM. However, other mutations are likely involved because not all Maine Coon cats with evidence for HCM have the identified mutation, and not all cats with the mutation develop HCM.

145

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myocardial relaxation may be slow and incomplete, espe­ cially in the presence of myocardial ischemia or abnormal Ca++ kinetics. This further reduces ventricular distensibility and promotes diastolic dysfunction. The increased ventricu­ lar stiffness impairs LV filling and increases diastolic pres­ sure. LV volume remains normal or decreased. Reduced ventricular volume results in a lower stroke volume, which may contribute to neurohormonal activation. Higher heart rates further interfere with LV filling, promote myocardial ischemia, and contribute to pulmonary venous congestion and edema by shortening the diastolic filling period. Con­ tractility, or systolic function, is usually normal in affected cats. However, some cats experience progression to ventricu­ lar systolic failure and dilation. Higher LV filling pressures lead to increased left atrial (LA) and pulmonary venous pressures. Progressive LA dilation, as well as pulmonary congestion and edema, can result. The degree of LA enlargement can become massive over time. An intracardiac thrombus is sometimes found, usually within the left auricular appendage but occasionally in the left atrium (LA), left ventricle (LV), or attached to a ventricular wall. Arterial thromboembolism is a major com­ plication of HCM and other forms of cardiomyopathy in cats (see Chapter 12). Mitral regurgitation develops in some affected cats. Changes in LV geometry, papillary muscle structure, or mitral SAM may prevent normal valve closure. Valve insufficiency exacerbates the increased LA size and pressure. Systolic dynamic LV outflow obstruction occurs in some cats. This is also known as hypertrophic obstructive cardiomyopathy (or functional subaortic stenosis). LV papillary muscle hypertrophy and abnormal (anterior) displacement are thought to cause SAM and interfere with normal LV outflow. Excessive asymmetric hypertrophy of the basilar interven­ tricular septum can contribute to the dynamic obstruction. Systolic outflow obstruction increases LV pressure, wall stress, and myocardial oxygen demand and promotes myo­ cardial ischemia. Mitral regurgitation is exacerbated by the tendency of hemodynamic forces to pull the anterior mitral leaflet toward the interventricular septum during ejection (SAM, see Fig. 8-3). Increased LV outflow turbulence com­ monly causes an ejection murmur of variable intensity in these cats. Several factors probably contribute to the development of myocardial ischemia in cats with HCM. These include narrowing of intramural coronary arteries, increased LV filling pressure, decreased coronary artery perfusion pres­ sure, and insufficient myocardial capillary density for the degree of hypertrophy. Tachycardia contributes to ischemia by increasing myocardial O2 requirements while reducing diastolic coronary perfusion time. Ischemia impairs early, active ventricular relaxation, which further increases ven­ tricular filling pressure, and over time leads to myocardial fibrosis. Ischemia can provoke arrhythmias and possibly thoracic pain. Atrial fibrillation (AF) and other tachyarrhythmias further impair diastolic filling and exacerbate venous

congestion; the loss of the atrial “kick” and the rapid heart rate associated with AF are especially detrimental. Ventricu­ lar tachycardia or other arrhythmias may lead to syncope or sudden death. Pulmonary venous congestion and edema result from increasing LA pressure. Increased pulmonary venous and capillary pressures are thought to cause pulmonary vasocon­ striction; increased pulmonary arterial pressure and second­ ary right-sided CHF signs may occur. Eventually, refractory biventricular failure with profuse pleural effusion develops in some cats with HCM. The effusion is usually a modified transudate, although it can be (or become) chylous. Clinical Features Overt HCM may be most common in middle-aged male cats, but clinical signs can occur at any age. Cats with milder disease may be asymptomatic for years. Increased echocar­ diographic screening of cats with a murmur, arrhythmia, or occasionally a gallop sound, heard on routine examination, has uncovered numerous cases of subclinical HCM. Several studies in apparently healthy cats have found variable preva­ lence of a cardiac murmur, ranging from 15% to more than 34% (see p. 11 in Chapter 1). The estimated prevalence of subclinical cardiomyopathy in cats with a murmur, based on echocardiography, has ranged from about 31% to more than 50%. Subclinical cardiomyopathy has also been identified by echocardiography in cats with no murmur or other abnor­ mal physical examination findings, although the estimated prevalence is much lower at 11% to 16%. Symptomatic cats are most often presented for respira­ tory signs of variable severity or acute signs of thromboem­ bolism (see p. 201). Respiratory signs include tachypnea; panting associated with activity; dyspnea; and, only rarely, coughing (which can be misinterpreted as vomiting). Disease onset may seem acute in sedentary cats, even though patho­ logic changes have developed gradually. Occasionally, lethargy or anorexia is the only evidence of disease. Some cats have syncope or sudden death in the absence of other signs. Stresses such as anesthesia; surgery; fluid administra­ tion; systemic illnesses (e.g., fever, anemia); or boarding can precipitate CHF in an otherwise compensated cat. Such a stressful event or recent corticosteroid administration was identified in about half of cats with overt CHF in one study. Systolic murmurs compatible with mitral regurgitation or LV outflow tract obstruction are common. Some cats do not have an audible murmur, even in the face of marked ventricular hypertrophy. A diastolic gallop sound (usually S4) may be heard, especially if heart failure is evident or imminent. Cardiac arrhythmias are relatively common. Femoral pulses are usually strong, unless distal aortic throm­ boembolism has occurred. The precordial impulse often feels vigorous. Prominent lung sounds, pulmonary crackles, and sometimes cyanosis accompany severe pulmonary edema. However, pulmonary crackles are not always heard with edema in cats. Pleural effusion usually attenuates ventral pulmonary sounds.

CHAPTER 8â•…â•… Myocardial Diseases of the Cat

147

A

C

B FIG 8-1â•…

Radiographic examples of feline hypertrophic cardiomyopathy. Lateral (A) and dorsoventral (B) views showing atrial and mild ventricular enlargement in a male domestic shorthair cat. Lateral (C) view of a cat with hypertrophic cardiomyopathy and marked pulmonary edema.

Diagnosis

RADIOGRAPHY Although the cardiac silhouette appears normal in most cats with mild HCM, radiographic features of advanced HCM include a prominent LA and variable LV enlargement (Fig. 8-1). The classic valentine-shaped appearance of the heart on dorsoventral or ventrodorsal views is not always present, although usually the point of the LV apex is main­ tained. Enlarged and tortuous pulmonary veins may be noted in cats with chronically high LA and pulmonary venous pressure. Left-sided CHF produces variable degrees of patchy interstitial or alveolar pulmonary edema infiltrates. The radiographic distribution of pulmonary edema is vari­ able; a diffuse or focal distribution throughout the lung fields is common, in contrast to the characteristic perihilar distribution of cardiogenic pulmonary edema seen in dogs. Pleural effusion is common in cats with advanced or biven­ tricular CHF. ELECTROCARDIOGRAPHY Many cats with HCM have electrocardiogram (ECG) abnor­ malities, including criteria for LA or LV enlargement, ven­ tricular and/or (less often) supraventricular tachyarrhythmias, and a left anterior fascicular block pattern (see Fig. 8-2

and Chapter 2). Atrioventricular (AV) conduction delay, complete AV block, or sinus bradycardia is occasionally found. Nevertheless, the ECG is too insensitive to be useful as a screening test for HCM.

ECHOCARDIOGRAPHY Echocardiography is the best means of diagnosis and dif­ ferentiation of HCM from other disorders. The extent of hypertrophy and its distribution within the ventricular wall, septum, and papillary muscles is shown by two-dimensional (2-D) and M-mode echo studies. Doppler techniques can demonstrate LV diastolic or systolic abnormalities. Widespread myocardial thickening is common, and the hypertrophy is often asymmetrically distributed among various LV wall, septal, and papillary muscle locations. Focal areas of hypertrophy also occur. Use of 2-D–guided M-mode echocardiography helps ensure proper beam position. Stan­ dard M-mode views and measurements are obtained, but thickened areas outside these standard positions should also be measured (Fig. 8-3). The 2-D right parasternal long-axis view is useful for measuring basilar interventricular septum thickness. The diagnosis of early disease may be questionable in cats with mild or only focal thickening. Falsely increased thickness measurements (pseudohypertrophy) can occur with dehydration and sometimes tachycardia. Spurious

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FIG 8-2â•…

Electrocardiogram from a cat with hypertrophic cardiomyopathy showing occasional ventricular premature complexes and a left axis deviation. Leads I, II, III, at 25╯mm/sec. 1╯cm = 1╯mV.

diastolic thickness measurements also arise when the beam does not transect the wall/septum perpendicularly and when the measurement is not taken at the end of diastole, as can happen without simultaneous ECG recording or when using 2-D imaging of insufficient frame rate. A (properly obtained) end-diastolic LV wall or septal thickness greater than 5.5 (to 5.9) mm is considered abnormal. Cats with severe HCM may have diastolic LV wall or septal thicknesses of 8╯mm or more, although the degree of hypertrophy is not necessarily cor­ related with the severity of clinical signs. Doppler-derived estimates of diastolic function, such as isovolumic relaxation time, and mitral inflow and pulmonary venous velocity pat­ terns, as well as Doppler tissue imaging techniques, are being employed more often to define disease characteristics. Papillary muscle hypertrophy can be marked, and systolic LV cavity obliteration is observed in some cats with HCM. Increased echogenicity (brightness) of papillary muscles and subendocardial areas is thought to be a marker for chronic myocardial ischemia with resulting fibrosis. LV fractional shortening (FS) is generally normal to increased. However,

some cats have mild to moderate LV dilation and reduced contractility (FS ≈ 23%-29%; normal FS is 35%-65%). RV enlargement and pericardial or pleural effusion are occa­ sionally detected. Cats with dynamic LV outflow tract obstruction often have SAM of the mitral valve (Fig. 8-4) or premature closure of the aortic valve leaflets on M-mode scans. Abnormalities of the mitral valve apparatus, including increased papillary muscle hypertrophy and anterior mitral leaflet length, have been associated with SAM and severity of dynamic LV outflow obstruction. Mitral valve motion can be evaluated using both short-axis and long-axis (LV outflow tract) views. Doppler modalities can demonstrate mitral regurgitation and LV outflow turbulence (Fig. 8-5). Optimal alignment with the maximal-velocity outflow jet using spectral Doppler is often difficult, and it is easy to underestimate the systolic gradient. The left apical five-chamber view may be most useful. Pulsed wave (PW) Doppler may show a delayed relax­ ation mitral inflow pattern (E waveâ•›:â•›A wave < 1) or evidence for more advanced diastolic dysfunction. However, the rapid heart rate in many cats, as well as changes in loading condi­ tions, often confounds accurate assessment of diastolic func­ tion. Doppler tissue imaging of lateral mitral annulus motion has been used to assess the early diastolic function of longi­ tudinal myocardial fibers. Reduced early annular motion has also been found in cats with HCM. LA enlargement may be mild to marked (see Chapter 2). Prominent LA enlargement is expected in cats with clinical signs of CHF. Spontaneous contrast (swirling, smoky echoes) is visible within the enlarged LA of some cats. This is thought to result from blood stasis with cellular aggregations and to be a harbinger of thromboembolism. A thrombus is occasionally visualized within the LA, usually in the auricle (Fig. 8-6). Other causes of myocardial hypertrophy (see p. 152) should be excluded before a diagnosis of idiopathic HCM is made. Myocardial thickening in cats can also result from infiltrative disease (such as lymphoma). Variation in myo­ cardial echogenicity or wall irregularities may be noted in such cases. Excess moderator bands appear as bright, linear echoes within the LV cavity. Clinicopathologic Findings Clinical pathology tests are often noncontributory. NTproBNP testing can discriminate between cardiac failure and primary respiratory causes of dyspnea in cats. Elevated con­ centrations of circulating natriuretic peptide and cardiac troponin concentrations occur in cats with moderate to severe HCM. Some studies have shown variable ability to identify cats with subclinical disease. However, a recent mul­ ticenter study (Fox et╯al, 2011) found that plasma NT-proBNP elevation was associated with several echocardiographic markers of disease severity and could discriminate cats with occult cardiomyopathy from normal cats in a population referred for cardiac evaluation. A cutoff of greater than 99╯pmol/L was 100% specific and 71% sensitive for occult disease; cutoff values of greater than 46╯pmol/L had 91%

CHAPTER 8â•…â•… Myocardial Diseases of the Cat

149

A

B

C FIG 8-3â•…

Echocardiographic examples of feline hypertrophic cardiomyopathy. M-mode image (A) at the left ventricular level from a 7-year-old male domestic shorthair cat. The left ventricular diastolic free-wall and septal thicknesses are about 8╯mm. Two-dimensional right parasternal short-axis views during diastole (B) and systole (C) in male Maine Coon cat with hypertrophic obstructive cardiomyopathy. In (B) note the hypertrophied and bright papillary muscles. In (C) note the almost total systolic obliteration of the left ventricular chamber. IVS, Interventricular septum; LV, left ventricle; LVW, left ventricular free wall; RV, right ventricle.

specificity and 86% sensitivity. Variably elevated plasma TNFα concentrations have been found in cats with CHF. Treatment

SUBCLINICAL HYPERTROPHIC CARDIOMYOPATHY Whether (and how) asymptomatic cats should be treated is controversial. It is unclear if disease progression can be

slowed or survival prolonged by medical therapy before the onset of clinical signs. Various small studies using a β-blocker, diltiazem, an angiotensin-converting enzyme inhibitor (ACEI), or spironolactone have been done, but clear benefit from any of these interventions is yet to be proven. With this in mind, some clinicians still suggest using a β-blocker in cats with evidence of substantial dynamic outflow obstruc­ tion or arrhythmias; in those with marked, nonobstructive myocardial hypertrophy, an ACEI or diltiazem may be

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A

B FIG 8-4â•…

A, Two-dimensional echo image in midsystole from the cat in Fig. 8-3, B and C. Echoes from the anterior mitral leaflet appear within the LV outflow tract (arrow) because of abnormal systolic anterior (toward the septum) motion (SAM) of the valve. B, The M-mode echocardiogram at the mitral valve level also shows the mitral SAM (arrows). Ao, Aorta; LA, left atrium; LV, left ventricle.

FIG 8-5â•…

Color flow Doppler image taken in systole from a male domestic longhair cat with hypertrophic obstructive cardiomyopathy. Note the turbulent flow just above where the thickened interventricular septum protrudes into the left ventricular outflow tract and a small mitral insufficiency jet into the LA, common with SAM. Right parasternal long-axis view. Ao, Aorta; LA, left atrium; LV, left ventricle.

FIG 8-6â•…

Echocardiogram obtained from the right parasternal short-axis position at the aortic-left atrial level in an old male domestic shorthair cat with restrictive cardiomyopathy. Note the massive left atrial enlargement and thrombus (arrows) within the auricle. A, Aorta; LA, left atrium; RVOT, right ventricular outflow tract.

suggested. For cats with LA enlargement, especially with spontaneous echocontrast, instituting antithrombotic pro­ phylaxis is prudent (see Chapter 12). Avoidance of stressful situations likely to cause persistent tachycardia and reevaluation on a semiannual or annual basis are usually advised. Secondary causes of myocardial hypertrophy, such as systemic arterial hypertension and hyperthyroidism, should be ruled out (or treated, if found).

CLINICALLY EVIDENT HYPERTROPHIC CARDIOMYOPATHY Goals of therapy are to enhance ventricular filling, relieve congestion, control arrhythmias, minimize ischemia, and prevent thromboembolism (Box 8-1). Furosemide is used only at the dosage needed to help control congestive signs for long-term therapy. Moderate to severe pleural effusion is treated by thoracocentesis, with the cat restrained gently in sternal position. Cats with severe pulmonary edema are given supplemen­ tal oxygen and parenteral furosemide, usually intramuscular (IM) initially (2╯mg/kg q1-4h; see Box 3-1 and p. 62), until an IV catheter can be placed without excessive stress to the cat. Nitroglycerin ointment can be used (q4-6h, see Box 3-1), although no studies of its efficacy in this situation have been done. An ACEI is given as soon as oral medication is possible. Once initial medications have been given, the cat should be allowed to rest. The respiratory rate is noted initially and then every 15 to 30 minutes or so without disturbing the cat. Respiratory rate and effort are used to guide ongoing diuretic therapy. Catheter placement, blood sampling, radiographs, and other tests and therapies should be delayed until the cat’s condition is more stable. Butorphanol can be helpful to reduce anxiety (see Box 3-1). Acepromazine can be used as an alternative and can promote peripheral redistribution of blood by its α-blocking effects; however, it may potentially exacerbate LV outflow obstruction in cats with hypertrophic obstructive cardiomyopathy. Peripheral vasodilation may worsen preexisting hypothermia. Morphine should not be used in cats. The bronchodilating and mild diuretic effects of aminophylline (e.g., 5╯mg/kg q12h, IM, IV) may be helpful in cats with severe pulmonary edema, as long as the drug does not increase the heart rate. Airway suctioning and mechanical ventilation with positive end-expiratory pressure can be considered in extreme cases. As respiratory distress resolves, furosemide can be contin­ ued at a reduced dose (≈1╯mg/kg q8-12h). Once pulmonary edema is controlled, furosemide is given orally and the dose gradually titrated downward to the lowest effective level. A starting dose of 6.25╯mg/cat q8-12h can be slowly reduced over days to weeks, depending on the cat’s response. Some cats do well with dosing a few times per week, whereas others require furosemide several times per day. Complications of excessive diuresis include azotemia, anorexia, electrolyte dis­ turbances, and poor LV filling. If the cat is unable to rehydrate itself by oral water intake, cautious parenteral fluid adminis­ tration may be necessary (e.g., 15-20╯mL/kg/day of 0.45% saline, 5% dextrose in water, or other low-sodium fluid).

CHAPTER 8â•…â•… Myocardial Diseases of the Cat

151

  BOX 8-1â•… Treatment Outline for Cats with Hypertrophic Cardiomyopathy Severe, Acute Signs of Congestive Heart Failure*

Supplemental O2 Minimize patient handling Furosemide (parenteral) Thoracocentesis, if pleural effusion present Heart rate control and antiarrhythmic therapy, if indicated (can use IV diltiazem, esmolol, [±] or propranolol)† ±Nitroglycerin (cutaneous) ±Bronchodilator (e.g., aminophylline or theophylline) ±Sedation Monitor: respiratory rate, HR and rhythm, arterial blood pressure, renal function, serum electrolytes, etc. Mild to Moderate Signs of Congestive Heart Failure*

Furosemide ACE inhibitor Antithrombotic prophylaxis (aspirin, clopidogrel, LMWH, or warfarin)‡ Exercise restriction Reduced-salt diet, if the cat will eat it ±β-blocker (e.g., atenolol) or diltiazem Chronic Hypertrophic Cardiomyopathy Management*

ACE inhibitor Furosemide (lowest effective dosage and frequency) Antithrombotic prophylaxis (aspirin, clopidogrel, LMWH, or warfarin)‡ Thoracocentesis as needed ±Spironolactone and/or hydrochlorothiazide ±β-blocker or diltiazem therapy ±Additional antiarrhythmic drug therapy, if indicated Home monitoring of resting respiratory rate (+HR if possible) Dietary salt restriction, if accepted Monitor renal function, electrolytes, etc. Manage other medical problems (rule out hyperthyroidism and hypertension if not done previously) ±Pimobendan (for refractory CHF or deteriorating systolic function without LV outflow obstruction) *See text and Chapters 3 and 4 for further details. † See Chapter 4 for additional ventricular antiarrhythmic drug therapy. ‡ See Chapter 12 for further details. ACE, Angiotensin-converting enzyme; CHF, congestive heart failure; HR, heart rate; IV, intravenous; LMWH, low-molecular-weight heparin.

Ventricular filling is improved by slowing the heart rate and enhancing relaxation. Stress and activity level should be minimized to the extent possible. Although the Ca++-channel blocker diltiazem or a β-blocker (see Chapter 4 and Table 4-2) has historically formed the foundation of long-term oral therapy, an ACEI probably has greater benefit in cats

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with CHF. An ACEI is usually prescribed in hope of reducing neurohormonal activation and abnormal cardiac remodel­ ing. Enalapril and benazepril are the agents used most often in cats, although others are available (see Chapter 3 and Table 3-3). The negative chronotropic drug ivabradine may prove helpful in controlling heart rate in cats with HCM. Ivabra­ dine is a selective “funny” current (If ) inhibitor. The If is important in sinus node (pacemaker) function. Activation of this current increases membrane permeability to Na+ and K+, thereby increasing the slope of sinus node spontaneous phase 4 (diastolic) depolarization and increasing the heart rate. Preliminary studies have shown ivabradine to produce dose-dependent heart rate reduction with minimal adverse effects. Specific recommendations await further study. The decision to use other drugs is influenced by echocardio­ graphic or other findings in the individual cat. Diltiazem has been used more in cats with severe, sym­ metric LV hypertrophy. Its Ca++-blocking effects can mod­ estly reduce heart rate and contractility (which reduces myocardial O2 demand). Diltiazem promotes coronary vaso­ dilation and may have a positive effect on myocardial relax­ ation. Longer-acting diltiazem products are more convenient for chronic use, although the serum concentrations achieved can be variable. Diltiazem XR, dosed at one half of an inter­ nal (60-mg) tablet from the 240-mg capsule q24(-12)h, or Cardizem CD, compounded and dosed at 10╯mg/kg q24h, have been used most often. β-blockers can reduce heart rate and dynamic LV outflow obstruction to a greater extent than diltiazem. They are also used to suppress tachyarrhythmias in cats. Furthermore, sympathetic inhibition leads to reduced myocardial O2 demand, which can be important in cats with myocardial ischemia or infarction. A β-blocker is favored in cats with concurrent hyperthyroidism. By inhibiting catecholamineinduced myocyte damage, β-blockers may reduce myocar­ dial fibrosis. β-blockers can slow active myocardial relaxation, although the benefits of heart rate reduction may outweigh this. Atenolol, a nonselective agent, is used most commonly. Propranolol or other nonselective β-blocker could be used, but these should be avoided when pulmonary edema is present. Airway β2-receptor antagonism leading to broncho­ constriction is a concern when using nonselective agents in CHF. Propranolol (a lipid-soluble drug) causes lethargy and depressed appetite in some cats. Occasionally, a β-blocker is added to diltiazem therapy (or vice versa) in cats with chronic refractory failure or to further reduce heart rate in cats with AF. However, care must be taken to prevent bradycardia or hypotension in animals receiving this combination. Long-term management gener­ ally includes therapy to reduce the likelihood of arterial thromboembolism (see Chapter 12). Dietary sodium restric­ tion is recommended if the cat will accept such a diet, but it is more important to forestall anorexia. Certain drugs should generally be avoided in cats with HCM. These include digoxin and other positive inotropic agents because they increase myocardial oxygen demand and

can worsen dynamic LV outflow obstruction. However, pimobendan has been helpful in managing cats with chronic refractory CHF. Any drug that accelerates the heart rate is also potentially detrimental because tachycardia shortens ventricular filling time and predisposes to myocardial is­ chemia. Arterial vasodilators can cause hypotension and reflex tachycardia, and cats with HCM have little preload reserve. Hypotension also exacerbates dynamic outflow obstruction. Although ACEIs have this potential, their vasodilating effects are usually mild.

CHRONIC REFRACTORY CONGESTIVE HEART FAILURE Refractory pulmonary edema or pleural effusion is difficult to manage. Moderate to large pleural effusions should be treated by thoracocentesis. Various medical strategies may help slow the rate of abnormal fluid accumulation, including maximizing the dosage of (or adding) an ACEI; increasing the dosage of furosemide (up to ≈4╯mg/kg q8h); adding pimobendan; using diltiazem or a β-blocker for greater heart rate control; adding spironolactone; and using an additional diuretic (e.g., hydrochlorothiazide; see Table 3-3). Spirono­ lactone can be compounded into a flavored suspension for more accurate dosing. Digoxin could also be used for treat­ ing refractory right-sided CHF signs in cats without LV outflow obstruction and with myocardial systolic failure in end-stage disease; however, toxicity can easily occur. Fre­ quent monitoring for azotemia, electrolyte disturbances, and other complications is warranted. Prognosis Several factors influence the prognosis for cats with HCM, including the speed with which the disease progresses, the occurrence of thromboembolic events and/or arrhythmias, and the response to therapy. Asymptomatic cats with only mild to moderate LV hypertrophy and atrial enlargement often live well for many years. Cats with marked LA enlarge­ ment and more severe hypertrophy appear to be at greater risk for CHF, thromboembolism, and sudden death. LA size and age (i.e., older cats) appear to be negatively correlated with survival. Median survival time for cats with CHF is probably between 1 and 2 years. The prognosis is worse in cats with AF or refractory right-sided CHF. Cats with low or high body weight may have a worse prognosis than those of normal weight. Thromboembolism and CHF confer a guarded prognosis (median survival of 2-6 months), although some cats do well if congestive signs can be con­ trolled and infarction of vital organs has not occurred. Recurrence of thromboembolism is common.

SECONDARY HYPERTROPHIC MYOCARDIAL DISEASE Myocardial hypertrophy is a compensatory response to certain identifiable stresses or diseases. Marked LV wall and septal thickening and clinical heart failure can occur in some

of these cases, although they are generally not considered to be idiopathic HCM. Secondary causes should be ruled out whenever LV hypertrophy is identified. Evaluation for hyperthyroidism is indicated in cats older than 6 years of age with myocardial hypertrophy. Hyperthy­ roidism alters cardiovascular function by its direct effects on the myocardium and through the interaction of heightened sympathetic nervous system activity and excess thyroid hormone on the heart and peripheral circulation. Cardiac effects of thyroid hormone include myocardial hypertrophy and increased heart rate and contractility. The metabolic acceleration that accompanies hyperthyroidism causes a hyperdynamic circulatory state characterized by increased cardiac output, oxygen demand, blood volume, and heart rate. Systemic hypertension can further stimulate myocardial hypertrophy. Manifestations of hyperthyroid heart disease often include a systolic murmur, hyperdynamic arterial pulses, a strong precordial impulse, sinus tachycardia, and various arrhythmias. Criteria for LV enlargement or hyper­ trophy are often found on ECG, thoracic radiographs, or echocardiogram. Signs of CHF develop in approximately 15% of hyperthyroid cats; most have normal to high FS, but a few have poor contractile function. Cardiac therapy, in addition to treatment of the hyperthyroidism, may be neces­ sary for these cats. A β-blocker can temporarily control many of the adverse cardiac effects of excess thyroid hormone, especially tachyarrhythmias. Diltiazem is an alternative therapy. Treatment for CHF is the same as that described for HCM. The rare hypodynamic (dilated) cardiac failure is treated in the same way as dilated cardiomyopathy. Cardiac therapy, including a β-blocker, is not a substitute for anti­ thyroid treatment. LV concentric hypertrophy is the expected response to increased ventricular systolic pressure (afterload). Systemic arterial hypertension (see Chapter 11) increases afterload because of high arterial pressure and resistance. Increased resistance to ventricular outflow also occurs with a fixed (e.g., congenital) subaortic stenosis or dynamic LV outflow tract obstruction (hypertrophic obstructive cardiomyopa­ thy). Cardiac hypertrophy also develops in cats with hyper­ somatotropism (acromegaly) as a result of growth hormone’s trophic effects on the heart. CHF occurs in some of these cats. Increased myocardial thickness occasionally results from infiltrative myocardial disease, most notably from lymphoma.

RESTRICTIVE CARDIOMYOPATHY Etiology and Pathophysiology Restrictive cardiomyopathy (RCM) is associated with exten­ sive endocardial, subendocardial, or myocardial fibrosis of unclear, but probably multifactorial, cause. This condition may be a consequence of endomyocarditis or the end-stage of myocardial failure and infarction caused by HCM. Neo­ plastic (e.g., lymphoma) or other infiltrative or infectious diseases occasionally cause a secondary RCM.

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There are a variety of histopathologic findings in cats with RCM, including marked perivascular and interstitial fibrosis, intramural coronary artery narrowing, and myocyte hyper­ trophy, as well as areas of degeneration and necrosis. Some cats have extensive LV endomyocardial fibrosis with chamber deformity, or fibrous tissue bridging between the septum and LV wall. The mitral apparatus and papillary muscles may be fused to surrounding tissue or distorted. LA enlargement is prominent in cats with RCM, as a consequence of chronically high LV filling pressure from increased LV wall stiffness. The LV may be normal to reduced in size or mildly dilated. LV hypertrophy is variably present and may be regional. Intracardiac thrombi and systemic thromboembolism are common. LV fibrosis impairs diastolic filling. Most affected cats have normal to only mildly reduced contractility, but this may progress with time as more functional myocardium is lost. Some cases develop regional LV dysfunction, possibly from myocardial infarction, which decreases overall systolic function. These cases are perhaps better considered unclas­ sified rather than restrictive. If mitral regurgitation is present, it is usually mild. Arrhythmias, ventricular dilation, and myocardial ischemia or infarction also contribute to the development of diastolic dysfunction. Chronically elevated left heart filling pressures, combined with compensatory neurohormonal activation, lead to left-sided or biventricular CHF. The duration of subclinical disease progression in RCM is unknown. Clinical Features Middle-aged and older cats are most often diagnosed with RCM. Young cats are sometimes affected. Inactivity, poor appetite, vomiting, and weight loss of recent onset are common in the history. The clinical presentation varies but usually includes respiratory signs from pulmonary edema or pleural effusion. Clinical signs are often precipitated or acutely worsened by stress or concurrent disease that causes increased cardiovascular demand. Thromboembolic events are also common. Sometimes the condition is discovered by detecting abnormal heart sounds or arrhyth­ mias on routine examination or radiographic evidence of cardiomegaly. A systolic murmur of mitral or tricuspid regurgitation, a gallop sound, and/or an arrhythmia may be discovered on physical examination. Pulmonary sounds may be abnormal in cats with pulmonary edema or muffled with pleural effu­ sion. Femoral arterial pulses are normal or slightly weak. Jugular vein distention and pulsation are common in cats with right-sided CHF. Acute signs of distal aortic (or other) thromboembolism may be the reason for presentation. Diagnosis Diagnostic test results are frequently similar to those in cats with HCM. Radiographs indicate LA or biatrial enlargement (sometimes massive) and LV or generalized heart enlarge­ ment (Fig. 8-7). Mild to moderate pericardial effusion contributes to the cardiomegaly in some cats. Proximal

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A

B FIG 8-7â•…

Lateral (A) and dorsoventral (B) radiographs from an older domestic shorthair cat with restrictive cardiomyopathy show marked left atrial enlargement and prominent proximal pulmonary veins.

pulmonary veins may appear dilated and tortuous. Other typical radiographic findings in cats with CHF include infil­ trates of pulmonary edema, pleural effusion, and sometimes hepatomegaly and ascites. ECG abnormalities often include various arrhythmias such as ventricular or atrial premature complexes, supraven­ tricular tachycardia, or atrial fibrillation. Wide QRS com­ plexes, tall R waves, evidence of intraventricular conduction disturbances, or wide P waves may also be evident. Echocar­ diography typically shows marked LA (and sometimes right atrial [RA]) enlargement. LV wall and interventricular septal thicknesses are normal to only mildly increased. Ventricular wall motion is often normal but may be somewhat depressed (FS usually > 25%). Hyperechoic areas of fibrosis within the LV wall and/or endocardial areas may be evident. Extraneous intraluminal echoes representing excess moderator bands are occasionally seen. Sometimes, extensive LV endocardial fibrosis, with scar tissue bridging between the free-wall and septum, constricts part of the ventricular chamber. RV dila­ tion is often seen. Sometimes an intracardiac thrombus is found, usually in the left auricle or LA, but occasionally in the LV (see Fig. 8-6). Mild mitral or tricuspid regurgitation and a restrictive mitral inflow pattern are typically seen with Doppler studies. Some cats have marked regional wall dys­ function, especially of the LV free wall, which depresses FS, along with mild LV dilation. These may represent cases of myocardial infarction or unclassified cardiomyopathy rather than RCM.

The clinicopathologic findings are nonspecific. Pleural effusions are usually classified as modified transudate or chyle. Plasma taurine concentration is low in some affected cats and should be measured if decreased contractility is identified. Treatment and Prognosis Therapy for acute CHF is the same as for cats with HCM (see p. 62). Cats that require inotropic support can be given dobutamine by constant rate infusion (CRI). Management of thromboembolism is described on page 203. Long-term therapy for heart failure includes furosemide at the lowest effective dosage and an ACEI (see Table 3-3). Ideally, blood pressure should be monitored when initiating or adjusting therapy. The resting respiratory rate, activity level, and radiographic findings are used to monitor treat­ ment efficacy. A β-blocker is usually used for tachyarrhyth­ mias or if myocardial infarction is suspected. Refractory ventricular tachyarrhythmias may respond to sotolol, mex­ iletine, or both together. Alternatively, in cats that are not receiving a β-blocker, diltiazem could be used in an attempt to reduce heart rate and improve diastolic function, although its value in the face of significant fibrosis is controversial. Cats that need chronic inotropic support can be given pimo­ bendan (or digoxin; see Table 3-3). Testing for taurine defi­ ciency may be helpful. Prophylaxis against thromboembolism is recommended (see p. 207), and a reduced-sodium diet should be fed, if accepted. Renal function and electrolyte

concentrations at minimum are measured periodically. Medication adjustments are made accordingly if hypoten­ sion, azotemia, or other complications occur. Cats with refractory heart failure and pleural effusion are difficult to manage. In addition to thoracocentesis as needed, the ACEI and furosemide dosages can be increased cau­ tiously. Adding pimobendan (or digoxin), if not already being used, can help control refractory failure. Other strate­ gies include adding spironolactone (with or without hydro­ chlorothiazide) or nitroglycerin ointment to the regimen. The prognosis is generally guarded to poor for cats with RCM and heart failure. Nevertheless, some cats survive more than a year after diagnosis. Thromboembolism and refrac­ tory pleural effusion commonly occur.

DILATED CARDIOMYOPATHY Etiology Since the late 1980s when taurine deficiency was identified as a major cause of DCM in cats and pet food manufacturers subsequently increased the taurine content of feline diets, clinical DCM has become uncommon in cats. Not all cats fed a taurine-deficient diet develop DCM. Other factors besides a simple deficiency of this essential amino acid are likely to be involved in the pathogenesis, including genetic factors and a possible link with potassium depletion. Rela­ tively few cases of DCM are identified now, and most of these cats are not taurine deficient. DCM in these cats may be idiopathic or the end stage of another myocardial metabolic abnormality, toxicity, or infection. Doxorubicin can cause characteristic myocardial histo­ pathologic lesions in cats as it does in dogs, and in rare instances echocardiographic changes consistent with DCM may occur after cumulative doses of 170 to 240╯mg/m2. However, clinically relevant doxorubicin-induced cardiomy­ opathy is not an issue in the cat; anecdotally, total cumulative doses of up to about 600╯mg/m2 (23╯mg/kg) have been administered without evidence of cardiotoxicity. Pathophysiology DCM in cats has a similar pathophysiology to that in dogs (see p. 130). Poor myocardial contractility is the characteristic feature (Fig. 8-8). Usually, all cardiac cham­ bers become dilated. AV valve insufficiency occurs secondary to chamber enlargement and papillary muscle atrophy. As cardiac output decreases, compensatory neurohormonal mechanisms are activated, leading eventually to signs of CHF and low cardiac output. Besides pulmonary edema, pleural effusion and arrhythmias are common in cats with DCM. Clinical Features DCM can occur at any age, although most affected cats are late-middle aged to geriatric. There is no breed or gender predilection. Clinical signs often include anorexia, lethargy, increased respiratory effort or dyspnea, dehydration, and

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155

hypothermia. Subtle evidence of poor ventricular function is usually found in conjunction with signs of respiratory compromise. Jugular venous distention, an attenuated pre­ cordial impulse, weak femoral pulses, a gallop sound (usually S3), and a left or right apical systolic murmur (of mitral or tricuspid regurgitation) are common. Bradycardia and arrhythmias can be present, although many affected cats have normal sinus rhythm. Increased lung sounds and pul­ monary crackles sometimes can be auscultated, but pleural effusion often muffles the lung sounds. Some cats have signs of arterial thromboembolism (see p. 202). Diagnosis Generalized cardiomegaly with rounding of the cardiac apex is often seen on radiographs. Pleural effusion is quite common and may obscure the heart shadow and coexisting evidence of pulmonary edema or venous congestion. Hepa­ tomegaly and ascites may also be detected. Variable ECG findings include ventricular or supraven­ tricular tachyarrhythmias (although atrial fibrillation is rare), AV conduction disturbance, and an LV enlargement pattern. However, the ECG does not consistently reflect chamber enlargement in cats. Echocardiography is an impor­ tant tool to differentiate DCM from other myocardial patho­ physiology. Findings are analogous to those in dogs with DCM (see p. 133). Poor fractional shortening (1.1╯cm) and end-diastolic (e.g., >1.8╯cm) diameters, and wide mitral E point-septal separation (>0.4╯cm) have been described as diagnostic cri­ teria for DCM in cats. Some cats have areas of focal hyper­ trophy with hypokinesis of only the LV wall or septum. These may represent indeterminate myocardial disease rather than typical DCM. An intracardiac thrombus is iden­ tified in some cats, more often within the LA. Nonselective angiocardiography is a more risky alterna­ tive to echocardiography and is not often done now. Never­ theless, characteristic findings include generalized chamber enlargement, atrophied papillary muscles, small aortic diam­ eter, and slow circulation time (see Fig. 8-8). Complications of angiography, especially in cats with poor myocardial func­ tion or CHF, include vomiting and aspiration, arrhythmias, and cardiac arrest. The pleural effusion in cats with DCM is usually a modified transudate, although it can be chylous. Prerenal azotemia, mildly increased liver enzyme activity, and a stress leukogram are common clinicopathologic find­ ings. An elevated NT-proBNP concentration is expected. Cats with arterial thromboembolism often have high serum muscle enzyme activities and may have an abnormal hemo­ stasis profile. Plasma or whole blood taurine concentration measurement is recommended to detect possible deficiency. Specific instructions for sample collection and mailing should be obtained from the laboratory used. Plasma taurine concentrations are influenced by the amount of taurine in the diet, the type of diet, and the time of sampling in relation to eating; however, a plasma taurine concentration of less than 30 to 50╯nmol/mL in a cat with DCM is diagnostic for taurine deficiency. Non-anorexic cats with a plasma taurine

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PART Iâ•…â•… Cardiovascular System Disorders

FIG 8-8â•…

Nonselective angiogram from a 13-yearold female Siamese cat with dilated cardiomyopathy. A bolus of radiographic contrast material was injected into the jugular vein. A, Three seconds after injection, some contrast medium remains in the right ventricle and pulmonary vasculature. Dilated pulmonary veins are seen entering the left atrium. Note the dilated left atrium and ventricle. B, Thirteen seconds after the injection, the left heart and pulmonary veins are still opacified, illustrating the poor cardiac contractility and extremely slow circulation time. The thin left ventricular caudal wall and papillary muscles are better seen in this frame.

A

B concentration of less than 60╯nmol/mL probably should receive taurine supplementation or a different diet. Whole blood samples produce more consistent results than plasma samples. Normal whole blood taurine concentrations exceed 200 to 250╯nmol/mL. Treatment and Prognosis The goals of treatment are analogous to those for dogs with DCM. Pleural fluid is removed by thoracocentesis. In cats with acute CHF, furosemide is given to promote diuresis, as described for HCM. Overly aggressive diuresis is discouraged because it can markedly reduce cardiac output in these cases with poor systolic function. Supplemental O2 is recom­ mended. The venodilator nitroglycerin may be helpful in cats with severe pulmonary edema. Pimobendan and ACEI therapy is begun as soon as oral medication can be safely given. Other vasodilators (nitroprusside, hydralazine, or amlodipine) may help maximize cardiac output, but they increase the risk of hypotension (see Box 3-1). Blood pressure, hydration, renal function, electrolyte balance, and peripheral perfusion should be monitored closely.

Hypothermia is common in cats with decompensated DCM; external warming is provided as needed. Additional positive inotropic support may be necessary. Dobutamine (or dopamine) is administered by CRI for criti­ cal cases (see p. 60 and Box 3-1). Possible adverse effects include seizures or tachycardia; if they occur, the infusion rate is decreased by 50% or discontinued. Pimobendan is recommended for oral inotropic therapy. Digoxin could be used instead or in addition (see p. 66 and Table 3-3), but toxicity can easily occur, especially in cats receiving concur­ rent drug therapy. Serum digoxin concentration should be monitored if this drug is used (see p. 67). Digoxin tablets are preferred; the elixir is distasteful to many cats. Frequent ventricular tachyarrhythmias may respond to lidocaine, mexiletine, conservative doses of sotolol, or com­ bination antiarrhythmic therapy (see Table 4-2). However, β-blockers (including sotolol) should be used only cau­ tiously (if at all) in cats with DCM and CHF because of their negative inotropic effect. Serious supraventricular tachyar­ rhythmias are treated with diltiazem, sometimes in combi­ nation with digoxin.

Diuretic and vasodilator therapy used for acute CHF can lead to hypotension and predispose to cardiogenic shock in cats with DCM. Half-strength saline solution with 2.5% dex­ trose or other low-sodium fluids can be used intravenously with caution to help support blood pressure (e.g., 2035╯mL/kg/day in several divided doses or by CRI); potassium supplementation may be necessary. Fluid can be adminis­ tered subcutaneously if necessary, although its absorption from the extravascular space may be impaired in these cases. Chronic therapy for DCM in cats that survive acute CHF includes oral furosemide (tapered to the lowest effective dosage), an ACEI, pimobendan (or digoxin), antithrombotic prophylaxis (see p. 207), and (if the patient is taurine defi­ cient) supplemental taurine or a high-taurine diet. Taurine supplementation is instituted as soon as practical, at 250 to 500╯mg orally q12h, when plasma taurine concentration is low or cannot be measured. Clinical improvement, if it occurs, is generally not apparent until after a few weeks of taurine supplementation. Improved systolic function is seen echocardiographically within 6 weeks of starting taurine supplementation in most taurine-deficient cats. Drug therapy may become unnecessary in some cats after 6 to 12 weeks, but resolution of pleural effusion and pulmo­ nary edema should be confirmed before weaning the cat from medications. If normal systolic function, based on echocardiography, returns, the patient can be slowly weaned from supplemental taurine as long as a diet known to support adequate plasma taurine concentrations (e.g., most namebrand commercial foods) is consumed. Dry diets with 1200╯mg of taurine per kilogram of dry weight and canned diets with 2500╯mg of taurine per kilogram of dry weight are thought to maintain normal plasma taurine concentrations in adult cats. Requirements may be higher for diets incorpo­ rating rice or rice bran. Reevaluation of the plasma taurine concentration 2 to 4 weeks after discontinuing the supple­ ment is advised. Taurine-deficient cats that survive a month after initial diagnosis often can be weaned from all or most medications and appear to have approximately a 50% chance for 1-year survival. The prognosis for cats that are not taurine deficient is guarded to poor. Thromboembolism in cats with DCM is a grave sign.

OTHER MYOCARDIAL DISEASES ARRHYTHMOGENIC RIGHT VENTRICULAR CARDIOMYOPATHY Arrhythmogenic RV cardiomyopathy (ARVC) is a rare idio­ pathic cardiomyopathy that is similar to ARVC in people. Characteristic features include moderate to severe RV chamber dilation, with either focal or diffuse RV wall thin­ ning. RV wall aneurysm can also occur, as can dilation of the right atrium (RA) and, less commonly, the LA. Myocardial atrophy with fatty and/or fibrous replacement tissue, focal myocarditis, and evidence of apoptosis are typical histologic findings. These are most prominent in the RV wall. Fibrous

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tissue or fatty infiltration is sometimes found in the LV and atrial walls. Signs of right-sided CHF are common, with labored res­ pirations caused by pleural effusion, jugular venous disten­ tion, ascites or hepatosplenomegaly, and occasionally syncope. Lethargy and inappetence without overt heart failure are sometimes the presenting signs. Thoracic radiographs indicate right heart and sometimes LA enlargement. Pleural effusion is common. Ascites, caudal vena caval distention, and evidence of pericardial effusion may also occur. The ECG can document various arrhythmias in affected cats, including ventricular premature complexes (VPCs), ventricular tachycardia, AF, and supraventricular tachyarrhythmias. A right bundle branch block pattern appears to be common; some cats have first-degree AV block. Echocardiography shows severe RA and RV enlargement similar to that seen with congenital tricuspid valve dysplasia, except that the valve apparatus appears structurally normal. Other possible findings include abnormal muscular trabecu­ lation, aneurysmal dilation, areas of dyskinesis, and para­ doxical septal motion. Tricuspid regurgitation appears to be a consistent finding on Doppler examination. Some cats also have LA enlargement, if the LV myocardium is affected. The prognosis is guarded once signs of heart failure appear. Recommended therapy includes diuretics as needed, an ACEI, pimobendan (or digoxin), and prophylaxis against thromboembolism. Additional antiarrhythmic therapy may be necessary (see Chapter 4). In people with ARVC, various tachyarrhythmias are a prominent feature and sudden death is common.

CORTICOSTEROID-ASSOCIATED HEART FAILURE Some cats develop CHF after receiving corticosteroid therapy. It is unclear whether this represents a previously unrecog­ nized form of feline heart failure, unrelated to preexisting HCM, hypertension, or hyperthyroidism. An acute onset of lethargy, anorexia, tachypnea, and respiratory distress is described in affected cats. Most cats have normal ausculta­ tory findings without tachycardia. Moderate cardiomegaly, with diffuse pulmonary infiltrates and mild or moderate pleural effusion, appears to be typical on radiographic examination. Possible ECG findings include sinus bradycardia, intraventricular conduction abnormali­ ties, atrial standstill, atrial fibrillation, and VPCs. On echo­ cardiogram, most affected cats have some degree of LV wall or septal hypertrophy and LA enlargement. Some have AV valve insufficiency or abnormal systolic mitral motion. CHF is treated in the same way as HCM; corticosteroids should be discontinued. Partial resolution of abnormal cardiac findings and successful weaning from cardiac medi­ cations are reported in some cats. MYOCARDITIS Inflammation of the myocardium and adjacent structures may occur in cats, as it does in other species (see also p. 140). In one study myocarditis was histologically identified in

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PART Iâ•…â•… Cardiovascular System Disorders

samples from more than half of cardiomyopathic cats but none from cats in the control group; viral deoxyribonucleic acid (panleukopenia) was found in about one third of the cats with myocarditis. However, the possible role of viral myocarditis in the pathogenesis of cardiomyopathy is not clear. Severe, widespread myocarditis may cause CHF or fatal arrhythmias. Cats with focal myocardial inflammation may be asymptomatic. Acute and chronic viral myocarditis have been suspected. A viral cause is rarely documented, although feline coronavirus has been identified as a cause of pericarditis-epicarditis. Endomyocarditis has been documented mostly in young cats. Acute death, with or without preceding signs of pulmo­ nary edema for 1 to 2 days, is the most common presenta­ tion. Histopathologic characteristics of acute endomyocarditis include focal or diffuse lymphocytic, plasmacytic, and his­ tiocytic infiltrates with few neutrophils. Myocardial degen­ eration and lysis are seen adjacent to the infiltrates. Chronic endomyocarditis may have a minimal inflammatory response but much myocardial degeneration and fibrosis. RCM could represent the end stage of nonfatal endomyocarditis. Therapy involves managing CHF signs and arrhythmias and other supportive care. Bacterial myocarditis may develop in association with sepsis or as a result of bacterial endocarditis or pericarditis. Experimental Bartonella sp. infection can cause subclinical lymphoplasmacytic myocarditis, but it is unclear whether natural infection plays a role in the development of cardio­ myopathy in cats. Toxoplasma gondii has occasionally been associated with myocarditis, usually in immunosuppressed cats as part of a generalized disease process. Traumatic myo­ carditis is recognized infrequently in cats. Suggested Readings Cober RE et al: Pharmacodynamic effects of ivabradine, a negative chronotropic agent, in healthy cats, J Vet Cardiol 13:231, 2011. Ferasin L et al: Feline idiopathic cardiomyopathy: a retrospective study of 106 cats (1994-2001), J Feline Med Surg 5:151, 2003. Finn E et al: The relationship between body weight, body condition, and survival in cats with heart failure, J Vet Intern Med 24:1369, 2010. Fox PR: Hypertrophic cardiopathy: clinical and pathologic corre­ lates, J Vet Cardiol 5:39, 2003. Fox PR: Endomyocardial fibrosis and restrictive cardiomyopathy: pathologic and clinical features, J Vet Cardiol 6:25, 2004. Fox PR et al: Multicenter evaluation of plasma N-terminal probrain natriuretic peptide (NT-proBNP) as a biochemical screening test for asymptomatic (occult) cardiomyopathy in cats, J Vet Intern Med 25:1010, 2011. Fox PR et al: Utility of N-terminal pro-brain natriuretic peptide (NT-proBNP) to distinguish between congestive heart failure and non-cardiac causes of acute dyspnea in cats, J Vet Cardiol 11:S51, 2009. Fries R, Heaney AM, Meurs KM: Prevalence of the myosin-binding protein C mutation in Maine Coon cats, J Vet Intern Med 22:893, 2008. Granstrom S et al: Prevalence of hypertrophic cardiomyopathy in a cohort of British Shorthair cats in Denmark, J Vet Intern Med 25:866, 2011.

Harvey AM et al: Arrhythmogenic right ventricular cardiomyopa­ thy in two cats, J Small Anim Pract 46:151, 2005. Koffas H et al: Pulsed tissue Doppler imaging in normal cats and cats with hypertrophic cardiomyopathy, J Vet Intern Med 20:65, 2006. MacDonald KA et al: Tissue Doppler imaging in Maine Coon cats with a mutation of myosin binding protein C with or without hypertrophy, J Vet Intern Med 21:232, 2007. MacDonald KA, Kittleson MD, Kass PH: Effect of spironolactone on diastolic function and left ventricular mass in Maine Coon cats with familial hypertrophic cardiomyopathy, J Vet Intern Med 22:335, 2008. MacLean HN et al: N-terminal atrial natriuretic peptide immuno­ reactivity in plasma of cats with hypertrophic cardiomyopathy, J Vet Intern Med 20:284, 2006. Mary J et al: Prevalence of the MYBPC3-A31P mutation in a large European feline population and association with hypertrophic cardiomyopathy in the Maine Coon breed, J Vet Cardiol 12:155, 2010. MacGregor JM et al: Use of pimobendan I 170 cats (2006-2010), J Vet Cardiol 13:251, 2011. Meurs KM et al: A cardiac myosin binding protein C mutation in the Maine Coon cat with familial hypertrophic cardiomyopathy, Hum Mol Genet 14:3587, 2005. Paige CF et al: Prevalence of cardiomyopathy in apparently healthy cats, J Am Vet Med Assoc 234:1398, 2009. Riesen SC et al: Effects of ivabradine on heart rate and left ventricu­ lar function in healthy cats and cats with hypertrophic cardio­ myopathy, Am J Vet Res 73:202, 2012. Rush JE et al: Population and survival characteristics of cats with hypertrophic cardiomyopathy: 260 cases (1990-1999), J Am Vet Med Assoc 220:202, 2002. Sampedrano CC et al: Systolic and diastolic myocardial dysfunction in cats with hypertrophic cardiomyopathy or systemic hyperten­ sion, J Vet Intern Med 20:1106, 2006. Sampedrano CC et al: Prospective echocardiographic and tissue Doppler imaging screening of a population of Maine Coon cats tested for the A31P mutation in the myosin-binding protein C gene: a specific analysis of the heterozygous status, J Vet Intern Med 23:91, 2009. Schober KE, Maerz I: Assessment of left atrial appendage flow velocity and its relation to spontaneous echocardiographic con­ trast in 89 cats with myocardial disease, J Vet Intern Med 20:120, 2006. Schober KE, Todd A: Echocardiographic assessment of left ven­ tricular geometry and the mitral valve apparatus in cats with hypertrophic cardiomyopathy, J Vet Cardiol 12:1, 2010. Smith SA et al: Corticosteroid-associated congestive heart failure in 12 cats, Intern J Appl Res Vet Med 2:159, 2004. Trehiou-Sechi E et al: Comparative echocardiographic and clinical features of hypertrophic cardiomyopathy in 5 breeds of cats: a retrospective analysis of 344 cases (2001-2011), J Vet Intern Med 26:532, 2012. Singletary GE et al: Effect of NT-proBNP assay on accuracy and confidence of general practitioners in diagnosing heart failure or respiratory disease in cats with respiratory signs, J Vet Intern Med 26:542, 2012. Wess G et al: Association of A31P and A74T polymorphisms in the myosin binding protein C3 gene and hypertrophic cardiomyopa­ thy in Maine Coon and other breed cats, J Vet Intern Med 24:527, 2010.

C H A P T E R

9â•…

Pericardial Disease and Cardiac Tumors

GENERAL CONSIDERATIONS Several diseases of the pericardium and intrapericardial space can disrupt cardiac function. Although these comprise a fairly small proportion of cases presented for clinical signs of cardiac disease, it is important to recognize them because the approach to their management differs from other cardiac disorders. Normally, the pericardium anchors the heart in place and provides a barrier to infection or inflammation from adjacent tissues. The pericardium is a closed serosal sac that envelops the heart and is attached to the great vessels at the heartbase. Directly adhered to the heart is the visceral pericardium, or epicardium, which is composed of a thin layer of mesothelial cells. This layer reflects back over itself at the base of the heart to line the outer fibrous parietal layer. The ventral portion of the parietal pericardium extends to the diaphragm as the sternopericardiac ligament. A small amount (≈0.25╯mL/kg body weight) of clear, serous fluid normally serves as a lubricant between these layers. The pericardium helps balance the output of the right and left ventricles and limits acute distention of the heart, although there are usually no overt clinical consequences associated with its removal. Excess or abnormal fluid accumulation in the pericardial sac is the most common pericardial disorder, and it occurs most often in dogs. Other acquired and congenital pericardial diseases are seen infrequently. Acquired pericardial disease causing clinical signs is uncommon in cats.

CONGENITAL PERICARDIAL DISORDERS PERITONEOPERICARDIAL DIAPHRAGMATIC HERNIA Peritoneopericardial diaphragmatic hernia (PPDH) is the most common pericardial malformation in dogs and cats. It occurs when abnormal embryonic development (probably of the septum transversum) allows persistent communication between the pericardial and peritoneal cavities at the ventral midline. The pleural space is not involved. Other

congenital defects such as umbilical hernia, sternal malformations, and cardiac anomalies may coexist with PPDH. Abdominal contents herniate into the pericardial space to a variable degree and cause associated clinical signs. Although the peritoneal-pericardial communication is not trauma induced in dogs and cats, trauma can facilitate movement of abdominal contents through a preexisting defect. Clinical Features The initial onset of clinical signs associated with PPDH can occur at any age (ages between 4 weeks and 15 years have been reported). The majority of cases are diagnosed during the first 4 years of life, usually within the first year. In some animals clinical signs never develop. Males appear to be affected more frequently than females, and Weimaraners may be predisposed. The malformation is common in cats as well; Persians, Himalayans, and domestic longhair cats may be predisposed. Clinical signs usually relate to the gastrointestinal (GI) or respiratory system. Vomiting, diarrhea, anorexia, weight loss, abdominal pain, cough, dyspnea, and wheezing are most often reported; shock and collapse may also occur. Possible physical examination findings include muffled heart sounds on one or both sides of the chest; displacement or attenuation of the apical precordial impulse; an “empty” feel on abdominal palpation (with herniation of many organs); and, rarely, signs of cardiac tamponade (discussed in more detail later). Diagnosis Thoracic radiographs are often diagnostic or highly suggestive of PPDH. Enlargement of the cardiac silhouette, dorsal tracheal displacement, overlap of the diaphragmatic and caudal heart borders, and abnormal fat and/or gas densities within the cardiac silhouette are characteristic findings (Fig. 9-1, A and B). Especially in cats, a pleural fold (dorsal peritoneopericardial mesothelial remnant), extending between the caudal heart shadow and the diaphragm ventral to the caudal vena cava on lateral view, may be evident. Gas-filled loops of bowel crossing the diaphragm 159

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PART Iâ•…â•… Cardiovascular System Disorders

A

B

C FIG 9-1â•…

Lateral (A) and dorsoventral (B) radiographs from a 5-year-old male Persian cat with a congenital peritoneopericardial diaphragmatic hernia (PPDH). Note the greatly enlarged cardiac silhouette containing fat, soft tissue, and gas densities, as well as tracheal elevation. There is overlap between the cardiac and diaphragmatic borders on both views. Presence of a portion of the stomach and duodenum within the pericardium is evident after barium administration (C); omental fat and liver are also present within the pericardial sac. In C, the dorsal pleural fold between pericardium and diaphragm is best appreciated (arrow).

into the pericardial sac, a small liver, and few organs within the abdominal cavity may also be seen. Echocardiography (or abdominothoracic ultrasonography) helps confirm the diagnosis when radiographic findings are equivocal (Fig. 9-2). A GI barium series is diagnostic if the stomach and/or intestines are in the pericardial cavity (see Fig. 9-1, C). Fluoroscopy, nonselective angiography (especially if only falciform fat or liver has herniated), or celiography can also aid in diagnosis. Electrocardiogram changes are inconsistent; decreased amplitude complexes and axis deviations caused by cardiac position changes sometimes occur. Treatment Therapy involves surgical closure of the peritoneal-pericardial defect after viable organs are returned to their normal location. The presence of other congenital abnormalities and the animal’s clinical signs influence the decision to operate. The prognosis in uncomplicated cases is excellent. However,

perioperative complications are common and, although often mild, can include death. Older animals without clinical signs may do well without surgery, especially because organs chronically adhered to the heart or pericardium may be traumatized during attempted repositioning.

OTHER PERICARDIAL ANOMALIES Pericardial cysts are rare anomalies. They may originate from abnormal fetal mesenchymal tissue or from incarcerated omental or falciform fat associated with a small PPDH. The pathophysiologic signs and clinical presentation can mimic those seen with pericardial effusion. Radiographically, the cardiac silhouette may appear enlarged and deformed. Echocardiography can reveal the diagnosis. Surgical cyst removal, combined with partial pericardiectomy, usually resolves the clinical signs. Congenital defects of the pericardium itself are extremely rare in dogs and cats; most are incidental postmortem

CHAPTER 9â•…â•… Pericardial Disease and Cardiac Tumors

161

FIG 9-2â•…

Right parasternal short-axis echocardiogram from a female Persian cat with peritoneopericardial diaphragmatic hernia (PPDH). The pericardium (PERI), indicated by arrows, surrounds liver and omental tissue, as well as the heart. LV, Left ventricle.

findings. Sporadic cases of partial (usually left-sided) or complete absence of the pericardium are reported. A possible complication of partial absence of the pericardium is herniation of a portion of the heart; this could cause syncope, embolic disease, or sudden death. Echocardiography or angiocardiography may allow antemortem diagnosis.

PERICARDIAL EFFUSION Etiology and Types of Fluid In dogs most pericardial effusions are serosanguineous or sanguineous and are of neoplastic or idiopathic origin. Transudates, modified transudates, and exudates are found occasionally in both dogs and cats; rarely a chylous effusion is discovered. In cats, pericardial effusion is most commonly associated with congestive heart failure (CHF) from cardiomyopathy, although these rarely cause tamponade. A minority of feline pericardial effusions result from various neoplasia, feline infectious peritonitis, PPDH, pericarditis, and other infectious or inflammatory disease.

HEMORRHAGE Hemorrhagic effusions are common in dogs. The fluid usually appears dark red, with a packed cell volume (PCV) greater than 7%, a specific gravity greater than 1.015, and a protein concentration greater than 3╯g/dL. Cytologic analysis shows mainly red blood cells, but reactive mesothelial, neoplastic, or other cells may be seen. The fluid does not clot unless hemorrhage was recent. Neoplastic hemorrhagic effusions are more likely in dogs older than 7 years. Middle-aged, large-breed dogs are most likely to have idiopathic “benign” hemorrhagic effusion. Hemangiosarcoma (HSA) is by far the most common neoplasm causing hemorrhagic pericardial effusion in dogs;

it is rare in cats. Hemorrhagic pericardial effusion also occurs in association with various heartbase tumors; pericardial mesotheliomas; malignant histiocytosis (MH); some cases of lymphoma and, rarely, metastatic carcinoma. HSAs (see p. 169) usually arise within the right heart, especially in the right auricular appendage. Chemodectoma is the most common heartbase tumor; it arises from chemoreceptor cells at the base of the aorta. Thyroid, parathyroid, lymphoid, and connective tissue neoplasms also occur at the heartbase. Pericardial mesothelioma sometimes causes mass lesions at the heartbase or elsewhere but often has a diffuse distribution and may mimic idiopathic disease. Lymphoma involving various parts of the heart is seen more often in cats than in dogs (and often causes a modified transudative effusion). Dogs with MH and pericardial effusion usually have pleural effusion and ascites (“tricavitary effusion”) despite the fact that they do not have cardiac tamponade. Idiopathic (benign) pericardial effusion is the secondmost common cause of canine hemorrhagic pericardial effusion. Its cause is still unknown; no evidence for an underlying viral, bacterial, or immune-mediated etiology has been found. Idiopathic pericardial effusion is reported most frequently in medium- to large-breed dogs. Golden Retrievers, Labrador Retrievers, and Saint Bernards may be predisposed. Although dogs of any age can be affected, the median age is 6 to 7 years. More cases have been reported in males than females. Mild pericardial inflammation, with diffuse or perivascular fibrosis and focal hemorrhage, is common on histopathologic examination. Layers of fibrosis suggest a recurrent process in some cases. Constrictive pericardial disease is a potential complication. Other, less common causes of intrapericardial hemorrhage include left atrial (LA) rupture secondary to severe mitral insufficiency (see p. 117), coagulopathy (mainly rodenticide toxicity or disseminated intravascular coagulation),

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PART Iâ•…â•… Cardiovascular System Disorders

penetrating trauma (including iatrogenic laceration of a coronary artery during pericardiocentesis), and possibly uremic pericarditis.

TRANSUDATES Pure transudates are clear, with a low cell count (usually < 1000 cells/µL), specific gravity (6╯µm wide

Move across field

40% in some reports), the cost of therapy, the intensive care required, and

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PART Iâ•…â•… Cardiovascular System Disorders

the lack of clearly established dosing protocols have pre­ vented their widespread use. Furthermore, a clear survival advantage has not been shown. If used, this therapy is best instituted within 3 to 4 hours of vascular occlusion. An intensive care setting, including frequent monitoring of serum potassium concentration and acid-base status, as well as electrocardiographic (ECG) monitoring is important to detect reperfusion-induced hyperkalemia and metabolic aci­ dosis. The risk-to-benefit profile of thrombolytic treatment may be better in patients with brain, renal, or splanchnic thromboembolism. Streptokinase is a nonspecific plasminogen activator that promotes the breakdown of fibrin and fibrinogen. This action leads to the degradation of fibrin within thrombi and clot lysis but also potentially leads to systemic fibrinolysis, coagulopathy, and bleeding. Streptokinase also degrades factors V and VIII and prothrombin. Although its half-life is about 30 minutes, fibrinogen depletion continues for much longer. Streptokinase has been used with variable success in a small number of dogs with arterial TE disease. The reported protocol is 90,000╯IU of streptokinase infused IV over 20 to 30 minutes, then at a rate of 45,000╯IU/h for 3 (to 8) hours. Dilution of 250,000╯IU into 5╯mL saline and then into 50╯mL to yield 5000╯U/mL for infusion with a syringe pump has been suggested for cats. Adverse effects include bleeding and reperfusion injury. Although minor in some cases, with bleeding responding to streptokinase discontinuation, there is a risk for serious hemorrhage and the mortality rate can be high. Acute hyperkalemia (secondary to thrombolysis and reperfusion injury), metabolic acidosis, bleeding, and other complications are thought to be responsible for causing death. Streptokinase can increase platelet aggregability and induce platelet dysfunction. It is unclear if lower doses would be effective with fewer complications. Streptokinase com­ bined with heparin therapy can increase the risk of hemor­ rhage, especially when coagulation times are increased. Streptokinase is potentially antigenic because it is produced by β-hemolytic streptococci. No survival benefit has been shown for streptokinase therapy compared with conven­ tional (i.e., aspirin and heparin) treatment in cats. Urokinase has similar activity to streptokinase but is thought to be more specific for fibrin. A protocol that has been used in cats is 4400╯ IU/kg IV over 10 minutes, fol­ lowed by 4400╯ IU/kg/h constant rate infusion for 12 hours. Variable success occurred in a small number of cats with aortic thromboembolism, but mortality was greater than 50%. rt-PA is a single-chain polypeptide serine protease with a higher specificity for fibrin within thrombi and a low affinity for circulating plasminogen. Although the risk of hemor­ rhage is less than with streptokinase, there is the potential for serious bleeding and other side effects. rt-PA is also potentially antigenic in animals because it is a human protein. Like streptokinase, rt-PA induces platelet dysfunc­ tion but not hyperaggregability. Experience with rt-PA is limited, the optimal dosage is not known, and it is relatively expensive. An IV dose of 0.25 to 1╯mg/kg/h up to a total of

1 to 10╯mg/kg was used in a small number of cats; although signs of reperfusion occurred, the mortality rate was high. The cause of death in most cats was attributed to reperfusion (hyperkalemia, metabolic acidosis) and hemor­ rhage, although CHF and arrhythmias were also involved. Surgical thromboembolus removal is generally not advised in cats. The surgical risk is high, and significant neuromuscular ischemic injury is likely to have already occurred by the time of surgery. Clot removal using an embolectomy catheter has not been effective in cats. Antiplatelet therapy is used to inhibit platelet aggregation and in hope of improving collateral blood flow by reducing production of vasoconstrictive substances released from activated platelets, such as thromboxane A2 and serotonin. Aspirin (acetylsalicylic acid) has been commonly employed to block platelet activation and aggregation in patients with, or at risk for, TE disease. Aspirin irreversibly inhibits cyclo­ oxygenase, which reduces prostaglandin and thromboxane A2 synthesis and therefore could reduce subsequent platelet aggregation, serotonin release, and vasoconstriction. Because platelets cannot synthesize additional cyclooxygenase, this reduction of procoagulant prostaglandins and thromboxane persists for the platelet’s life span (7-10 days). Endothelial production of prostacyclin (also via the cyclooxygenase pathway) is reduced by aspirin but only transiently as endo­ thelial cells synthesize additional cyclooxygenase. Aspirin’s benefit may relate more to in situ thrombus formation; effi­ cacy at clinical doses in acute arterial TE disease is unknown. Adverse effects of aspirin tend to be mild and usually related to signs of GI upset, mainly anorexia and vomiting. The optimal dose is unclear. Cats lack an enzyme (glucuronyl transferase) that is necessary to metabolize aspirin, so less frequent dosing is required compared with dogs. In cats with experimental aortic thrombosis, 10 to 25╯mg/kg (81 mg tab/ cat) given by mouth once every (2 to) 3 days inhibited plate­ let aggregation and improved collateral circulation. However, low-dose aspirin (5╯mg/cat q72h) has also been used with fewer GI adverse effects, although its efficacy in preventing TE events is unknown. Aspirin therapy is started when the patient is able to take food and oral medications. Clopidogrel (Plavix) is a second-generation thienopyri­ dine with antiplatelet effects that are more potent than aspirin; however, clinical efficacy compared with aspirin has not yet been reported. The thienopyridines inhibit adeno­ sine diphosphate (ADP)-binding at platelet receptors and subsequent ADP-mediated platelet aggregation. Clopido­ grel’s antiplatelet effects occur after the drug is transformed in the liver to an active metabolite. Its irreversible antago­ nism of the platelet membrane ADP2Y12 receptor inhibits a conformational change of the glycoprotein IIb/IIIa complex, resulting in reduced binding of fibrinogen and von Willi­ brand factor. Clopidogrel also impairs platelet release of serotonin, ADP, and other vasoconstrictive and platelet aggregating substances. When given orally at 18.75╯mg/cat/ day (or 2 to 4╯mg/kg/day) maximal antiplatelet effects occur within 72 hours and disappear in about 7 days after drug discontinuation. An oral loading dose (of 10╯mg/kg) in dogs

can provide antithrombotic effect within 90 minutes; simi­ larly accelerated onset of action may occur in cats as well. A loading dose of 75╯mg/cat given as soon as possible after an acute arterial TE event may have a positive effect on improv­ ing collateral blood flow. Short-term administration of this dose appears to be well tolerated. Clopidogrel does not cause GI ulceration, as aspirin can, but vomiting does occur in some cats. This appears to be ameliorated by giving the drug with food or in a gel capsule. In general, the prognosis is poor in cats with arterial TE disease. Historically, only about one third of cats survive the initial episode irrespective of whether conservative or throm­ bolytic therapy is used. However, survival statistics improve when cats euthanized without therapy are excluded or when only cases from recent years are analyzed. Survival is better if only one limb is involved and/or if some motor function is preserved at presentation. Hypothermia and CHF at pre­ sentation are both associated with poor survival in cats. Other negative factors may include hyperphosphatemia; progressive hyperkalemia or azotemia; bradycardia; persis­ tent lack of motor function; progressive limb injury (contin­ ued muscle contracture after 2-3 days, necrosis); severe LA enlargement; presence of intracardiac thrombi or spontane­ ous contrast (“swirling smoke”) on echocardiogram; DIC; and history of thromboembolism. Barring complications, limb function should begin to return within 1 to 2 weeks. Some cats become clinically normal within 1 to 2 months, although residual deficits may persist for a variable time. Tissue necrosis may require wound management and skin grafting. Permanent limb deformity develops in some cats, and amputation is occa­ sionally necessary. Repeated events are common. Significant embolization of the kidneys, intestines, or other organs carries a grave prognosis.

PROPHYLAXIS AGAINST ARTERIAL THROMBOEMBOLISM Prophylactic therapy with an antiplatelet or anticoagulant drug is commonly used in animals thought to be at increased risk for TE disease. These include cats with cardiomyopathy (especially those with marked LA enlargement, echocardio­ graphic evidence for intracardiac spontaneous contrast or thrombus, or a previous TE event) and animals with sepsis, IMHA, severe pancreatitis, or other procoagulant condi­ tions. However, the efficacy of TE prophylaxis is unknown, and a strategy that consistently prevents thromboembolism is not yet identified. Drugs used for arterial TE prophylaxis include aspirin, clopidogrel, warfarin (coumadin), and LMWH. Aspirin and clopidogrel (see earlier, p. 206) present a low risk for serious hemorrhage and require less monitoring compared with warfarin. Adverse GI effects (e.g., vomiting, inappetence, ulceration, hematemesis) occur in some animals receiving aspirin. Buffered aspirin formulation or an aspirin-Maalox combination product may be helpful. Low-dose aspirin (5╯mg/cat every third day) has been advocated in cats. Although adverse effects are unlikely with this dose, it is not

CHAPTER 12â•…â•… Thromboembolic Disease

207

known whether antiplatelet effectiveness is compromised. Clopidogrel is being used more commonly now and likely has advantages over aspirin. With the availability of generic clopidogrel cost is less of a concern. Warfarin (discussed in more detail later) is associated with greater expense and a higher rate of fatal hemorrhage. No survival benefit has been shown for warfarin compared with aspirin in cats. In some reports, recurrent thromboembolism occurred in almost half of cats treated with warfarin. Clopidogrel or LMWH prophylaxis may be more efficacious, with less risk of hem­ orrhage, but more clinical evidence regarding these therapies is necessary. LMWH is expensive and must be given by SC injection, but some owners are motivated to do this. In cats without thrombocytopenia, aspirin or clopidogrel could be used concurrently with LMWH. Diltiazem, at clinical doses, does not appear to have significant platelet-inhibiting effects. Warfarin inhibits the enzyme (vitamin K epoxide reduc­ tase) responsible for activating the vitamin K–dependent factors (II, VII, IX, and X), as well as proteins C and S. Initial warfarin treatment causes transient hypercoagulability because anticoagulant proteins have a shorter half-life than most procoagulant factors. Therefore heparin (e.g., 100╯IU/ kg administered subcutaneously q8h) or LMWH is given for 2 to 4 days after warfarin is initiated. There is wide variability in dose response and potential for serious bleeding, even in cats that are monitored closely. Warfarin is highly protein bound; concurrent use of other protein-bound drugs or change in serum protein concentration can markedly alter the anticoagulant effect. Bleeding may be manifested as weakness, lethargy, or pallor rather than overt hemorrhage. A baseline coagulation profile and platelet count are obtained, and aspirin discontinued, before beginning treatment. The usual initial warfarin dose is 0.25 to 0.5╯mg (total dose) administered orally q24-48h in cats. Uneven distribution of drug within the tablets is reported, so compounding rather than administering tablet fragments is recommended. Drug administration and blood sampling times should be consistent. The dose is adjusted either on the basis of prothrombin time (PT) or the international normalization ratio (INR). The INR is a more precise method that has been recom­ mended to prevent problems related to variation in com­ mercial PT assays. The INR is calculated by dividing the animal’s PT by the control PT and raising the quotient to the power of the international sensitivity index (ISI) of the thromboplastin used in the assay, or INR = (animal PT/ control PT)ISI. The ISI is provided with each batch of throm­ boplastin made. Extrapolation from human data suggests that an INR of 2 to 3 is as effective as higher values, with less chance for bleeding. Using a warfarin dose of 0.05 to 0.1╯mg/kg/day in the dog achieves this INR in about 5 to 7 days. Heparin overlap until the INR is greater than 2 is recommended. When PT is used to monitor warfarin therapy, a goal of 1.25 to 1.5 (to 2) times pretreatment PT at 8 to 10 hours after dosing is advised; the animal is weaned off heparin when the PT is greater than 1.25 times baseline. The PT is evaluated (several hours after dosing) daily initially,

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PART Iâ•…â•… Cardiovascular System Disorders

then at progressively increasing time intervals (e.g., twice a week, then once a week, then every month to 2 months) as long as the cat’s condition appears stable. If the PT or INR increases excessively, warfarin is discon­ tinued and vitamin K1 administered (1-2╯mg/kg/day admin­ istered orally or subcutaneously) until the PT is normal and the packed cell volume (PCV) is stable. Transfusion with fresh frozen plasma, packed red blood cells, or whole fresh blood is sometimes necessary. A number of new antithrombotic drugs are becoming available for human use. Synthetic factor Xa inhibitors (e.g., rivaroxaban, apixiban, fondaparinux, idraparinux) potenti­ ate effects of AT without affecting thrombin or platelet function. Their effect is monitored via anti-Xa activity measurement because they do not affect results of routine coagulation tests. Dabigatran etexilate is an oral direct thrombin inhibitor. Ticagrelor and prasugrel are newer platelet ADP2Y12 receptor antagonists, with similar effects as clopidogrel.

SYSTEMIC ARTERIAL THROMBOEMBOLISM IN DOGS Arterial TE disease in dogs is relatively uncommon com­ pared with cats. However, the true prevalence is unknown and it may be underrecognized in dogs because of differ­ ences in pathogenesis and clinical presentation. Arterial TE disease has been associated with many conditions, including protein-losing nephropathies, hyperadrenocorticism, neo­ plasia (including pulmonary neoplasia causing local pulmo­ nary venous thrombosis), chronic interstitial nephritis, HWD, hypothyroidism, gastric dilation/volvulus, pancre­ atitis, and several cardiovascular diseases. The distal aorta is the most commonly reported location. However, occlusion or partial occlusion of the distal aorta is often from primary thrombus formation in dogs, rather than an acute embolic event as in cats. The development of clinical signs in these dogs is usually more vague and chronic. Concurrent cardiac disease is reported only in a minority of dogs with aortic thrombosis, and in most of these its relation to the TE disease is unclear. Aortic thrombosis has occurred in dogs with underlying procoagulant conditions, especially proteinlosing nephropathy; however, in up to half of reported cases no predisposing abnormality was identified. Aortic TE disease appears more prevalent in male compared with female dogs; it is unclear whether any true breed predisposi­ tion exists, although Cavalier King Charles Spaniels and Lab­ radors were overrepresented in different reports. The most common cardiac disease associated with sys­ temic TE disease in dogs is vegetative endocarditis. Other cardiovascular conditions that have been associated with canine TE disease include patent ductus arteriosus (surgical ligation site), dilated cardiomyopathy, myocardial infarction, arteritis, aortic intimal fibrosis, atherosclerosis, aortic dissec­ tion, granulomatous inflammatory erosion into the LA, and other thrombi in the left heart. In the presence of an atrial

septal defect, or right-to-left shunting ventricular septal defect, fragments originating from venous thrombosis could cross the defect to cause systemic arterial embolization. TE disease is a rare complication of arteriovenous (A-V) fistu­ lae; it may relate to venous stasis from distal venous hypertension. Atherosclerosis is uncommon in dogs, but it has been associated with TE disease in this species, as it has in people. Endothelial disruption in areas of atherosclerotic plaque, hypercholesterolemia, increased plasminogen activator inhibitor-1, and possibly other mechanisms may be involved in thrombus formation. Atherosclerosis may develop with profound hypothyroidism, hypercholesterolemia, or hyper­ lipidemia. The aorta and coronary and other medium to large arteries are affected. Myocardial and cerebral infarc­ tions occur in some cases, and there is a high rate of inter­ stitial myocardial fibrosis in affected dogs. Vasculitis related to infectious, inflammatory, immunemediated, neoplastic, or toxic disease can underlie throm­ bosis or embolic events. Arteritis of immune-mediated pathogenesis is described in some young Beagles and other dogs. Inflammation and necrosis that affect small to mediumsized arteries can be associated with thrombosis. Coronary artery thromboembolism causes myocardial ischemia and infarction. Infective endocarditis, neoplasia that involves the heart directly or by neoplastic emboli, coro­ nary atherosclerosis, dilated cardiomyopathy, degenerative mitral valve disease with CHF, and coronary vasculitis are reported causes. In other dogs coronary TE events have occurred with severe renal disease, IMHA, exogenous corti­ costeroids or hyperadrenocorticism, and acute pancreatic necrosis. These cases may have TE lesions in other locations as well. Clinical Features The distal aorta is the most common location for clinically recognized TE disease. Affected dogs typically present for intermittent rear limb lameness (claudication) and have weak femoral pulses on the affected side. In contrast to cats, most dogs have some clinical signs from 1 to 8 weeks before presentation. Less than a quarter of cases have per­ acute paralysis without prior signs of lameness, as usually occurs in cats. Clinical signs in dogs include decreased exercise tolerance, pain, bilateral or unilateral lameness or weakness (which may be progressive or intermittent), hindlimb paresis or paralysis, and chewing or hypersensitiv­ ity of the affected limb(s) or lumbar area. Although about half of affected dogs present with sudden paresis or paraly­ sis, this is often preceded by a variable period (days to months) of lameness or exercise intolerance. Intermittent claudication, common in people with peripheral occlusive vascular disease, may be a manifestation of distal aortic TE disease. This involves pain, weakness, and lameness that develop during exercise. These signs intensify until walking becomes impossible and then disappear with rest. Inade­ quate perfusion during exercise leads to lactic acid accumu­ lation and cramping.

Physical examination findings in dogs with aortic throm­ boembolism include absent or weak femoral pulses and neu­ romuscular dysfunction; cool extremities, hindlimb pain, loss of sensation in the digits, hyperesthesia, and cyanotic nailbeds are variably present. Occasionally, a brachial or other artery is embolized. TE disease involving an abdominal organ causes abdominal pain, with clinical and laboratory evidence of damage to the affected organ. Coronary artery thromboembolism is likely to be associ­ ated with arrhythmias, as well as ST segment and T wave changes on ECG. Ventricular (or other) tachyarrhythmias are common, but if the atrioventricular (AV) nodal area is injured, conduction block may result. Clinical signs of acute myocardial infarction/necrosis may mimic those of pulmo­ nary TE disease; these include weakness, dyspnea, and col­ lapse. Respiratory difficulty may develop as a result of pulmonary abnormalities or left heart failure (pulmonary edema) depending on the underlying disease and degree of myocardial dysfunction. Some animals with respiratory dis­ tress have no radiographically evident pulmonary infiltrates. Increased pulmonary venous pressure preceding overt edema (from acute myocardial dysfunction) or concurrent pulmonary emboli are potential causes. Other findings in animals with myocardial necrosis include sudden death, tachycardia, weak pulses, increased lung sounds or crackles, cough, cardiac murmur, hyperthermia or sometimes hypo­ thermia, and (less commonly) GI signs. Signs of other sys­ temic disease may be concurrent. Acute ischemic myocardial injury that causes sudden death may not be detectable on routine histopathology. Diagnosis Thoracic radiography is used to screen for cardiac abnor­ malities, especially in animals with systemic arterial TE disease and for pulmonary changes in animals suspected to have pulmonary thromboemboli. Evidence for CHF or other pulmonary disease associated with TE disease (e.g., neopla­ sia, HWD, other infections) may also be found. A complete echocardiographic examination is important to define whether (and what type of) heart disease might be present. Thrombi within the left or right heart chambers and proximal great vessels can be readily seen with twodimensional echocardiography. In dogs with coronary TE disease, the echocardiographic examination may indicate reduced myocardial contractility with or without regional dysfunction. Areas of myocardial fibrosis secondary to chronic ischemia or infarction appear hyperechoic com­ pared with the surrounding myocardium. Spontaneous echo-contrast (swirling smoke) is sometimes seen within the heart in dogs with endocarditis, neoplasia, and other inflam­ matory conditions. It has been associated with hyperfibrino­ genemia and, similar to cats, is thought to indicate increased risk for TE disease. Abdominal ultrasonography should allow visualization of thromboemboli in the distal aorta (and sometimes other vessels). Doppler studies can demon­ strate partial or complete obstruction to blood flow in some cases.

CHAPTER 12â•…â•… Thromboembolic Disease

209

Angiography or other imaging modalities may be used to document vascular occlusion when ultrasonography is inconclusive or unavailable. Angiography can also show the extent of collateral circulation; the choice of selective or nonselective technique depends on patient size and the sus­ pected location of the thrombus. Routine laboratory test results depend largely on the disease process underlying the TE event(s). Systemic arterial TE disease also produces elevated muscle enzyme concentra­ tions from skeletal muscle ischemia and necrosis. Aspartate aminotransferase (AST) and alanine aminotransferase (ALT) activities rise soon after the TE event. Widespread muscle injury causes increased lactate dehydrogenase and creatine kinase (CK) activities as well. Coagulation test results in patients with TE disease are variable. The concentration of FDPs or d-dimer may be increased, but this can occur in patients with inflammatory disease and is not specific for a TE event or DIC. Modestly increased d-dimer concentrations occur in diseases such as neoplasia, liver disease, and IMHA. This could reflect sub­ clinical TE disease or another clot activation mechanism because these conditions are associated with a procoagulant state. Body cavity hemorrhage also causes a rise in d-dimer concentrations. Because this condition is associated with increased fibrin formation, elevated d-dimer levels may not indicate TE disease in such cases. The specificity of d-dimer testing for pathologic thromboembolism is lower at lower d-dimer concentrations, but the high sensitivity at lower concentrations provides an important screening tool. ddimer testing appears to be as specific for DIC as FDP mea­ surement. A number of assays have been developed to measure d-dimer concentrations in dogs; some are qualita­ tive or semiquantitative (i.e., latex agglutination, immuno­ chromatographic, and immunofiltration tests), and others are more quantitative (i.e., immunoturbidity, enzymatic immunoassays). It is important to interpret d-dimer results in the context of other clinical and test findings. Assays for circulating AT and proteins C and S are also available for dogs and cats. Deficiencies of these proteins are associated with increased risk of thrombosis. Thromboelastography (TEG) provides an easy point-ofcare method of assessing global hemostasis and is quite valu­ able when evaluating patients with TE disease. However, in most Greyhounds and sighthounds with aortic TE, results of TEG are within normal limits for the breed. Treatment and Prognosis The goals of therapy for dogs with an acute TE event are the same as for cats with TE disease: Stabilize the patient by supportive treatment as indicated, prevent extension of the existing thrombus and additional TE events, and reduce the size of the thromboembolus and restore perfusion. Support­ ive care is given to improve and maintain adequate tissue perfusion, minimize further endothelial damage and blood stasis, and optimize organ function, as well as to allow time for collateral circulation development. Correcting or managing underlying disease(s), to the extent possible, is

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important. Antiplatelet and anticoagulant therapies are used to reduce platelet aggregation and growth of existing thrombi (see p. 204 and Box 12-3). Warfarin therapy has been used successfully in the long-term treatment of dogs with aortic thrombosis (see later); aspirin or clopidogrel can be admin­ istered concurrently when platelets are adequate. The results of TEG, if available, should be used to monitor response to anticoagulants in patients with TE disease. Management strategies used for acute TE disease are out­ lined in Box 12-3. Although fibrinolytic therapy is used in some cases, dosage uncertainties, the need for intensive care, and the potential for serious complications limit its use. The reported streptokinase protocol for dogs is 90,000╯IU infused intravenously over 20 to 30 minutes, then continued at a rate of 45,000╯IU/hour for 3 (to 12) hours. This was fairly suc­ cessful in a small number of dogs. Clinical experience with urokinase in dogs appears to be even more limited and asso­ ciated with extremely high mortality using the protocol described for cats (see p. 206). rt-PA has been used in dogs, with variable success, as 1╯mg/kg boluses administered intra­ venously q1h for 10 doses, with IV fluid, other supportive therapy, and close monitoring. The half-life of t-PA is about 2 to 3 minutes in dogs, but effects persist longer because of binding to fibrin. The consequences of reperfusion injury present serious complications to thrombolytic therapy. The iron chelator deferoxamine mesylate has been used in an attempt to reduce oxidative damage caused by free radicals involving iron. Allopurinol has also been used but with uncertain results. Thromboembolus removal using an embo­ lectomy catheter has not been effective in cats but might be more successful in dogs of larger size. Arterial stenting has been used successfully in some dogs with aortic thromboembolism. Fluid therapy is used to expand vascular volume, support blood pressure, and correct electrolyte and acid/base abnor­ malities depending on individual patient needs. However, for animals with heart disease and especially CHF, fluid therapy is given only with great caution (if at all). Hypothermia that persists after circulating volume is restored can be addressed with external warming. Specific treatment for heart disease, CHF, and arrhythmias is provided as indicated (see Chapters 3 and 4 and other relevant chapters). Acute respiratory signs may signal CHF, pain, or pulmonary thromboembolism. Differentiation is important because diuretic or vasodilator therapy could worsen perfusion in animals without CHF. Because acute arterial embolization is particularly painful, analgesic therapy is important in such cases, especially for the first 24 to 36 hours (see Box 12-3). Loosely bandaging the affected limb(s) to prevent self-mutilation may be neces­ sary in some animals with aortic TE disease. Renal function and serum electrolyte concentrations are monitored daily or more frequently if fibrinolytic therapy is used. Continuous ECG monitoring during the first several days may help the clinician detect acute hyperkalemia associated with reperfu­ sion (see Chapter 2, p. 30). In general, the prognosis is poor. Long-term oral warfarin therapy has improved ambula­ tion in dogs with aortic thrombosis. Rear limb function

  TABLE 12-1â•… Guidelines for Adjusting Total Weekly Warfarin Dose* INR

TOTAL WEEKLY WARFARIN DOSE ADJUSTMENT

RECHECK INR IN

1.0-1.4

Increase TWD by 10%-20%

1 week

1.5-1.9

Increase TWD by 5%-10%

2 weeks

2.0-3.0

No change in TWD

4-6 weeks

3.1-4.0

Decrease TWD by 5%-10%

2 weeks

4.1-5.0

Stop warfarin for 1 day Decrease TWD 10%-20%

1 week

>5.0

Stop warfarin until INR < 3.0 Decrease TWD 20%-40%

1 week

*See p. 210 for additional information. INR = (animal PT/control PT)ISI Control PT, Laboratory reference mean prothrombin time; INR, international normalized ratio; ISI, international sensitivity index (of the thromboplastin reagent); TWD, total weekly warfarin dose. Modified from Winter RL et╯al: Aortic thrombosis in dogs: presentation, therapy, and outcome in 26 cases, J Vet Cardiol 14:333, 2012.

improvement may be seen within several days of initiating therapy; however, two or more weeks are required in most cases. Application of a standardized warfarin protocol to dogs with aortic thrombosis has recently been described (Winter RL et╯al, 2012). Initial doses of warfarin ranged from 0.05 to 0.2╯mg/kg PO q24h; the total weekly dose was then adjusted based on the calculated INR (see p. 207) according to the guidelines in Table 12-1. Changes in the total weekly dose may require some variation in day-to-day doses.

PROPHYLAXIS AGAINST ARTERIAL THROMBOEMBOLISM Prophylactic strategies are similar to those used for cats. Aspirin, clopidogrel, LMWH, or warfarin are agents to con­ sider. In dogs with IMHA, aspirin or clopidogrel along with immunosuppressive therapy appears to improve survival. GI erosions are commonly seen endoscopically in dogs receiv­ ing aspirin, even in the absence of clinical signs of vomiting or anorexia. Clopidogrel has been shown to inhibit ADPinduced platelet aggregation in normal dogs. It has not been associated with GI ulceration. Doses of 1 to 3╯mg/kg PO q24h produce maximal antiplatelet effects within 3 days in dogs. Effects are minimal by 7 days after discontinuing the drug. Peak concentration of clopidogrel’s active metabolite (SR 26334) appears in about 1 hour after administration. Antiplatelet effects are seen at lower clopidogrel doses with hepatic P450 enzyme activation. More clinical experience is necessary to better define optimal dosing guidelines. If war­ farin is used, the usual initial warfarin dose in dogs is 0.1 to 0.2╯mg/kg PO q24h. A loading dose of approximately 0.2╯mg/ kg for 2 days appears to be safe in dogs.

VENOUS THROMBOSIS Thrombosis in large veins is more likely to be clinically evident than thrombosis in small vessels. Cranial vena caval thrombosis has been associated with IMHA and/or immunemediated thrombocytopenia, sepsis, neoplasia, proteinlosing nephropathies, mycotic disease, heart disease, and glucocorticoid therapy (especially in patients with systemic inflammatory disease) in dogs. Most cases have more than one predisposing factor. An indwelling jugular catheter increases the risk for cranial caval thrombosis, probably by causing vascular endothelial damage or laminar flow disrup­ tion or by acting as a nidus for clot formation. Portal vein thrombosis, along with DIC, has occurred in dogs with pancreatitis and pancreatic necrosis. Peritonitis, neoplasia, hepatitis, protein-losing nephropathy, IMHA, and vasculitis have also been diagnosed occasionally in dogs with portal thrombosis. A high proportion of dogs with incidental portal or splenic vein thrombosis are receiving corticosteroids. Systemic venous thrombosis produces signs related to increased venous pressure upstream from the obstruction. Thrombosis of the cranial vena cava can lead to the cranial caval syndrome. The cranial caval syndrome is char­ acterized by bilaterally symmetric subcutaneous edema of the head, neck, and forelimbs; another cause of this syn­ drome is external compression of the cranial cava, usually by a neoplastic mass. Pleural effusion occurs commonly. This effusion is often chylous because lymph flow from the tho­ racic duct into the cranial vena cava is also impaired. Pal­ pable thrombosis extends into the jugular veins in some cases. Because vena caval obstruction reduces pulmonary blood flow and left heart filling, signs of poor cardiac output are common. Vena caval thrombosis may be visible on ultrasound examination, especially when the clot extends into the RA. Portal vein thrombosis and thromboemboli in the aorta or other large peripheral vessels can also be documented on ultrasound examination. Clinicopathologic findings generally reflect underlying disease and tissue damage resulting from vascular obstruc­ tion. Cranial caval thrombosis has been associated with thrombocytopenia. Management is as discussed earlier for arterial thrombosis; stenting of the affected vessel is another therapeutic option. Suggested Readings Alwood AJ et al: Anticoagulant effects of low-molecular–weight heparins in healthy cats, J Vet Intern Med 21:378, 2007. Bedard C et al: Evaluation of coagulation markers in the plasma of healthy cats and cats with asymptomatic hypertrophic cardiomy­ opathy, Vet Clin Pathol 36:167, 2007. Boswood A, Lamb CR, White RN: Aortic and iliac thrombosis in six dogs, J Small Anim Pract 41:109, 2000. Bright JM, Dowers K, Powers BE: Effects of the glycoprotein IIb/ IIIa antagonist abciximab on thrombus formation and platelet function in cats with arterial injury, Vet Ther 4:35, 2003.

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211

Carr AP, Panciera DL, Kidd L: Prognostic factors for mortality and thromboembolism in canine immune-mediated hemolytic anemia: a retrospective study of 72 dogs, J Vet Intern Med 16:504, 2002. De Laforcade AM et al: Hemostatic changes in dogs with naturally occurring sepsis, J Vet Intern Med 17:674, 2003. Goggs R et al: Pulmonary thromboembolism, J Vet Emerg Crit Care (San Antonio) 19:30, 2009. Goncalves R et al: Clinical and neurological characteristics of aortic thromboembolism in dogs, J Small Anim Pract 49:178, 2008. Good LI, Manning AM: Thromboembolic disease: physiology of hemostasis and pathophysiology of thrombosis, Compend Contin Educ Pract Vet 25:650, 2003. Good LI, Manning AM: Thromboembolic disease: predispositions and clinical management, Compend Contin Educ Pract Vet 25:660, 2003. Goodwin JC, Hogan DF, Green HW: The pharmacodynamics of clopidogrel in the dog, J Vet Intern Med 21:609, 2007. Goodwin JC et al: Hypercoagulability in dogs with protein-losing enteropathy, J Vet Intern Med 25:273, 2011. Hogan DF et al: Antiplatelet effects and pharmacodynamics of clopidogrel in cats, J Am Vet Med Assoc 225:1406, 2004. Hamel-Jolette A et al: Plateletworks: a screening assay for clopido­ grel therapy monitoring in healthy cats, Can J Vet Res 73:73, 2009. Kidd L, Stepien RL, Amrheiw DP: Clinical findings and coronary artery disease in dogs and cats with acute and subacute myocardial necrosis: 28 cases, J Am Anim Hosp Assoc 36:199, 2000. Laurenson MP et al: Concurrent diseases and conditions in dogs with splenic vein thrombosis, J Vet Intern Med 24:1298, 2010. Licari LG, Kovacic JP: Thrombin physiology and pathophysiology, J Vet Emerg Crit Care (San Antonio) 19:11, 2009. Lunsford KV, Mackin AJ: Thromboembolic therapies in dogs and cats: an evidence-based approach, Vet Clin North Am Small Anim Pract 37:579, 2007. Mellett AM, Nakamura RK, Bianco D: A prospective study of clopi­ dogrel therapy in dogs with primary immune-mediated hemo­ lytic anemia, J Vet Intern Med 25:71, 2011. Moore KE et al: Retrospective study of streptokinase administra­ tion in 46 cats with arterial thromboembolism, J Vet Emerg Crit Care 10:245, 2000. Nelson OL, Andreasen C: The utility of plasma D-dimer to identify thromboembolic disease in dogs, J Vet Intern Med 17:830, 2003. Olsen LH et al: Increased platelet aggregation response in Cavalier King Charles Spaniels with mitral valve prolapse, J Vet Intern Med 15:209, 2001. Ralph AG et al: Spontaneous echocardiographic contrast in three dogs, J Vet Emerg Crit Care (San Antonio) 21:158, 2011. Respess M et al: Portal vein thrombosis in 33 dogs: 1998-2011, J Vet Intern Med 26:230, 2012. Schermerhorn TS, Pembleton-Corbett JR, Kornreich B: Pulmonary thromboembolism in cats, J Vet Intern Med 18:533, 2004. Smith CE et al: Use of low molecular weight heparin in cats: 57 cases (1999-2003), J Am Vet Med Assoc 225:1237, 2004. Smith SA et al: Arterial thromboembolism in cats: acute crisis in 127 cases (1992-2001) and long-term management with lowdose aspirin in 24 cases, J Vet Intern Med 17:73, 2003. Smith SA, Tobias AH: Feline arterial thromboembolism: an update, Vet Clin North Am: Small Anim Pract 34:1245, 2004.

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Stokol T et al: D-dimer concentrations in healthy dogs and dogs with disseminated intravascular coagulation, Am J Vet Res 61:393, 2000. Stokol T et al: Hypercoagulability in cats with cardiomyopathy, J Vet Intern Med 22:546, 2008. Thompson MF, Scott-Moncrieff JC, Hogan DF: Thrombolytic therapy in dogs and cats, J Vet Emerg Crit Care 11:111, 2001. Van De Wiele CM et al: Antithrombotic effect of enoxaparin in clinically healthy cats: a venous stasis model, J Vet Intern Med 24:185, 2010.

Van Winkle TJ, Hackner SG, Liu SM: Clinical and pathological features of aortic thromboembolism in 36 dogs, J Vet Emerg Crit Care 3:13, 1993. Winter RL et al: Aortic thrombosis in dogs: presentation, therapy, and outcome in 26 cases, J Vet Cardiol 14:333, 2012. Welch KM et al: Prospective evaluation of tissue plasminogen acti­ vator in 11 cats with arterial thromboembolism, J Feline Med Surg 12:122, 2010.

╇ Drugs Used in Cardiovascular Disorders GENERIC NAME

TRADE NAME

DOG

CAT

Diuretics

Furosemide

Lasix Salix

1-3 (or more) mg/kg q8-24h chronic PO (use lowest effective dose) or (acute therapy) 2-5 (-8) mg/kg q1-4h until RR decreases, then 1-4╯mg/kg q6-12h IV, IM, SC; or 0.6-1╯mg/kg/h CRI (see Chapter 3)

1-2╯mg/kg q8-12h chronic PO (use lowest effective dose) or (acute therapy) up to 4╯mg/kg q1-4h until RR decreases, then q6-12h IV, IM, SC as needed

Spironolactone

Aldactone

0.5-2╯mg/kg PO q(12-)24h

0.5-1╯mg/kg PO q(12-)24h

Chlorothiazide

Diuril

10-40╯mg/kg PO q12-48h (start low)

10-40╯mg/kg PO q12-48hr (start low)

Hydrochlorothiazide

Hydrodiuril

0.5-4╯mg/kg PO q12-48h (start low)

0.5-2╯mg/kg PO q12-48h (start low)

Angiotensin-Converting Enzyme Inhibitors

Enalapril

Enacard Vasotec

0.5╯mg/kg PO q12-24h; or for hypertensive crisis: enalaprilat 0.2╯mg/kg IV, repeat q1-2h as needed

0.25-0.5╯mg/kg PO q(12-)24h

Benazepril

Lotensin

0.25-0.5╯mg/kg PO q(12-)24h

0.25-0.5╯mg/kg PO q(12-)24h

Captopril

Capoten

0.5-2╯mg/kg PO q8-12h

0.5-1.25╯mg/kg PO q(8-)24h

Lisinopril

Prinivil Zestril

0.25-0.5╯mg/kg PO q(12-)24h

0.25-0.5╯mg/kg PO q24h

Fosinopril

Monopril

0.25-0.5╯mg/kg PO q24h

Ramipril

Altace

0.125-0.25╯mg/kg PO q24h

0.125 mg/kg PO q24h

Imidapril

Tanatril, Prilium

0.25╯mg/kg PO q24h

Hydralazine

Apresoline

0.5-2╯mg/kg PO q12h (to 1╯mg/kg initial) For decompensated CHF: 0.5-1╯mg/ kg PO, repeat in 2-3h, then q12h (see Chapter 3); or for hypertensive crisis: 0.2╯mg/kg, IV or IM, q2h as needed

2.5 (up to 10) mg/cat PO q12h

Amlodipine besylate

Norvasc

0.05-0.3 (-0.5) mg/kg PO q(12-)24h

0.625 (-1.25) mg/cat (or 0.1-0.5 mg/kg) PO q24(-12)h

Na+ nitroprusside

Nitropress

0.5-1╯µg/kg/min CRI (initial), to 5-15╯µg/kg/min CRI

Same

Other Vasodilators

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CHAPTER 12â•…â•… Thromboembolic Disease

╇ Drugs Used in Cardiovascular Disorders—cont’d GENERIC NAME

TRADE NAME

Nitroglycerin ointment 2%

Nitrobid Nitrol

Isosorbide dinitrate

DOG

-112 inch q6-8h cutaneously

CAT

-

inch q6-8h cutaneously

1 2

1 1 4 2

Isordil Titradose

0.5-2╯mg/kg PO q(8)-12h

Sildenafil citrate

Viagra

For pulmonary hypertension: 1-2 (to 3) mg/kg q8-12h (see p. 72, Chapter 3 and p. 111, Chapter 5)

Same?

Prazosin

Minipress

0.05-0.2╯mg/kg PO q8-12h

Do not use

Phenoxybenzamine

Dibenzyline

0.25╯mg/kg PO q8-12h or 0.5╯mg/ kg q24h

2.5╯mg/cat PO q8-12h or 0.5╯mg/kg q(12-)24h

Phentolamine

Regitine

0.02-0.1╯mg/kg IV bolus, followed by CRI to effect

Same

0.05-0.1╯mg/kg (up to 3╯mg total) IV (IM, SC)

Same

Acepromazine Positive Inotropic Drugs

Pimobendan

Vetmedin

0.2-0.3╯mg/kg PO q12h

Same, or 1.25╯mg/cat PO q12h

Digoxin

Cardoxin Digitek Lanoxin

Oral: dogs < 22╯kg, 0.0050.008╯mg/kg q12h; dogs > 22╯kg, 0.22╯mg/m2 or 0.003-0.005╯mg/ kg q12h. Decrease by 10% for elixir. Maximum 0.5╯mg/day (0.375╯mg/day for Doberman Pinschers) PO loading dose—1 or 2 doses at twice calculated maintenance IV loading (rarely advised): calculate 0.01-0.02╯mg/kg; give 14 of total dose in slow boluses over 2-4h to effect

Oral: 0.007╯mg/kg (or 14 of 0.125╯mg tab/cat) q48h IV loading (rarely advised): calculate 0.005╯mg/kg; give 12 of total, then 1-2h later give 14 dose bolus as needed

Dobutamine

Dobutrex

1-10 (-20) µg/kg/min CRI (start low)

1-5╯µg/kg/min CRI (start low)

Dopamine

Intropin

1-10╯µg/kg/min CRI (start low)

1-5╯µg/kg/min CRI (start low)

Amrinone

Inocor

1-3╯mg/kg initial bolus, IV; 10-100╯µg/kg/min CRI

Same?

Milrinone

Primacor

50╯µg/kg IV over 10╯min initially; 0.375-0.75╯µg/kg/min CRI (humans)

Same?

Lidocaine

Xylocaine

Initial boluses of 2╯mg/kg slowly IV, up to 8╯mg/kg; or rapid IV infusion at 0.8╯mg/kg/min; if effective, then 25-80╯µg/kg/min CRI

Initial bolus of 0.25-0.5 (or 1) mg/kg slowly IV; can repeat boluses of 0.15-0.25╯mg/kg, up to total of 4╯mg/kg; if effective, 10-40╯µg/kg/min CRI

Procainamide

Pronestyl Pronestyl SR Procan SR

6-10 (up to 20) mg/kg IV over 5-10╯min; 10-50╯µg/kg/min CRI; 6-20 (up to 30) mg/kg IM q4-6h; 10-25╯mg/kg PO q6h (sustained release: q6-8h)

1-2╯mg/kg slowly IV; 10-20╯µg/ kg/min CRI; 7.5-20╯mg/kg IM, PO q(6-)8h

Antiarrhythmic Drugs Class I

Continued

214

PART Iâ•…â•… Cardiovascular System Disorders

╇ Drugs Used in Cardiovascular Disorders—cont’d GENERIC NAME

TRADE NAME

DOG

CAT

Quinidine

Quinidex Extentabs Quinaglute Dura-Tabs Cardioquin

6-20╯mg/kg IM q6h (loading dose 14 to 20╯mg/kg); 6-16╯mg/kg PO q6h; sustained action preps 8-20╯mg/kg PO q8h

6-16╯mg/kg IM, PO q8h

Mexiletine

Mexitil

4-10╯mg/kg PO q8h

Phenytoin

Dilantin

10╯mg/kg slow IV; 20-50╯mg/kg PO q8h

Do not use

Propafenone

Rythmol

2-4 (up to 6) mg/kg PO q8h (start low)

Flecainide

Tambocor

1-5╯mg/kg PO q(8-)12h

Atenolol

Tenormin

0.2-1╯mg/kg PO q12-24h (start low)

6.25-12.5╯mg/cat PO q12-24h

Propranolol

Inderal

IV: initial bolus of 0.02╯mg/kg slowly, up to max. of 0.1╯mg/kg Oral: initial dose of 0.1-0.2╯mg/kg q8h, up to max. of 1╯mg/kg q8h

IV: Same Oral: 2.5 up to 10╯mg/cat q8-12h

Esmolol

Brevibloc

0.1-0.5╯mg/kg IV over 1 minute (loading dose), followed by infusion of 0.025-0.2╯mg/kg/min

Same

Metroprolol

Lopressor

0.1-0.2╯mg/kg initial dose PO q24(-12)h; up to 1╯mg/kg q8(-12)h

Carvedilol

Coreg

0.05╯mg/kg q24h (initial, if cardiac disease) gradually titrate up to 0.2-0.4╯mg/kg PO q12h as tolerated; possibly up to 1.5╯mg/kg PO q12h if needed (see Chapter 3)

(Hypertensive crisis) 0.25╯mg/kg IV over 2 minutes, repeat up to total dose of 3.75╯mg/kg, followed by CRI of 25╯µg/kg/min

Same

Class II

Labetolol

Class III

Sotalol

Betapace

1-3.5 (-5) mg/kg PO q12h

10-20╯mg/cat (or 2-4╯mg/kg) PO q12h

Amiodarone

Cordarone Pacerone

10╯mg/kg PO q12h for 7 days, then 8╯mg/kg PO q24h (lower and higher doses have been used); 3 (to 5) mg/kg slowly (over 10-20 minutes) IV, suggest diphenhydramine pretreatment (can repeat amiodarone but do not exceed 10╯mg/kg in 1 hour)

CHAPTER 12â•…â•… Thromboembolic Disease

215

╇ Drugs Used in Cardiovascular Disorders—cont’d GENERIC NAME

TRADE NAME

DOG

CAT

Class IV

Diltiazem

Cardizem Cardizem-CD Dilacor XR

Oral maintenance: initial dose 0.5╯mg/kg (up to 2+ mg/kg) PO q8h; acute IV for supraventricular tachycardia: 0.15-0.25╯mg/kg over 2-3 minutes IV, can repeat every 15 minutes until conversion or maximum 0.75╯mg/kg; CRI: 2-8 μg/kg/min; oral loading dose: 0.5╯mg/kg PO followed by 0.25╯mg/kg PO q1h to a total of 1.5(-2) mg/kg or conversion. Diltiazem XR: 1.5 to 4(-6) mg/kg PO q12-24h

Same? For hypertrophic cardiomyopathy, 1.5-2.5╯mg/kg (or 7.5-10╯mg/ cat) PO q8h; sustained release preparations: diltiazem (Dilacor) XR, 30╯mg/cat/day (one half of a 60-mg controlled-release tablet within the 240╯mg gelatin capsule), can increase to 60╯mg/day in some cats if necessary; Cardizem-CD, 10╯mg/kg/day (45╯mg/cat ≈105╯mg of Cardizem-CD, or amount that fits into small end of a No. 4 gelatin capsule)

Verapamil

Calan Isoptin

0.02-0.05╯mg/kg slowly IV; can repeat q5 min, up to total of 0.15 (to 0.2) mg/kg; 0.5-2╯mg/kg PO q8h (Note: diltiazem preferred; avoid if myocardial failure)

Initial dose 0.025╯mg/kg slowly IV; can repeat q5 min, up to total of 0.15 (to 0.2) mg/kg; 0.5-1╯mg/kg PO q8h (Note: diltiazem preferred; avoid if myocardial failure)

0.02-0.04╯mg/kg IV, IM, SC; atropine challenge test: 0.04╯mg/ kg IV (see Chapter 4)

Same

Antiarrhythmic Drugs

Atropine

Glycopyrrolate

Robinul

0.005-0.01╯mg/kg IV, IM; 0.010.02╯mg/kg SC

Same

Propantheline Br

Pro-Banthine

0.25-0.5 mg/kg or 3.73-30 mg/dog PO q8-12h

Hyoscyamine

Anaspaz, Levsin

0.003-0.006╯mg/kg PO q8h

Isoproterenol

Isuprel

0.045-0.09╯µg/kg/min CRI

Same

Terbutaline

Brethine Bricanyl

1.25-5╯mg/dog PO q8-12h

1 1 8 4

See Chapter 10 Follow manufacturer’s injection instructions carefully; “alternate” regimen (preferred): 2.5 mg/kg IM for 1 dose, then 1 month later give standard regimen; “standard” regimen: 2.5 mg/kg deep into lumbar muscles q24h for 2 doses

Sympathomimetics

- of 2.5╯mg tab/cat PO q12h initially, up to 12 tab q12h

Drugs for Heartworm Disease Heartworm adulticide

Melarsomine

Immiticide

Continued

216

PART Iâ•…â•… Cardiovascular System Disorders

╇ Drugs Used in Cardiovascular Disorders—cont’d GENERIC NAME

TRADE NAME

DOG

CAT

Heartworm prevention

Ivermectin

Heartgard

0.006-0.012╯mg/kg PO once a month

0.024╯mg/kg PO once a month

Milbemycin oxime

Interceptor

0.5 (to 1) mg/kg PO once a month

2╯mg/kg PO once a month

Selamectin

Revolution

6-12╯mg/kg topically once a month

Same

Moxidectin/ imidacloprid

Advantage Multi

2.5╯mg/kg moxidectin and 10╯mg/ kg imidacloprid topically once a month

1╯mg/kg moxidectin and 10╯ mg/kg imidacloprid topically once a month

Diethylcarbamazine

Filaribits Nemacide

3╯mg/kg (6.6╯mg/kg of 50% citrate) PO once a day

Same

0.5╯mg/kg PO q12h

low dose, 5╯mg/cat q72h; 20-40╯mg/cat 2-3 times a week PO (see Chapter 12)

(1-) 2-4╯mg/kg PO q24h; (oral loading dose, 10╯mg/kg)

18.75 (-37.5?) mg/cat PO q24h; (oral loading dose, 75╯mg/cat)

200-300╯IU/kg IV, followed by 200-250╯IU/kg SC q6-8h for 2-4 days or as needed

200-375╯IU/kg IV, followed by 150-250╯IU/kg SC q6-8h for 2-4 days or as needed

Antithrombotic Agents

Aspirin

Clopidogrel

Plavix

Heparin Na

Dalteparin Na

Fragmin

100(-150) U/kg SC q8-12h (see Chapter 12)

100-150 U/kg SC q(4-)6-12h (see Chapter 12)

Enoxaparin

Lovenox

1(-1.5) mg/kg SC q6-12h

1(-1.5) mg/kg SC q6-12h

CHF, Congestive heart failure; CRI, constant rate infusion; IM, intramuscular; IV, intravenous; PO, by mouth; RR, respiratory rate; SC, subcutaneous.

PART TWO

Respiratory System Disorders Eleanor C. Hawkins

C H A P T E R

13â•…

Clinical Manifestations of Nasal Disease

GENERAL CONSIDERATIONS The nasal cavity and paranasal sinuses have a complex anatomy and are lined by mucosa. Their rostral portion is inhabited by bacteria in health. Nasal disorders are frequently associated with mucosal edema, inflammation, and secondary bacterial infection. They are often focal or multifocal in distribution. These factors combine to make the accurate diagnosis of nasal disease a challenge that can be met only through a thorough, systematic approach. Diseases of the nasal cavity and paranasal sinuses typically cause nasal discharge; sneezing; stertor (i.e., snoring or snorting sounds); facial deformity; systemic signs of illness (e.g., lethargy, inappetence, weight loss); or, in rare instances, central nervous system signs. The most common clinical manifestation is nasal discharge. The general diagnostic approach to animals with nasal disease is included in the discussion of nasal discharge. Specific considerations related to sneezing, stertor, and facial deformity follow. Stenotic nares are discussed in the section on brachycephalic airway syndrome (see Chapter 18). Nasal foreign bodies are mentioned throughout the discussion of nasal disease. Nasal foreign bodies most often enter the nasal cavity through the external nares, although nasal or pharyngeal signs can also be the result of foreign material taken into the mouth and subsequently coughed into the caudal nasopharynx. Plant material is most often the culprit. Blades of grass, grass seeds arranged in heads with stiff bristles (grass awns; Fig. 13-1), and thin, stiff leaves (such as those of juniper bushes and cedar trees) have a physical design that facilitates movement in one direction. Consider running a blade of grass between your fingertips. Usually the grass moves smoothly in one direction but resists movement in the other. Because of this property, attempts to expel the foreign material by coughing or sneezing often cause the material to travel more deeply into the body instead. Nasal foreign bodies are particularly common in the

western United States, where “foxtail” grasses (those with awns) are widespread. Awns can enter the body through any orifice, even through intact skin; the external nares are one common route.

NASAL DISCHARGE Classification and Etiology Nasal discharge is most commonly associated with disease localized within the nasal cavity and paranasal sinuses, although it may also develop with disorders of the lower respiratory tract, such as bacterial pneumonia and infectious tracheobronchitis, or with systemic disorders, such as coagulopathies and systemic hypertension. Nasal discharge is characterized as serous, mucopurulent with or without hemorrhage, or purely hemorrhagic (epistaxis). Serous nasal discharge has a clear, watery consistency. Depending on the quantity and duration of the discharge, a serous discharge may be normal, may be indicative of viral upper respiratory infection, or may precede the development of a mucopurulent discharge. As such, many of the causes of mucopurulent discharge can initially cause serous discharge (Box 13-1). Mucopurulent nasal discharge typically is characterized by a thick, ropey consistency and has a white, yellow, or green tint. A mucopurulent nasal discharge implies inflammation. Most intranasal diseases result in inflammation and secondary bacterial infection, making this sign a common presentation for most nasal diseases. Potential etiologies include infectious agents, foreign bodies, neoplasia, polyps, and extension of disease from the oral cavity (see Box 13-1). If mucopurulent discharge is present in conjunction with signs of lower respiratory tract disease, such as cough, respiratory distress, or auscultable crackles, the diagnostic emphasis is initially on evaluation of the lower airways and pulmonary parenchyma. Hemorrhage may be associated with muco� purulent exudate from any etiology, but significant and 217

218

PART IIâ•…â•… Respiratory System Disorders

  BOX 13-1â•… Differential Diagnoses for Nasal Discharge in Dogs and Cats Serous Discharge

Normal Viral infection Early sign of etiology of mucopurulent discharge Mucopurulent Discharge with or without Hemorrhage

FIG 13-1â•…

Typical grass awn. Seed heads from “foxtail” grasses have stiff bristles that facilitate movement of the awns in one direction and make it difficult for the awns to be expelled from the body. (Courtesy Lynelle R. Johnson.)

prolonged bleeding in association with mucopurulent discharge is usually associated with neoplasia or mycotic infections. Persistent pure hemorrhage (epistaxis) can result from trauma, local aggressive disease processes (e.g., neoplasia, mycotic infections), systemic bleeding disorders, or systemic hypertension. Systemic hemostatic disorders that can cause epistaxis include thrombocytopenia, thrombocytopathies, von Willebrand disease, rodenticide toxicity, and vasculitides. Ehrlichiosis and Rocky Mountain spotted fever can cause epistaxis through several of these mechanisms. Nasal foreign bodies may cause hemorrhage after entry into the nasal cavity, but the bleeding tends to subside quickly. Bleeding can also occur after aggressive sneezing from any cause. Diagnostic Approach A complete history and physical examination can be used to prioritize the differential diagnoses for each type of nasal discharge (see Box 13-1). Acute and chronic diseases are defined by obtaining historical information regarding the onset of signs and by evaluating the overall condition of the animal. Acute processes, such as foreign bodies or acute feline viral infections, often result in a sudden onset of signs, including sneezing, while the animal’s body condition is excellent. In chronic processes, such as mycotic infections or neoplasia, signs are present over a long period and the overall body condition can be deleteriously affected. A history of gagging, retching, or reverse sneezing may indicate masses, foreign bodies, or exudate in the caudal nasopharynx. Nasal discharge is characterized as unilateral or bilateral on the basis of both historical and physical examination findings. When nasal discharge is apparently unilateral, a cold microscope slide may be held close to the external nares to determine the patency of the side of the nasal cavity without discharge. Condensation will not be visible in front

Viral infection Feline herpesvirus (rhinotracheitis virus) Feline calicivirus Canine influenza virus Bacterial infection (usually secondary) Fungal infection Aspergillus Cryptococcus Penicillium Rhinosporidium Nasal parasites Pneumonyssoides Capillaria (Eucoleus) Foreign body Neoplasia Carcinoma Sarcoma Malignant lymphoma Nasopharyngeal polyp Extension of oral disease Tooth root abscess Oronasal fistula Deformed palate Allergic rhinitis Feline chronic rhinosinusitis Canine chronic/lymphoplasmacytic rhinitis Pure Hemorrhagic Discharge (Epistaxis)

Nasal disease Acute trauma Acute foreign body Neoplasia Fungal infection Less commonly, other etiologies as listed for mucopurulent discharge Systemic disease Clotting disorders • Thrombocytopenia • Thrombocytopathy • Coagulation defect Vasculitis Hyperviscosity syndrome Polycythemia Systemic hypertension

of the naris if airflow is obstructed, which suggests that the disease is actually bilateral. Although any bilateral process can cause signs from one side only and unilateral disease can progress to involve the opposite side, some generalizations can be made. Systemic disorders and infectious diseases tend to involve both sides of the nasal cavity, whereas foreign bodies, polyps, and tooth root abscessation tend to cause unilateral discharge. Neoplasia initially may cause unilateral discharge that later becomes bilateral after destruction of the nasal septum. Ulceration of the nasal plane is highly suggestive of a diagnosis of nasal aspergillosis (Fig. 13-2). Polypoid masses protruding from the external nares in the dog are typical of rhinosporidiosis, and in the cat they are typical of cryptococcosis. A thorough assessment of the head, including facial symmetry, teeth, gingiva, hard and soft palate, mandibular lymph nodes, and eyes, should be performed. Mass lesions invading beyond the nasal cavity can cause deformity of facial bones or the hard palate, exophthalmos, or inability to retropulse the eye. Pain on palpation of the nasal bones is suggestive of aspergillosis. Gingivitis, dental calculi, loose teeth, or pus in the gingival sulcus should raise an index of suspicion for oronasal fistulae or tooth root abscess, especially if unilateral nasal discharge is present. Foci of inflammation and folds of hyperplastic gingiva in the dorsum of the mouth should be probed for oronasal fistulae. A normal examination of the oral cavity does not rule out oronasal fistulae or tooth root abscess. The hard and soft palates are examined for deformation, erosions, or congenital defects such as clefts or hypoplasia. Mandibular lymph node enlargement suggests active inflammation or neoplasia, and fine-needle aspirates of enlarged or firm nodes are evaluated for organisms, such as Cryptococcus, and neoplastic cells (Fig. 13-3). A fundic

CHAPTER 13â•…â•… Clinical Manifestations of Nasal Disease

examination should always be performed because active chorioretinitis can occur with cryptococcosis, ehrlichiosis, and malignant lymphoma (Fig. 13-4). Retinal detachment can occur with systemic hypertension or mass lesions extending into the bony orbit. With epistaxis, identification of petechiae or hemorrhage in other mucous membranes, skin,

FIG 13-3â•…

Photomicrograph of fine-needle aspirate of a cat with facial deformity. Identification of cryptococcal organisms provides a definitive diagnosis for cats with nasal discharge or facial deformity. Organisms can often be found in swabs of nasal discharge, fine-needle aspirates of facial masses, or fine-needle aspirates of enlarged mandibular lymph nodes. The organisms are variably sized, ranging from about 3 to 30╯µm in diameter, with a wide capsule and narrow-based budding. They may be found intracellularly or extraÂ� cellularly.

FIG 13-4â•… FIG 13-2â•…

Depigmentation and ulceration of the planum nasale are suggestive of nasal aspergillosis. The visible lesions usually extend from one or both nares and are most severe ventrally. This dog has unilateral depigmentation and mild ulceration.

219

Fundic examination can provide useful information in animals with signs of respiratory tract disease. This fundus from a cat with chorioretinitis caused by cryptococcosis has a large, focal, hyporeflective lesion in the area centralis. Smaller regions of hyporeflectivity were also seen. The optic disk can be seen in the upper left-hand corner of the photograph. (Courtesy M. Davidson, North Carolina State University, Raleigh, NC.)

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ocular fundus, feces, or urine supports a systemic bleeding disorder. Note that melena may be present as a result of swallowing of blood from the nasal cavity. Diagnostic tests that should be considered for a dog or cat with nasal discharge are presented in Box 13-2. The signalment, history, and physical examination findings dictate in part which diagnostic tests are ultimately required to establish the diagnosis. As a general rule, less invasive diagnostic tests are performed initially. A complete blood count (CBC) with platelet count, a coagulation panel (i.e., activated clotting time or prothrombin and partial thromboplastin times), buccal mucosal bleeding time, and arterial blood pressure should be evaluated in dogs and cats with epistaxis. Von Willebrand factor assays are performed in purebred dogs with epistaxis and in dogs with prolonged mucosal bleeding times. Determination of Ehrlichia spp. and Rocky Mountain spotted fever titers are indicated for dogs with epistaxis in regions of the country where potential exposure to these rickettsial agents exists. Testing for Bartonella spp. is also considered. Testing for feline immunodeficiency virus (FIV) and feline leukemia virus (FeLV) should be performed in cats with chronic nasal discharge and potential exposure. Cats infected with FeLV may be predisposed to chronic infection with herpesvirus or calicivirus,

whereas those with FIV may have chronic nasal discharge without concurrent infection with these upper respiratory viruses. Most animals with intranasal disease have normal thoracic radiographs. However, thoracic radiographs may be useful in identifying primary bronchopulmonary disease, pulmonary involvement with cryptococcosis, and rare metastases from neoplastic disease. They may also serve as a useful preanesthetic screening test for animals that will require nasal imaging, rhinoscopy, and nasal biopsy. Cytologic evaluation of superficial nasal swabs may identify cryptococcal organisms in cats (see Fig. 13-3). Nonspecific findings include proteinaceous background, moderate to severe inflammation, and bacteria. Tests to identify herpesvirus and calicivirus infections may be performed in cats with acute and chronic rhinitis. These tests are most useful in evaluating cattery problems rather than the condition of an individual cat (see Chapter 15). Fungal titer determinations are available for aspergillosis in dogs and cryptococcosis in dogs and cats. The test for aspergillosis detects antibodies in the blood. A single positive test result strongly suggests active infection by the organism; however, a negative titer does not rule out the disease. In either case, the result of the test must be interpreted in

  BOX 13-2â•… General Diagnostic Approach to Dogs and Cats with Chronic Nasal Discharge Phase I (Noninvasive Testing)

ALL PATIENTS

DOGS

CATS

DOGS AND CATS WITH HEMORRHAGE

History Physical examination Funduscopic examination Thoracic radiographs

Aspergillus titer

Nasal swab cytologic evaluation (cryptococcosis) Cryptococcal antigen titer Viral testing Feline leukemia virus Feline immunodeficiency virus ± Herpesvirus ± Calicivirus

Complete blood count Platelet count Coagulation times Buccal mucosal bleeding time Tests for tick-borne diseases (dogs) Arterial blood pressure von Willebrand factor assay (dogs)

Phase II—All Patients (General Anesthesia Required)

Nasal radiography or computed tomography (CT) Oral examination Rhinoscopy: external nares and nasopharynx Nasal biopsy/histologic examination Deep nasal culture Fungal Bacterial (significance of growth is uncertain) Phase III—All Patients (Referral Usually Required)

CT (if not previously performed) or magnetic resonance imaging (MRI) Frontal sinus exploration (if involvement identified by CT, MRI, or radiography) Phase IV—All Patients (Consider Referral)

Phase II repeated using CT or MRI Exploratory rhinotomy with turbinectomy

conjunction with results of nasal imaging, rhinoscopy, and nasal histology and culture. The blood test of choice for cryptococcosis is the latex agglutination capsular antigen test (LCAT). Because organism identification is usually possible in specimens from infected organs, organism identification is the method of choice for a definitive diagnosis. The LCAT is performed if cryptococcosis is suspected but an extensive search for the organism has failed. The LCAT is also performed in animals with a confirmed diagnosis as a means of monitoring therapeutic response (see Chapter 95). In general, nasal radiography or computed tomography (CT), rhinoscopy, and biopsy are required to establish a diagnosis of intranasal disease in most dogs and cats in which acute viral infection is not suspected. These diagnostic tests are performed with the dog or cat under general anesthesia. Nasal radiographs or CT scans are obtained first, followed by oral examination and rhinoscopy and then specimen collection. This order is recommended because results of radiography or CT and rhinoscopy are often useful in the selection of biopsy sites. In addition, hemorrhage from biopsy sites could obscure or alter radiographic and rhinoscopic detail if the specimen were collected first. In dogs and cats suspected of having acute foreign body inhalation, rhinoscopy is performed first in the hopes of identifying and removing the foreign material. (See Chapter 14 for more detail on nasal radiography, CT, and rhinoscopy.) The combination of radiography, rhinoscopy, and nasal biopsy has a diagnostic success rate of approximately 80% in dogs. Dogs with persistent signs in which a diagnosis cannot be obtained following the assessment described earlier require further evaluation. It is more difficult to evaluate the success rate for cats. High proportions of cats with chronic nasal discharge suffer from feline chronic rhinosinusitis (idiopathic rhinitis) and are diagnosed only through exclusion. Cats are evaluated further only if signs suggestive of another disease are found during any part of the evaluation, or if the clinical signs are progressive or intolerable to the owners. Nasal CT is considered if not performed previously and if a diagnosis has not been made. CT provides excellent visualization of all of the nasal turbinates and may allow identification of small masses that are not visible on nasal radiography or rhinoscopy. CT is also more accurate than nasal radiography in determining the extent of nasal tumors. Magnetic resonance imaging (MRI) may be more accurate than CT in the assessment of soft tissues, such as nasal neoplasia. In the absence of a diagnosis, nasal imaging (preferably CT or MRI), rhinoscopy, and biopsy can be repeated after a 1- to 2-month period. Frontal sinus exploration should be considered in dogs with fluid or tissue opacity in the frontal sinus in the absence of a diagnosis. Aspergillosis, in particular, may be localized within the frontal sinus and may elude diagnosis through rhinoscopy. Exploratory rhinotomy with turbinectomy is the final diagnostic test. Surgical exploration of the nose allows direct

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visualization of the nasal cavity for detecting the presence of foreign bodies, mass lesions, or fungal mats and for obtaining biopsy and culture specimens. The potential benefits of surgery, however, should be weighed against the potential complications associated with rhinotomy and turbinectomy. The Suggested Readings section offers surgical references.

SNEEZING Etiology and Diagnostic Approach A sneeze is an explosive release of air from the lungs through the nasal cavity and mouth. It is a protective reflex that expels irritants from the nasal cavity. Intermittent, occasional sneezing is considered normal. Persistent, paroxysmal sneezing should be considered abnormal. Disorders commonly associated with acute-onset, persistent sneezing include nasal foreign body and feline upper respiratory infection. The canine nasal mite, Pneumonyssoides caninum, and exposure to irritating aerosols are less common causes of sneezing. All nasal diseases considered as differential diagnoses for nasal discharge are also potential causes for sneezing; however, animals with these diseases generally present with nasal discharge as the primary complaint. The owners should be questioned carefully concerning possible recent exposure of the pet to foreign bodies (e.g., rooting in the ground, running through grassy fields), powders, and aerosols or, in cats, exposure to respiratory viruses through new cats or kittens. Sneezing is an acute phenomenon that often subsides with time. A foreign body should not be excluded from the differential diagnoses just because sneezing subsides. In the dog a history of acute sneezing followed by the development of a nasal discharge is suggestive of a foreign body. Other findings may help narrow the list of differential diagnoses. Dogs with foreign bodies or nasal mites may paw at their nose. Foreign bodies are typically associated with unilateral, mucopurulent nasal discharge, although serous or serosanguineous discharge may be present initially. Foreign bodies in the caudal nasopharynx may cause gagging, retching, or reverse sneezing. The nasal discharge associated with reactions to aerosols, powders, or other inhaled irritants is usually bilateral and serous in nature. In cats other clinical signs supportive of a diagnosis of upper respiratory infection, such as conjunctivitis and fever, may be present as well as a history of exposure to other cats or kittens. Dogs in which acute, paroxysmal sneezing develops should undergo prompt rhinoscopic examination (see Chapter 14). With time, foreign material may become covered with mucus or may migrate more deeply into the nasal passages, and any delay in performing rhinoscopy may interfere with identification and removal of foreign bodies. Nasal mites are also identified rhinoscopically. In contrast, cats sneeze more often as a result of acute viral infection rather than a foreign body. Immediate rhinoscopic examination is not indicated unless there has been known exposure

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to a foreign body or the history and physical examination findings do not support a diagnosis of viral upper respiratory infection.

REVERSE SNEEZING Reverse sneezing is a paroxysm of noisy, labored inspiration that can be initiated by nasopharyngeal irritation. Such irritation can be the result of a foreign body located dorsal to the soft palate, or it may be associated with nasopharyngeal inflammation. Foreign bodies usually originate from grass or plant material that is prehended into the oral cavity and that, presumably, is coughed up or migrates into the nasopharyx. Epiglottic entrapment of the soft palate has also been proposed as a cause. Most cases are idiopathic. Small-breed dogs are usually affected, and signs may be associated with excitement or drinking. The paroxysms last only a few seconds and do not significantly interfere with oxygenation. Although these animals usually display this sign throughout their lifetime, the problem rarely progresses. Clients may present a dog with reverse sneeze if they are not familiar with this sign. Their ability to describe the events may be limited, and dogs will rarely exhibit reverse sneeze during an examination. A key historic feature of reverse sneezing is that the dog instantly returns to normal breathing and attitude as soon as the event is over. This immediate return to normal is not characteristic of more serious problems, such as upper airway obstructions. Confirmation that described events indicate reverse sneezing can be obtained by showing the client a videotape of a dog reverse sneezing. Several are available on the web, including on the Small Animal Internal Medicine Service webpage of the North Carolina State University Veterinary Health Complex (www.cvm.ncsu.edu/vhc/). This approach is

A

usually more efficient than having the client try to capture the reverse sneeze by video, although the latter is ideal. A thorough history and physical examination is indicated to identify signs of potential underlying nasal or pharyngeal disorders. Further evaluation is needed if syncope, exercise intolerance, or other signs of respiratory disease are reported, or if reverse sneezing is severe or progressive. In the absence of an underlying disease, treatment is rarely needed for reverse sneezing itself, because episodes are nearly always self-limiting. Some owners report that massaging the neck shortens an ongoing episode, or that administration of antihistamines decreases the frequency and severity of episodes, but controlled studies are lacking.

STERTOR Stertor refers to coarse, audible snoring or snorting sounds associated with breathing. It indicates upper airway obstruction. Stertor is most often the result of pharyngeal disease (see Chapter 16). Intranasal causes of stertor include obstruction caused by congenital deformities, masses, exudate, or blood clots. Evaluation for nasal disease proceeds as described for nasal discharge.

FACIAL DEFORMITY Carnassial tooth root abscess in dogs can result in swelling, often with drainage, adjacent to the nasal cavity and beneath the eye. Excluding dental disease, the most common causes of facial deformity adjacent to the nasal cavity are neoplasia and, in cats, cryptococcosis (Fig. 13-5). Visible swellings can

B FIG 13-5â•…

Facial in this in this of this

deformity characterized by firm swelling over the maxilla in two cats. A, Deformity cat was the result of carcinoma. Notice the ipsilateral blepharospasm. B, Deformity cat was the result of cryptococcosis. A photomicrograph of the fine-needle aspirate swelling is provided in Fig. 13-2.

often be evaluated directly through fine-needle aspiration or punch biopsy (see Fig. 13-3). Further evaluation proceeds as for nasal discharge if such an approach is not possible or is unsuccessful. Suggested Readings Bissett SA et al: Prevalence, clinical features, and causes of epistaxis in dogs: 176 cases (1996-2001), J Am Vet Med Assoc 231:1843, 2007. Demko JL et al: Chronic nasal discharge in cats, J Am Vet Med Assoc 230:1032, 2007.

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Fossum TW: Small animal surgery, ed 4, St Louis, 2013, Elsevier Mosby. Henderson SM: Investigation of nasal disease in the cat: a retrospective study of 77 cases, J Fel Med Surg 6:245, 2004. Pomrantz JS et al: Comparison of serologic evaluation via agar gel immunodiffusion and fungal culture of tissue for diagnosis of nasal aspergillosis in dogs, J Am Vet Med Assoc 203:1319, 2007. Strasser JL et al: Clinical features of epistaxis in dogs: a retrospective study of 35 cases (1999-2002), J Am Anim Hosp Assoc 41:179, 2005.

C H A P T E R

14â•…

Diagnostic Tests for the Nasal Cavity and Paranasal Sinuses NASAL IMAGING Nasal imaging is a key component of the diagnostic assessment of animals with signs of intranasal disease, allowing assessment of bone and soft tissue structures that are not visible by physical examination or rhinoscopy. Nasal radiography, the type of imaging most readily available, is described in some detail. However, computed tomography (CT) provides images that are superior to radiographs in most cases. The role of magnetic resonance imaging (MRI) in the evaluation of canine and feline nasal disease has not been well established, but it likely provides more accurate images of soft tissue than are provided by CT. MRI is not used routinely on account of its limited availability and relatively high expense. Because nasal imaging rarely provides a definitive diagnosis, it is usually followed by rhinoscopy and nasal biopsy. All of these procedures require general anesthesia. Imaging should be performed before, rather than after, these procedures for two reasons: (1) The results of nasal imaging help the clinician direct biopsy instruments to the most abnormal regions, and (2) rhinoscopy and biopsy cause hemorrhage, which obscures soft tissue detail.

RADIOGRAPHY Nasal radiographs are useful for identifying the extent and severity of disease, localizing sites for biopsy within the nasal cavity, and prioritizing the differential diagnoses. The dog or cat must be anesthetized to prevent motion and facilitate positioning. Radiographic abnormalities are often subtle. At least four views should be taken: lateral, ventrodorsal, intraoral, and frontal sinus or skyline. Radiographs of the tympanic bullae are obtained in cats because of the frequent occurrence of otitis media in cats with nasal disease (see Detweiler et╯al, 2006). Determination of involvement of the middle ear is particularly important in cats with suspected nasopharyngeal polyps. Lateral-oblique views or dental films are also indicated in dogs and cats with possible tooth root abscess. The intraoral view is particularly helpful for detecting subtle asymmetry between the left and right nasal cavities. 224

The intraoral view is taken with the animal in sternal recumbency. The corner of a nonscreen film is placed above the tongue as far into the oral cavity as possible, and the radiographic beam is positioned directly above the nasal cavity (Figs. 14-1 and 14-2). The frontal sinus view is obtained with the animal in dorsal recumbency. Adhesive tape can be used to support the body and draw the forelimbs caudally, out of the field. The head is positioned perpendicular to the spine and the table by drawing the muzzle toward the sternum with adhesive tape. Endotracheal tube and anesthetic tubes are displaced lateral to the head to remove them from the field. A radiographic beam is positioned directly above the nasal cavity and frontal sinuses (Figs. 14-3 and 14-4). The frontal sinus view identifies disease involving the frontal sinuses, which in diseases such as aspergillosis or neoplasia may be the only area of disease involvement. The tympanic bullae are best seen with an open-mouth projection in which the beam is aimed at the base of the skull (Figs. 14-5 and 14-6). The bullae are also evaluated individually by lateral-oblique films, offsetting each bulla from the surrounding skull. Nasal radiographs are evaluated for increased fluid density, loss of turbinates, lysis of facial bones, radiolucency at the tips of the tooth roots, and the presence of radiodense foreign bodies (Box 14-1). Increased fluid density can be caused by mucus, exudate, blood, or soft tissue masses such as polyps, tumors, or granulomas. Soft tissue masses may appear localized, but the surrounding fluid often obscures their borders. A thin rim of lysis surrounding a focal density may represent a foreign body. Fluid density within the frontal sinuses may represent normal mucus accumulation caused by obstruction of drainage into the nasal cavity, extension of disease into the frontal sinuses from the nasal cavity, or primary disease involving the frontal sinuses. Loss of the normal fine turbinate pattern in combination with increased fluid density within the nasal cavity can occur with chronic inflammatory conditions of any etiology. Early neoplastic changes can also be associated with an increase in soft tissue density and destruction of the turbinates (see

CHAPTER 14â•…â•… Diagnostic Tests for the Nasal Cavity and Paranasal Sinuses

225

FIG 14-1â•…

Positioning of a dog for intraoral radiographs.

FIG 14-3â•…

Positioning of a dog for frontal sinus radiographs. The endotracheal and anesthetic tubes are displaced laterally in this instance by taping them to an upright metal cylinder.

FIG 14-2â•…

Intraoral radiograph of a cat with carcinoma. Normal fine turbinate pattern is visible on the left side (L) of the nasal cavity and provides a basis for comparison with the right side (R). The turbinate pattern is less apparent on the right side, and an area of turbinate lysis can be seen adjacent to the first premolar.

Figs. 14-2 and 14-4). More aggressive neoplastic changes may include marked lysis or deformation of the vomer and/or facial bones. Multiple, well-defined lytic zones within the nasal cavity and increased radiolucency in the rostral portion of the nasal cavity suggest aspergillosis (Fig. 14-7). The vomer bone may be roughened but is rarely destroyed. Previous traumatic fracture of the nasal bones and secondary osteomyelitis can also be detected radiographically.

FIG 14-4â•…

Frontal sinus view of a dog with a nasal tumor. The left frontal sinus (L) has increased soft tissue density compared with the air-filled sinus on the right side (R).

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  BOX 14-1â•… Radiographic Signs of Common Nasal Diseases* Feline Chronic Rhinosinusitis

Soft tissue opacity within nasal cavity, possibly asymmetric Mild turbinate lysis Soft tissue opacity in frontal sinus(es) Nasopharyngeal Polyp

Soft tissue opacity above soft palate Soft tissue opacity within nasal cavity, usually unilateral Mild turbinate lysis possible Bulla osteitis: soft tissue opacity within bulla, thickening of bone Nasal Neoplasia t t

Soft tissue opacity, possibly asymmetric Turbinate destruction Vomer bone and/or facial bone destruction Soft tissue mass external to facial bones Nasal Aspergillosis

FIG 14-5â•…

Positioning of a cat for open-mouth projection of the tympanic bullae. The beam (arrow) is aimed through the mouth toward the base of the skull. Adhesive tape (t) is holding the head and mandible in position.

Well-defined lucent areas within the nasal cavity Increased radiolucency rostrally Increased soft tissue opacity possibly also present No destruction of vomer or facial bones, although signs often bilateral Vomer bone sometimes roughened Fluid density within the frontal sinus; frontal bones sometimes thickened or moth-eaten Cryptococcosis

Soft tissue opacity, possibly asymmetric Turbinate lysis Facial bone destruction Soft tissue mass external to facial bones Canine Chronic/Lymphoplasmacytic Rhinitis

Soft tissue opacity Lysis of nasal turbinates, especially rostrally Allergic Rhinitis

Increased soft tissue opacity Mild turbinate lysis possible Tooth Root Abscesses

FIG 14-6â•…

Radiograph obtained from a cat with nasopharyngeal polyp using the open-mouth projection demonstrated in Fig. 14-5. The left bulla has thickening of bone and increased fluid density, indicating bulla osteitis and probable extension of the polyp.

COMPUTED TOMOGRAPHY AND MAGNETIC RESONANCE IMAGING CT provides excellent visualization of the nasal turbinates, nasal septum, hard palate, and cribriform plate (Fig. 14-8).

Radiolucency adjacent to tooth roots, commonly apically Foreign Bodies

Mineral and metallic dense foreign bodies readily identified Plant foreign bodies: focal, ill-defined, increased soft tissue opacity Lucent rim around abnormal tissue (rare) *Note that these descriptions represent typical cases and are not specific findings.

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In cats CT is also useful for determining middle ear involvement with nasopharyngeal polyps or other nasal disease. CT is more accurate than conventional radiography in assessing the extent of neoplastic disease insofar as it allows more accurate localization of mass lesions for subsequent biopsy than nasal radiography, and it is instrumental for radiotherapy treatment planning. Determination of the integrity of the cribriform plate is important in treatment planning for nasal aspergillosis. CT may also identify the presence of lesions in animals with undiagnosed nasal disease when other techniques have failed. Typical lesions are as described in Box 14-1. MRI may be more accurate than CT in the assessment of soft tissues, such as nasal neoplasia.

RHINOSCOPY

FIG 14-7â•…

Intraoral radiograph of a dog with nasal aspergillosis. Focal areas of marked turbinate lysis are present on both sides of the nasal cavity. The vomer bone remains intact.

Rhinoscopy allows visual assessment of the nasal cavity through the use of a rigid or flexible endoscope or an otoscopic cone. Rhinoscopy is used to visualize and remove foreign bodies; to grossly assess the nasal mucosa for the presence of inflammation, turbinate erosion, mass lesions, fungal plaques, and parasites; and to aid in the collection of nasal specimens for histopathologic examination and culture. Complete rhinoscopy always includes a thorough examination of the oral cavity and caudal nasopharynx, in addition to visualization of the nasal cavity through the external nares. The extent of visualization depends on the quality of the equipment and the outside diameter of the rhinoscope. A narrow (2- to 3-mm diameter), rigid fiberoptic endoscope provides good visualization through the external nares in

F

E

E

T

T

A FIG 14-8â•…

B

Computed tomography (CT) scans of the nasal cavity of two different dogs at the level of the eyes. A, Normal nasal turbinates and intact nasal septum are present. B, Neoplastic mass is present within the right cavity; it is eroding through the hard palate (white arrow), the frontal bone into the retrobulbar space (small black arrows), and the nasal septum. The tumor also extends into the right frontal sinus. E, Endotracheal tube; F, frontal sinus; T, tongue.

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most patients. Endoscopes without biopsy or suction channels are preferable because of their small outside diameter. Some of these systems are relatively inexpensive. Scopes designed for arthroscopy, cystoscopy, and sexing of birds also work well. In medium-sized to large dogs, a flexible pediatric bronchoscope (e.g., 4-mm outer diameter) can be used. Flexible endoscopes are now available in smaller sizes, similar to small rigid scopes, although they are relatively more expensive and fragile. If an endoscope is not available, the rostral region of the nasal cavity can be examined with an otoscope. Human pediatric otoscopic cones (2- to 3-mm diameter) can be purchased for examining cats and small dogs. General anesthesia is required for rhinoscopy. Rhinoscopy is usually performed immediately after nasal imaging unless a foreign body is strongly suspected. The oral cavity and caudal nasopharynx should be assessed first. During the oral examination the hard and soft palates are visually examined and palpated for deformation, erosions, or defects, and the gingival sulci are probed for fistulae. The caudal nasopharynx is evaluated for the presence of nasopharyngeal polyps, neoplasia, foreign bodies, and strictures (stenosis). Foreign bodies, particularly grass or plant material, are commonly found in this location in cats and occasionally in dogs. The caudal nasopharynx is best visualized with a flexible endoscope that is passed into the oral cavity and retroflexed around the soft palate (Figs. 14-9 through 14-11). Alternatively, the caudal nasopharynx can be evaluated with the aid of a dental mirror, penlight, and spay hook, which is attached to the caudal edge of the soft palate and pulled forward to improve visualization of the area. It may be possible to visualize nasal mites of infected dogs by observing the caudal nasopharynx while flushing anesthetic gases (e.g., isoflurane and oxygen) through the nares. Rhinoscopy must be performed patiently, gently, and thoroughly to maximize the likelihood of identifying gross

FIG 14-10â•…

View of the internal nares obtained by passing a flexible bronchoscope around the edge of the soft palate in a dog with sneezing. A small white object is seen within the left nasal cavity adjacent to the septum. Note that the septum is narrow and the right internal naris is oval in shape and is not obstructed. On removal, the object was found to be a popcorn kernel. The dog had an abnormally short soft palate, and the kernel presumably entered the caudal nasal cavity from the oropharynx.

FIG 14-11â•… FIG 14-9â•…

The caudal nasopharynx is best examined with a flexible endoscope that is passed into the oral cavity and retroflexed 180 degrees around the edge of the soft palate, as shown in this radiograph.

View of the internal nares (thin arrows) obtained by passing a flexible bronchoscope around the edge of the soft palate in a dog with nasal discharge. A soft tissue mass (broad arrow) is blocking the normally thin septum and is partially obstructing the airway lumens. Compare this view with the appearance of the normal septum and the right internal naris in Fig. 14-10.

CHAPTER 14â•…â•… Diagnostic Tests for the Nasal Cavity and Paranasal Sinuses

abnormalities and to minimize the risk of hemorrhage. The more normal side of the nasal cavity is examined first. The tip of the scope is passed through the naris with the tip pointed medially. Each nasal meatus is evaluated, beginning ventrally and working dorsally to ensure visualization should hemorrhage develop during the procedure. Each nasal meatus should be examined as far caudally as the scope can be passed without trauma. Although the rhinoscope can be used to evaluate the large chambers of the nose, many of the small recesses cannot be examined, even with the smallest endoscopes. Thus disease or a foreign body may be missed if only these small recesses are involved. Swollen and inflamed nasal mucosa, hemorrhage caused by the procedure, and the accumulation of exudate and mucus can also interfere with visualization of the nasal cavity. Foreign bodies and masses are frequently coated and effectively hidden by seemingly insignificant amounts of mucus, exudate, or blood. The tenacious material must be removed using a rubber catheter with the tip cut off attached to a suction unit. If necessary, saline flushes can also be used, although resulting fluid bubbles may further interfere with visualization. Some clinicians prefer to maintain continuous saline infusion of the nasal cavity using a standard intravenous administration set attached to a catheter or, if available, the biopsy channel of the rhinoscope. The entire examination is done “under water.” No catheter should ever be passed blindly into the nasal cavity beyond the level of the medial canthus of the eye to avoid entering the cranial vault through the cribriform plate. The clinician must be sure the endotracheal tube cuff is fully inflated and the back of the pharynx is packed with gauze to prevent aspiration of blood, mucus, or saline flush into the lungs. The clinician must be careful not to overinflate the endotracheal tube cuff, which could result in a tracheal tear. The nasal mucosa is normally smooth and pink, with a small amount of serous to mucoid fluid present along the mucosal surface. Potential abnormalities visualized with the rhinoscope include inflammation of the nasal mucosa; mass lesions; erosion of the turbinates (Fig. 14-12, A); mats of fungal hyphae (see Fig. 14-12, B); foreign bodies; and, rarely, nasal mites or Capillaria worms (Fig. 14-13). Differential diagnoses for gross rhinoscopic abnormalities are provided in Box 14-2. The location of any abnormality should be noted, including the meatus involved (common, ventral, middle, dorsal), the medial-to-lateral orientation within the meatus, and the distance caudal from the naris. Exact localization is critical for directing instruments for the retrieval of foreign bodies or nasal biopsy specimens should visual guidance become impeded by hemorrhage or size of the cavity.

FRONTAL SINUS EXPLORATION Occasionally the primary site of disease is the frontal sinuses, most often in dogs with aspergillosis. Boney destruction may be sufficient to allow visualization and sampling by

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A

B FIG 14-12â•…

A, Rhinoscopic view through the external naris of a dog with aspergillosis showing erosion of turbinates and a green-brown granulomatous mass. B, A closer view of the fungal mat shows white, filamentous structures (hyphae).

rhinoscopy through the external naris. However, in cases with evidence of frontal sinus involvement on imaging studies and the absence of a diagnosis through rhinoscopy and biopsy, frontal sinus exploration may be necessary.

NASAL BIOPSY: INDICATIONS AND TECHNIQUES Visualization of a foreign body or nasal parasites during rhinoscopy establishes a diagnosis. For many dogs and cats, however, the diagnosis must be based on cytologic, histologic, and microbiologic evaluation of nasal biopsy specimens. Nasal biopsy specimens should be obtained immediately after nasal imaging and rhinoscopy, while the animal is still anesthetized. These earlier procedures can help localize the lesion, maximizing the likelihood of obtaining material representative of the primary disease process.

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A

B FIG 14-13â•…

Rhinoscopic view through the external naris. A, A single nasal mite is seen in this dog with Pneumonyssoides caninum. B, A thin white worm is seen in this dog with Capillaria (Eucoleus) boehmi.

  BOX 14-2â•… Differential Diagnoses for Gross Rhinoscopic Abnormalities in Dogs and Cats Inflammation (Mucosal Swelling, Hyperemia, Increased Mucus, Exudate)

Nonspecific finding; consider all differential diagnoses for mucopurulent nasal discharge (infectious, inflammatory, neoplastic) Mass

Neoplasia Nasopharyngeal polyp Cryptococcosis Mat of fungal hyphae or fungal granuloma (aspergillosis, penicilliosis, rhinosporidiosis) Turbinate Erosion

Mild Feline herpesvirus Chronic inflammatory process Marked Aspergillosis Neoplasia Cryptococcosis Penicilliosis Fungal Plaques

Aspergillosis Penicilliosis Parasites

Mites: Pneumonyssoides caninum Worms: Capillaria (Eucoleus) boehmi Foreign Bodies

Nasal biopsy techniques include nasal swab, nasal flush, pinch biopsy, and turbinectomy. Fine-needle aspirates can be obtained from mass lesions as described in Chapter 72. Pinch biopsy is the preferred nonsurgical method of specimen collection. It is more likely than nasal swabs or flushes to provide pieces of nasal tissue that extend beneath the superficial inflammation, which is common to many nasal disorders. In addition, the pieces of tissue obtained with this more aggressive method can be evaluated histologically, whereas the material obtained with the less traumatic techniques may be suitable only for cytologic analysis. Histopathologic examination is preferred over cytologic examination in most cases because the marked inflammation that accompanies many nasal diseases makes it difficult to cytologically differentiate primary from secondary inflammation and reactive from neoplastic epithelial cells. Carcinomas can also appear cytologically as lymphoma and vice versa. Regardless of the technique used (except for nasal swab), the cuff of the endotracheal tube should be inflated (avoiding overinflation) and the caudal pharynx packed with gauze sponges to prevent the aspiration of fluid. Intravenous crystalloid fluids (10 to 20╯mL/kg/h plus replacement of estimated blood loss) are recommended during the procedure to counter the hypotensive effects of prolonged anesthesia and blood loss from hemorrhage after biopsy. Blood-clotting capabilities should be assessed before the more aggressive biopsy techniques are performed if there is any history of hemorrhagic exudate or epistaxis or any other indication of coagulopathy.

NASAL SWAB The least traumatic techniques are the nasal swab and nasal flush. Unlike the other collection techniques, nasal swabs can be collected from an awake animal. Nasal swabs

CHAPTER 14â•…â•… Diagnostic Tests for the Nasal Cavity and Paranasal Sinuses

are useful for identifying cryptococcal organisms cytologically and should be collected early in the evaluation of cats with chronic rhinitis. Other findings are generally nonspecific. Exudate immediately within the external nares or draining from the nares is collected using a cottontipped swab. Relatively small swabs are available that can facilitate specimen collection from cats with minimal discharge. The swab is then rolled on a microscope slide. Routine cytologic stains are generally used, although India ink can be applied to reveal cryptococcal organisms (see Chapter 95).

NASAL FLUSH Nasal flush is a minimally invasive technique. A soft catheter is positioned in the caudal region of the nasal cavity via the oral cavity and internal nares, with the tip of the catheter pointing rostrally. With the animal in sternal recumbency and the nose pointed toward the floor, approximately 100╯mL of sterile saline solution is forcibly injected in pulses by syringe. The fluid exiting the external nares is collected in a bowl and can be examined cytologically. Occasionally nasal mites can be identified in nasal flushings. Magnification or placement of dark paper behind the specimen for contrast may be needed to visualize the mites. A portion of fluid can also be filtered through a gauze sponge. Large particles trapped in the sponge can be retrieved and submitted for histopathologic analysis. These specimens are often insufficient for providing a definitive diagnosis. PINCH BIOPSY Pinch biopsy is the author’s preferred method of nasal biopsy. In the pinch biopsy technique, alligator cup biopsy forceps (minimum size, 2 × 3╯mm) are used to obtain pieces of nasal mucosa for histologic evaluation (Fig. 14-14). Fullthickness tissue specimens can be obtained, and guided specimen collection is more easily performed with this technique than with previously described methods. The biopsy

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forceps are passed adjacent to a rigid endoscope and directed to any gross lesions. If a flexible scope is used, biopsy instruments can be passed through the biopsy channel of the endoscope. The resulting specimens are extremely small and may not be of sufficient quality for diagnostic purposes. Larger alligator forceps are preferred. If lesions are not present grossly but are present radiographically or by CT, the biopsy instrument can be guided using the relationship of the lesion to the upper teeth. After the first piece is taken, bleeding will prevent further visual guidance; therefore the forceps are passed blindly to the position identified during rhinoscopic examination (e.g., meatus involved and depth from external naris). If a mass is present, the forceps are passed in a closed position until just before the mass is reached. The forceps are then opened and passed a short distance farther until resistance is felt. Larger forceps, such as a mare uterine biopsy instrument, are useful for collecting large volumes of tissue from medium-sized to large dogs with nasal masses. No forceps should ever be passed into the nasal cavity deeper than the level of the medial canthus of the eye without visual guidance to keep from penetrating the cribriform plate. A minimum of six tissue specimens (using 2 × 3−mm forceps or larger) should be obtained from any lesion. If no localizable lesion is identified radiographically or rhinoscopically, multiple biopsy specimens (usually 6 to 10) are obtained randomly from both sides of the nasal cavity.

TURBINECTOMY Turbinectomy provides the best tissue specimens for histologic examination and allows the clinician to remove abnormal or poorly vascularized tissues, debulk fungal granulomas, and place drains for subsequent topical nasal therapy. Turbinectomy is performed through a rhinotomy incision and is a more invasive technique than those previously described. Turbinectomy is a reasonably difficult surgical procedure that should be considered only when other less invasive

FIG 14-14â•…

Cup biopsy forceps are available in different sizes. To obtain sufficient tissue, a minimum size of 2 × 3╯mm is recommended. The larger forceps are particularly useful for obtaining biopsy specimens from nasal masses in dogs.

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techniques have failed to establish the diagnosis. Potential operative and postoperative complications include pain, excessive hemorrhage, inadvertent entry into the cranial vault, and recurrent nasal infections. Cats may be anorectic postoperatively. Placement of an esophagostomy or gastrostomy tube (see Chapter 30) should be considered if necessary to provide a means for meeting nutritional requirements during the recovery period. (See Suggested Readings in Chapter 13 for information on the surgical procedure.) Complications The major complication associated with nasal biopsy is hemorrhage. The severity of hemorrhage depends on the method used to obtain the biopsy, but even with aggressive techniques the hemorrhage is rarely life threatening. When any technique is used, the floor of the nasal cavity is avoided to prevent damage to major blood vessels. For minor hemorrhage, the rate of administration of intravenous fluids should be increased and manipulations within the nasal cavity should be stopped until the bleeding subsides. Cold saline solution with or without diluted epinephrine (1â•›:â•›100,000) can be gently infused into the nasal cavity. Persistent severe hemorrhage can be controlled by packing the nasal cavity with umbilical tape. The tape must be packed through the nasopharynx as well as through the external nares, or the blood will only be redirected. Similarly, placing swabs or gauze in the external nares serves only to redirect blood caudally. In the rare event of uncontrolled hemorrhage, the carotid artery on the involved side can be ligated without subsequent adverse effects. Rhinotomy should not be attempted. In the vast majority of animals, only time or cold saline infusions are required to control hemorrhage. The fear of severe hemorrhage should not prevent the collection of good-quality tissue specimens. Trauma to the brain is prevented by never passing any object into the nasal cavity beyond the level of the medial canthus of the eye without visual guidance. The distance from the external nares to the medial canthus is noted by holding the instrument or catheter against the face, with the tip at the medial canthus. The level of the nares is marked on the instrument or catheter with a piece of tape or marking pen. The object should never be inserted beyond that mark. Aspiration of blood, saline solution, or exudate into the lungs must be avoided. A cuffed endotracheal tube should be in place during the procedure, and the caudal pharynx should be packed with gauze after visual assessment of the oral cavity and nasopharynx. The cuff should be sufficiently inflated to prevent audible leakage of air during gentle compression of the reservoir bag of the anesthesia machine. Overinflation of the cuff may lead to tracheal trauma or tear. The nose is pointed toward the floor over the end of the examination table, allowing blood and fluid to drip out from the external nares after rhinoscopy and biopsy. Finally, the caudal pharynx is examined during gauze removal and before extubation for visualization of continued accumulation of fluid. Gauze sponges are counted during placement

and then re-counted during removal so that none is inadvertently left behind.

NASAL CULTURES: SAMPLE COLLECTION AND INTERPRETATION Microbiologic cultures of nasal specimens are generally recommended but can be difficult to interpret. Aerobic and anaerobic bacterial cultures, mycoplasmal cultures, and fungal cultures can be performed on material obtained by swab, nasal flush, or tissue biopsy. According to Harvey (1984), the normal nasal flora can include Escherichia coli, Staphylococcus, Streptococcus, Pseudomonas, Pasteurella, and Aspergillus organisms and a variety of other aerobic and anaerobic bacteria and fungi. Thus bacterial or fungal growth from nasal specimens does not necessarily confirm the presence of infection. Cultures should be performed on specimens collected within the caudal nasal cavity of anesthetized patients. Bacterial growth from superficial specimens, such as nasal discharge or swabs inserted into the external nares of unanesthetized patients, is unlikely to be clinically significant. It is difficult for a culture swab to be passed into the caudal nasal cavity without its being contaminated with superficial (insignificant) organisms. Guarded specimen swabs can prevent contamination but are relatively expensive. Alternatively, mucosal biopsies from the caudal nasal cavity can be obtained for culture using sterilized biopsy forceps; the results may be more indicative of true infection than those from swabs because, in theory, the organisms have invaded the tissues. Superficial contamination may still occur. Regardless of the method used, the growth of many colonies of one or two types of bacteria rather than the growth of many different organisms more likely reflects infection. The microbiology laboratory should be asked to report all growth. Otherwise, the laboratory may report only one or two organisms that more often are pathogenic and provide misleading information about the relative purity of the culture. The presence of septic inflammation based on histologic examination of nasal specimens and a positive response to antibiotic therapy support a diagnosis of bacterial infection contributing to clinical signs. Although bacterial rhinitis is rarely a primary disease entity, improvement in nasal discharge may be seen if the bacterial component of the problem is treated; however, the improvement is generally transient unless the underlying disease process can be corrected. Some animals in which a primary disease process is never identified or cannot be corrected (e.g., cats with chronic rhinosinusitis) respond well to long-term antibiotic therapy. Sensitivity data from bacterial cultures considered to represent significant infection may help in antibiotic selection. (See Chapter 15 for further therapeutic recommendations.) The role of Mycoplasma spp. in respiratory tract infections of dogs and cats is still being elucidated. Cultures for

CHAPTER 14â•…â•… Diagnostic Tests for the Nasal Cavity and Paranasal Sinuses

Mycoplasma spp. and treatment with appropriate antibiotics are a consideration for cats with chronic rhinosinusitis. A diagnosis of nasal aspergillosis or penicilliosis requires the presence of several supportive signs, and fungal cultures are indicated whenever fungal disease is one of the differential diagnoses. The growth of Aspergillus or Penicillium organisms is considered along with other clinical data, such as radiographic and rhinoscopic findings, and serologic titers. Fungal growth supports a diagnosis of mycotic rhinitis only when other data also support the diagnosis. The fact that fungal infection occasionally occurs secondary to nasal tumors should not be overlooked during initial evaluation and monitoring of therapeutic response. The sensitivity of fungal culture can be greatly enhanced by collecting a swab or biopsy for culture directly from a fungal plaque or granuloma with rhinoscopic guidance. Suggested Readings Detweiler DA et al: Computed tomographic evidence of bulla effusion in cats with sinonasal disease: 2001-2004, J Vet Intern Med 20:1080, 2006.

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Harvey CE: Therapeutic strategies involving antimicrobial treatment of the upper respiratory tract in small animals, J Am Vet Med Assoc 185:1159, 1984. Harcourt-Brown N: Rhinoscopy in the dog, Part I: anatomy and techniques, In Practice 18:170, 2006. Lefebvre J: Computed tomography as an aid in the diagnosis of chronic nasal disease in dogs, J Small Anim Pract 46:280, 2005. McCarthy TC: Rhinoscopy: the diagnostic approach to chronic nasal disease. In McCarthy TR, editor: Veterinary endoscopy for the small animal practitioner, St Louis, 2005, Saunders, p 137. Saylor DK, Williams JE: Rhinoscopy. In Tams TR, Rawlins CA, editors: Small animal endoscopy, ed 3, 2011, Elsevier Mosby, p 563. Schoenborn WC et al: Retrospective assessment of computed tomographic imaging of feline sinonasal disease in 62 cats, Vet Rad Ultrasound 44:198, 2003.

C H A P T E R

15â•…

Disorders of the Nasal Cavity

FELINE UPPER RESPIRATORY INFECTION Etiology Upper respiratory infections (URIs) are common in cats. Feline herpesvirus (FHV), also known as feline rhinotracheitis virus, and feline calicivirus (FCV) cause nearly 90% of these infections. Bordetella bronchiseptica and Chlamydophila felis (previously known as Chlamydia psittaci) are less commonly involved. Other viruses and Mycoplasmas may play a primary or secondary role, whereas other bacteria are considered secondary pathogens. Cats become infected through contact with actively infected cats, carrier cats, and fomites. Cats that are young, stressed, or immunosuppressed are most likely to develop clinical signs. Infected cats often become carriers of FHV or FCV after resolution of the clinical signs. The duration of the carrier state is not known, but it may last from weeks to years. Bordetella can be isolated from asymptomatic cats, although the effectiveness of transmission of disease from such cats is not known. Clinical Features Clinical manifestations of feline URI can be acute, chronic and intermittent, or chronic and persistent. Acute disease is most common. The clinical signs of acute URI include fever, sneezing, serous or mucopurulent nasal discharge, conjunctivitis and ocular discharge, hypersalivation, anorexia, and dehydration. FHV can also cause corneal ulceration, abortion, and neonatal death, whereas FCV can cause oral ulcerations, mild interstitial pneumonia, or polyarthritis. Rare, short-lived outbreaks of highly virulent strains of calicivirus have been associated with severe upper respiratory disease, signs of systemic vasculitis (facial and limb edema pro� gressing to focal necrosis), and high rates of mortality. Bordetella can cause cough and, in young kittens, pneumonia. Chlamydophila infections are commonly associated with conjunctivitis. Some cats that recover from the acute disease have periodic recurrence of acute signs, usually in association with stressful or immunosuppressive events. Other cats may have chronic, persistent signs, most notably a serous to 234

mucopurulent nasal discharge with or without sneezing. Chronic nasal discharge can presumably result from persistence of an active viral infection or from irreversible damage to turbinates and mucosa by FHV; the latter predisposes the cat to an exaggerated response to irritants and secondary bacterial rhinitis. Unfortunately, correlation between tests to confirm exposure to or the presence of viruses and clinical signs is poor (Johnson et╯al, 2005). Because the role of viral infection in cats with chronic rhinosinusitis is not well understood, cats with chronic signs of nasal disease are discussed in the section on feline chronic rhinosinusitis (see p. 243). Diagnosis Acute URI is usually diagnosed on the basis of history and physical examination findings. Specific tests that are available to identify FHV, FCV, and Bordetella and Chlamydophila organisms include polymerase chain reaction (PCR), virus isolation procedures or bacterial cultures, and serum antibody titers. PCR testing and virus isolation can be performed on pharyngeal, conjunctival, or nasal swabs (using sterile swabs made of cotton) or on tissue specimens such as tonsillar biopsy specimens or mucosal scrapings. Tissue specimens are usually preferred. Specimens are placed in appropriate transport media. Routine cytologic preparations of conjunctival smears can be examined for intracytoplasmic inclusion bodies suggestive of Chlamydophila infection, but these findings are nonspecific. Although routine bacterial cultures of the oropharynx can be used to identify Bordetella, the organism can be found in both healthy and infected cats. Demonstration of rising antibody titers against a specific agent over 2 to 3 weeks suggests active infection. Regardless of the method used, close coordination with the pathology laboratory on specimen collection and handling is recommended for optimal results. Tests to identify specific agents are particularly useful in cattery outbreaks in which the clinician is asked to recommend specific preventive measures. Multiple cats, both with and without clinical signs, should be tested when cattery surveys are performed. Test panels are commercially available to probe specimens for multiple respiratory pathogens by PCR. Specific diagnostic tests are less useful for testing

individual cats because their results do not alter therapy; false-negative results may occur if signs are the result of permanent nasal damage or if the specimen does not contain the agent, and positive results may merely reflect a carrier cat that has a concurrent disease process causing the clinical signs. The exception to this generalization is seen in individual cats with suspected Chlamydophila infection, in which case specific effective therapy can be recommended. Treatment In most cats URI is a self-limiting disease, and treatment of cats with acute signs includes appropriate supportive care. Hydration should be provided and nutritional needs met when necessary. Dried mucus and exudate should be cleaned from the face and nares. The cat can be placed in a steamy bathroom or a small room with a vaporizer for 15 to 20 minutes two or three times daily to help clear excess secretions. Severe nasal congestion is treated with pediatric topical decongestants such as 0.25% phenylephrine or 0.025% oxymetazoline. A drop is gently placed in each nostril daily for a maximum of 3 days. If longer therapy is necessary, the decongestant is withheld for 3 days before another 3-day course is begun to prevent possible rebound congestion after withdrawal of the drug (based on problems with rebound congestion that occurs in people). Another option for prolonged decongestant therapy is to alternate daily the naris treated. Antibiotic therapy to treat secondary infection is indicated in cats with severe clinical signs. The initial antibiotic of choice is ampicillin (22 mg/kg q8h) or amoxicillin (22╯mg/ kg q8h to q12h) given orally, because these agents are often effective, are associated with few adverse reactions, and can be administered to kittens. If Bordetella, Chlamydophila, or Mycoplasma spp. are suspected, doxycycline (5 to 10╯mg/kg q12h given orally and followed by a bolus of water) should be given. Doxycycline should be administered for 42 days in cats infected with Chlamydophila felis or Mycoplasma spp. to eliminate detectable organisms (Hartmann et╯al, 2008). Azithromycin (5 to 10╯mg/kg q24h for 3 days, then q48h, orally) can be prescribed for cats that are difficult to medicate. Cats with FHV infection may benefit from treatment with lysine. It has been postulated that excessive concentrations of lysine may antagonize arginine, a promoter of herpesvirus replication. Lysine (500╯mg/cat q12h), obtained from health food stores, is added to food. Administration of feline recombinant omega interferon or human recombinant α-2b interferon may also be of some benefit in FHV-infected cats (Seibeck et╯al, 2006). Chlamydophila infection should be suspected in cats with conjunctivitis as the primary problem and in cats from catteries in which the disease is endemic. Oral antibiotics are administered for a minimum of 42 days. In addition, chloramphenicol or tetracycline ophthalmic ointment should be applied at least three times daily and continued for a minimum of 14 days after signs have resolved. Corneal ulcers resulting from FHV are treated with topical antiviral drugs, such as trifluridine, idoxuridine, or

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adenine arabinoside. One drop should be applied to each affected eye five to six times daily for no longer than 2 to 3 weeks. Routine ulcer management is also indicated. Tetracycline or chloramphenicol ophthalmic ointment is administered two to four times daily. Topical atropine is used for mydriasis as needed to control pain. Treatment is continued for 1 to 2 weeks after epithelialization has occurred. Topical and systemic corticosteroids are contraindicated in cats with acute URI or ocular manifestations of FHV infection. They can prolong clinical signs and increase viral shedding. Treatment of cats with chronic signs is discussed on p. 244. Prevention in the Individual Pet Cat Prevention of URI in all cats is based on avoiding exposure to the infectious agents (e.g., FHV, FCV, Bordetella and Chlamydophila organisms) and strengthening immunity against infection. Most household cats are relatively resistant to prolonged problems associated with URIs, and routine health care with regular vaccination using a subcutaneous product is adequate. Vaccination decreases the severity of clinical signs resulting from URIs but does not prevent infection. Owners should be discouraged from allowing their cats to roam freely outdoors. Subcutaneous modified-live virus vaccines for FHV and FCV are used for most cats and are available in combination with panleukopenia vaccine. These vaccines are convenient to administer, do not result in clinical signs when used correctly, and provide adequate protection for cats that are not heavily exposed to these viruses. These vaccines are not effective in kittens while maternal immunity persists. Kittens are usually vaccinated beginning at 6 to 10 weeks of age and again in 3 to 4 weeks. At least two vaccines must be given initially, with the final vaccine administered after the kitten is 16 weeks old. A booster vaccination is recommended 1 year after the final vaccine in the initial series. Subsequent booster vaccinations are recommended every 3 years, unless the cat has increased risk of exposure to infection. A study by Lappin et╯al (2002) indicates that detection of FHV and FCV antibodies in the serum of cats is predictive of susceptibility to disease and therefore may be useful in determining the need for revaccination. Queens should be vaccinated before breeding. Subcutaneous modified-live vaccines for FHV and FCV are safe but can cause disease if introduced into the cat by the normal oronasal route of infection. The vaccine should not be aerosolized in front of the cat. Vaccine inadvertently left on the skin after injection should be washed off immediately before the cat licks the area. Modified-live vaccines should not be used in pregnant queens. Killed products are available for FHV and FCV that can be used in pregnant queens. Killed vaccines have also been recommended for cats with feline leukemia virus (FeLV) or feline immunodeficiency virus (FIV) infection. Modified-live vaccines for FHV and FCV are also available for intranasal administration. Signs of acute URI occasionally occur after vaccination. Attention should be paid to

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ensure that panleukopenia is included in the intranasal product or that a panleukopenia vaccine is administered subcutaneously. Vaccines against Bordetella or Chlamydophila are recommended for use only in catteries or shelters where these infections are endemic. Infections with Bordetella or Chlamydophila are less common than FHV and FCV infection, and disease resulting from Bordetella infections occurs primarily in cats housed in crowded conditions. Furthermore, these diseases can be effectively treated with antibiotics. Prognosis The prognosis for cats with acute URI is good. Chronic disease does not develop in most pet cats.

BACTERIAL RHINITIS Acute bacterial rhinitis caused by Bordetella bronchiseptica occurs occasionally in cats (see the section on feline upper respiratory infection) and rarely in dogs (see the section on canine infectious tracheobronchitis in Chapter 21). It is possible that Mycoplasma spp. and Streptococcus equi, subsp. zooepidemicus, can act as primary nasal pathogens. In the vast majority of cases, bacterial rhinitis is a secondary complication and not a primary disease process. Bacterial rhinitis occurs secondarily to almost all diseases of the nasal cavity. The bacteria that inhabit the nasal cavity in health are quick to overgrow when disease disrupts normal mucosal defenses. Antibiotic therapy often leads to clinical improvement, but the response is usually temporary. Therefore management of dogs and cats with suspected bacterial rhinitis should include a thorough diagnostic evaluation for an underlying disease process, particularly when signs are chronic.

FIG 15-1â•…

A photomicrograph of a slide prepared from a nasal swab of a patient with chronic mucopurulent discharge shows the typical findings of mucus, neutrophilic inflammation, and intracellular and extracellular bacteria. These findings are not specific and generally reflect secondary processes.

Diagnosis Most dogs and cats with bacterial rhinitis have mucopurulent nasal discharge. No clinical signs are pathognomonic for bacterial rhinitis, and it is difficult to make a definitive diagnosis because of the diverse flora in the normal nasal cavity (see Chapter 14). Microscopic evidence of neutrophilic inflammation and bacteria is a nonspecific finding in the majority of animals with nasal signs (Fig. 15-1). Bacterial cultures of swabs or nasal mucosal biopsy specimens collected deep within the nasal cavity can be performed. The growth of many colonies of only one or two organisms may represent significant infection. Growth of many different organisms or small numbers of colonies probably represents normal flora. The microbiology laboratory should be requested to report all growth. Specimens for Mycoplasma cultures should be placed in appropriate transport media for culture using specific isolation methods. Beneficial response to antibiotic therapy is often used to support a diagnosis of bacterial involvement.

is believed to be significant, sensitivity information can be used in selecting antibiotics. Anaerobic organisms may be involved. Broad-spectrum oral antibiotics that may be effective include amoxicillin (22╯mg/kg q8-12h), clindamycin (5.5 to 11╯mg/kg q12h), and trimethoprim-sulfadiazine (15╯mg/kg q12h). Doxycycline (5 to 10╯mg/kg q12h, followed by a bolus of water) or chloramphenicol is often effective against Bordetella and Mycoplasma organisms. For acute infection or in cases in which the primary etiology (e.g., foreign body, diseased tooth root) has been eliminated, antibiotics are administered for 7 to 10 days. Chronic infections require prolonged treatment. Antibiotics are administered initially for 1 week. If a beneficial response is seen, the drug is continued for a minimum of 4 to 6 weeks. If signs recur after discontinuation of drug after 4 to 6 weeks, the same antibiotic is reinstituted for even longer periods. If no response is seen after the initial week of treatment, the drug should be discontinued. Another antibiotic can be tried, although further evaluation for another, as yet unidentified, primary disorder should be pursued. Further diagnostic evaluation is particularly warranted in dogs because, compared with cats, they less frequently have idiopathic disease. Frequent stopping and starting of different antibiotics every 7 to 14 days is not recommended and may predispose the animal to the growth of resistant gram-negative infections.

Treatment The bacterial component of nasal disease is treated with antibiotic therapy. If growth obtained by bacterial culture

Prognosis Bacterial rhinitis is usually responsive to antibiotic therapy. However, long-term resolution of signs depends on the

identification and correction of any underlying disease process.

NASAL MYCOSES CRYPTOCOCCOSIS Cryptococcus neoformans is a fungal agent that infects cats and, less commonly, dogs. It most likely enters the body through the respiratory tract and, in some animals, may disseminate to other organs. In cats clinical signs usually reflect infection of the nasal cavity, central nervous system (CNS), eyes, or skin and subcutaneous tissues. In dogs signs of CNS involvement are most common. The lungs are commonly infected in both species, but clinical signs of lung involvement (e.g., cough, dyspnea) are rare. Clinical features, diagnosis, and treatment of cryptococcosis are discussed in Chapter 95. ASPERGILLOSIS Aspergillus fumigatus is a normal inhabitant of the nasal cavity in many animals. In some dogs and, rarely, cats, it becomes a pathogen. The mold form of the organism can develop into visible fungal plaques that invade the nasal mucosa (“fungal mats”) and fungal granulomas. An animal that develops aspergillosis may have another nasal condition such as neoplasia, foreign body, prior trauma, or immune deficiency that predisposes the animal to secondary fungal infection. Most often no underlying disease is identified. Excessive exposure to Aspergillus organisms may explain the frequent occurrence of disease in otherwise healthy animals. Another type of fungus, Penicillium, can cause signs similar to those of aspergillosis. Clinical Features Aspergillosis can cause chronic nasal disease in dogs of any age or breed but is most common in young male dogs. Nasal infection is rare in cats. The discharge can be mucoid, mucopurulent with or without hemorrhage, or purely hemorrhagic. The discharge can be unilateral or bilateral. Sneezing may be reported. Features that are highly suggestive of aspergillosis are sensitivity to palpation of the face or depigmentation and ulceration of the external nares (see Fig. 13-2). Lung involvement is not expected. Systemic aspergillosis in dogs is generally caused by Aspergillus terreus and other Aspergillus spp. rather than A. fumigatus. It is an unusual, generally fatal disease that occurs primarily in German Shepherd Dogs. Nasal signs are not reported. Diagnosis No single test result is diagnostic for infection with aspergillosis. The diagnosis is based on the cumulative findings of a comprehensive evaluation of a dog with appropriate clinical signs. As aspergillosis can be an opportunistic infection, underlying nasal disease must also be considered.

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Radiographic signs of aspergillosis include well-defined lucent areas within the nasal cavity and increased radiolucency rostrally (see Fig. 14-7). Typically no destruction of the vomer or facial bones occurs, although the bones may appear roughened. However, destruction of these bones or the cribriform plate may occur in dogs with advanced disease. Increased fluid opacity may be present. Fluid opacity within the frontal sinus can represent a site of infection or mucus accumulation from obstructed drainage. In some patients the frontal sinus is the only site of infection. Rhinoscopic abnormalities include erosion of nasal turbinates and fungal plaques, which appear as white-to-green plaques of mold on the nasal mucosa (see Fig. 14-12). Failure to visualize these lesions does not rule out aspergillosis. Confirmation that presumed plaques are indeed fungal hyphae can be achieved by cytology (Fig. 15-2) and culture of material collected by biopsy or swab under visual guidance. During rhinoscopy, plaques are mechanically debulked by scraping or vigorous flushing to increase the efficacy of topical treatment. Invading Aspergillus organisms can generally be seen histologically in biopsy specimens of affected nasal mucosa after routine staining techniques, although special staining can be performed to identify subtle involvement. Neutrophilic, lymphoplasmacytic, or mixed inflammation is usually also present. Multiple biopsy specimens should be obtained because the mucosa is affected multifocally rather than diffusely. Best results are obtained when mucosa adjacent to a visible fungus is sampled. Results of fungal cultures are difficult to interpret, unless the specimen is obtained from a visualized plaque. The organism can be found in the nasal cavity of normal animals, and false-negative culture results can also occur. A positive culture, in conjunction with other appropriate clinical and diagnostic findings, supports the diagnosis. Positive serum antibody titers also support a diagnosis of infection. Although titers provide indirect evidence of infection, animals with Aspergillus organisms as a normal nasal inhabitant do not usually develop measurable antibodies

FIG 15-2â•…

Branching hyphae of Aspergillus fumigatus from a swab of a visualized fungal plaque.

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against the organism. Pomerantz et╯al (2007) found that serum antibodies had a sensitivity of 67%, a specificity of 98%, a positive predictive value of 98%, and a negative predictive value of 84% for the diagnosis of nasal aspergillosis. Treatment Topical treatment is currently recommended for nasal aspergillosis, after debridement of fungal plaques. Oral itraconazole is recommended for patients with extension of disease beyond the nasal cavity and frontal sinuses. Oral therapy is simpler to administer than topical therapy but appears to be somewhat less successful, has potential systemic side effects, and requires prolonged treatment. Itraconazole is administered orally at a dose of 5╯mg/kg every 12 hours and must be continued for 60 to 90 days or longer. Some clinicians give terbinafine concurrently. (See Chapter 95 for a complete discussion of these drugs.) Successful topical treatment of aspergillosis was originally documented with enilconazole administered through tubes placed surgically into both frontal sinuses and both sides of the nasal cavity. The drug was administered through the tubes twice daily for 7 to 10 days. Subsequently, it was discovered that the over-the-counter drug clotrimazole was equally efficacious when infused through surgically placed tubes over a 1-hour period (70% success with a single treatment; Mathews et╯al, 1996). During 1-hour infusion, the dogs were kept under anesthesia and the caudal nasopharynx and external nares were packed to allow filling of the nasal cavity. It has since been demonstrated that good distribution of the drug can be achieved using a noninvasive technique (discussed in the next paragraphs). In a full review of the literature, success rate following a single topical treatment was not statistically associated with drug (enilconazole or clotrimazole) or method of application (Sharman et╯al, 2010). When all reports are considered, the single treatment response rate was only 46%. As a result, the following adjunctive treatments are currently recommended in addition to noninvasive clotrimazole soaks. Visible fungal plaques are aggressively debrided during rhinoscopy immediately before topical therapy. In dogs with frontal sinus involvement, debridement is performed and clotrimazole cream is packed into the sinuses. All dogs are reevaluated 2 to 3 weeks after treatment. Rhinoscopy, debridement, and topical treatment are repeated if signs persist. In the previously mentioned report (Sharman et╯al, 2010), 70% of dogs recovered after receiving multiple treatments. For noninvasive clotrimazole treatment, the animal is anesthetized and oxygenated through a cuffed endotracheal tube. The dog is positioned in dorsal recumbency with the nose pulled down parallel with the table (Figs. 15-3 and 15-4). For a large-breed dog, a 24F Foley catheter with a 5-mL balloon is passed through the oral cavity, around the soft palate, and into the caudal nasopharynx such that the bulb is at the junction of the hard and soft palates. The bulb is inflated with approximately 10╯ mL of air to ensure a snug fit. A laparotomy sponge is inserted within the oropharynx, caudal to the balloon and ventral to the

soft palate, to help hold the balloon in position and to further obstruct the nasal pharynx. Additional laparotomy sponges are packed carefully into the back of the mouth around the tracheal tube to prevent any drug that might leak past the nasopharyngeal packing from reaching the lower airways. A 10F polypropylene urinary catheter is passed into the dorsal meatus of each nasal cavity to a distance approximately midway between the external naris and the medial canthus of the eye. The correct distance is marked on the catheters with tape to prevent accidental insertion of the catheters too far during the procedure. A 12F Foley catheter with a 5-mL balloon is passed adjacent to the polypropylene catheter into each nasal cavity. The cuff is inflated and pulled snugly against the inside of the naris. A small suture is placed across each naris lateral to the catheter to prevent balloon migration. A gauze sponge is placed between the endotracheal tube and the incisive ducts behind the upper incisors to minimize leakage. A solution of 1% clotrimazole is administered through the polypropylene catheters. Approximately 30╯mL is used for each side in a typical retriever-size dog. Each Foley catheter is checked for filling during the initial infusion and is then clamped when clotrimazole begins to drip from the catheter. The solution is viscous, but excessive pressure is not required for infusion. Additional clotrimazole is administered during the next hour at a rate that results in approximately 1 drop every few seconds from each external naris. In dogs of the size described, a total of approximately 100 to 120╯mL will be used. After the initial 15 minutes, the head is tilted slightly to one side and then the other for 15 minutes each and then back into dorsal recumbency for 15 minutes. After this hour of contact time, the dog is rolled into sternal recumbency with the head hanging over the end of the table and the nose pointing toward the floor. The catheters are removed from the external nares, and the clotrimazole and resulting mucus are allowed to drain. Drainage will usually subside in 10 to 15 minutes. A flexible suction tip may be used to expedite this process. The laparotomy pads are then carefully removed from the nasopharynx and oral cavity and are counted to ensure that all are retrieved. The catheter in the nasopharynx is removed. Any drug within the oral cavity is swabbed or suctioned. Two potential complications of clotrimazole treatment are aspiration pneumonia and meningoencephalitis. Meningoencephalitis is generally fatal and results when clotrimazole and its carrier, polyethylene glycol (PEG), make contact with the brain through a compromised cribriform plate. It is difficult to determine the integrity of the cribriform plate before treatment without the aid of computed tomography (CT) or magnetic resonance imaging (MRI), although marked radiographic changes in the caudal nasal cavity should increase concern. Fortunately, complications are not common. Some dogs have a persistent nasal discharge after treatment for aspergillosis. Most often the discharge indicates

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E

FIG 15-3â•…

Dog with nasal mycotic infection prepared for 1-hour soak with clotrimazole. A cuffed endotracheal tube is in place (E). A 24F Foley catheter (broad arrow) is in the caudal nasopharynx. A 12F Foley catheter (black arrowheads) is obstructing each nostril. A 10F polypropylene catheter (red arrowheads) is placed midway into each dorsal meatus for infusion of the drug. Laparotomy sponges are used to further pack the caudal nasopharynx, around the tracheal tube and the caudal oral cavity. et npf

nf hp s

ic

sp

cp

mfs rfs

ifs

FIG 15-4â•…

Schematic diagram of a cross section of the head of a dog prepared for a 1-hour soak with clotrimazole. et, Endotracheal tube; npf, Foley catheter placed in caudal nasopharynx; s, pharyngeal sponges; ic, polypropylene infusion catheter; nf, rostral Foley catheter obstructing nostril; hp, hard palate; sp, soft palate; cp, cribriform plate; rfs, rostral frontal sinus; mfs, medial frontal sinus; lfs, lateral frontal sinus. (Reprinted with permission from Mathews KG et╯al: Computed tomographic assessment of noninvasive intranasal infusions in dogs with fungal rhinitis, Vet Surg 25:309, 1996.)

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incomplete elimination of the fungal infection. However, some dogs may have secondary bacterial rhinitis or sensitivity to inhaled irritants because of the damaged nasal anatomy and mucosa. If recurrence of fungal infection cannot be found and signs persist despite repeated treatments, dogs are managed as described in the section on canine chronic/lymphoplasmacytic rhinitis in this chapter. Prognosis The prognosis for dogs with nasal aspergillosis has improved with debridement and repeated topical treatments. For most animals a fair to good prognosis is warranted. Reported success rates were provided in the treatment section.

NASAL PARASITES NASAL MITES Pneumonyssoides caninum is a small white mite approximately 1╯mm in size (see Fig. 14-13, A). Most infestations are clinically silent, but some dogs may have moderate to severe clinical signs. Clinical Features and Diagnosis A common clinical feature of nasal mites is sneezing, which is often violent. Head shaking, pawing at the nose, reverse sneezing, chronic nasal discharge, and epistaxis can also occur. These signs are similar to those caused by nasal foreign bodies. The diagnosis is made by visualizing the mites during rhinoscopy or by retrograde nasal flushing, as described in Chapter 14. The mites can be easily overlooked in the retrieved saline solution; they should be specifically searched for with slight magnification or by placing dark material behind the specimen for contrast. Further, the mites are often located in the frontal sinuses and the caudal nasal cavity. Flushing the nasal cavities from the nares with an anesthetic gas in oxygen may cause the mites to migrate to the caudal nasopharynx. The mites can be visualized in the nasopharynx by endoscopy during the flushing procedure.

sinuses in foxes. The adult worm is small, thin, and white and lives on the mucosa of the nasal cavity and frontal sinuses of dogs (see Fig. 14-13, B). The adults shed eggs that are swallowed and pass in the feces. Clinical signs include sneezing and mucopurulent nasal discharge, with or without hemorrhage. The diagnosis is made by identifying double operculated Capillaria (Eucoleus) eggs on routine fecal flotation (similar to the eggs of Capillaria [Eucoleus] aerophila; see Fig. 20-12, C) or by visualizing adult worms during rhinoscopy. Treatments include ivermectin (0.2╯mg/kg, orally, once) or fenbendazole (25 to 50╯mg/kg, orally, q12h for 10 to 14 days). Ivermectin is not safe for certain breeds. Success of treatment should be confirmed with repeated fecal examinations, in addition to resolution of clinical signs. Repeated treatments may be necessary, and reinfection is possible if exposure to contaminated soil continues.

FELINE NASOPHARYNGEAL POLYPS Nasopharyngeal polyps are benign growths that occur most often in kittens and young adult cats, although they are occasionally found in older animals. Their origin is unknown, but they are often attached to the base of the eustachian tube. They can extend into the external ear canal, middle ear, pharynx, and nasal cavity. Grossly, they are pink, polypoid growths, often arising from a stalk (Fig. 15-5). Because of their gross appearance, they are sometimes mistaken for neoplasia.

Treatment Milbemycin oxime (0.5 to 1╯mg/kg, orally, every 7 to 10 days for three treatments) and selemectin (6-24╯mg/kg, topically over the shoulders, every 2 weeks for three treatments) have been used successfully for treating nasal mites. Ivermectin is also effective (0.2╯mg/kg, administered subcutaneously and repeated in 3 weeks), but it is not safe for certain breeds. Any dogs in direct contact with the affected animal should also be treated. Prognosis The prognosis for dogs with nasal mites is excellent.

NASAL CAPILLARIASIS Nasal capillariasis is caused by a nematode, Capillaria (Eucoleus) boehmi, originally identified as a worm of the frontal

FIG 15-5â•…

A nasopharyngeal polyp was visualized during rhinoscopy through the exterior naris of a cat with chronic nasal discharge. The polyp was excised by traction and has an obvious stalk.

Clinical Features Respiratory signs caused by nasopharyngeal polyps include stertorous breathing, upper airway obstruction, and serous to mucopurulent nasal discharge. Signs of otitis externa or otitis media/interna, such as head tilt, nystagmus, or Horner’s syndrome, can also occur. Diagnosis Identification of a soft tissue opacity above the soft palate radiographically and gross visualization of a mass in the nasopharynx, nasal cavity, or external ear canal support a tentative diagnosis of nasopharyngeal polyp. Complete evaluation of cats with polyps also includes a deep otoscopic examination and radiographs or CT scans of the osseous bullae to determine the extent of involvement. Most cats with polyps have otitis media, detectable radiographically as thickened bone or increased soft tissue opacity of the bulla (see Fig. 14-6). The definitive diagnosis is made by histopathologic analysis of biopsy tissue; the specimen is usually obtained during surgical excision. Nasopharyngeal polyps are composed of inflammatory tissue, fibrous connective tissue, and epithelium. Treatment Treatment of nasopharyngeal polyps consists of surgical excision. Surgery is usually performed through the oral cavity by traction. In addition, bullae osteotomy should be considered in cats with radiographic or CT evidence of involvement of the osseous bullae. Rarely, rhinotomy is required for complete removal. An early study by Kapatkin et╯al (1990) reported that 5 of 31 cats had regrowth of an excised polyp. Of the five cats with regrowth, four had not had bulla osteotomies. These findings support the importance of addressing involvement of the osseous bulla in cats with polyps. However, a subsequent study by Anderson et╯al (2000) reported successful treatment with traction alone, particularly when followed by a course of prednisolone in some cats. Prednisolone was administered orally at 1 to 2╯mg/kg every 24 hours for 2 weeks, then at half the original dose for 1 week, then every other day for 7 to 10 more days. A course of antibiotics (e.g., amoxicillin) was also administered. Prognosis The prognosis is excellent, but treatment of recurrent disease may be necessary. Regrowth of a polyp can occur at the original site if abnormal tissue remains, with signs of recurrence typically appearing within 1 year. Bulla osteotomies if not performed with initial treatment should be considered in cats with recurrence and signs of otitis media.

CANINE NASAL POLYPS Dogs rarely develop nasal polyps. These masses can result in chronic nasal discharge, with or without hemorrhage. They

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are often locally destructive to turbinates and bone, and as a result can be misdiagnosed as neoplasia. The diagnosis is made by histologic evaluation of biopsy specimens. Aggressive surgical removal is recommended. Complete excision may be impossible and signs may recur.

NASAL TUMORS Most nasal tumors in the dog and cat are malignant. Adenocarcinoma, squamous cell carcinoma, and undifferentiated carcinoma are common nasal tumors in dogs. Lymphoma and adenocarcinoma are common in cats. Fibrosarcomas and other sarcomas also occur in both species. Benign tumors include adenomas, fibromas, papillomas, and transmissible venereal tumors (the latter only in dogs). Clinical Features Nasal tumors usually occur in older animals but cannot be excluded from the differential diagnosis of young dogs and cats. No breed predisposition has been consistently identified. The clinical features of nasal tumors (usually chronic) reflect the locally invasive nature of these tumors. Nasal discharge is the most common complaint. The discharge can be serous, mucoid, mucopurulent, or hemorrhagic. One or both nostrils can be involved. With bilateral involvement, the discharge is often worse from one nostril than from the other. For many animals the discharge is initially unilateral and progresses to bilateral. Sneezing may be reported. Obstruction of the nasal cavity by the tumor may cause decreased or absent air flow through one of the nares. Deformation of the facial bones, hard palate, or maxillary dental arcade may be visible (see Fig. 13-5). Tumor growth extending into the cranial vault can result in neurologic signs. Growth into the orbit may cause exophthalmos or inability to retropulse the eye. Animals only rarely experience neurologic signs (e.g., seizures, behavior changes, abnormal mental status) or ocular abnormalities as the primary complaints (i.e., no signs of nasal discharge). Weight loss and anorexia may accompany the respiratory signs but are often absent. Diagnosis A diagnosis of neoplasia is based on clinical features and is supported by typical abnormalities detected by imaging of the nasal cavity and frontal sinuses or rhinoscopy. A definitive diagnosis requires histopathologic examination of a biopsy specimen, although fine-needle aspirates of nasal masses may provide conclusive results. Imaging (radiography, CT, or MRI) and rhinoscopic abnormalities can reflect soft tissue mass lesions; turbinate, vomer bone, or facial bone destruction (see Figs. 14-2, 14-4, and 14-8, B); or diffuse infiltration of the mucosa with neoplastic and inflammatory cells. Biopsy specimens, including tissue from deep within the lesion, should be obtained in all patients for histologic

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confirmation. Nasal neoplasms frequently cause a marked inflammatory response of the nasal mucosa and, in some patients, secondary bacterial or fungal infection. A cytologic diagnosis of neoplasia must be accepted cautiously, with consideration of concurrent inflammation and potentially marked hyperplastic and metaplastic change. Furthermore, in some cases the cytologic characteristics of lymphoma and carcinoma will mimic each other, which may lead to an erroneous classification. Not all cases of neoplasia will be diagnosed on initial evaluation of the dog or cat. Imaging, rhinoscopy, and biopsy may need to be repeated in 1 to 3 months in animals with persistent signs in which a definitive diagnosis has not been made. CT and MRI are more sensitive techniques than routine radiography for imaging nasal tumors, and one of these should be performed when available (see Fig. 14-8, B). Surgical exploration is occasionally necessary to obtain a definitive diagnosis. Once a definitive diagnosis has been made, determining the extent of disease can help in assessing the feasibility of surgical or radiation therapy versus chemotherapy. Some information can be obtained from high-quality nasal radiographs, but CT and MRI are more sensitive methods for evaluating the extent of abnormal tissue. Aspirates of mandibular lymph nodes should be examined cytologically for evidence of local spread. Thoracic radiographs are evaluated, although pulmonary metastases are uncommon at the time of initial diagnosis. Cytologic evaluation of bone marrow aspirates, as well as abdominal radiography or ultrasound, is indicated for patients with lymphoma. Cats with lymphoma are also tested for FeLV and FIV. Treatment Treatment for benign tumors should include surgical excision. Malignant nasal tumors can be treated with radiation therapy (with or without surgery) and/or chemotherapy. Palliative treatment can also be tried. The treatments of choice for cats with nasal lymphoma are chemotherapy using standard lymphoma protocols (see Chapter 77), radiation therapy, or both. Radiation therapy avoids the systemic adverse effects of chemotherapeutic drugs but may be insufficient if the tumor involves other organs. Radiation therapy is the treatment of choice for most other malignant nasal tumors. Surgical debulking before radiation is recommended if orthovoltage radiation will be used. Surgery is not beneficial before megavoltage radiation (cobalt or linear accelerator), but improved success of treatment has been reported with surgical debulking performed after megavoltage radiotherapy (Adams et╯ al, 2005). Palliative radiation therapy can improve duration and quality of life in some patients, while avoiding many of the side effects of full-dose radiation. Treatment of malignant nasal tumors with surgery alone does not result in prolonged survival times; it may indeed shorten survival times. It is doubtful whether all abnormal tissue can be excised in most cases.

Chemotherapy may be attempted when radiation therapy has failed or is not a viable option. Carcinomas may be responsive to cisplatin, carboplatin, or multiagent chemotherapy. (See Chapter 74 for a discussion of general principles for the selection of chemotherapy.) Treatment with piroxicam, a nonsteroidal antiinflammatory drug, can be considered for dogs with carcinoma for which radiation therapy is not elected. Partial remission or improvement in clinical signs has been reported for some dogs with transitional cell carcinoma of the urinary bladder, oral squamous cell carcinoma, and several other carcinomas. Potential side effects include gastrointestinal ulceration (which can be severe) and kidney damage. For dogs with other types of tumors and for cats, improvement of clinical signs may be seen with antiinflammatory doses of glucocorticoids. Prednisolone is prescribed for cats, and either prednisone or prednisolone is prescribed for dogs (0.5 to 1╯mg/kg/day orally; tapered to lowest effective dose). Neither drug should be given in conjunction with piroxicam. Prognosis The prognosis for dogs and cats with untreated malignant nasal tumors is poor. Survival after diagnosis is usually only a few months. Euthanasia is often requested because of persistent epistaxis or discharge, labored respirations, anorexia and weight loss, or neurologic signs. Epistaxis is a poor prognostic indicator. In a study of 132 dogs with untreated nasal carcinoma by Rassnick et╯al (2006), the median survival time of dogs with epistaxis was 88 days (95% confidence interval [CI], 65-106 days) and of dogs without epistaxis was 224 days (95% CI, 54-467 days). The overall median survival time was 95 days (range, 7-1114 days). Radiation therapy can prolong survival and improve quality of life in some animals. The therapy is well tolerated by most animals, and in those that achieve remission the quality of life is usually excellent. Early studies of dogs treated with megavoltage radiation, with or without prior surgical treatment, found median survival times of approximately 1 year. For dogs receiving megavoltage radiation followed by surgical debulking, median survival time was 47.7 months, with survival rates for 2 and 3 years of 69% and 58%, respectively (Adams et╯al, 2005). The dogs in the study by Adams et╯al (2005) that did not receive postradiotherapy surgery had a median survival of 19.7 months and lower 2- and 3-year survival rates (44% and 24%, respectively). Less information is available concerning prognosis in cats. A study by Theon et╯ al (1994) of 16 cats with nonlymphoid neoplasia receiving radiation therapy showed a 1-year survival rate of 44% and a 2-year survival rate of 17%. Cats with nasal lymphoma treated with radiation and chemotherapy had a median survival time of 511 days, according to preliminary data from Arteaga et╯ al (2007). Of eight cats with nasal lymphoma treated with cyclophosphamide, vincristine, and prednisolone (COP), without radiation, six (75%) achieved complete remission (Teske et╯ al, 2002). Median survival time was 358 days, and the estimated 1-year survival rate was 75%.

ALLERGIC RHINITIS Etiology Allergic rhinitis has not been well characterized in dogs or cats. However, dermatologists provide anecdotal reports of atopic dogs rubbing the face (possibly indicating nasal pruritus) and experiencing serous nasal discharge, in addition to dermatologic signs. Allergic rhinitis is generally considered to be a hypersensitivity response within the nasal cavity and sinuses to airborne antigens. It is possible that food allergens play a role in some patients. Other antigens are capable of inducing a hypersensitivity response as well, and thus the differential diagnoses must include parasites, other infectious diseases, and neoplasia. Clinical Features Dogs or cats with allergic rhinitis experience sneezing and/ or serous or mucopurulent nasal discharge. Signs may be acute or chronic. Careful questioning of the owner may reveal a relationship between signs and potential allergens. For instance, signs may be worse during certain seasons; in the presence of cigarette smoke; or after the introduction of a new brand of kitty litter or new perfumes, cleaning agents, furniture, or fabric in the house. Note that worsening of signs may simply be a result of exposure to irritants rather than an actual allergic response. Debilitation of the animal is not expected. Diagnosis Identifying a historical relationship between signs and a particular allergen and then achieving resolution of signs after removal of the suspected agent from the animal’s environment support the diagnosis of allergic rhinitis. When this approach is not possible or successful, a thorough diagnostic evaluation of the nasal cavity is indicated (see Chapters 13 and 14). Nasal radiographs reveal increased soft tissue opacity with minimal or no turbinate destruction. Classically, nasal biopsy reveals eosinophilic inflammation. It is possible that with chronic disease, a mixed inflammatory response occurs, obscuring the diagnosis. There should be no indication in any of the diagnostic tests of an aggressive disease process, parasites or other active infection, or neoplasia. Treatment Removing the offending allergen from the animal’s environment or diet is the ideal treatment for allergic rhinitis. When this is not possible, a beneficial response may be achieved with antihistamines. Chlorpheniramine can be administered orally at a dose of 4 to 8╯mg/dog every 8 to 12 hours or 2╯mg/cat every 8 to 12 hours. The second-generation antihistamine cetirizine (Zyrtec, Pfizer) may be more successful in cats. A pharmacokinetic study of this drug in healthy cats found a dosage of 1╯mg/kg, administered orally every 24 hours, to maintain plasma concentrations similar to those reported in people (Papich et╯al, 2006). Glucocorticoids may be used if antihistamines are unsuccessful. Prednisone is

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initiated at a dose of 0.25╯mg/kg, orally, every 12 hours until signs resolve. The dose is then tapered to the lowest effective amount. If treatment is effective, signs will generally resolve within a few days. Drugs are continued only as long as needed to control signs. Prognosis The prognosis for dogs and cats with allergic rhinitis is excellent if the allergen can be eliminated. Otherwise, the prognosis for control is good, but a cure is unlikely.

IDIOPATHIC RHINITIS Idiopathic rhinitis is a more common diagnosis in cats compared with dogs. The diagnosis cannot be made without a thorough diagnostic evaluation to rule out specific diseases (see Chapters 13 and 14).

FELINE CHRONIC RHINOSINUSITIS Etiology Feline chronic rhinosinusitis has long been presumed to be a result of viral infection with FHV or FCV (see the section on feline upper respiratory infection, p. 234). Persistent viral infection has been implicated, but studies have failed to show an association between tests indicating exposure to or infection with these viruses and clinical signs. It is possible that infection with these viruses results in damaged mucosa that is more susceptible to bacterial infection or that mounts an excessive inflammatory response to irritants or normal nasal flora. Preliminary studies have failed to show an association with feline chronic rhinosinusitis and Bartonella infection, based on serum antibody titers or PCR of nasal tissue (Berryessa et╯al, 2008). In the absence of a known cause, this disease will be denoted by the term idiopathic feline chronic rhinosinusitis. Clinical Features and Diagnosis Chronic mucoid or mucopurulent nasal discharge is the most common clinical sign of idiopathic feline chronic rhinosinusitis. The discharge is typically bilateral. Fresh blood may be seen in the discharge of some cats but is not usually a primary complaint. Sneezing may occur. Given that this is an idiopathic disease, the lack of specific findings is important. Cats should have no funduscopic lesions, no lymphadenopathy, no facial or palate deformities, and healthy teeth and gums. Anorexia and weight loss are rarely reported. Thorough diagnostic testing is indicated, as described in Chapters 13 and 14. Results of such testing do not support the diagnosis of a specific disease. Usual nonspecific findings include turbinate erosion, mucosal inflammation, and increased mucus accumulation as assessed by nasal imaging and rhinoscopy; neutrophilic or mixed inflammation with bacteria on cytology of nasal discharge; and neutrophilic and/or lymphoplasmacytic inflammation on nasal biopsy. Nonspecific abnormalities

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attributable to chronic inflammation, such as epithelial hyperplasia and fibrosis, may also be seen. Secondary bacterial rhinitis or Mycoplasma infection may be identified. Treatment Cats with idiopathic chronic rhinosinusitis often require management for years. Fortunately, most of these cats are healthy in all other respects. Treatment strategies include facilitating drainage of discharge; decreasing irritants in the environment; controlling secondary bacterial infections; treating possible Mycoplasma or FHV infection; reducing inflammation; and, as a last resort, performing a turbinectomy and frontal sinus ablation (Box 15-1). Keeping secretions moist, performing intermittent nasal flushes, and judiciously using topical decongestants facilitate drainage. Keeping the cat in a room with a vaporizer, for instance, during the night, can provide symptomatic relief by keeping secretions moist. Alternatively, drops of sterile saline can be placed into the nares. Some cats experience a marked improvement in clinical signs for weeks after flushing of the nasal cavity with copious amounts of saline or

  BOX 15-1â•… Management Considerations for Cats with Idiopathic Chronic Rhinosinusitis Facilitate Drainage of Discharge

Vaporizer treatments Topical saline administration Nasal cavity flushes under anesthesia Topical decongestants Decrease Irritants in the Environment

Improvement of indoor air quality Control Secondary Bacterial Infections

Long-term antibiotic treatment Treat Possible Mycoplasma Infection

Antibiotic treatment Treat Possible Herpesvirus Infection

Lysine treatment Reduce Inflammation

Second-generation antihistamine treatment Oral prednisolone treatment Other unproven treatments with possible antiinflammatory effects Azithromycin Piroxicam Leukotriene inhibitors Omega-3 fatty acids Provide Surgical Intervention

Turbinectomy Frontal sinus ablation

dilute betadine solution. General anesthesia is required, and the lower airways must be protected with an endotracheal tube, gauze sponges, and positioning of the head to facilitate drainage from the external nares. Topical decongestants, as described for feline upper respiratory infection (see p. 235), may provide symptomatic relief during episodes of severe congestion. Irritants in the environment can further exacerbate mucosal inflammation. Irritants such as smoke (from tobacco or fireplace) and perfumed products should be avoided. Motivated clients can take steps to improve the air quality in their homes, such as by cleaning carpet, furniture, drapery, and furnace; regularly replacing air filters; and using an air cleaner. The American Lung Association has a useful Web site with nonproprietary recommendations for improving indoor air quality (www.lung.org). Long-term antibiotic therapy may be required to manage secondary bacterial infections. Broad-spectrum oral anti� biotics such as amoxicillin (22╯mg/kg q8-12h) or trime� thoprim-sulfadiazine (15╯mg/kg q12h) are often successful. Doxycycline (5 to 10╯mg/kg q12h, followed by a bolus of water) has activity against some bacteria and Chlamydophila and Mycoplasma organisms and can be effective in some cats when other drugs have failed. Azithromycin (5 to 10╯mg/kg q24h for 3 days, then q48h) can be prescribed for cats that are difficult to medicate. This author reserves fluoroquinolones for cats with documented resistant gram-negative infections. If a beneficial response to antibiotic therapy is seen within 1 week of its initiation, the antibiotic should be continued for at least 4 to 6 weeks. If a beneficial response is not seen, the antibiotic is discontinued. Note that frequent stopping and starting of different antibiotics every 7 to 14 days is not recommended and may predispose the cat to resistant gram-negative infections. Cats that respond well during the prolonged course of antibiotics but that relapse shortly after discontinuation of the drug despite 4 to 6 weeks of relief are candidates for continuous long-term antibiotic therapy. Treatment with the previously used antibiotic often can be successfully reinstituted. Amoxicillin administered twice daily is often sufficient. Treatment with lysine may be effective in cats with active herpesvirus infection. It has been postulated that excessive concentrations of lysine may antagonize arginine, a promoter of herpesvirus replication. Because the specific organism involved is rarely known, trial therapy is initiated. Lysine (500╯mg/cat q12h), which can be obtained from health food stores, is added to food. A minimum of 4 weeks of treatment is necessary before the success of treatment can be assessed. Anecdotal success in occasional cats has been reported with treatment with the second-generation antihistamine cetirizine (Zyrtec, Pfizer) as described for allergic rhinitis (see p. 243). Cats with severe signs that persist despite the previously described methods of supportive care may benefit from glucocorticoids to reduce inflammation. However, certain risks are involved. Glucocorticoids may further predispose the cat

to secondary infection, increase viral shedding, and mask signs of a more serious disease. Glucocorticoids should be prescribed only after a complete diagnostic evaluation has been performed to rule out other diseases. Prednisolone is administered orally at a dose of 0.5╯mg/kg every 12 hours. If a beneficial response is seen within 1 week, the dose is gradually decreased to the lowest effective dose. A dose as low as 0.25╯mg/kg every 2 to 3 days may be sufficient to control clinical signs. If a clinical response is not seen within 1 week, the drug should be discontinued. Other drugs with potential antiinflammatory effects include azithromycin (described with antibiotics), piroxicam, and leukotriene inhibitors. Omega-3 fatty acid supplementation may also serve to dampen the inflammatory response. Effectiveness of these treatments in cats with chronic signs is based on anecdotal reports of success in individual cats. Cats with severe or deteriorating signs that persist despite conscientious care are candidates for turbinectomy and frontal sinus ablation, if a complete diagnostic evaluation to eliminate other causes of chronic nasal discharge has been performed (see Chapters 13 and 14). Turbinectomy and frontal sinus ablation are difficult surgical procedures. Major blood vessels and the cranial vault must be avoided, and tissue remnants must not be left behind. Anorexia can be a postoperative problem; placement of an esophagostomy or gastrostomy tube (see p. 414) serves as an excellent means of meeting nutritional requirements if necessary after surgery. Complete elimination of respiratory signs is unlikely, but signs may be more easily managed. The reader is referred to surgical texts for a description of surgical techniques (e.g., see Fossum in Suggested Readings).

CANINE CHRONIC/ LYMPHOPLASMACYTIC RHINITIS Etiology Idiopathic chronic rhinitis in dogs is sometimes characterized by the inflammatory infiltrates seen in nasal mucosal biopsy specimens; thus the disease lymphoplasmacytic rhinitis has been described. It was originally reported to be a steroid-responsive disorder, but a subsequent report by Windsor et╯ al (2004) and clinical experience suggest that corticosteroids are not always effective in the treatment of lymphoplasmacytic rhinitis. It is not uncommon for neutrophilic inflammation to be found, predominantly or along with lymphoplasmacytic infiltrates. For these reasons, the less specific term idiopathic canine chronic rhinitis will be used. Many specific causes of nasal disease result in a concurrent inflammatory response because of the disease itself or as a response to the secondary effects of infection or as an enhanced response to irritants; this makes a thorough diagnostic evaluation of these cases imperative. Windsor et╯al (2004) performed multiple PCR assays on paraffin-embedded nasal tissue from dogs with idiopathic chronic rhinitis and failed to find evidence for a role of bacteria (based on

CHAPTER 15â•…â•… Disorders of the Nasal Cavity

245

DNA load), canine adenovirus-2, parainfluenza virus, Chlamydophila spp., or Bartonella spp. in affected dogs. Large amounts of fungal DNA were found in affected dogs, suggesting a possible contribution to clinical signs. Alternatively, the result may simply reflect decreased clearance of fungal organisms from the diseased nasal cavity. Although not supported in the previously quoted study, a potential role for Bartonella infection has been suggested on the basis of a study that found an association between seropositivity for Bartonella spp. and nasal discharge or epistaxis (Henn et╯al, 2005) and a report of three dogs with epistaxis and evidence of infection with Bartonella spp. (Breitschwerdt et╯al, 2005). A study conducted in our lab� oratory (Hawkins et╯al, 2008) failed to find an obvious association between bartonellosis and idiopathic rhinitis, in agreement with findings by Windsor et╯al (2004). Clinical Features and Diagnosis The clinical features and diagnosis of idiopathic canine chronic rhinitis are similar to those described for idiopathic feline chronic rhinosinusitis. Chronic mucoid or mucopurulent nasal discharge is the most common clinical sign and is typically bilateral. Fresh blood may be seen in the discharge of some dogs, but it is not usually a primary complaint. Given that it is an idiopathic disease, the lack of specific findings is important. Dogs should have no funduscopic lesions, no lymphadenopathy, no facial or palate deformities, and healthy teeth and gums. Anorexia and weight loss are rarely reported. Thorough diagnostic testing is indicated, as described in Chapters 13 and 14. Results of such testing do not support the diagnosis of a specific disease. Usual nonspecific findings include turbinate erosion, mucosal inflammation, and increased mucus accumulation as assessed by nasal imaging and rhinoscopy; neutrophilic or mixed inflammation with bacteria on cytology of nasal discharge; and lymphoplasmacytic and/or neutrophilic inflammation on nasal biopsy. Nonspecific abnormalities attributable to chronic inflammation, such as epithelial hyperplasia and fibrosis, can also be seen. Secondary bacterial rhinitis or Mycoplasma infection may be identified. Treatment Treatment of idiopathic canine chronic rhinitis is also similar to that described for idiopathic feline rhinosinusitis (see previous section and Box 15-1). Dogs are treated for secondary bacterial rhinitis (as described on p. 236), and efforts are made to decrease irritants in the environment (see p. 243). As with cats, some dogs will benefit from efforts to facilitate the draining of nasal discharge by humidification of air or instillation of sterile saline into the nasal cavity. Although antiinflammatory treatment as described for cats may be beneficial in some dogs, successful treatment was originally reported in dogs with lymphoplasmacytic rhinitis using immunosuppressive doses of prednisone (1╯mg/ kg, orally, q12h). A positive response is expected within 2 weeks, at which time the dose of prednisone is decreased

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gradually to the lowest effective amount. If no response to initial therapy occurs, other immunosuppressive drugs such as azathioprine can be added to the treatment regimen (see Chapter 100). Unfortunately, immunosuppressive treatment is not always effective. If clinical signs worsen during treatment with corticosteroids, the clinician should discontinue therapy and carefully reevaluate the dog for other diseases. Another drug that may be effective is itraconazole. According to preliminary data from Kuehn (2006), administration of itraconazole (5╯mg/kg, orally, q12h) resulted in dramatic improvement in clinical signs in some dogs with idiopathic chronic rhinitis. Treatment was required for a minimum of 3 to 6 months. The rationale for this treatment may be supported by the findings of increased fungal load in affected dogs by Windsor et╯al (2004). Dogs with severe or nonresponsive signs are candidates for rhinotomy and turbinectomy, as described for cats on p. 245. Prognosis The prognosis for idiopathic chronic rhinitis in dogs is generally good with respect to management of signs and quality of life. However, some degree of clinical signs persists in many dogs. Suggested Readings Adams WM et al: Outcome of accelerated radiotherapy alone or accelerated radiotherapy followed by exenteration of the nasal cavity in dogs with intranasal neoplasia: 53 cases (1990-2002), J Am Vet Med Assoc 227:936, 2005. Anderson DM et al: Management of inflammatory polyps in 37 cats, Vet Record 147:684, 2000. Arteaga T et al: A retrospective analysis of nasal lymphoma in 71 cats (1999-2006), Abstract, J Vet Intern Med 21:573, 2007. Berryessa NA et al: Microbial culture of blood samples and serologic testing for bartonellosis in cats with chronic rhinitis, J Am Vet Med Assoc 233:1084, 2008. Binns SH et al: Prevalence and risk factors for feline Bordetella bronchiseptica infection, Vet Rec 144:575, 1999. Breitschwerdt EB et al: Bartonella species as a potential cause of epistaxis in dogs, J Clin Microbiol 43:2529, 2005. Buchholz J et al: 3D conformational radiation therapy for palliative treatment of canine nasal tumors, Vet Radiol Ultrasound 50:679, 2009. Fossum TW: Small animal surgery, ed 4, St Louis, 2013, Elsevier Mosby. Gunnarsson L et al: Efficacy of selemectin in the treatment of nasal mite (Pneumonyssoides caninum) infection in dogs, J Am Anim Hosp Assoc 40:400, 2004. Hartmann AD et al: Efficacy of pradofloxacin in cats with feline upper respiratory tract disease due to Chlamydophila felis or Mycoplasma infections, J Vet Intern Med 22:44, 2008. Hawkins EC et al: Failure to identify an association between serologic or molecular evidence of Bartonella spp infection and idiopathic rhinitis in dogs, J Am Vet Med Assoc 233:597, 2008.

Henn JB et al: Seroprevalence of antibodies against Bartonella species and evaluation of risk factors and clinical signs associated with seropositivity in dogs, Am J Vet Res 66:688, 2005. Holt DE, Goldschmidt MH: Nasal polyps in dogs: five cases (20052011), J Small Anim Pract 52:660, 2011. Johnson LR et al: Assessment of infectious organisms associated with chronic rhinosinusitis in cats, J Am Vet Med Assoc 227:579, 2005. Kapatkin AS et al: Results of surgery and long-term follow-up in 31 cats with nasopharyngeal polyps, J Am Anim Hosp Assoc 26:387, 1990. Kuehn NF: Prospective long term pilot study using oral itraconazole therapy for the treatment of chronic idiopathic (lymphoplasmacytic) rhinitis in dogs, Abstract, British Small Animal Veterinary Association Annual Congress, 2006, Prague, Czech Republic. Lappin MR et al: Use of serologic tests to predict resistance to feline herpesvirus 1, feline calicivirus, and feline parvovirus infection in cats, J Am Vet Med Assoc 220:38, 2002. Mathews KG et al: Computed tomographic assessment of noninvasive intranasal infusions in dogs with fungal rhinitis, Vet Surg 25:309, 1996. Papich MG et al: Cetirizine (Zyrtec) pharmacokinetics in healthy cats, Abstract, J Vet Intern Med 20:754, 2006. Piva S et al: Chronic rhinitis due to Streptococcus equi subspecies zooepidemicus in a dog, Vet Record 167:177, 2010. Pomerantz JS et al: Comparison of serologic evaluation via agar gel immunodiffusion and fungal culture of tissue for diagnosis of nasal aspergillosis in dogs, J Am Vet Med Assoc 230:1319, 2007. Rassnick KM et al: Evaluation of factors associated with survival in dogs with untreated nasal carcinomas: 139 cases (1993-2003), J Am Vet Med Assoc 229:401, 2006. Richards JR et al: The 2006 American Association of Feline Practitioners Feline Vaccine Advisory Panel Report, J Am Vet Med Assoc 229:1405, 2006. Schmidt BR et al: Evaluation of piroxicam for the treatment of oral squamous cell carcinoma in dogs, J Am Vet Med Assoc 218:1783, 2001. Seibeck N et al: Effects of human recombinant alpha-2b interferon and feline recombinant omega interferon on in vitro replication of feline herpesvirus, Am J Vet Res 67:1406, 2006. Sharman M et al: Muti-centre assessment of mycotic rhinosinusitis in dogs: a retrospective study of initial treatment success, J Small Anim Pract 51:423, 2010. Teske E et al: Chemotherapy with cyclophosphamide, vincristine and prednisolone (COP) in cats with malignant lymphoma: new results with an old protocol, J Vet Intern Med 16:179, 2002. The 2006 American Association of Feline Practitioners Feline Vaccine Advisory Panel Report. J Am Vet Med Assoc 229:1405, 2006. Theon AP et al: Irradiation of nonlymphoproliferative neoplasms of the nasal cavity and paranasal sinuses in 16 cats, J Am Vet Med Assoc 204:78, 1994. Windsor RC et al: Idiopathic lymphoplasmacytic rhinitis in dogs: 37 cases (1997-2002), J Am Vet Med Assoc 224:1952, 2004.

C H A P T E R

16â•…

Clinical Manifestations of Laryngeal and Pharyngeal Disease CLINICAL SIGNS LARYNX Regardless of the cause, diseases of the larynx result in similar clinical signs, most notably respiratory distress and stridor. Gagging or coughing may also be reported. Voice change is specific for laryngeal disease but is not always reported. Clients may volunteer that they have noticed a change in the dog’s bark or the cat’s meow, but specific questioning may be necessary to obtain this important information. Localization of disease to the larynx can generally be achieved with a good history and physical examination. A definitive diagnosis is made through a combination of laryngeal radiography, laryngoscopy, and laryngeal biopsy. Respiratory distress resulting from laryngeal disease is due to airway obstruction. Although most laryngeal diseases are progressive over several weeks to months, animals typically present in acute distress. Dogs and cats are able to compensate for their disease initially through self-imposed exercise restriction. Often an exacerbating event occurs, such as exercise, excitement, or high ambient temperature, resulting in markedly increased respiratory efforts. These increased efforts lead to excess negative pressures on the diseased larynx, sucking the surrounding soft tissues into the lumen and causing laryngeal inflammation and edema. Obstruction to airflow becomes more severe, leading to even greater respiratory efforts (Fig. 16-1). The airway obstruction can ultimately be fatal. A characteristic breathing pattern can often be identified on physical examination of patients in distress from extrathoracic (upper) airway obstruction, such as that resulting from laryngeal disease (see Chapter 26). The respiratory rate is normal to only slightly elevated (often 30 to 40 breaths/ min), which is particularly remarkable in the presence of overt distress. Inspiratory efforts are prolonged and labored, relative to expiratory efforts. The larynx tends to be sucked into the airway lumen as a result of negative pressure within the extrathoracic airways that occurs during inspiration, making inhalation of air more difficult. During expiration, pressures are positive in the extrathoracic airways, “pushing”

the soft tissues open. Nevertheless, expiration may not be effortless. Some obstruction to airflow may occur during expiration with fixed obstructions, such as laryngeal masses. Even with the dynamic obstruction that results from laryngeal paralysis, in which expiration should be possible without any blockage of flow, resultant laryngeal edema and inflammation can interfere with normal expiration. On auscultation, referred upper airway sounds are heard and lung sounds are normal to increased. Stridor, a high-pitched wheezing sound, is sometimes heard during inspiration. It is audible without a stethoscope, although auscultation of the neck may aid in identifying mild disease. Stridor is produced by air turbulence through the narrowed laryngeal opening. Narrowing of the extrathoracic trachea less commonly produces stridor, instead producing a coarse stertorous sound. When patients are not presented for respiratory distress (e.g., patients with exercise intolerance or voice change), it may be necessary to exercise the patient to identify the characteristic breathing pattern and stridor associated with laryngeal disease. Some patients with laryngeal disease, particularly those whose laryngeal paralysis is an early manifestation of diffuse neuromuscular disease or those presenting with distortion of normal laryngeal anatomy, have subclinical aspiration or overt aspiration pneumonia resulting from the loss of normal protective mechanisms. Patients may show clinical signs reflecting aspiration, such as cough, lethargy, anorexia, fever, tachypnea, and abnormal lung sounds. (See p. 323 for a discussion of aspiration pneumonia.)

PHARYNX Space-occupying lesions of the pharynx can cause signs of upper airway obstruction as described for the larynx, but overt respiratory distress occurs only with advanced disease. More typical presenting signs of pharyngeal disease include stertor, reverse sneezing, gagging, retching, and dysphagia. Stertor is a loud, coarse sound such as that produced by snoring or snorting. Stertor results when excessive soft tissue in the pharynx, such as an elongated soft palate or 247

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Heat Excitement Exercise

↑ Effort

  BOX 16-1â•… Differential Diagnoses for Laryngeal Disease in Dogs and Cats

↑ Obstruction

↑ Intraluminal pressures

FIG 16-1â•…

Patients with extrathoracic (upper) airway obstruction often present in respiratory distress as a result of progressive worsening of airway obstruction after an exacerbating event.

mass, causes turbulent airflow. Reverse sneezing (see p. 222), gagging, or retching may result from local stimulation from the tissue itself or from secondary secretions. Dysphagia results from physical obstruction, usually caused by a mass. As with laryngeal disorders, a definitive diagnosis is made through a combination of visual examination, radiography, and biopsy of abnormal tissue. Visual examination includes a thorough evaluation of the oral cavity, larynx (see p. 249), and caudal nasopharynx (see p. 227). In some cases, fluoroscopy or CT scan may be necessary to assess abnormalities visible only during the stress of labored breathing or with mass lesions resulting in external compression of the airway, respectively.

DIFFERENTIAL DIAGNOSES FOR LARYNGEAL SIGNS IN DOGS AND CATS Differential considerations for dogs and cats with respiratory distress are discussed in Chapter 26. Dogs are more commonly presented for laryngeal disease than cats and usually have laryngeal paralysis (Box 16-1). Laryngeal neoplasia can occur in dogs or cats. Obstructive laryngitis is a poorly characterized inflammatory disorder. Other possible diseases of the larynx include laryngeal collapse (see p. 252), web formation (i.e., adhesions or fibrotic tissue across the laryngeal opening, usually as a complication of surgery), trauma, foreign body, and compression caused by an extraluminal mass. Acute laryngitis is not a wellcharacterized disease in dogs or cats but presumably could result from viral or other infectious agents, foreign bodies, or excessive barking. Gastroesophageal reflux, a cause of laryngitis in people, has recently been documented to cause laryngeal dysfunction in a dog (Lux, 2012).

DIFFERENTIAL DIAGNOSES FOR PHARYNGEAL SIGNS IN DOGS AND CATS The most common pharyngeal disorders in dogs are bra� chycephalic airway syndrome and elongated soft palate

Laryngeal paralysis Laryngeal neoplasia Obstructive laryngitis Laryngeal collapse Web formation Trauma Foreign body Extraluminal mass Acute laryngitis

  BOX 16-2â•… Differential Diagnoses for Pharyngeal Disease in Dogs and Cats Brachycephalic airway syndrome Elongated soft palate Nasopharyngeal polyp Foreign body Neoplasia Abscess Granuloma Extraluminal mass Nasopharyngeal stenosis

(Box 16-2). Elongated soft palate is a component of brachycephalic airway syndrome and is discussed with this disorder in Chapter 18 (see p. 255), but it can also occur in nonbrachycephalic dogs. The most common pharyngeal disorders in cats are lymphoma and nasopharyngeal polyps (Allen et╯al, 1999). Nasopharyngeal polyps, nasal tumors, and foreign bodies are discussed in the chapters on nasal diseases (see Chapters 13 to 15). Other differential diagnoses are abscess or granuloma and compression caused by an extra� luminal mass. Nasopharyngeal stenosis can occur as a complication of chronic inflammation (rhinitis or pharyngitis), vomiting, or gastroesophageal reflux in dogs or cats. Suggested Readings Allen HS et al: Nasopharyngeal diseases in cats: a retrospective study of 53 cases (1991-1998), J Am Anim Hosp Assoc 35:457, 1999. Hunt GB et al: Nasopharyngeal disorders of dogs and cats: a review and retrospective study, Compendium 24:184, 2002. Lux CN: Gastroesophageal reflux and laryngeal dysfunction in a dog, J Am Vet Med Assoc 240:1100, 2012.

C H A P T E R

17â•…

Diagnostic Tests for the Larynx and Pharynx

RADIOGRAPHY Radiographs of the pharynx and larynx should be evaluated in animals with suspected upper airway disease (Figs. 17-1 and 17-2). They are particularly useful in identifying radiodense foreign bodies such as needles, which can be embedded in tissues and may be difficult to find during laryngoscopy, and adjacent bony changes. Soft tissue masses and soft palate abnormalities may be seen, but apparent abnormal opacities are often misleading, particularly if there is any rotation of the head and neck, and overt abnormalities are often not identified. Abnormal soft tissue opacities or narrowing of the airway lumen identified radiographically must be confirmed with laryngoscopy or endoscopy and biopsy. Laryngeal paralysis cannot be detected radiographically. A lateral view of the larynx, caudal nasopharynx, and cranial cervical trachea is usually obtained. The vertebral column interferes with airway evaluation on dorsoventral or ventrodorsal (VD) projections. In animals with abnormal opacities identified on the lateral view, a VD or oblique view may confirm the existence of the abnormality and allow further localization of it. When radiographs of the laryngeal area are obtained, the head is held with the neck slightly extended. Padding under the neck and around the head may be needed to avoid rotation, but should not distort the anatomic structures. Radiodense foreign bodies are readily identified. Soft tissue masses that are within the airway or that distort the airway are apparent in some animals with neoplasia, granulomas, abscesses, or polyps. Elongated soft palate is sometimes detectable.

ULTRASONOGRAPHY Ultrasonography provides another noninvasive imaging modality for evaluating the pharynx and larynx, and for assessing laryngeal motion. Because air interferes with sound waves, accurate assessment of this area can be difficult. Nevertheless, ultrasonography was found to be useful in the

diagnosis of laryngeal paralysis in dogs (Rudorf et╯al, 2001). Experience is necessary to avoid misdiagnosis. Localization of mass lesions and guidance of needle aspiration can also be performed.

FLUOROSCOPY In some patients, signs of upper airway obstruction occur only during labored breathing. A diagnosis may be missed if adequate efforts do not occur during routine radiography or during visual examination under anesthesia. In these cases, fluoroscopic evaluation during clinical signs may be invaluable. Unusual diagnoses, such as epiglottic retroversion and collapse of the dorsal pharyngeal wall, may not be possible by other means. Extrathoracic tracheal collapse, a differential diagnosis for upper airway obstruction due to pharyngeal or laryngeal disease, can often be diagnosed as well.

COMPUTED TOMOGRAPHY AND MAGNETIC RESONANCE IMAGING Computed tomography and magnetic resonance imaging are sensitive modalities for identifying masses that result in external compression of the larynx or pharynx. Extent of involvement and size of local lymph nodes can be assessed for patients with mass lesions external to or within the airway.

LARYNGOSCOPY AND PHARYNGOSCOPY Laryngoscopy and pharyngoscopy allow visualization of the larynx and pharynx for assessment of structural abnormalities and laryngeal function. These procedures are indicated in any dog or cat with clinical signs that suggest upper airway obstruction or laryngeal or pharyngeal disease. It should be noted that patients with increased respiratory 249

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efforts resulting from upper airway obstruction might have difficulty during recovery from anesthesia. For a period between removal of the endotracheal tube and full recovery of neuromuscular function, the patient may be unable to maintain an open airway. Therefore laryngoscopy should not be undertaken in these patients unless the clinician is prepared

FIG 17-1â•…

Lateral radiograph of the neck, larynx, and pharynx showing normal anatomy. Note that the patient’s head and neck are not rotated. Excellent visualization of the soft palate and epiglottis is possible. Images obtained from poorly positioned patients often result in the appearance of “lesions” such as masses or abnormal soft palate because normal structures are captured at an oblique angle or are superimposed on one another.

to perform whatever surgical treatments may be indicated during the same anesthetic period. The animal is placed in sternal recumbency. Anesthesia is induced and maintained with a short-acting injectable agent without prior sedation. Propofol is commonly used. Depth of anesthesia is carefully titrated, with just enough drug administered to allow visualization of the laryngeal cartilages; some jaw tone is maintained, and spontaneous deep respirations occur. Gauze is passed under the maxilla behind the canine teeth, and the head is elevated by hand or by tying the gauze to a stand (Fig. 17-3). This positioning avoids external compression of the neck. Retraction of the tongue with a gauze sponge should allow visualization of the caudal pharynx and larynx. A laryngoscope is also helpful in illuminating this region and enhancing visualization. The motion of the arytenoid cartilages is evaluated while the patient takes several deep breaths. An assistant is needed to verbally report the onset of each inspiration by observing chest wall movements. Normally the arytenoid cartilages abduct symmetrically and widely with each inspiration and close on expiration (Fig. 17-4). Laryngeal paralysis resulting in clinical signs is usually bilateral. The cartilages are not abducted during inspiration. In fact, they may be passively forced outward during expiration and/or sucked inward during inspiration, resulting in paradoxical motion. If the patient fails to take deep breaths, doxapram hydrochloride (1.1-2.2╯mg/kg, administered intravenously) can be given to stimulate breathing. In a study by Tobias et╯al (2004), none of the potential systemic side effects of the drug were

FIG 17-3â•… FIG 17-2â•…

Lateral radiograph of a dog with a neck mass showing marked displacement of the larynx.

Dog positioned with the head held off the table by gauze passed around the maxilla and hung from an intravenous pole. The tongue is pulled out, and a laryngoscope is used to visualize the pharyngeal anatomy and laryngeal motion.

CHAPTER 17â•…â•… Diagnostic Tests for the Larynx and Pharynx

251

SP

* A A

E

SP

*

B FIG 17-4â•…

Canine larynx. A, During inspiration, arytenoid cartilages and vocal folds are abducted, resulting in wide symmetric opening to the trachea. B, During expiration, cartilages and vocal folds nearly close the glottis.

E

B FIG 17-5â•…

noted, but some dogs required intubation when increased breathing efforts resulted in significant obstruction to airflow at the larynx. If no laryngeal motion is observed, examination of the arytenoid cartilages should be continued as long as possible while the animal recovers from anesthesia. Effects of anesthesia and shallow breathing are the most common causes for an erroneous diagnosis of laryngeal paralysis. After evaluation of laryngeal function, the plane of anesthesia is deepened and the caudal pharynx and larynx are thoroughly evaluated for structural abnormalities, foreign bodies, or mass lesions; appropriate diagnostic samples should be obtained for histopathologic analysis and perhaps culture. The length of the soft palate should be assessed. The soft palate normally extends to the tip of the epiglottis during inhalation. An elongated soft palate can contribute to signs of upper airway obstruction. As described in Chapter 14, the caudal nasopharynx should be evaluated for nasopharyngeal polyps, mass lesions,

The laryngeal anatomy from a healthy dog (A) is contrasted with that of a dog with laryngeal collapse (B). In the collapsed larynx, the cuneiform process (*) of the arytenoid process has folded medially and obstructs most of the airway. Also labeled are the soft palate (SP) and the epiglottis (E). In the photograph from the healthy dog, the soft palate is being held dorsally by a retractor (reflective, silver) and the tip of the epiglottis is not in view. (Courtesy Elizabeth M. Hardie.)

and foreign bodies. Needles or other sharp objects may be buried in tissue, and careful visual examination and palpation are required for detection. Neoplasia, granulomas, abscesses, or other masses can occur within or external to the larynx or pharynx, causing compression or deviation of normal structures or both. Severe, diffuse thickening of the laryngeal mucosa can be caused by infiltrative neoplasia or obstructive laryngitis. Biopsy specimens for histologic examination should be

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obtained from any lesions to establish an accurate diagnosis because the prognoses for these diseases are quite different. The normal diverse flora of the pharynx makes culture results difficult or impossible to interpret. Bacterial growth from abscess fluid or tissue obtained from granulomatous lesions may represent infection. Obliteration of most of the airway lumen by surrounding mucosa is known as laryngeal collapse (Fig. 17-5). With prolonged upper airway obstruction, the soft tissues are sucked into the lumen by the increased negative pressure created as the dog or cat struggles to get air into its lungs. Eversion of the laryngeal saccules, thickening and elongation of the soft palate, and inflammation with thickening of the pharyngeal mucosa can occur. The laryngeal cartilages can become soft and deformed, unable to support the soft tissues of the pharynx. It is unclear whether this chondromalacia is a concurrent or secondary component of laryngeal collapse.

Collapse most often occurs in dogs with brachycephalic airway syndrome but can also occur with any chronic obstructive disorder. The trachea should be examined radiographically or visually with an endoscope if abnormalities are not identified on laryngoscopy in the dog or cat with signs of upper airway obstruction. For these animals, the laryngeal cartilages can be held open with an endotracheal tube for a cursory examination of the proximal trachea at the time of laryngoscopy if an endoscope is not available. Suggested Readings Rudorf H et al: The role of ultrasound in the assessment of laryngeal paralysis in the dog, Vet Radiol Ultrasound 42:338, 2001. Tobias KM et al: Effects of doxapram HCl on laryngeal function of normal dogs and dogs with naturally occurring laryngeal paralysis, Vet Anaesth Analg 31:258, 2004.

C H A P T E R

18â•…

Disorders of the Larynx and Pharynx

LARYNGEAL PARALYSIS Laryngeal paralysis refers to failure of the arytenoid cartilages to abduct during inspiration, creating extrathoracic (upper) airway obstruction. The abductor muscles are innervated by the left and right recurrent laryngeal nerves. If clinical signs develop, both arytenoid cartilages are usually affected. The disease can affect dogs and cats, but dogs are more often presented with clinical signs. Etiology Potential causes of laryngeal paralysis are listed in Box 18-1, with the cause remaining idiopathic in most cases. Historically, dogs with idiopathic laryngeal paralysis were considered to have dysfunction limited to the laryngeal nerve. It is now believed that idiopathic laryngeal paralysis is part of a generalized neuromuscular disorder. A study by Stanley et╯al (2010) demonstrated that dogs with idiopathic laryngeal paralysis have esophageal dysfunction detected by swallowing studies. This study further showed that, on the basis of neurologic examination, these dogs will demonstrate signs of generalized neuromuscular disease within a year. Abnormal electrodiagnostic testing and histologic changes in peripheral nerves have also been reported (Thieman et╯al, 2010). Dogs with overt polyneuropathy-polymyopathy also may be presented with laryngeal paralysis as the predominant clinical sign. Polyneuropathies in turn have been associated with immune-mediated diseases, endocrinopathies, or other systemic disorders (see Chapter 68). Congenital laryngeal paralysis has been documented in the Bouvier des Flandres and is suspected in Siberian Huskies and Bull Terriers. A laryngeal paralysis-polyneuropathy complex has been described in young Dalmatians, Rottweilers, and Great Pyrenees. The possibility that a genetic predisposition exists in Labrador Retrievers, even though signs appear later in life, has been proposed on the basis of their over-representation in reports of laryngeal paralysis (Shelton, 2010). Direct damage to the laryngeal nerves or the larynx can also result in paralysis. Trauma or neoplasia involving the

ventral neck can damage the recurrent laryngeal nerves directly or through inflammation and scarring. Masses or trauma involving the anterior thoracic cavity can also cause damage to the recurrent laryngeal nerves as they course around the subclavian artery (right side) or the ligamentum arteriosum (left side). These causes are less commonly encountered. Clinical Features Laryngeal paralysis can occur at any age and in any breed, although it is most commonly seen in older large-breed dogs. Labrador Retrievers are over-represented. The disease is uncommon in cats. Clinical signs of respiratory distress and stridor are a direct result of narrowing of the airway at the arytenoid cartilages and vocal folds. The owner may also note a change in voice (i.e., bark or meow). Most patients are presented for acute respiratory distress, in spite of the chronic, progressive nature of this disease. Decompensation is frequently a result of exercise, excitement, or high environmental temperatures, resulting in a cycle of increased respiratory efforts; increased negative airway pressures, which suck the soft tissue into the airway; and pharyngeal edema and inflammation, which lead to further increased respiratory efforts. Cyanosis, syncope, and death can occur. Dogs in respiratory distress require immediate emergency therapy. Some dogs with laryngeal paralysis exhibit gagging or coughing with eating or drinking. These signs could be a result of secondary laryngitis or concurrent pharyngeal or proximal esophageal dysfunction. Rarely, dogs present primarily for signs of aspiration pneumonia. Diagnosis A definitive diagnosis of laryngeal paralysis is made through laryngoscopy (see p. 249). Movement of the arytenoid cartilages is observed during a light plane of anesthesia while the patient is taking deep breaths. In laryngeal paralysis the arytenoid cartilages and the vocal folds remain closed during inspiration and open slightly during expiration. The larynx does not exhibit the normal coordinated movement associated with breathing, opening on inspiration and closing on 253

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  BOX 18-1â•… Potential Causes of Laryngeal Paralysis Idiopathic Ventral Cervical Lesion

Trauma to nerves Direct trauma Inflammation Fibrosis Neoplasia Other inflammatory or mass lesion Anterior Thoracic Lesion

Neoplasia Trauma Postoperative Other Other inflammatory or mass lesion Polyneuropathy and Polymyopathy

Idiopathic Immune mediated Endocrinopathy Hypothyroidism Other systemic disorder Toxicity Congenital disease

  BOX 18-2â•… Diagnostic Evaluation of Dogs and Cats with Confirmed Laryngeal Paralysis Underlying Cause

Thoracic radiographs Cervical radiographs Serum biochemical panel Thyroid hormone evaluation Ancillary tests in select cases Evaluation for polyneuropathy-polymyopathy • Electromyography • Nerve conduction measurements Antinuclear antibody test Antiacetylcholine receptor antibody test Concurrent Pulmonary Disease

Thoracic radiographs Concurrent Pharyngeal Dysfunction

Evaluation of gag reflex Observation of patient swallowing food and water Fluoroscopic observation of barium swallow Concurrent Esophageal Dysfunction

Thoracic radiographs Contrast-enhanced esophagram Fluoroscopic observation of barium swallow

Myasthenia Gravis

expiration. Additional laryngoscopic findings may include laryngeal edema and inflammation. The larynx and the pharynx are also examined for neoplasia, foreign bodies, or other diseases that might interfere with normal function and for laryngeal collapse (see p. 252; Fig. 17-5). Once a diagnosis of laryngeal paralysis has been established, additional diagnostic tests should be considered to identify underlying or associated diseases, to rule out concurrent pulmonary problems (e.g., aspiration pneumonia) that may be contributing to the clinical signs, and to rule out concurrent pharyngeal and esophageal motility problems (Box 18-2). The latter is especially important if surgical correction for the treatment of laryngeal paralysis is being considered. Treatment In animals with respiratory distress, emergency medical therapy to relieve upper airway obstruction is indicated (see Chapter 26). Following stabilization and a thorough diagnostic evaluation, surgery is usually the treatment of choice. Even when specific therapy can be directed at an associated disease (e.g., hypothyroidism), complete resolution of clinical signs of laryngeal paralysis is rarely seen. Various laryngoplasty techniques have been described, including arytenoid lateralization (tie-back) procedures, partial laryngectomy, and castellated laryngoplasty. The goal

of surgery is to provide an adequate opening for the flow of air but not one so large that the animal is predisposed to aspiration and the development of pneumonia. Several operations to gradually enlarge the glottis may be necessary to minimize the chance of subsequent aspiration. The recommended initial procedure for most dogs and cats is unilateral arytenoid lateralization. If surgery is not an option, medical management consisting of antiinflammatory doses of short-acting glucocorticoids (e.g., prednisone, 0.5╯mg/kg given orally q12h initially) and cage rest may reduce secondary inflammation and edema of the pharynx and larynx and enhance airflow. For long-term management, situations resulting in prolonged or increased breathing efforts, such as heavy exercise, and high ambient temperatures are avoided. Exercise may need to be limited to leash walks or other routines where the intensity of activity is controlled. Prognosis The overall prognosis for dogs with laryngeal paralysis treated surgically is fair to good, despite evidence for progressive, generalized disease. As many as 90% of owners of dogs with laryngeal paralysis that underwent unilateral arytenoid lateralization consider the procedure successful 1 year or longer after surgery (Hammel et╯al, 2006; White, 1989). MacPhail et╯al (2001) reported a median survival time of

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1800 days (nearly 5 years) for 140 dogs that underwent various surgical procedures, although the mortality rate from postoperative complications was high, at 14%. The most common complication is aspiration pneumonia. A guarded prognosis is warranted for patients with signs of aspiration, dysphagia, megaesophagus, or overt systemic polyneuropathy or polymyopathy. A good prognosis was reported for a small number of cats undergoing unilateral arytenoid lateralization (Thunberg et╯al, 2010). Postoperative aspiration pneumonia was not reported, but care must be taken during surgery to minimize damage to the relatively fragile cartilages, and co-morbidities must be considered. A

BRACHYCEPHALIC AIRWAY SYNDROME The term brachycephalic airway syndrome, or upper airway obstruction syndrome, refers to the multiple anatomic abnormalities commonly found in brachycephalic dogs and, to a lesser extent, in short-faced cats such as Himalayans. The predominant anatomic abnormalities include stenotic nares, elongated soft palate, and, in Bulldogs, hypoplastic trachea. Prolonged upper airway obstruction resulting in increased inspiratory efforts may lead to eversion of the laryngeal saccules and, ultimately, to laryngeal collapse (see p. 252; Fig. 17-5). The severity of these abnormalities varies, and one or any combination of these abnormalities may be present in any given brachycephalic dog or short-faced cat (Fig. 18-1). Concurrent gastrointestinal signs such as ptyalism, regurgitation, and vomiting are common in dogs with brachycephalic airway syndrome (Poncet et╯al, 2005) Underlying gastrointestinal disease may be a concurrent problem in these breeds of dogs or may result from or may be exacerbated by increased intrathoracic pressures generated in response to the upper airway obstruction. Clinical Features Abnormalities associated with the brachycephalic airway syndrome impair the flow of air through the extrathoracic (upper) airways and cause clinical signs of upper airway obstruction, including loud breathing sounds, stertor, increased inspiratory efforts, cyanosis, and syncope. Clinical signs are exacerbated by exercise, excitement, and high environmental temperatures. The increased inspiratory effort commonly associated with this syndrome may cause secondary edema and inflammation of the laryngeal and pharyngeal mucosae and may enhance eversion of the laryngeal saccules or laryngeal collapse, further narrowing the glottis, exacerbating the clinical signs, and creating a vicious cycle. As a result, some dogs may be presented with life-threatening upper airway obstruction that requires immediate emergency therapy. Concurrent gastrointestinal signs are commonly reported. Diagnosis A tentative diagnosis is made on the basis of breed, clinical signs, and appearance of the external nares (Fig. 18-2).

B FIG 18-1â•…

Two Bulldog puppies (A) and a Boston Terrier (B) with brachycephalic airway syndrome. Abnormalities can include stenotic nares, elongated soft palate, everted laryngeal saccules, laryngeal collapse, and hypoplastic trachea.

Stenotic nares are generally bilaterally symmetric, and the alar folds may be sucked inward during inspiration, thereby worsening the obstruction to airflow. Laryngoscopy (see Chapter 17) and radiographic evaluation of the trachea (see Chapter 20) are necessary to fully assess the extent and severity of abnormalities. Most other causes of upper airway obstruction (see Chapter 26 and Boxes 16-1 and 16-2) can also be ruled in or out on the basis of the results of these diagnostic tests. Treatment Therapy should be designed to enhance the passage of air through the upper airways and to minimize the factors that exacerbate clinical signs (e.g., excessive exercise and excitement, overheating). Surgical correction of anatomic defects is the treatment of choice. The specific surgical procedure selected depends on the nature of the existing problems and can include widening of the external nares and removal of excessive soft palate and everted laryngeal saccules. Correction of stenotic nares is a simple procedure and can lead to a surprising alleviation of signs in affected patients.

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animals. Laryngeal collapse is generally considered a poor prognostic indicator, although a recent study demonstrated that even dogs with severe laryngeal collapse can respond well to surgical intervention (Torrez et╯al, 2006). Permanent tracheostomy can be considered as a salvage procedure in animals with severe collapse that are not responsive. A hypoplastic trachea is not surgically correctable, but there is no clear relationship between the degree of hypoplasia and morbidity or mortality. A

OBSTRUCTIVE LARYNGITIS

B

Nonneoplastic infiltration of the larynx with inflammatory cells can occur in dogs and cats, causing irregular proliferation, hyperemia, and swelling of the larynx. Clinical signs of an upper airway obstruction may result. The larynx may appear grossly neoplastic during laryngoscopy but is differentiated from neoplasia on the basis of the histopathologic evaluation of biopsy specimens. Inflammatory infiltrates can be granulomatous, pyogranulomatous, or lymphocytic-plasmacytic. Etiologic agents have not been identified. This syndrome is poorly characterized and probably includes several different diseases. Some animals respond to glucocorticoid therapy. Prednisone or prednisolone (1╯mg/ kg given orally q12h) is used initially. Once the clinical signs have resolved, the dose of prednisone can be tapered to the lowest amount that effectively maintains remission of clinical signs. Conservative excision of the tissue obstructing the airway may be necessary in animals with severe signs of upper airway obstruction or large granulomatous masses. The prognosis varies, depending on the size of the lesion, the severity of laryngeal damage, and the responsiveness of the lesion to glucocorticoid therapy.

FIG 18-2â•…

Cat with severely stenotic nares (A), as compared with the nares of a normal cat (B). Early correction of stenotic nares and other amenable upper airway obstructions, such as an elongated soft palate, is highly recommended.

Stenotic nares can be safely corrected at 3 to 4 months of age, ideally before clinical signs develop. The soft palate should be evaluated at the same time and corrected if elongated. Such early relief of obstruction should decrease the amount of negative pressure placed on pharyngeal and laryngeal structures during inspiration and should decrease progression of disease. Medical management consisting of the administration of short-acting glucocorticoids (e.g., prednisone, 0.5╯mg/kg given orally q12h initially) and cage rest may reduce the secondary inflammation and edema of the pharynx and larynx and enhance airflow, but it will not eliminate the problem. Emergency therapy may be required to alleviate the upper airway obstruction in animals presenting in respiratory distress (see Chapter 26). Weight management and concurrent treatment for gastrointestinal disease should not be neglected in patients with brachycephalic airway syndrome. Prognosis The prognosis depends on the severity of the abnormalities at the time of diagnosis and the ability to surgically correct them. Clinical signs will progressively worsen if the underlying problems go uncorrected. The prognosis after early surgical correction of the abnormalities is good for many

LARYNGEAL NEOPLASIA Neoplasms originating from the larynx are uncommon in dogs and cats. More commonly, tumors originating in tissues adjacent to the larynx, such as thyroid carcinoma and lymphoma, compress or invade the larynx and distort normal laryngeal structures. Clinical signs of extrathoracic (upper) airway obstruction result. Laryngeal tumors include carcinoma (squamous cell, undifferentiated, and adenocarcinoma), lymphoma, melanoma, mast cell tumors and other sarcomas, and benign neoplasia. Lymphoma is the most common tumor in cats. Clinical Features The clinical signs of laryngeal neoplasia are similar to those of other laryngeal diseases and include noisy respiration, stridor, increased inspiratory efforts, cyanosis, syncope, and a change in bark or meow. Mass lesions can also cause concurrent dysphagia, aspiration pneumonia, or visible or palpable masses in the ventral neck.

Diagnosis Extralaryngeal mass lesions are often identified by palpation of the neck. Primary laryngeal tumors are rarely palpable and are best identified by laryngoscopy. Laryngeal radiographs, ultrasonography, or computed tomography can be useful in assessing the extent of disease. Differential diagnoses include obstructive laryngitis, nasopharyngeal polyp, foreign body, traumatic granuloma, and abscess. Cytologic examination of fine-needle mass aspirates often provides a diagnosis. Yield and safety are increased with ultrasound guidance. A definitive diagnosis of neoplasia requires histologic examination of a biopsy specimen of the mass. A diagnosis of malignant neoplasia should not be made on the basis of gross appearance alone. Treatment The therapy used depends on the type of tumor identified histologically. Benign tumors should be excised surgically, if possible. Complete surgical excision of malignant tumors is rarely possible, although ventilation may be improved and time may be gained to allow other treatments such as radiation or chemotherapy to become effective. Complete laryngectomy and permanent tracheostomy may be considered in select animals. Prognosis The prognosis in animals with benign tumors is excellent if the tumors can be totally resected. Malignant neoplasms are associated with a poor prognosis. Suggested Readings Gabriel A et al: Laryngeal paralysis-polyneuropathy complex in young related Pyrenean mountain dogs, J Small Anim Pract 47:144, 2006. Hammel SP et al: Postoperative results of unilateral arytenoid lateralization for treatment of idiopathic laryngeal paralysis in dogs: 39 cases (1996-2002), J Am Vet Med Assoc 228:1215, 2006.

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Jakubiak MJ et al: Laryngeal, laryngotracheal, and tracheal masses in cats: 27 cases (1998-2003), J Am Anim Hosp Assoc 41:310, 2005. Lodato DL et al: Brachycephalic airway syndrome: pathophysiology and diagnosis, Compend Contin Educ Pract Vet 34:E1, 2012. MacPhail CM et al: Outcome of and postoperative complications in dogs undergoing surgical treatment of laryngeal paralysis: 140 cases (1985-1998), J Am Vet Med Assoc 218:1949, 2001. Poncet CM et al: Prevalence of gastrointestinal tract lesions in 73 brachycephalic dogs with upper respiratory syndrome, J Small Anim Pract 46:273, 2005. Riecks TW et al: Surgical correction of brachycephalic airway syndrome in dogs: 62 cases (1991-2004), J Am Vet Med Assoc 230:1324, 2007. Schachter S et al: Laryngeal paralysis in cats: 16 cases (1990-1999), J Am Vet Med Assoc 216:1100, 2000. Shelton DG: Acquired laryngeal paralysis in dogs: evidence accumulating for a generalized neuromuscular disease, Vet Surg 39:137, 2010. Stanley BJ et al: Esophageal dysfunction in dogs with idiopathic laryngeal paralysis: a controlled cohort study, Vet Surg 39:139, 2010. Thieman KM et al: Histopathological confirmation of polyneuropathy in 11 dogs with laryngeal paralysis, J Am Anim Hosp Assoc 46:161, 2010. Thunberg B et al: Evaluation of unilateral arytenoid lateralization for the treatment of laryngeal paralysis in 14 cats, J Am Anim Hosp Assoc 46:418, 2010. Torrez CV et al: Results of surgical correction of abnormalities associated with brachycephalic airway syndrome in dogs in Australia, J Small Anim Pract 47:150, 2006. White RAS: Unilateral arytenoid lateralisation: an assessment of technique and long term results in 62 dogs with laryngeal paralysis, J Small Anim Pract 30:543, 1989. Zikes C et al: Bilateral ventriculocordectomy via ventral laryngotomy for idiopathic laryngeal paralysis in 88 dogs, J Am Anim Hosp Assoc 48:234, 2012.

C H A P T E R

19â•…

Clinical Manifestations of Lower Respiratory Tract Disorders CLINICAL SIGNS In this discussion, the term lower respiratory tract disorders refers to diseases of the trachea, bronchi, bronchioles, alveoli, interstitium, and vasculature of the lung (Box 19-1). Dogs and cats with diseases of the lower respiratory tract are commonly seen for evaluation of cough. Lower respiratory tract diseases that interfere with the oxygenation of blood can result in respiratory distress, exercise intolerance, weakness, cyanosis, or syncope. Nonlocalizing signs such as fever, anorexia, weight loss, and depression also occur and are the only presenting sign in some animals. In rare instances, potentially misleading signs, such as vomiting, can occur in animals with lower respiratory tract disease. Auscultation and thoracic radiography help localize the disease to the lower respiratory tract in these animals. The two major presenting signs in animals with lower respiratory tract disease—cough and respiratory distress—can be further characterized by a careful history and physical examination.

COUGH A cough is an explosive release of air from the lungs through the mouth. It is generally a protective reflex to expel material from the airways, although inflammation or compression of the airways can also stimulate cough. Cough is sometimes caused by disease outside of the lower respiratory tract. Chylothorax can cause cough. Although not well documented in dogs or cats, gastroesophageal reflux and postnasal drip are common causes of cough in people. Classically, differential diagnoses for cough are divided into those that cause productive cough and those that cause nonproductive cough. A productive cough results in the delivery of mucus, exudate, edema fluid, or blood from the airways into the oral cavity. A moist sound can often be heard during the cough. Animals rarely expectorate the fluid, but swallowing can be seen after a coughing episode. If expectoration occurs, clients may confuse the cough with vomiting. In human medicine, categorizing cough as productive or nonproductive is rarely difficult 258

because the patient can report the coughing up of secretions. In veterinary medicine, recognition of a productive cough is more difficult. If the owner or veterinarian has heard or seen evidence that the cough is productive, it usually is. However, not hearing or seeing evidence of productivity does not rule out the possibility of its presence. Productive coughs are most commonly caused by inflammatory or infectious diseases of the airways or alveoli and by heart failure (Box 19-2). Cough in cats can be confused with attempts to vomit a hairball. Cats that never produce a hairball are likely coughing. Hemoptysis is the coughing up of blood. Blood-tinged saliva may be observed within the oral cavity or dripping from the commissures of the mouth after a cough. Hemoptysis is an unusual clinical sign that most commonly occurs in animals with heartworm disease or pulmonary neoplasia. Less common causes of hemoptysis are mycotic infection, foreign bodies, severe congestive heart failure, thromboembolic disease, lung lobe torsion, and some systemic bleeding disorders such as disseminated intravascular coagulation (see Box 19-2). Intensity of cough is useful in prioritizing the differential diagnoses. Cough associated with airway inflammation (i.e., bronchitis) or large airway collapse is often loud, harsh, and paroxysmal. The cough associated with tracheal collapse is often described as a “goose-honk.” Cough resulting from tracheal disease can usually be induced by palpation of the trachea, although concurrent involvement of deeper airways is possible. Cough associated with pneumonias and pulmonary edema is often soft. The association of coughing with temporal events can be helpful. Cough resulting from tracheal disease is exacerbated by pressure on the neck, such as pulling on the animal’s collar. Cough caused by heart failure tends to occur more frequently at night, whereas cough caused by airway inflammation (bronchitis) tends to occur more frequently upon rising from sleep or during and after exercise or exposure to cold air. The client’s perception of frequency may be biased by the times of day during which they have the

CHAPTER 19â•…â•… Clinical Manifestations of Lower Respiratory Tract Disorders

  BOX 19-1â•… Differential Diagnoses for Lower Respiratory Tract Disease in Dogs and Cats

  BOX 19-2â•… Differential Diagnoses for Productive Cough* in Dogs and Cats

Disorders of the Trachea and Bronchi

Edema

Canine infectious tracheobronchitis Canine chronic bronchitis Collapsing trachea Feline bronchitis (idiopathic) Allergic bronchitis Bacterial, including Mycoplasma, infections Oslerus osleri infection Neoplasia Foreign body Tracheal tear Bronchial compression Left atrial enlargement Hilar lymphadenopathy Neoplasia

Heart failure Noncardiogenic pulmonary edema

Disorders of the Pulmonary Parenchyma and Vasculature

Infectious diseases Viral pneumonias • Canine influenza • Canine distemper • Calicivirus • Feline infectious peritonitis Bacterial pneumonia Protozoal pneumonia • Toxoplasmosis Fungal pneumonia • Blastomycosis • Histoplasmosis • Coccidioidomycosis Parasitic disease • Heartworm disease • Pulmonary parasites • Paragonimus infection • Aelurostrongylus infection • Capillaria infection • Crenosoma infection Aspiration pneumonia Eosinophilic lung disease Idiopathic interstitial pneumonias Idiopathic pulmonary fibrosis Pulmonary neoplasia Pulmonary contusions Pulmonary hypertension Pulmonary thromboembolism Pulmonary edema

most contact with their pets, often in the evenings and during exercise. It is surprising to note that cats with many of the disorders listed in Box 19-2 do not cough. In cats that cough, the index of suspicion for bronchitis, lung parasites, and heartworm disease is high.

259

Mucus or Exudate

Canine infectious tracheobronchitis Canine chronic bronchitis Feline bronchitis (idiopathic)† Allergic bronchitis† Bacterial infection (bronchitis or pneumonia) Parasitic disease† Aspiration pneumonia Fungal pneumonia (severe) Blood (Hemoptysis)

Heartworm disease† Neoplasia Fungal pneumonia Thromboembolism Severe heart failure Foreign body Lung lobe torsion Systemic bleeding disorder *Because it can be difficult to determine the productive nature of a cough in veterinary medicine, these differential diagnoses should also be considered in patients with nonproductive cough. † Diseases of the lower respiratory tract most often associated with cough in cats. Cough in cats is rarely identified as productive.

EXERCISE INTOLERANCE AND RESPIRATORY DISTRESS Diseases of the lower respiratory tract can compromise the lung’s function of oxygenating the blood through a variety of mechanisms (see the section on blood gas analysis in Chapter 20). Clinical signs of such compromise begin as mildly increased respirations and subtly decreased activity and progress through exercise intolerance (manifested as reluctance to exercise or respiratory distress with exertion) to overt respiratory distress at rest. Because of compensatory mechanisms, the ability of most pets to self-regulate their activity, and the inability of pets to communicate, many veterinary patients with compromised lung function arrive in overt respiratory distress. Dogs in overt distress will often stand with their neck extended and elbows abducted. Movements of the abdominal muscles may be exaggerated. Healthy cats have minimally visible respiratory efforts. Cats that show noticeable chest excursions or open-mouth breathing are severely compromised. Patients in overt distress require rapid physical assessment and immediate stabilization before further diagnostic testing, as discussed in Chapter 26.

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Resting Respiratory Rate Resting respiratory rate can be used as an indicator of pulmonary function in patients that are not yet in respiratory distress. The measurement is ideally made at home by the owner, which spares the patient the stress of the veterinary hospital. The normal respiratory rate of a dog or cat without stress, at rest, is less than 20 respirations per minute. A rate of up to 30 respirations per minute is generally considered normal during a routine physical examination. Mucous Membrane Color Cyanosis, in which normally pink mucous membranes are bluish, is a sign of severe hypoxemia and indicates that the increased respiratory effort is not sufficiently compensating for the degree of respiratory dysfunction. Pallor of mucous membranes is a more common sign of acute hypoxemia resulting from respiratory disease. Breathing Pattern Patients in respiratory distress resulting from diseases of the lower respiratory tract, excluding the large airways, typically have rapid and often shallow respirations; increased expiratory or inspiratory efforts, or both; and abnormal lung sounds on auscultation. Patients with intrathoracic large airway obstruction (intrathoracic trachea and/or large bronchi) generally have normal to slightly increased respiratory rate; prolonged, labored expiration; and audible or auscultable expiratory sounds (see Chapter 26).

insufficiency is often an incidental finding, but the clinician must consider both cardiac and respiratory tract diseases as differential diagnoses in these animals. Mitral insufficiency can lead to left atrial enlargement with compression of the mainstem bronchi causing cough, or to congestive heart failure. Dogs in congestive heart failure are nearly always tachycardic, and any cough is usually soft. Other signs of heart disease include prolonged capillary refill time, weak or irregular pulses, abnormal jugular pulses, ascites or subcutaneous edema, gallop rhythms, and pulse deficits. Thoracic radiographs and occasionally echocardiography may be needed before cardiac problems can be comfortably ruled out as a cause of lower respiratory tract signs. Thoracic auscultation.╇ Careful auscultation of the upper airways and lungs is a critical component of the physical examination in dogs and cats with respiratory tract signs. Auscultation should be performed in a quiet location with the animal calm. Panting and purring do not result in deep inspiration, precluding evaluation of lung sounds. The heart and upper airways should be auscultated first. The clinician can then mentally subtract the contribution of these sounds from the sounds auscultated over the lung fields. Initially, the stethoscope is placed over the trachea near the larynx (Fig. 19-1). Discontinuous snoring or snorting sounds can be referred from the nasal cavity and pharynx as a result of obstructions stemming from structural abnormalities,

DIAGNOSTIC APPROACH TO DOGS AND CATS WITH LOWER RESPIRATORY TRACT DISEASE INITIAL DIAGNOSTIC EVALUATION The initial diagnostic evaluation of dogs or cats with signs of lower respiratory tract disease includes a complete history, physical examination, thoracic radiographs, and complete blood count (CBC). Further diagnostic tests are selected on the basis of information obtained from these procedures; these include the evaluation of specimens collected from the lower respiratory tract, tests for specific diseases, and arterial blood gas analysis. Historical information was discussed in previous paragraphs. Physical Examination Measurement of respiratory rate, assessment of mucous membrane color, and observation of the breathing pattern were described in the previous sections. A complete physical examination, including a fundic examination, is warranted to identify signs of disease that may be concurrently or secondarily affecting the lungs (e.g., systemic mycoses, metastatic neoplasia, megaesophagus). The cardiovascular system should be carefully evaluated. Mitral insufficiency murmurs are frequently auscultated in older small-breed dogs brought to the clinician with the primary complaint of cough. Mitral

4

1 3 2

FIG 19-1â•…

Auscultation of the respiratory tract begins with the stethoscope positioned over the trachea (stethoscope position 1). After upper airway sounds are assessed, the stethoscope is positioned to evaluate the cranioventral, central, and dorsal lung fields on both sides of the chest (stethoscope positions 2, 3, and 4). Note that the lung fields extend from the thoracic inlet to approximately the seventh rib along the sternum and to approximately the eleventh intercostal space along the spine (thin red line). Common mistakes are to neglect the cranioventral lung fields, reached by placing the stethoscope between the forelimb and the chest, and to position the stethoscope too far caudally, beyond the lung fields and over the liver. (Thick black line indicates position of the thirteenth rib.)

CHAPTER 19â•…â•… Clinical Manifestations of Lower Respiratory Tract Disorders

such as an elongated soft palate or mass lesions, and excessive mucus or exudate. Collapse of the extrathoracic trachea can also cause coarse sounds. Wheezes, which are continuous high-pitched sounds, occur in animals with obstructive laryngeal conditions, such as laryngeal paralysis, neoplasia, inflammation, and foreign bodies. Discontinuous snoring sounds and wheezes are known as stertor and stridor, respectively, when they can be heard without a stethoscope. The entire cervical trachea is then auscultated for areas of highpitched sounds caused by localized airway narrowing. Several breaths are auscultated with the stethoscope in each position, and the phase of respiration in which abnormal sounds occur is noted. Abnormal sounds resulting from extrathoracic disease are generally loudest during inspiration. The lungs are auscultated next. Normally, the lungs extend cranially to the thoracic inlet and caudally to about the seventh rib ventrally along the sternum and to approximately the eleventh intercostal space dorsally along the spine (see Fig. 19-1). The cranioventral, central, and dorsal lung fields on both the left and right sides are auscultated systematically. Any asymmetry in the sounds between the left and right sides is abnormal. Normal lung sounds have been described historically as a mixture of “bronchial” and “vesicular” sounds, although all sounds originate from the large airways. The bronchial sounds are most prominent in the central regions of the lungs. They are tubular sounds similar in character to those heard over the trachea, but they are quieter. Vesicular sounds are most prominent in the peripheral lung fields. They are soft and have been likened to a breeze blowing through leaves. These normal sounds are best described as “normal breath sounds.” Decreased lung sounds over one or both sides of the thorax occur in dogs and cats with pleural effusion, pneumothorax, diaphragmatic hernia, or mass lesions. It is surprising to note that consolidated lung lobes and mass lesions can result in enhanced lung sounds because of improved transmission of airway sounds from adjacent lobes. Abnormal lungs sounds are described as increased breath sounds (alternatively, harsh lung sounds), crackles, or wheezes. Increased breath sounds are a nonspecific finding but are common in patients with pulmonary edema or pneumonia. Crackles are nonmusical, discontinuous noises that sound like paper being crumpled or bubbles popping. Diseases resulting in the formation of edema or an exudate within the airways (e.g., pulmonary edema, infectious or aspiration pneumonia, bronchitis) and some interstitial pneumonias, particularly interstitial fibrosis, can result in crackles. Wheezes are musical, continuous sounds that indicate the presence of airway narrowing. Narrowing can occur as a result of bronchoconstriction, bronchial wall thickening, exudate or fluid within the bronchial lumen, intraluminal masses, or external airway compression. Wheezes are most commonly heard in cats with bronchitis. Wheezes caused by an intrathoracic airway obstruction are loudest during early expiration. Sudden snapping at the end of expiration can be heard in some dogs with intrathoracic tracheal collapse.

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Radiography Thoracic radiographs are indicated in dogs and cats with lower respiratory tract signs. Neck radiographs should also be obtained in animals with suspected tracheal disease. Radiography is perhaps the single most helpful diagnostic tool in the evaluation of dogs and cats with intrathoracic disease. It helps in localizing the problem to an organ system (i.e., cardiac, pulmonary, mediastinal, pleural), identifying the area of involvement within the lower respiratory tract (i.e., vascular, bronchial, alveolar, interstitial), and narrowing the list of potential differential diagnoses. It also helps in the formulation of a diagnostic plan (see Chapter 20). Additional diagnostic tests are necessary in most animals to establish a definitive diagnosis. Complete Blood Count The CBC of patients with lower respiratory tract disease may show anemia of inflammatory disease, polycythemia secondary to chronic hypoxia, or a white blood cell response characteristic of an inflammatory process of the lungs. The hematologic changes are insensitive, however, and an absence of abnormalities cannot be used as the basis for ruling out inflammatory lung disease. For instance, only half of dogs with bacterial pneumonia have a neutrophilic leukocytosis and a left shift. Abnormalities are not specific. For instance, eosinophilia is commonly encountered as a result of hypersensitivity or parasitic disease involving organs other than the lung. PULMONARY SPECIMENS AND SPECIFIC DISEASE TESTING On the basis of results of the history, physical examination, thoracic radiographs, and CBC, a prioritized list of differential diagnoses is developed. Additional diagnostic tests (Fig. 19-2) are nearly always required to achieve a definitive diagnosis, which is necessary for optimal therapy and outcome. Selection of appropriate tests is based on the most likely differential diagnoses, the localization of disease within the lower respiratory tract (e.g., diffuse bronchial disease, single mass lesion), the degree of respiratory compromise of the patient, and the client’s motivation for optimal care. Invasive and noninvasive tests are available. Noninvasive tests have the obvious advantage of being nearly risk free but are usually aimed at confirming a specific diagnosis. Most patients with lower respiratory tract disease require collection of a pulmonary specimen for microscopic and microbiologic analysis to further narrow the list of differential diagnoses or make a definitive diagnosis. Although the procedures for specimen collection from the lung are considered invasive, they carry varying degrees of risk, depending on the procedure used and the degree of respiratory compromise of the patient. The risk is minimal in many instances. Noninvasive tests include serology, urine antigen tests, and polymerase chain reaction (PCR) tests for pulmonary

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INITIAL EVALUATION History Physical examination Thoracic radiographs CBC

TESTS FOR COLLECTION OF PULMONARY SPECIMENS

TESTS FOR SPECIFIC DISEASES

TESTS OF PULMONARY FUNCTION

SPECIALIZED IMAGING TECHNIQUES

Tracheal washing Bronchoalveolar lavage Transthoracic lung aspiration/ biopsy Bronchoscopy and visually guided specimen collection Bronchial brushing Bronchial biopsy Bronchoalveolar lavage Transbronchial biopsy Thoracotomy or thoracoscopy with lung biopsy

Serology Heartworm disease Histoplasmosis Blastomycosis Coccidioidomycosis Toxoplasmosis Feline coronavirus Canine influenza Urine antigen tests Histoplasmosis Blastomycosis PCR tests Respiratory infectious disease panels Various individual organisms Fecal examination for parasites Flotation Baermann examination Sedimentation

Arterial blood gas analysis Pulse oximetry

Specialized radiography Fluoroscopy Angiography Computed tomography Magnetic resonance imaging Ultrasonography Nuclear imaging

FIG 19-2â•… Diagnostic approach for dogs and cats with lower respiratory tract disease.

pathogens, fecal examinations for parasites, and specialized imaging techniques such as fluoroscopy, angiography, computed tomography (CT), ultrasonography, magnetic resonance imaging (MRI), and nuclear imaging. Techniques for collection of pulmonary specimens that can be performed without specialized equipment include tracheal wash, bronchoalveolar lavage, and transthoracic lung aspiration. Visually guided specimens can be collected during bronchoscopy. Bronchoscopy offers the additional benefit of allowing visual assessment of the airways. If analysis of lung specimens and results of reasonable noninvasive tests do not provide a diagnosis in a patient with progressive disease, thoracoscopy or thoracotomy with lung biopsy is indicated. Valuable information about patients with lower respiratory tract disease can also be obtained by assessing lung

function through arterial blood gas analysis. Results are rarely helpful in making a final diagnosis, but they are useful in determining degree of compromise and in monitoring response to therapy. Pulse oximetry, a noninvasive technique used to measure oxygen saturation of the blood, is par� ticularly valuable in monitoring patients with respiratory compromise during anesthetic procedures or respiratory crises. Suggested Readings Hamlin RL: Physical examination of the pulmonary system, Vet Clin N Am Small Anim Pract 30:1175, 2000. Hawkins EC et al: Demographic and historical findings, including exposure to environmental tobacco smoke, in dogs with chronic cough, J Vet Intern Med 24:825, 2010.

C H A P T E R

20â•…

Diagnostic Tests for the Lower Respiratory Tract

THORACIC RADIOGRAPHY GENERAL PRINCIPLES Thoracic radiographs play an integral role in the diagnostic evaluation of dogs and cats with clinical signs related to the lower respiratory tract. They are also indicated for the evaluation of animals with vague, nonspecific signs of disease to detect occult pulmonary disease. Thoracic radiographs can be helpful in localizing disease processes, narrowing and prioritizing the differential diagnoses, determining the extent of disease involvement, and monitoring the progression of disease and response to treatment. A minimum of two views of the thorax should be taken in all dogs and cats. Right lateral and ventrodorsal (VD) views usually are preferred. The sensitivity of radiographs in the detection of lesions is improved if both right and left lateral views are obtained. These are indicated if disease of the right middle lung lobe, metastatic disease, or other subtle changes are suspected. The side of the lung away from the table is more aerated, thereby providing more contrast for soft tissue opacities, and is slightly magnified compared with the side against the table. Dorsoventral (DV) views are taken to evaluate the dorsal pulmonary arteries in animals with suspected heartworm disease, pulmonary thromboembolism, or pulmonary hypertension. The combination of DV and VD views offers the same advantages as the combination of right and left lateral views in detecting subtle changes in the dorsally oriented vessels. DV, rather than VD, views are taken to minimize stress in animals in respiratory distress. Horizontal beam lateral radiographs with the animal standing can be used to evaluate animals with suspected cavitary lesions or pleural effusion. Careful technique is essential to ensure that thoracic radiographs are obtained that yield useful information. Poor technique can lead to underinterpretation or overinterpretation of abnormalities. Appropriate exposure settings should be used and the settings recorded so that the same technique can be used when future images of the patient are obtained; this allows for more critical comparison of progression of disease. For nondigital systems, appropriate film selection

and development procedures should be used. Radiographs should be interpreted with proper lighting. The dog or cat should be restrained adequately to prevent movement, and a short exposure time used. Radiographs should be taken during maximum inspiration. Fully expanded lungs provide the greatest air contrast for soft tissue opacities, and motion is minimized during this phase of the respiratory cycle. Radiographic indications of maximum inspiration include widening of the angle between the diaphragm and the vertebral column (representing maximal expansion of caudal lung lobes); a lucent region in front of the heart shadow (representing maximal expansion of the cranial lung lobes); flattening of the diaphragm; minimal contact between the heart and the diaphragm; and a welldelineated, nearly horizontal vena cava. Radiographs of the lungs obtained during phases of respiration other than peak inspiration are difficult to interpret. For example, incomplete expansion of the lungs can cause increased pulmonary opacities to be seen that appear pathologic, resulting in misdiagnosis. Animals that are panting should be allowed to calm down before thoracic radiographs are obtained. A paper bag can be placed over the animal’s muzzle to increase the concentration of carbon dioxide in the inspired air, causing the animal to take deeper breaths. It may be necessary to sedate some animals. All structures of the thorax should be evaluated systematically in every animal to enhance diagnostic accuracy. Extrapulmonary abnormalities may develop secondary to pulmonary disease and may be the only radiographic finding (e.g., subcutaneous emphysema after tracheal laceration). Conversely, pulmonary disease may occur secondary to other evident thoracic diseases, such as mitral valve insufficiency, megaesophagus, and neoplasia of the body wall.

TRACHEA The trachea and, in young animals, the thymus are recognizable in the cranial mediastinum. Radiographs of the cervical trachea must be taken in dogs and cats with suspected upper airway obstruction or primary tracheal disease, most notably 263

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tracheal collapse. During evaluation of the trachea, it is important to obtain radiographs of the cervical portion during inspiration and of the thorax during both inspiration and expiration to identify dynamic changes in luminal diameter. Only the inner wall of the trachea should be visible. If the outer wall of the trachea is identified, this is suggestive of pneumomediastinum. The trachea normally has a uniform diameter and is straight, deviating ventrally from the vertebral bodies on lateral views as it progresses toward the carina. It may appear elevated near the carina if the heart is enlarged or if pleural effusion is present. Flexion or extension of the neck may cause bowing of the trachea. On VD views, the trachea may deviate to the right of midline in some dogs. The tracheal cartilage becomes calcified in some older dogs and chondrodystrophic breeds. The overall size and continuity of the tracheal lumen should also be evaluated. The normal tracheal lumen is nearly as wide as the laryngeal lumen. Hypoplastic tracheas have a lumen less than half the normal size (Fig. 20-1). Strictures and fractured cartilage rings can cause an abrupt, localized narrowing of the air stripe. Mass lesions in the tissues adjacent to the trachea can compress the trachea, causing a more gradual, localized narrowing of the air stripe. In animals with extrathoracic tracheal collapse, the tracheal air stripe may be narrowed in the cervical region during inspiration. In animals with intrathoracic tracheal collapse, the air stripe may be narrowed on thoracic films during expiration. Fluoroscopy, available primarily through referral centers, provides a more sensitive assessment of tracheal collapse. Finally, the air contrast of the trachea sometimes allows foreign bodies or masses to be visualized within the trachea. Most foreign bodies lodge at the level of the carina or within the bronchi. The inability to radiographically identify a foreign body does not rule out the diagnosis, however.

LUNGS The clinician must be careful not to overinterpret lung abnormalities on thoracic radiographs. A definitive diagnosis is not possible in most animals, and microscopic examination of pulmonary specimens, further evaluation of the heart, or testing for specific diseases is necessary. The lungs are examined for the possible presence of four major abnormal patterns: vascular, bronchial, alveolar, and interstitial. Mass lesions are considered with the interstitial patterns. Lung lobe consolidation, atelectasis, pulmonary cysts, and lung lobe torsions are other potential abnormalities. Animals in severe respiratory distress with normal thoracic radiograph findings usually have thromboembolic disease or have suffered a very recent insult to the lungs, such as trauma or aspiration (Box 20-1). Vascular Pattern The pulmonary vasculature is assessed by evaluating the vessels to the cranial lung lobes on the lateral view and the vessels to the caudal lung lobes on the VD or DV view. Normally, the blood vessels should taper gradually from the left atrium (pulmonary vein) or the right ventricle (pulmonary arteries) toward the periphery of the lungs. Companion arteries and veins should be similar in size. Arteries and veins have a consistent relationship with each other and with the associated bronchus. On lateral radiographs the pulmonary artery is dorsal and the pulmonary vein is ventral to the bronchus. On VD or DV radiographs the pulmonary artery is lateral and the pulmonary vein is medial to the bronchus. Vessels that are pointed directly toward or away from the X-ray beam are “end-on” and appear as circular nodules.

  BOX 20-1â•… Common Lower Respiratory Tract Differential Diagnoses for Dogs and Cats with Respiratory Signs and Normal Thoracic Radiographs Respiratory Distress

Pulmonary thromboembolism Acute aspiration Acute pulmonary hemorrhage Acute foreign body inhalation Cough

FIG 20-1â•…

Lateral radiograph of a Bulldog with a hypoplastic trachea. The tracheal lumen (narrow arrows) is less than half the size of the larynx (broad arrows).

Canine infectious tracheobronchitis Canine chronic bronchitis Collapsing trachea Feline bronchitis (idiopathic) Acute foreign body inhalation Gastroesophageal reflux* *Gastroesophageal reflux is a common cause of cough in people. Documentation in dogs and cats is limited, but the possibility should be considered.

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  BOX 20-2â•… Differential Diagnoses for Dogs and Cats with Abnormal Pulmonary Vascular Patterns on Thoracic Radiographs Enlarged Arteries

Heartworm disease Aelurostrongylosis (cats) Pulmonary thromboembolism Pulmonary hypertension Enlarged Veins

Left-sided heart failure Enlarged Arteries and Veins (Pulmonary Overcirculation)

Left-to-right shunts Patent ductus arteriosus Ventricular septal defect Atrial septal defect Small Arteries and Veins

Pulmonary undercirculation Cardiovascular shock Hypovolemia • Severe dehydration • Blood loss • Hypoadrenocorticism Pulmonic valve stenosis Hyperinflation of the lungs Feline bronchitis (idiopathic) Allergic bronchitis

They are distinguished from lesions by their association with a linear vessel and adjacent bronchus. Abnormal vascular patterns generally involve an increase or decrease in the size of arteries or veins (Box 20-2). The finding of arteries larger than their companion veins indicates the presence of pulmonary hypertension or thromboembolism, most commonly caused by heartworm disease—a finding seen in both dogs and cats (Fig. 20-2). The pulmonary arteries often appear tortuous and truncated in such animals. Concurrent enlargement of the main pulmonary artery and the right side of the heart may be seen in affected dogs. Interstitial, bronchial, or alveolar infiltrates may also be present in cats and dogs with heartworm disease as a result of concurrent inflammation, edema, or hemorrhage. Infection with Aelurostrongylus abstrusus can cause pulmonary artery enlargement. Veins larger than their companion arteries indicate the presence of congestion resulting from left-sided heart failure. Pulmonary edema may also be present. Dilation of both arteries and veins is an unusual finding, except in young animals. The finding of pulmonary overcirculation is suggestive of left-to-right cardiac or vascular shunts, such as patent ductus arteriosus and ventricular septal defects.

FIG 20-2â•…

Dilation of pulmonary arteries is apparent on this ventrodorsal view of the thorax in a dog with heartworm disease. The artery to the left caudal lung lobe is extremely enlarged. Arrowheads delineate the borders of the arteries to the left cranial and caudal lobes.

The finding of smaller-than-normal arteries and veins may indicate the presence of pulmonary undercirculation or hyperinflation. Undercirculation most often occurs in combination with microcardia resulting from hypoadrenocorticism or other causes of severe hypovolemia. Pulmonic stenosis may also cause radiographically visible undercirculation in some dogs. Hyperinflation is associated with obstructive airway disease, such as allergic or idiopathic feline bronchitis.

Bronchial Pattern Bronchial walls normally are most easily discernible radiographically at the hilus. They should taper and grow thinner as they extend toward the periphery of each lung lobe. Bronchial structures are not normally visible radiographically in the peripheral regions of the lungs. The cartilage may be calcified in older dogs and in chondrodystrophic breeds, making the walls more prominent but still sharply defined. A bronchial pattern is caused by thickening of the bronchial walls or bronchial dilation. Thickened bronchial walls are visible as “tram lines” and “doughnuts” in the peripheral regions of the lung (Fig. 20-3). Tram lines are produced by airways that run transverse to the X-ray beam, causing the appearance of parallel thick lines with an air stripe in

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FIG 20-3â•…

A bronchointerstitial pattern is present in this lateral radiograph from a cat with idiopathic bronchitis. The bronchial component results from thickening of the bronchial walls and is characterized by “doughnuts” and “tram lines.” In this radiograph the bronchial changes are most apparent in the caudal lung lobes.

between. Doughnuts are produced by airways that are pointing directly toward or away from the beam, causing a thick circle to be seen radiographically, with the airway lumen creating the “hole.” The walls of the bronchi tend to be indistinct. The finding of thickened walls indicates the presence of bronchitis and results from an accumulation of mucus or exudate along the walls within the lumens, an infiltration of inflammatory cells within the walls, muscular hypertrophy, epithelial hyperplasia, or a combination of these changes. Potential causes of bronchial disease are listed in Box 20-3. Chronic bronchial disease can result in irreversible dilation of the airways, which is termed bronchiectasis. It is identified radiographically by the presence of widened, nontapering airways (Fig. 20-4). Bronchiectasis can be cylindrical (tubular) or saccular (cystic). Cylindrical bronchiectasis is characterized by fairly uniform dilation of the airway. Saccular bronchiectasis additionally has localized dilations peripherally that can lead to a honeycomb appearance. All major bronchi are usually affected.

Alveolar Pattern Alveoli are not normally visible radiographically. Alveolar patterns occur when the alveoli are filled with fluid-dense material (Box 20-4). The fluid opacity may be caused by edema, inflammation, hemorrhage, or neoplastic infiltrates, which generally originate from the interstitial tissues. The fluid-filled alveoli are silhouetted against the walls of the airways they surround. The result is a visible stripe of air from the airway lumen in the absence of definable airway walls. This stripe is an air bronchogram (Fig. 20-5). If fluid continues to accumulate, the airway lumen eventually will

  BOX 20-3â•… Differential Diagnoses for Dogs and Cats with Bronchial Patterns on Thoracic Radiographs* Canine chronic bronchitis Feline bronchitis (idiopathic) Allergic bronchitis Canine infectious tracheobronchitis Bacterial infection Mycoplasmal infection Pulmonary parasites *Bronchial disease can occur in conjunction with parenchymal lung disease. See Boxes 20-4 to 20-6 for additional differential diagnoses if mixed patterns are present.

also become filled with fluid, resulting in the formation of solid areas of fluid opacity, or consolidation. When fluiddense regions are located at the edge of the lung lobe, a lobar sign occurs. The curvilinear edge of the affected lung lobe is visible in contrast with the adjacent, aerated lobe. Edema most often results from left-sided heart failure (see Chapter 22). In dogs the fluid initially accumulates in the perihilar region, and eventually the entire lung is affected. In cats patchy areas of edema can be present initially throughout the lung fields. The finding of enlarged pulmonary veins supports the cardiac origin of the infiltrates. Noncardiogenic edema is typically most severe in the caudal lung lobes. Inflammatory infiltrates can be caused by infectious agents, noninfectious inflammatory disease, or neoplasia.

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267

FIG 20-4â•…

Lateral radiograph of a dog with chronic bronchitis and bronchiectasis. The airway lumens are greatly enlarged, and normal tapering of the airway walls is not seen.

  BOX 20-4â•… Differential Diagnoses for Dogs and Cats with Alveolar Patterns on Thoracic Radiographs* Pulmonary Edema Severe Inflammatory Disease

Bacterial pneumonia Aspiration pneumonia Hemorrhage

Pulmonary contusion Pulmonary thromboembolism Neoplasia Fungal pneumonia Systemic coagulopathy *Any of the differential diagnoses for interstitial patterns (see Boxes 20-5 and 20-6) can cause an alveolar pattern if associated with severe inflammation, edema, or hemorrhage.

The location of the infiltrative process can often help establish a tentative diagnosis. For example, diseases of airway origin, such as most bacterial and aspiration pneumonias, primarily affect the dependent lung lobes (i.e., the right middle and cranial lobes and the left cranial lobe). In contrast, diseases of vascular origin, such as dirofilariasis, thromboemboli, systemic fungal infection, and bacterial infection of hematogenous origin, primarily affect the caudal lung

FIG 20-5â•…

Lateral view of the thorax of a dog with aspiration pneumonia. An alveolar pattern is evident by the increased soft tissue opacity with air bronchograms. Air bronchograms are bronchial air stripes without visible bronchial walls. In this radiograph the pattern is most severe in the ventral (dependent) regions of the lung, consistent with bacterial or aspiration pneumonia.

lobes. Localized processes involving only one lung lobe suggest the presence of a foreign body, neoplasia, abscess, granuloma, or lung lobe torsion. Hemorrhage usually results from trauma. Thromboembolism, neoplasia, coagulopathies, and fungal infections can also cause hemorrhage into the alveoli.

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  BOX 20-5â•… Differential Diagnoses for Dogs and Cats with Nodular Interstitial Patterns Neoplasia Mycotic Infection

Blastomycosis Histoplasmosis Coccidioidomycosis Pulmonary Parasites

Aelurostrongylus infection Paragonimus infection Abscess

Bacterial pneumonia Foreign body Eosinophilic Lung Disease

FIG 20-6â•…

Lateral view of the thorax in a dog with blastomycosis. A miliary, nodular interstitial pattern is present. Increased soft tissue opacity above the base of the heart may be the result of hilar lymphadenopathy.

Idiopathic Interstitial Pneumonia Inactive Lesions

Interstitial Pattern The pulmonary interstitial tissues confer a fine, lacy pattern to the pulmonary parenchyma of many dogs and cats as they age, in the absence of clinically apparent respiratory disease. They are not normally visible on inspiratory radiographs in young adult animals. Abnormal interstitial patterns are reticular (unstructured), nodular, or reticulonodular in appearance. A nodular interstitial pattern is characterized by the finding of roughly circular, fluid-dense lesions in one or more lung lobes. However, the nodules must be nearly 1╯cm in diameter to be routinely detected. Interstitial nodules may represent active or inactive inflammatory lesions or neoplasia (Box 20-5). Active inflammatory nodules often have poorly defined borders. Mycotic infections typically result in the formation of multiple, diffuse nodules. The nodules may be small (miliary; Fig. 20-6) or large and coalescing. Parasitic granulomas are often multiple, although paragonimiasis can result in the formation of a single pulmonary nodule. Abscesses can form as a result of foreign bodies or as a sequela to bacterial pneumonia. Nodular patterns may also be seen on the radiographs obtained in animals with some eosinophilic lung diseases and idiopathic interstitial pneumonias. Inflammatory nodules can persist as inactive lesions after the disease resolves. In contrast to active inflammatory nodules, however, the borders of inactive nodules are often well demarcated. Nodules may become mineralized in some conditions, such as histoplasmosis. Well-defined, small, inactive nodules are sometimes seen in healthy older dogs without a history of disease. Radiographs taken several months later in these animals typically show no change in the size of these inactive lesions.

FIG 20-7â•…

Lateral view of the thorax of a dog with malignant neoplasia. A well-circumscribed, solid, circular mass is present in the caudal lung field. Papillary adenocarcinoma was diagnosed after surgical excision.

Neoplastic nodules may be singular or multiple (Fig. 20-7). They are often well defined, although secondary inflammation, edema, or hemorrhage can obscure the margins. No radiographic pattern is diagnostic for neoplasia. Lesions caused by parasites, fungal infections, and some eosinophilic lung diseases or idiopathic interstitial pneumonias may be indistinguishable from neoplastic lesions. In the absence of strong clinical evidence, malignant neoplasia must be confirmed cytologically or histologically. If this is not possible, radiographs can be obtained again 4 weeks later to evaluate for progression of disease. Neoplastic involvement of the pulmonary parenchyma cannot be totally excluded on the basis of thoracic radiograph findings because malignant cells are present for a while before lesions reach a radiographically detectable size. The sensitivity of radiography in identifying neoplastic nodules can be improved by obtaining left and right lateral views of the thorax.

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269

FIG 20-8â•…

Lateral radiograph of a dog with pulmonary carcinoma. An unstructured pattern is present, as is an increased bronchial pattern.

The reticular interstitial pattern is characterized by a diffuse, unstructured, lacy increase in the opacity of the pulmonary interstitium, which partially obscures normal vascular and airway markings. Reticular interstitial patterns frequently occur in conjunction with nodular interstitial patterns (also called reticulonodular patterns) and alveolar and bronchial patterns (Fig. 20-8). Increased reticular interstitial opacity can result from edema, hemorrhage, inflammatory cells, neoplastic cells, or fibrosis within the interstitium (Box 20-6). The interstitial space surrounds the airways and vessels and is normally extremely small in dogs and cats. With continued accumulation of fluid or cells, however, the alveoli can become flooded, which produces an alveolar pattern. Visible focal interstitial accumulations of cells, or nodules, can also develop with time. Any of the diseases associated with alveolar and interstitial nodular patterns can cause a reticular interstitial pattern early in the course of disease (see Boxes 20-4 and 20-5). This pattern is also often seen in older dogs with no clinically apparent disease, presumably as a result of pulmonary fibrosis; this further decreases the specificity of the finding.

Lung Lobe Consolidation Lung lobe consolidation is characterized by a lung lobe that is entirely of soft tissue opacity (Fig. 20-9, A). Consolidation occurs when an alveolar or interstitial disease process progresses to the point at which the entire lobe is filled with fluid or cells. Common differential diagnoses for lung lobe consolidation are severe bacterial or aspiration pneumonia (essentially resulting in an abscess of the entire lobe), neoplasia, lung lobe torsion, and hemorrhage. Inhalation of

  BOX 20-6â•… Differential Diagnoses for Dogs and Cats with Reticular (Unstructured) Interstitial Patterns Pulmonary Edema (Mild) Infection

Viral pneumonia Bacterial pneumonia Toxoplasmosis Mycotic pneumonia Parasitic infection (more often bronchial or nodular interstitial pattern) Neoplasia Eosinophilic Lung Disease Idiopathic Interstitial Pneumonia

Idiopathic pulmonary fibrosis Hemorrhage (Mild)

plant material can also result in consolidation of the involved lung lobe as a result of the inflammatory reaction to foreign material and secondary infection. This differential diagnosis should be considered especially in regions of the country where foxtails are prevalent.

Atelectasis Atelectasis is also characterized by a lobe that is entirely of soft tissue opacity. In this instance the lobe is collapsed as a

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A

B

C

FIG 20-9â•…

Thoracic radiographs from three different patients, ventrodorsal projections. Radiograph A shows consolidation of the right middle lung lobe caused by neoplasia. Note that the soft tissue density of the lung silhouettes with the shadow of the heart. Radiograph B shows atelectasis of the middle region of the right lung and marked hyperinflation of the remaining lungs in a cat with idiopathic bronchitis. Note the shift of the heart shadow toward the collapsed region. Radiograph C shows atelectasis of the right middle lung lobe in another cat with idiopathic bronchitis. In this patient the adjacent lung lobes have expanded into the area previously occupied by the right middle lobe, preventing displacement of the heart.

result of airway obstruction. All the air within the lobe has been absorbed and not replaced. It is distinguished from consolidation by the small size of the lobe (see Fig. 20-9, B). Often the heart is displaced toward the atelectatic lobe. Atelectasis is most commonly seen involving the right middle lobe of cats with bronchitis (see Fig. 20-9, C). Displacement of the heart may not occur in these cats.

Cavitary Lesions Cavity lesions describe any abnormal air accumulation in the lung. They can be congenital, acquired, or idiopathic. Specific types of cavitary lesions include bullae, which result from ruptured alveoli due to congenital weakness of tissues and/or small airway obstruction, as seen in some cats with idiopathic bronchitis; blebs, which are bullae located within the pleura; and cysts, which are cavitary lesions lined by airway epithelium. Parasitic “cysts” (not lined by epithelium) can form around Paragonimus worms. Thoracic trauma is a common cause of cavitary lesions. Other differential diagnoses include neoplasia, lung infarction (from thromboembolism), abscess, and granuloma. Cavitary lesions may be apparent as localized accumulations of air or fluid, often with a partially visible wall (Fig. 20-10). An air-fluid interface may be visible when standing horizontal beam projections are used. Bullae and blebs are rarely apparent radiographically. Cavitary lesions may be discovered incidentally or on thoracic radiographs of dogs and cats with spontaneous

pneumothorax. If pneumothorax is present, surgical excision of the lesion is usually indicated (see Chapter 25). If inflammatory or neoplastic disease is suspected, further diagnostic testing is indicated. If the lesion is found incidentally, animals can be periodically reevaluated radiographically to determine whether the lesion is progressing or resolving. If the lesion does not resolve during the course of 1 to 3 months, surgical removal is considered for diagnostic purposes and to prevent potentially life-threatening spontaneous pneumothorax.

Lung Lobe Torsion Lung lobe torsion can develop spontaneously in deepchested dogs or as a complication of pleural effusion or pneumonectomy in dogs and cats. The right middle and left cranial lobes are most commonly involved. The lobe usually twists at the hilus, obstructing the flow of blood into and out of the lung lobe. Venous drainage is obstructed before arterial flow, causing the lung lobe to become congested with blood. Over time, air is absorbed from the alveoli and ate� lectasis can occur. Lung lobe torsion is difficult to identify radiographically. Severe bacterial or aspiration pneumonia resulting in consolidation of these same lobes is far more common and produces similar radiographic changes. The finding of pulmonary vessels or bronchi traveling in an abnormal direction is strongly suggestive of torsion. Unfortunately, pleural fluid, if not present initially, often develops and obscures the

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271

ULTRASONOGRAPHY Ultrasonography is used to evaluate pulmonary mass lesions adjacent to the body wall, diaphragm, or heart and also consolidated lung lobes (Fig. 20-11). Because air interferes with sound waves, aerated lungs and structures surrounded by aerated lungs cannot be examined. However, some patients with a reticular interstitial pattern on thoracic radiographs have sufficient infiltrates to be visualized where they abut the body wall. The consistency of lesions often can be determined to be solid, cystic, or fluid filled. Some solid masses are hypolucent and appear to be cystic on ultrasonograms. Vascular structures may be visible, particularly with Doppler ultrasound, and this can be helpful in identifying lung lobe torsion. Ultrasonography can also be used to guide needles or biopsy instruments into solid masses for specimen collection. It is used in evaluating the heart of animals with clinical signs that cannot be readily localized to the cardiac or the respiratory system. Ultrasonographic evaluation of patients with pleural disorders is discussed in Chapter 24.

COMPUTED TOMOGRAPHY AND MAGNETIC RESONANCE IMAGING

FIG 20-10â•…

Ventrodorsal view of the thorax in a cat showing a cystic lesion (arrowheads) in the left caudal lung lobe. Differential diagnoses included neoplasia and Paragonimus infection.

radiographic image of the affected lobe. Ultrasonography is often useful in detecting a torsed lung lobe. Bronchoscopy, bronchography, computed tomography, or thoracotomy is necessary to confirm the diagnosis in some animals.

ANGIOGRAPHY Angiography can be used to confirm a diagnosis of pulmonary thromboembolism. Obstructed arteries are blunted or do not show the normal gentle taper and arborization. Arteries may appear dilated and tortuous. Localized areas of extravasated contrast agent may also be noted. If several days have elapsed since embolization occurred, however, lesions may no longer be identifiable; therefore angiography should be performed as soon as the disorder is suspected and the animal’s condition has stabilized. Angiography may also be used as a confirmatory test in cats with presumptive dirofilariasis but negative adult antigen blood test results and echocardiographic findings (see Chapter 10).

Computed tomography (CT) and magnetic resonance imaging (MRI) are used routinely in human medicine for the diagnostic evaluation of lung disease. The accessibility of CT in particular has led to its increased use in dogs and cats. The resultant three-dimensional images are more sensitive and specific for the identification of certain airway, vascular, and parenchymal diseases as compared with thoracic radiography. In one study of dogs with metastatic neoplasia, only 9% of nodules detected by CT were identified by thoracic radiography (Nemanic et╯al, 2006). Examples of cases that may benefit from CT include those with possible metastatic disease; possible pulmonary thromboembolism; idiopathic interstitial pneumonias, including idiopathic pulmonary fibrosis; or potentially excisable disease (to determine the extent and location of disease and the potential involvement of other structures, such as the major vessels). The application of CT and MRI to the diagnosis of specific canine and feline pulmonary diseases requires further investigation.

NUCLEAR IMAGING Mucociliary clearance can be measured by placing a drop of technetium-labeled albumin at the carina and observing its movement with a gamma camera to assist in the diagnosis of ciliary dyskinesia. Nuclear imaging can be used for the relatively noninvasive measurement of pulmonary perfusion and ventilation, valuable for the diagnosis of pulmonary thromboembolism. Restrictions for handling radioisotopes

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A

B

C FIG 20-11â•…

Multiple pulmonary nodules are easily visible on the lateral radiograph (A) from a cat with a 1-year history of cough and recent episodes of respiratory distress with wheezing. Nodules do not obviously extend to the chest wall as seen on the ventrodorsal radiograph (B). However, a 1-cm mass was found on ultrasonographic examination of the right thorax (C; a red line has been positioned between ultrasound markers to indicate site of measurement). An ultrasound-guided aspirate was performed. The presence of eosinophils in the aspirate prompted the performance of fecal examinations for pulmonary parasites, and a diagnosis of paragonimiasis was made through identification of characteristic ova.

and the need for specialized recording equipment limit the availability of these tools to specialty centers.

PARASITOLOGY Parasites involving the lower respiratory tract are identified by direct observation, blood tests, cytologic analysis of respiratory tract specimens, or fecal examination. Oslerus osleri reside in nodules near the carina, which can be identified bronchoscopically. Rarely, other parasites may be seen. Blood tests are often used to diagnose heartworm disease (see Chapter 10). Larvae that may be present in fluid from tracheal or bronchial washings include O. osleri, Aelurostrongylus abstrusus (Fig. 20-12, A), and Crenosoma vulpis (see Fig. 20-12, B). Eggs that may be present include those of Capillaria (Eucoleus) aerophila and Paragonimus kellicotti (see Fig. 20-12, C and D). Larvated eggs or larvae from Filaroides hirthi or Aelurostrongylus milksi can be present but are rarely

associated with clinical signs. The more common organisms are described in Table 20-1. The hosts of lung parasites generally cough up and swallow the eggs or larvae, which then are passed in the feces to infect the next host or an intermediate host. Fecal examination for eggs or larvae is a simple, noninvasive tool for the diagnosis of such infestations. However, because shedding is intermittent, parasitic disease cannot be included solely on the basis of negative fecal examination findings. Multiple (at least three) examinations should be performed in animals that are highly suspected of having parasitic disease. If possible, several days should be allowed to elapse between collections of feces. Routine fecal flotation can be used to concentrate eggs from C. aerophila. High-density fecal flotation (specific gravity [s.g.], 1.30 to 1.35) can be used to concentrate P. kellicotti eggs. Sedimentation techniques are preferred for concentrating and identifying P. kellicotti eggs, particularly if few eggs are present. Larvae are identified through the use of the Baermann technique. However, O. osleri larvae are

CHAPTER 20â•…â•… Diagnostic Tests for the Lower Respiratory Tract

A

B

C

D

273

FIG 20-12â•…

A, Larva of Aelurostrongylus abstrusus. B, Larva of Crenosoma vulpis. C, Double operculated ova of Capillaria sp. D, Single operculated ova of Paragonimus kellicotti.

  TABLE 20-1â•… Characteristics of Eggs or Larvae from Respiratory Parasites PARASITE

HOST

STAGE

SOURCE

DESCRIPTION

Capillaria aerophila

Dog and cat

Eggs

Routine flotation of feces, airway specimens

Barrel shaped, yellow, with prominent, transparent, asymmetric bipolar plugs; slightly smaller than Trichuris eggs; 60-80╯µm × 30-40╯µm

Paragonimus kellicotti

Dog and cat

Eggs

High-density flotation or sedimentation of feces, airway specimens

Oval, golden-brown, single, operculated; operculum flat with prominent shoulders; 75-118╯µm × 42-67╯µm

Aelurostrongylus abstrusus

Cat

Larvae

Baermann technique of feces, airway specimens

Larvae with S-shaped tail; dorsal spine present; 350-400╯µm × 17╯µm; eggs or larvated eggs may be seen in airway specimens

Oslerus osleri

Dog

Larvae, eggs

Tracheal wash, bronchial brushing of nodules, zinc-sulfate flotation of feces

Larvae have S-shaped tail without dorsal spine; rarely found eggs are thin-walled, colorless, and larvated; 80╯µm × 50╯µm

Crenosoma vulpis

Dog

Larvae

Baermann technique of feces, airway specimens

Larvae have tapered tail without severe kinks or spines; 250-300╯µm; larvated eggs may be seen in airway specimens

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insufficiently motile for reliable identification with this technique, and zinc sulfate (s.g., 1.18) flotation is recommended. Even so, false-negative results are common in cases with O. osleri. All of these techniques can be readily performed at minimal expense. Methods for sedimentation and the Baermann technique are described in Boxes 20-7 and 20-8. Toxoplasma gondii occasionally causes pneumonia in dogs and cats. Dogs do not shed Toxoplasma organisms in the feces, but cats may. However, the shedding of eggs is part of the direct life cycle of the organisms and does not correlate with the presence of systemic disease resulting from the indirect cycle. Infection is therefore diagnosed by the finding of tachyzoites in pulmonary specimens or indirectly on the basis of serologic findings. Migrating intestinal parasites can cause transient pulmonary signs in young animals. Migration most often occurs

  BOX 20-7â•… Sedimentation of Feces for Concentration of Eggs 1. Homogenize 1 to 3╯g of feces with water (at least 30╯mL). 2. Pass through coarse sieve or gauze (250-µm mesh), washing debris remaining in sieve with fine spray of water. 3. Pour filtrate into conical urine flask, and let stand for 2 minutes. 4. Discard most of supernate. 5. Pour remaining 12 to 15╯mL into flat-bottomed tube, and let stand for 2 minutes. 6. Draw off supernate. 7. Add 2 to 3 drops of 5% methylene blue. 8. Examine under low power. Data from Urquhart GM et╯al: Veterinary parasitology, ed 2, Oxford, 1996, Blackwell Science.

  BOX 20-8â•… Baermann Technique for Concentration of Larvae 1. Set up apparatus. a. Glass funnel supported in ring stand b. Rubber tube attached to bottom of funnel, and closed with a clamp c. Coarse sieve (250-µm mesh) placed in top of funnel d. Double-layer gauze on top of sieve 2. Place feces on gauze in funnel. 3. Fill funnel slowly with water to immerse feces. 4. Leave overnight at room temperature. 5. Collect water via rubber tube from neck of funnel in a Petri dish. 6. Examine under low power. Data from Urquhart GM et╯al: Veterinary parasitology, ed 2, Oxford, 1996, Blackwell Science.

before the mature adults develop in the intestine, thus eggs may not be found in feces.

SEROLOGY Serologic tests can detect a variety of pulmonary pathogens. Antibody tests provide only indirect evidence of infection, however. In general, they should be used only to confirm a suspected diagnosis, not to screen for disease. Whenever possible, identification of infectious organisms is the preferred method of diagnosis. Tests available for common pulmonary pathogens include those for Histoplasma, Blastomyces, Coccidiodomyces, Toxoplasma, and feline coronavirus. These tests are discussed fully in Chapter 89. Antibody tests for canine influenza are discussed further in Chapter 22. Serum antigen tests for Cryptococcus (see Chapter 95) and adult heartworms are also available (see Chapter 10). Antibody tests for dirofilariasis are available and are used primarily to support the diagnosis of feline heartworm disease (see Chapter 10).

URINE ANTIGEN TESTS Antigen tests that can be performed on urine specimens are available for the detection of histoplasma and blastomyces antigens. The test for blastomyces is more sensitive than serum antibody testing by agar gel immunodiffusion for the diagnosis of blastomycosis (Spector et╯al, 2008). Studies have not been published regarding the test for histoplasma antigen.

POLYMERASE CHAIN REACTION TESTS Molecular diagnostic tests are available for identification of a wide range of individual respiratory pathogens. Panels of tests are commercially available for multiple agents commonly involved in acute respiratory tract infection in dogs or cats. Specimens that can be tested include swabs from the oropharynx, nasal cavity, or conjunctiva; tracheal wash or bronchoalveolar lavage specimens; airway brushings; and tissue. Best results are obtained when the timing and the site of collection are chosen on the basis of the pathophysiology of the target organism. Consultation with the diagnostic laboratory is recommended for specimen collection and handling to maximize results.

TRACHEAL WASH Indications and Complications Tracheal wash can yield valuable diagnostic information in animals with cough or respiratory distress resulting from disease of the airways or pulmonary parenchyma and in animals with vague presenting signs and pulmonary abnormalities detected on thoracic radiographs (i.e., most animals

CHAPTER 20â•…â•… Diagnostic Tests for the Lower Respiratory Tract

with lower respiratory tract disease). Tracheal wash is generally performed after results of the history, physical examination, and thoracic radiography, and other routine components of the database are known. Tracheal wash provides fluid and cells that can be used to identify diseases involving the major airways while bypassing the normal flora and debris of the oral cavity and pharynx. The fluid obtained is evaluated cytologically and microbiologically and therefore should be collected before antibiotic treatment is initiated whenever possible. Tracheal wash is likely to provide a representative specimen in patients with bronchial or alveolar disease (Table 20-2). It is less likely to identify interstitial and small focal disease processes. However, the procedure is inexpensive and minimally invasive, and this makes it reasonable to perform in most animals with lower respiratory tract disease if the risks of other methods of specimen collection are deemed too great. Potential complications are rare and include tracheal laceration, subcutaneous emphysema, and pneumomediastinum. Bronchospasm may be induced by the procedure in patients with hyperreactive airways, particularly cats with bronchitis.

TECHNIQUES Tracheal wash is performed with the use of transtracheal or endotracheal techniques. Transtracheal wash is performed by passing a catheter into the trachea to the level of the carina through the cricothyroid ligament or between the tracheal rings in an awake or sedated animal. Endotracheal wash is performed by passing a catheter through an endotracheal tube in an anesthetized animal. The endotracheal technique is preferred in cats and very small dogs, although either technique can be used in any animal. Patients with airways that may be hyperreactive, particularly cats, are treated with bronchodilators (see the section on endotracheal technique). Transtracheal Technique Transtracheal wash fluid is collected using an 18- to 22-gauge through-the-needle intravenous catheter (e.g., Intracath; Becton, Dickinson and Company, Franklin Lakes, New Jersey). The catheter should be long enough to reach the carina, which is located at approximately the level of the fourth intercostal space. The longest intravenous catheter available may measure 12 inches (30╯cm), which is long enough to reach from the cricothyroid ligament to the carina in most dogs. However, it may be necessary to insert the catheter between tracheal rings in giant-breed dogs to ensure that it reaches the carina. Alternatively, a 14-gauge, short, over-the-needle catheter is used to enter the trachea at the cricothyroid ligament, and a 3.5F polypropylene male dog urinary catheter is passed through the catheter into the airways. The ability of the urinary catheter to pass through the 14-gauge catheter should be tested each time before the procedure is performed. The dog can sit or lie down, depending on what position is more comfortable for the animal and the clinician. The

275

dog is restrained with its nose pointing toward the ceiling at about 45 degrees from horizontal (Fig. 20-13, A). Overextension of the neck causes the animal to be more resistant. Dogs that cannot be restrained should be tranquilized. If tranquilization is needed, premedication with atropine or glycopyrrolate is recommended to minimize contamination of the trachea with oral secretions. Narcotics are avoided to preserve the cough reflex, which can facilitate the retrieval of fluid. The cricothyroid ligament is identified by palpating the trachea in the ventral cervical region and following it dorsally toward the larynx to the raised, smooth, narrow band of the cricoid cartilage. Immediately above the cricoid cartilage is a depression, where the cricothyroid ligament is located (see Fig. 20-13, B). If the trachea is entered above the cricothyroid ligament, the catheter is passed dorsally into the pharynx and a nondiagnostic specimen is obtained. Such dorsal passage of the catheter often results in excessive gagging and retching. Lidocaine is always injected subcutaneously at the site of entry. The skin over the cricothyroid ligament is prepared surgically, and sterile gloves are worn to pass the catheter. The needle of the catheter is held with the bevel facing ventrally. The skin over the ligament is then tented, and the needle is passed through the skin. The larynx is stabilized with the nondominant hand. To properly stabilize it, the clinician should grasp at least 180 degrees of the circumference of the airway between the fingers and the thumb. Failure to hold the airway firmly is the most common technical mistake. Next, the tip of the needle is rested against the cricothyroid ligament and inserted through the ligament with a quick, short motion. The hand stabilizing the trachea is then used to pinch the needle at the skin, with the hand kept firmly in contact with the neck, while the catheter is threaded into the trachea with the other hand. By keeping the hand holding the needle against the neck of the animal so that the hand, needle, and neck can move as one, the clinician prevents laceration of the larynx or trachea and inadvertent removal of the needle from the trachea. Threading the catheter provokes coughing. Little or no resistance to passage of the catheter should be noted. Elevating the hub of the needle slightly so that the tip points more ventrally or retracting the needle a few millimeters facilitates passage of the catheter if it is lodged against the opposite tracheal wall. The catheter itself should not be pulled back through the needle because the tip can be sheared off within the airway by the cutting edge of the needle. Once the catheter has been completely threaded into the airway, the needle is withdrawn and the catheter guard is attached to prevent shearing of the catheter. The person restraining the animal now holds the catheter guard against the neck of the animal so that movement of the neck will not dislodge the catheter. The head can be restrained in a natural position. It is convenient to have four to six 12-mL syringes ready, each filled with 3 to 5╯mL of 0.9% sterile preservative-free

Ideal specimen Allows histologic examination in addition to culture

Large

Small airways, alveoli, interstitium

Thoracotomy or thoracoscopy with lung biopsy

Simple technique Minimal expense No special equipment Solid masses adjacent to body wall: excellent representation with minimal risk

Small

Interstitium, alveoli when flooded

Lung aspirate

Simple technique Nonbronchoscopic technique requires no special equipment and minimal expense Bronchoscopic technique allows airway evaluation and directed sampling Resultant hypoxemia is transient and responsive to oxygen supplementation Safe for animals in stable condition Large volume of lung sampled High cytologic quality Large volume for analysis

Large

Small airways, alveoli, sometimes interstitium

Bronchoalveolar lavage

ADVANTAGES

Simple technique Minimal expense No special equipment Complications rare Volume adequate for cytology and culture

SPECIMEN SIZE

Moderate

Large airways

SITE OF COLLECTION

Tracheal wash

TECHNIQUE

Comparisons of Techniques for Collecting Specimens from the Lower Respiratory Tract

  TABLE 20-2â•…

Localized process where excision may be therapeutic as well as diagnostic Any progressive disease not diagnosed by less invasive methods

Solid masses adjacent to chest wall (for solitary/localized disease, see also Thoracotomy or Thoracoscopy with Lung Biopsy) Diffuse interstitial disease Potential for complications: pneumothorax, hemothorax, pulmonary hemorrhage Relatively small area of lung sampled Specimen adequate only for cytology Specimen blood contaminated Relatively expensive Requires expertise Requires general anesthesia Major surgical procedure

Small airway, alveolar, or interstitial disease; but particularly interstitial disease Routine during bronchoscopy

Bronchial and alveolar disease Because of safety and ease, consider for any lung disease Less likely to be representative of interstitial or small focal processes

Airway must be involved for specimen to represent disease May induce bronchospasm in patients with hyperreactive airways, particularly cats

General anesthesia required Special equipment and expertise required for bronchoscopic collection Generally not recommended for animals with tachypnea, increased respiratory efforts or respiratory distress Capability to provide oxygen supplementation is required May induce bronchospasm in patients with hyperreactive airways, particularly cats

INDICATIONS

DISADVANTAGES

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CHAPTER 20â•…â•… Diagnostic Tests for the Lower Respiratory Tract

277

TC

CC

T

A

B

FIG 20-13â•…

A, When a transtracheal wash is performed, the animal is restrained in a comfortable position with the nose pointed toward the ceiling. The ventral neck is clipped and scrubbed, and the clinician wears sterile gloves. The cricothyroid ligament is identified as described in B. After an injection of lidocaine, the needle of the catheter is placed through the skin. The larynx is grasped firmly with the fingers and the thumb at least 180 degrees around the airway. The needle can then be inserted through the cricothyroid ligament into the airway lumen. B, The lateral view of this anatomic specimen demonstrates the trachea and larynx in a position similar to that of the dog in A. The cricothyroid ligament (arrow) is identified by palpating the trachea (T) from ventral to dorsal until the raised cricoid cartilage (CC) is palpated. The cricothyroid ligament is the first depression above the cricoid cartilage. The cricothyroid ligament attaches cranially to the thyroid cartilage (TC). The palpable depression above the thyroid cartilage (not shown) should not be entered.

sodium chloride solution. The entire bolus of saline in one syringe is injected into the catheter. Immediately after this, many aspiration attempts are made. After each aspiration, the syringe must be disconnected from the catheter and the air evacuated without loss of any of the retrieved fluid. Attachment of a three-way stopcock between the catheter and the syringe can make it easier to connect and disconnect the syringe. Aspirations should be forceful and should be repeated at least five or six times, so that small volumes of airway secretions that have been aspirated into the catheter are pulled the entire length of the catheter into the syringe. The procedure is repeated using additional boluses of saline until a sufficient amount of fluid is retrieved for analysis. A total of 1.5 to 3╯mL of turbid fluid is adequate in most instances. The clinician does not need to be concerned about “drowning” the animal with infusion of the modest volumes of fluid described because the fluid is rapidly absorbed into the circulation. Failure to retrieve adequate volumes of visibly turbid fluid can be the result of several technical difficulties, as outlined in Fig. 20-14. The catheter is removed after sufficient fluid is collected. A sterile gauze sponge with antiseptic ointment is

then immediately placed over the catheter site, and a light bandage is wrapped around the neck. This bandage is left in place for several hours while the animal rests quietly in a cage. These precautions minimize the likelihood that subcutaneous emphysema or pneumomediastinum will develop.

Endotracheal Technique The endotracheal technique is performed by passing a 5F male dog urinary catheter through a sterilized endotracheal tube. The animal is anesthetized with a short-acting intravenous agent to a sufficient depth to allow intubation. A shortacting barbiturate, propofol, or, in cats, a combination of ketamine and acepromazine or diazepam is effective. Premedication with atropine, particularly in cats, is recommended to minimize contamination of the trachea with saliva. Cats with lower respiratory tract disease may have airway hyperreactivity and generally should be administered a bronchodilator before the tracheal wash. Terbutaline (0.01╯mg/kg) can be given subcutaneously to cats not already receiving oral bronchodilators. It is also prudent to keep a metered dose inhaler of albuterol at hand to be administered

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Poor or no return Length of catheter within airway: -Too far within airway can result in catheterization of a bronchus and loss of horizontal surface required to recover fluid. -Not far enough within trachea leaves catheter tip in extrathoracic trachea, where surface is not horizontal.

Measure distance along path of trachea from cricothyroid ligament (transtracheal technique) or proximal end of endotracheal tube to fourth intercostal space for approximate distance to carina and ensure catheter reaches this position.

Position of tip when using stiff polypropylene urinary catheters: tip may be bent or curved such that it cannot rest on ventral surface of airway.

Physically straighten catheter before use. Once catheter is in position, rotate it along axis in several different positions until yield improves.

Time delay between instillation and suction is too long.

Suction vigorously immediately after instillation of saline.

Suction is not sufficiently vigorous.

Use a 12-mL syringe and suction with enthusiasm. Recovery of only saline

Catheter is not placed far enough within trachea to exit endotracheal tube using endotracheal tube technique.

See first remedy (above).

Too few suction attempts are performed to pull mucus through entire length of catheter.

Suction many, many times. Mucus that has only moved partway through catheter will be pushed back into airways with subsequent saline infusion. Negative pressure

Catheter is kinked at neck (transtracheal technique).

Holder adjusts position to prevent kinking.

Thick mucus is obstructing lumen of catheter.

Continue vigorous suction to retrieve this valuable material. If necessary, flush with more saline. If still unsuccessful, consider using a larger catheter.

Catheter tip is flush against airway wall.

Move catheter slightly forward or backward, or rotate catheter.

Oropharyngeal contamination Insertion of a transtracheal catheter proximal to the cricothyroid ligament.

Be sure of anatomy prior to procedure.

Excessive salivation, especially in cats.

Premedication with atropine.

Prolonged extension of the head and neck during catheter or endotracheal tube placement.

Minimize amount of time head and neck are extended.

FIG 20-14â•…

Overcoming problems with tracheal wash fluid collection. Green boxes indicate problems, blue boxes indicate possible causes, and orange boxes indicate remedies.

CHAPTER 20â•…â•… Diagnostic Tests for the Lower Respiratory Tract

through the endotracheal tube or by mask if breathing becomes labored. A sterilized endotracheal tube should be passed without dragging the tip through the oral cavity. The animal’s mouth is opened wide with the tongue pulled out, a laryngoscope is used, and, in cats, sterile topical lidocaine is applied to the laryngeal cartilages to ease passage of the tube with minimal contamination. The urinary catheter is passed through the endotracheal tube to the level of the carina (approximately the fourth intercostal space), while sterile technique is maintained. The wash procedure is performed as described for the transtracheal technique. Slightly larger boluses of saline may be required, however, because of the larger volume of the catheter. Use of a catheter larger than 5F seems to reduce the yield of the wash, except when secretions are extremely viscous.

SPECIMEN HANDLING The cells collected in the wash fluid are fragile. The fluid is ideally processed within 30 minutes of collection, with minimal manipulation. Bacterial culture is performed on at least 0.5 to 1╯mL of fluid. Fungal cultures are performed if mycotic disease is a differential diagnosis, and Mycoplasma culture or polymerase chain reaction (PCR) testing is considered for cats and dogs with signs of bronchitis. Cytologic preparations are made both from the fluid and from any mucus within the fluid. Both fluid and mucus are examined because infectious agents and inflammatory cells can be concentrated in the mucus, but the proteinaceous material causes cells to clump and interferes with evaluation of the cell morphology. Mucus is retrieved with a needle, and squash preparations are made. Direct smears of the fluid itself can be made, but such specimens are often hypocellular. Sediment or cytocentrifuge preparations are generally necessary to make adequate interpretation possible. Straining the fluid through gauze to remove the mucus is discouraged because infectious agents may be lost in the process. Routine cytologic stains are used. Microscopic examination of slides includes identification of cell types, qualitative evaluation of cells, and examination for infectious agents. Cells are evaluated qualitatively for evidence of macrophage activation, neutrophil degeneration, lymphocyte reactivity, and characteristics of malignancy. Epithelial hyperplasia secondary to inflammation should not be overinterpreted as neoplasia, however. Infectious agents such as bacteria, protozoa (Toxoplasma gondii), fungi (Histoplasma, Blastomyces, and Cryptococcus organisms), and parasitic larvae or eggs may be present (see Fig. 20-12, and Figs. 20-15 through 20-17). Because only one or two organisms may be present on an entire slide, a thorough evaluation is indicated. INTERPRETATION OF RESULTS Normal tracheal wash fluid contains primarily respiratory epithelial cells. Few other inflammatory cells are present (Fig. 20-18). Occasionally, macrophages are retrieved from the

279

FIG 20-15â•…

Photomicrograph of a Blastomyces organism from the lungs of a dog with blastomycosis. The organisms stain deeply basophilic, are 5 to 15╯µm in diameter, and have a thick refractile cell wall. Often, as in this figure, broad-based budding forms are seen. The cells present are alveolar macrophages and neutrophils. (Bronchoalveolar lavage fluid, Wright stain.)

FIG 20-16â•…

Photomicrograph of Histoplasma organisms from the lungs of a dog with histoplasmosis. The organisms are small (2 to 4╯µm) and round, with a deeply staining center and a lighter-staining halo. They are often found within phagocytic cells—in this figure, an alveolar macrophage. (Bronchoalveolar lavage fluid, Wright stain.)

small airways and alveoli because the catheter was extended into the lungs beyond the carina, or because relatively large volumes of saline were used. Most macrophages are not activated. In these instances the presence of macrophages does not indicate disease but rather reflects the acquisition of material from the deep lung (see the section on nonbronchoscopic bronchoalveolar lavage). Slides are examined for evidence of overt oral contamination, which can occur during transtracheal washing if the catheter needle was inadvertently inserted proximal to the cricothyroid ligament. Rarely, dogs can cough the catheter

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up into the oropharynx. Oral contamination can also result from drainage of saliva into the trachea, which usually occurs in cats that hypersalivate or dogs that are heavily sedated, particularly if the head and neck are extended more than briefly for passage of the endotracheal tube or transtracheal catheter. Oral contamination is indicated by the finding of numerous squamous epithelial cells, often coated with bacteria, and Simonsiella organisms (Fig. 20-19). Simonsiella

FIG 20-17â•…

Photomicrograph of Toxoplasma gondii tachyzoites from the lungs of a cat with acute toxoplasmosis. The extracellular tachyzoites are crescent shaped with a centrally placed nucleus. They are approximately 6╯µm in length. (Bronchoalveolar lavage fluid, Wright stain.)

FIG 20-18â•…

organisms are large basophilic rods that are frequently found stacked uniformly on top of one another along their broad side. Specimens with overt oral contamination generally do not provide accurate information about the airways, particularly with regard to bacterial infection. Cytologic results of tracheal wash fluid are most useful when pathogenic organisms or malignant cells are identified. The presence of pathogens such as Toxoplasma gondii, systemic fungal organisms, and parasites provides a definitive diagnosis. The finding of bacterial organisms in cytologic preparations without evidence of oral contamination indicates the presence of infection. The growth of any of the systemic mycotic agents in culture is also clinically significant, whereas the growth of bacteria in culture may or may not be significant because low numbers of bacteria can be present in the large airways of healthy animals. In general, the cytologic identification of bacteria and their growth in culture without multiplication in enrichment broth are significant findings. Bacteria that are not seen cytologically and that grow only after incubation in enrichment media can result from several situations. For example, the bacteria may be causing infection without being present in high numbers because of the prior administration of antibiotics, or because of the collection of a nonrepresentative specimen. The bacteria may also be clinically insignificant and represent normal tracheal inhabitants, or they may result from contamination during collection. Other clinical data must therefore be considered when such findings are interpreted. The role of Mycoplasma spp. in respiratory

Tracheal wash fluid from a healthy dog showing ciliated epithelium and few inflammatory cells.

CHAPTER 20â•…â•… Diagnostic Tests for the Lower Respiratory Tract

FIG 20-19â•…

Tracheal wash fluid showing evidence of oropharyngeal contamination. The numerous, uniformly stacked basophilic rods are Simonsiella organisms—normal inhabitants of the oral cavity. These organisms, as well as many other bacteria, are adhering to a squamous epithelial cell. Squamous epithelium is another indication of contamination from the oral cavity.

disease of the dog and cat is not well understood. These organisms cannot be seen on cytologic preparations and are difficult to grow in culture. Specific transport media are necessary. Growth of Mycoplasma organisms from tracheal wash fluid may indicate primary or secondary infection or may be an insignificant finding. Treatment is generally recommended. Criteria of malignancy for making a diagnosis of neoplasia must be interpreted with extreme caution. Overt characteristics of malignancy must be present in many cells in the absence of concurrent inflammation for a definitive diagnosis to be made. The type of inflammatory cells present in tracheal wash fluid can assist in narrowing the differential diagnoses, although a mixed inflammatory response is common. Neutrophilic (suppurative) inflammation is common in bacterial infections. Before antibiotic therapy is initiated, the neutrophils may be (but are not always) degenerative, and organisms can often be seen. Neutrophilic inflammation may be a response to a variety of other diseases. For instance, it can be caused by other infectious agents or seen in patients with canine chronic bronchitis, idiopathic pulmonary fibrosis, or other idiopathic interstitial pneumonias, or even neoplasia. Some cats with idiopathic bronchitis have neutrophilic inflammation rather than the expected eosinophilic response (see Chapter 21). The neutrophils in these instances are generally nondegenerative. Eosinophilic inflammation reflects a hypersensitivity response, and diseases commonly resulting in eosinophilic inflammation include allergic bronchitis, parasitic disease, and eosinophilic lung disease. Parasites that affect the lung include primary lungworms or flukes, migrating intestinal parasites, and heartworms. Over time, mixed inflammation

281

can occur in patients with hypersensitivity. It is occasionally possible for nonparasitic infection or neoplasia to cause eosinophilia, usually as part of a mixed inflammatory response. Macrophagic (granulomatous) inflammation is characterized by the finding of increased numbers of activated macrophages, generally present as a component of mixed inflammation, along with increased numbers of other inflammatory cells. Activated macrophages are vacuolated and have increased amounts of cytoplasm. This response is nonspecific unless an etiologic agent can be identified. Lymphocytic inflammation alone is uncommon. Viral or rickettsial infection, idiopathic interstitial pneumonia, and lymphoma are considerations. True hemorrhage can be differentiated from a traumatic specimen collection by the presence of erythrophagocytosis and hemosiderin-laden macrophages. An inflammatory response is also usually present. Hemorrhage can be caused by neoplasia, mycotic infection, heartworm disease, thromboembolism, foreign body, lung lobe torsion, or coagulopathies. Evidence of hemorrhage is seen occasionally in animals with congestive heart failure or severe bacterial pneumonia.

NONBRONCHOSCOPIC BRONCHOALVEOLAR LAVAGE Indications and Complications Bronchoalveolar lavage (BAL) is considered for the diagnostic evaluation of patients with lung disease involving the small airways, alveoli, or interstitium that are not tachypneic or otherwise showing signs of respiratory distress (see Table 20-2). BAL is particularly considered for patients with diffuse interstitial lung disease, because other nonbiopsy methods of specimen collection (tracheal wash or lung aspiration) are often unrewarding. A large volume of lung is sampled by BAL (Figs. 20-20 and 20-21). The collected specimens are of large volume, providing more than adequate material for routine cytology, cytology involving special stains (e.g., Gram stains, acid-fast stains), multiple types of cultures (e.g., bacterial, fungal, mycoplasmal), or other specific tests that might be helpful in particular patients (e.g., flow cytometry, PCR). Cytologic preparations from BAL fluid are of excellent quality and consistently provide large numbers of wellstained cells for examination. Although general anesthesia is required, the procedure is associated with few complications in stable patients and can be performed repeatedly in the same animal to follow the progression of disease or observe the response to therapy. The primary complication of BAL is transient hypoxemia. Hypoxemia generally can be corrected with oxygen supplementation, but animals exhibiting increased respiratory efforts or respiratory distress in room air are not good candidates for this procedure. Patients with hyperreactive airways, particularly cats, are treated with bronchodilators, as described previously, for endotracheal washing. For

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PART IIâ•…â•… Respiratory System Disorders

c

b TW

BAL

FIG 20-20â•…

The region of the lower respiratory tract that is sampled by bronchoalveolar lavage (BAL) in comparison with the region sampled by tracheal wash (TW). The solid line (b) within the airways represents a bronchoscope or a modified feeding tube. The open lines (c) represent the tracheal wash catheter. Bronchoalveolar lavage yields fluid representative of the deep lung, whereas tracheal wash yields fluid representative of processes involving major airways.

FIG 20-21â•…

The region of the lower respiratory tract presumed to be sampled by nonbronchoscopic bronchoalveolar lavage in cats using an endotracheal tube.

CHAPTER 20â•…â•… Diagnostic Tests for the Lower Respiratory Tract

patients with bacterial or aspiration pneumonia, tracheal washing routinely results in an adequate specimen for cytologic and microbiologic analysis and avoids the need for general anesthesia in these patients. BAL is a routine part of diagnostic bronchoscopy, during which visually guided BAL specimens can be collected from specific diseased lung lobes. However, nonbronchoscopic techniques (NB-BAL) have been developed that allow BAL to be performed with minimal expense in routine practice settings. Because visual guidance is not possible with these methods, they are used primarily for patients with diffuse disease. However, the technique described for cats probably samples the cranial and middle regions of the lung on the side of the cat placed against the table, whereas the technique described for dogs consistently samples one of the caudal lung lobes. In addition to the methods described later, other techniques for NB-BAL have been reported in which a long, thin, sterile catheter is passed through a sterile endotracheal tube until the catheter is lodged in a distal airway, and relatively small volumes of saline infused and recovered. Foster et╯al (2011) used a 6F to 8F dog urinary catheter and two 5- to 10-mL aliquots of sterile saline. Such methods likely result in less hypoxemia than those described later, but would be expected to sample a smaller portion of lung. Critical evaluation of different techniques for BAL in disease states has not been performed.

TECHNIQUE FOR NB-BAL IN CATS A sterile endotracheal tube and a syringe adapter are used in cats to collect lavage fluid (Fig. 20-22; see also Fig. 20-21). Cats, particularly those with signs of bronchitis, should be treated with bronchodilators before the procedure, as described previously for tracheal wash (endotracheal technique), to decrease the risk of bronchospasm. The cat is premedicated with atropine (0.05╯mg/kg subcutaneously)

FIG 20-22â•…

283

and is anesthetized with ketamine and acepromazine or diazepam, given intravenously. The endotracheal tube is passed as cleanly as possible through the larynx to minimize oral contamination. To achieve sufficient cleanliness, the tip of the tongue is pulled out, a laryngoscope is used, and sterile lidocaine is applied topically to the laryngeal mucosa. The cuff is then inflated sufficiently to create a seal, but overinflation is avoided to prevent tracheal rupture (i.e., use a 3-mL syringe and inflate the cuff in 0.5-mL increments only until no leak is audible when gentle pressure is placed on the oxygen reservoir bag). The cat is placed in lateral recumbency with the most diseased side, as determined by physical and radiographic findings, against the table. Oxygen (100%) is administered for several minutes through the endotracheal tube. The anesthetic adapter then is removed from the endotracheal tube and is replaced with a sterile syringe adapter, with caution to avoid contamination of the end of the tube or adapter. Immediately, a bolus of warmed, sterile 0.9% saline solution (5╯mL/kg body weight) is infused through the tube over approximately 3 seconds. Immediately after infusion, suction is applied by syringe. Air is eliminated from the syringe, and several aspiration attempts are made until fluid is no longer recovered. The procedure is repeated using a total of two or three boluses of saline solution. The cat is allowed to expand its lungs between infusions of saline solution. After the last infusion, the syringe adapter is removed (because it greatly interferes with ventilation) and excess fluid is drained from the large airways and endotracheal tube by elevating the caudal half of the cat a few inches off of the table. At this point, the cat is cared for as described in the section on recovery of patients after BAL.

TECHNIQUE FOR NB-BAL IN DOGS An inexpensive 122-cm 16F Levin-type polyvinyl chloride stomach tube can be used in dogs to collect lavage fluid. The

Bronchoalveolar lavage using an endotracheal tube in a cat. The fluid retrieved is grossly foamy because of the surfactant present. The procedure is performed quickly because the airway is completely occluded during infusion and aspiration of fluid.

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tube must be modified for best results. Sterile technique is maintained throughout. The distal end of the tube is cut off for removal of the side openings. The proximal end is cut off for removal of the flange and shortening of the tube to a length slightly greater than the distance from the open end of the dog’s endotracheal tube to the last rib. A syringe adapter is placed within the proximal end of the tube (Fig. 20-23). Recovery of BAL fluid can be improved by tapering the distal end of the tube. Tapering is readily achieved using a metal, single-blade, handheld pencil sharpener that has been autoclaved and is used only for this purpose (see Fig. 20-23, A and B). The dog is premedicated with atropine (0.05╯mg/kg subcutaneously) or glycopyrrolate (0.005╯mg/kg subcutaneously) and is anesthetized using a short-acting protocol that will allow intubation, such as with propofol, a short-acting barbiturate, or the combination of medetomidine and butorphanol. If the dog is of sufficient size to accept a size 6 or larger endotracheal tube, the dog is intubated with a sterile endotracheal tube placed as cleanly as possible to minimize oral contamination of the specimen. The modified stomach tube will not fit through a smaller endotracheal tube, so the technique must be performed without an endotracheal tube, or a smaller stomach tube must be used. If no endotracheal tube is used, extreme care must be taken to minimize oral contamination in passing the modified stomach tube, and an appropriately sized endotracheal tube should be available to gain control of the airway in case of complications and for recovery. Oxygen (100%) is provided through the endotracheal tube or by face mask for several minutes. The modified

FIG 20-23â•…

The catheter used for nonbronchoscopic bronchoalveolar lavage in dogs is a modified 16F Levin-type stomach tube. The tube is shortened by cutting off both ends. A simple pencil sharpener (inset A) is used to taper the distal end of the tube (inset B). A syringe adapter is added to the proximal end. Sterility is maintained throughout.

stomach tube is passed through the endotracheal tube using sterile technique until resistance is felt. The goal is to wedge the tube snugly into an airway rather than have it abut an airway division. Therefore the tube is withdrawn slightly, then is passed again, until resistance is consistently felt at the same depth. Rotating the tube slightly during passage may help achieve a snug fit. Remember that if the endotracheal tube is not much larger than the stomach tube, ventilation is restricted at this point and the procedure should be completed expediently. For medium-size dogs and larger, two 35-mL syringes are prepared in advance, each with 25╯mL of saline and 5╯mL of air. While the modified stomach tube is held in place, a 25-mL bolus of saline is infused through the tube, followed by the 5╯mL of air, by holding the syringe upright during infusion (Fig. 20-24). Gentle suction is applied immediately after infusion, using the same syringe. It may be necessary to withdraw the tube slightly if negative pressure is felt. The tube should not be withdrawn more than a few millimeters. If it is withdrawn too far, air will be recovered instead of fluid. The second bolus of saline is infused and recovered in the same manner, with the tube in the same position. The dog is cared for as described in the next section. In very small dogs, it is prudent to reduce the volume of saline used in each bolus, particularly if a smaller-diameter stomach tube is used. Overinflation of the lungs with excessive fluid volumes should be avoided.

RECOVERY OF PATIENTS AFTER BAL Regardless of the method used, BAL causes a transient decrease in the arterial oxygen concentration, but this hypoxemia responds readily to oxygen supplementation. Where possible, patients are monitored with pulse oximetry (see p. 295) before and throughout the procedure and during

FIG 20-24â•…

Bronchoalveolar lavage using a modified stomach tube in a dog. The tube is passed through a sterile endotracheal tube and is lodged in a bronchus. A syringe preloaded with saline and air is held upright during infusion so that saline is infused first, followed by air.

CHAPTER 20â•…â•… Diagnostic Tests for the Lower Respiratory Tract

recovery. After the procedure, 100% oxygen is provided through an endotracheal tube for as long as the dog or cat will allow intubation. Several gentle “sighs” are performed with the anesthesia bag to help expand any collapsed portions of lung. Bronchospasms are a reported complication of BAL in people, and increased airway resistance has been documented in cats after bronchoscopy and BAL (Kirschvink et╯al, 2005). Albuterol in a metered dose inhaler should be on hand to administer through the endotracheal tube or by spacer and mask if needed. After extubation the mucous membrane color, pulses, and the character of respirations are monitored closely. Crackles can be heard for several hours after BAL and are not cause for concern. Treatment with oxygen supplementation is continued by mask, oxygen cage, or nasal catheter if there are any indications of hypoxemia. Oxygen supplementation is rarely necessary for longer than 10 to 15 minutes after BAL in patients that were stable in room air before the procedure; however, the ability to provide supplementation for longer periods is a prerequisite for performance of this procedure, in case decompensation occurs.

285

fluid from later boluses is more representative of the alveoli and interstitium. BAL fluid is analyzed cytologically and microbiologically. Nucleated cell counts are performed on undiluted fluid using a hemocytometer. Cells are concentrated onto slides for differential cell counts and qualitative analysis using cytocentrifugation or sedimentation techniques. Slides of excellent quality then are stained using routine cytologic procedures. Differential cell counts are performed by counting at least 200 nucleated cells. Slides are scrutinized for evidence of macrophage activation, lymphocyte reactivity, neutrophil degeneration, and criteria of malignancy. All slides are examined thoroughly for possible etiologic agents, such as fungi, protozoa, parasites, and bacteria (see Figs. 20-12 and 20-15 to 20-17). As described for tracheal wash, visible strands of mucus can be examined for etiologic agents by squash preparation. Approximately 5╯mL of fluid is used for bacterial culture. Additional fluid is submitted for fungal culture if mycotic disease is among the differential diagnoses. Mycoplasma cultures are considered in cats and dogs with signs of bronchitis.

SPECIMEN HANDLING Successful BAL yields fluid that is grossly foamy, as a result of surfactant from the alveoli. Approximately 50% to 80% of the total volume of saline instilled is expected to be recovered. Less will be obtained from dogs with tracheobronchomalacia (collapsing airways). The fluid is placed on ice immediately after collection and is processed as soon as possible, with minimum manipulation to decrease cell lysis. For convenience, retrieved boluses can be combined for analysis; however, fluid from the first bolus usually contains more cells from the larger airways, and

INTERPRETATION OF RESULTS Normal cytologic values for BAL fluid are inexact because of inconsistency in the techniques used and variability among individual animals of the same species. In general, total nucleated cell counts in normal animals are less than 400 to 500/µL. Differential cell counts from healthy dogs and cats are listed in Table 20-3. Note that the provided values are means from groups of healthy animals. Values from individual patients should not be considered abnormal unless they are at least one or two standard deviations above these

  TABLE 20-3â•… Mean (±Standard Deviation [SD] or Standard Error [SE]) of Differential Cell Counts from Bronchoalveolar Lavage Fluid from Normal Animals BRONCHOSCOPIC BAL CELL TYPE

Macrophages

NONBRONCHOSCOPIC BAL

CANINE (%)*

FELINE (%)

70 ± 11

71 ± 10

CANINE (%)‡

FELINE (%)§

81 ± 11

78 ± 15

Lymphocytes

7±5

5±3

2±5

0.4 ± 0.6

Neutrophils

5±5

7±4

15 ± 12

5±5

16 ± 7

Eosinophils

6±6

2±3

16 ± 14

Epithelial cells

1±1

Mast cells

1±1

*Mean ± SD, 6 clinically and histologically normal dogs. (From Kuehn NF: Canine bronchoalveolar lavage profile. Thesis for masters of science degree, West Lafayette, Indiana, 1987, Purdue University.) † Mean ± SE, 11 clinically normal cats. (From King RR et╯al: Bronchoalveolar lavage cell populations in dogs and cats with eosinophilic pneumonitis. In Proceedings of the Seventh Veterinary Respiratory Symposium, Chicago, 1988, Comparative Respiratory Society.) ‡ Mean ± SD, 9 clinically normal dogs. (From Hawkins EC et╯al: Use of a modified stomach tube for bronchoalveolar lavage in dogs, J Am Vet Med Assoc 215:1635, 1999.) § Mean ± SD, 34 specific pathogen–free cats. (From Hawkins EC et╯al: Cytologic characterization of bronchoalveolar lavage fluid collected through an endotracheal tube in cats, Am J Vet Res 55:795, 1994.)

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the basis for a definitive diagnosis in 25% of cases and were supportive of the diagnosis in an additional 50%. Only dogs in which a definitive diagnosis was obtained by any means were included. Definitive diagnoses were possible on the basis of BAL only in those animals in which infectious organisms were identified, or in those cases in which overtly malignant cells were present in specimens in the absence of marked inflammation. BAL has been shown to be more sensitive than radiographs in identifying pulmonary involvement with lymphosarcoma. Carcinoma was definitively identified in 57% of cases, and other sarcomas were not found in BAL fluid. Fungal pneumonia was confirmed in only 25% of cases, although organisms were found in 67% of cases in a previous study of dogs with overt fungal pneumonia.

TRANSTHORACIC LUNG ASPIRATION AND BIOPSY FIG 20-25â•…

Bronchoalveolar lavage fluid from a normal dog. Note that alveolar macrophages predominate.

mean values. In our canine studies we have used values of ≥12% neutrophils, 14% eosinophils, or 16% lymphocytes as indicative of inflammation. Interpretation of BAL fluid cytology and cultures is essentially the same as that described for tracheal wash fluid, although the specimens are more representative of the deep lung than the airways. In addition, the normal cell population of macrophages must not be misinterpreted as being indicative of macrophagic or chronic inflammation (Fig. 20-25). As for all cytologic specimens, definitive diagnoses are made through identification of organisms or abnormal cell populations. Fungal, protozoal, or parasitic organisms may be present in extremely low numbers in BAL specimens; therefore the entire concentrated slide preparation must be carefully scanned. Profound epithelial hyperplasia can occur in the presence of an inflammatory response and should not be confused with neoplasia. If quantitative bacterial culture is available, growth of organisms at greater than 1.7 × 103 colony-forming units (CFUs)/mL has been reported to indicate infection (Peeters et╯al, 2000). In the absence of quantitative numbers, growth of organisms on a plate directly inoculated with BAL fluid is considered significant, whereas growth from fluid that occurs only after multiplication in enrichment broth may be a result of normal inhabitants or contamination. Patients that are already receiving antibiotics at the time of specimen collection may have significant infection with few or no bacteria by culture.

DIAGNOSTIC YIELD A retrospective study of BAL fluid cytologic analysis in dogs at referral institutions showed that BAL findings served as

Indications and Complications Pulmonary parenchymal specimens can be obtained by transthoracic needle aspiration or biopsy. Although only a small region of lung is sampled by these methods, collection can be guided by radiographic findings or ultrasonography to improve the likelihood of obtaining representative specimens. As with tracheal wash and BAL, a definitive diagnosis will be possible in patients with infectious or neoplastic disease. Patients with noninfectious inflammatory diseases require thoracoscopy or thoracotomy with lung biopsy for a definitive diagnosis. Potential complications of transthoracic needle aspiration or biopsy include pneumothorax, hemothorax, and pulmonary hemorrhage. These procedures are not recommended in animals with suspected cysts, abscesses, pulmonary hypertension, or coagulopathies. Severe complications are uncommon, but these procedures should not be performed unless the clinician is prepared to place a chest tube and otherwise support the animal if necessary. Lung aspirates and biopsy specimens are indicated for the nonsurgical diagnosis of intrathoracic mass lesions that are in contact with the thoracic wall. The risk of complications in these animals is relatively low because the specimens can be collected without disrupting aerated lung. Obtaining aspirates or biopsy specimens from masses that are far from the body wall and near the mediastinum carries the additional risk of lacerating important mediastinal organs, vessels, or nerves. If a solitary localized mass lesion is present, thoracotomy and biopsy should be considered rather than transthoracic sampling because this permits both the diagnosis of the problem and the potentially therapeutic benefits of complete excision. Transthoracic lung aspirates can be obtained in animals with a diffuse interstitial radiographic pattern. In some of these patients, solid areas of infiltrate in lung tissue immediately adjacent to the body wall can be identified ultrasonographically even though they are not apparent on thoracic

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287

radiographs (see Fig. 20-11). Ultrasound guidance of the aspiration needle into the areas of infiltrate should improve diagnostic yield and safety. If areas of infiltrate cannot be identified ultrasonographically, BAL should be considered before lung aspiration in animals that can tolerate the procedure because it yields a larger specimen for analysis and, in this author’s opinion, carries less risk than transthoracic aspiration in patients that are not experiencing increased respiratory efforts or distress. Tracheal wash (if BAL is not possible) and appropriate ancillary tests are generally indicated before lung aspiration in these patients because they carry little risk.

TECHNIQUES The site of collection in animals with localized disease adjacent to the body wall is best identified with ultrasonography. If ultrasonography is not available, or if the lesion is surrounded by aerated lung, the site is determined on the basis of two radiographic views. The location of the lesion during inspiration in all three dimensions is identified by its relationship to external landmarks: the nearest intercostal space or rib, the distance from the costochondral junctions, and the depth into the lungs from the body wall. If available, fluoroscopy or CT also can be used to guide the needle or biopsy instrument. The site of collection in animals with diffuse disease is a caudal lung lobe. The needle is inserted between the seventh and ninth intercostal spaces, approximately two thirds of the distance from the costochondral junctions to the spine. The animal must be restrained for the procedure, and sedation or anesthesia is necessary in some. Anesthesia is avoided, if possible, because the hemorrhage created by the procedure is not cleared as readily from the lungs in an anesthetized dog or cat. The skin at the site of collection is shaved and surgically prepared. Lidocaine is injected into subcutaneous tissues and intercostal muscles to provide local anesthesia. Lung aspiration can be performed with an injection needle, a spinal needle, or a variety of thin-walled needles designed specifically for lung aspiration in people. Spinal needles are readily available in most practices, are sufficiently long to penetrate through the thoracic wall, and have a stylet. A 22-gauge, 1.5- to 3.5-inch (3.75- to 8.75-cm) spinal needle is usually adequate. The clinician wears sterile gloves. The needle with stylet is advanced through the skin several rib spaces from the desired biopsy site. The needle and skin are then moved to the biopsy site. This is done because air is less likely to enter the thorax through the needle tract after the procedure if the openings in the skin and chest wall are not aligned. The needle is then advanced through the body wall to the pleura. The stylet is removed, and the needle hub is immediately covered by a finger to prevent pneumothorax until a 12-mL syringe can be placed on the hub. During inspiration the needle is thrust into the chest to a depth predetermined from the radiographs, usually about 1 inch (2.5╯cm), while suction is applied to the syringe (Fig. 20-26). To keep from inserting

FIG 20-26â•…

Transthoracic lung aspiration performed with a spinal needle. Note that sterile technique is used. The needle shaft can be pinched with finger and thumb at the maximum depth to which the needle should be passed. The finger and thumb thus act as a guard to prevent overinsertion of the needle. Although this patient is under general anesthesia, this is not usually indicated.

the needle too deeply, the clinician may pinch the needle shaft with the thumb and forefinger of the nondominant hand at the desired maximum depth of insertion. During insertion the needle can be twisted along its long axis in an attempt to obtain a core of tissue. The needle is then immediately withdrawn to the level of the pleura. Several quick stabs into the lung can be made along different lines to increase the yield. Each stab should take only a second. Prolonging the time that the needle is within the lung tissue increases the likelihood of complications. The lung tissue will be moving with respirations, resulting in laceration of tissue, even if the needle is held steady. The needle is withdrawn from the body wall with a minimal amount of negative pressure maintained by the syringe. It is unusual for the specimen to be large enough to have entered the syringe. The needle is removed from the syringe, the syringe is filled with air and reattached to the needle, and the contents of the needle are then forced onto one or more slides. Grossly, the material is bloody in most cases. Squash preparations are made. Slides are stained using routine procedures and then are evaluated cytologically. Increased numbers of inflammatory cells, infectious agents, or neoplastic cell populations are potential abnormalities. Alveolar macrophages are normal findings in parenchymal specimens and should not be interpreted as representing chronic inflammation. They should be carefully examined

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for evidence of phagocytosis of bacteria, fungi, or red blood cells and for signs of activation. Epithelial hyperplasia can occur in the presence of inflammation and should not be confused with neoplasia. Sometimes the liver is aspirated inadvertently, particularly in deep-chested dogs, yielding a population of cells that may resemble those from adenocarcinoma. However, hepatocytes typically contain bile pigment. Bacterial culture is indicated in some animals, although the volume of material obtained is quite small. Transthoracic lung core biopsies can be performed in animals with mass lesions. Specimens are collected after an aspirate has proved to be nondiagnostic. Needle biopsy instruments can be used to biopsy lesions adjacent to the chest wall (e.g., EZ Core biopsy needles, Products Group International, Lyons, Colorado). Smaller-bore, thin-walled lung biopsy instruments can be obtained from medical suppliers for human patients. These instruments collect smaller pieces of tissue but are less disruptive to normal lung. Ideally, sufficient material is collected for histologic evaluation. If not, squash preparations are made for cytologic studies.

BRONCHOSCOPY Indications Bronchoscopy is indicated for the evaluation of the major airways in animals with suspected structural abnormalities, for visual assessment of airway inflammation or pulmonary hemorrhage, and as a means of collecting specimens in animals with undiagnosed lower respiratory tract disease. Bronchoscopy can be used to identify structural abnormalities of the major airways, such as tracheal collapse, mass lesions, tears, strictures, lung lobe torsions, bronchiectasis, bronchial collapse, and external airway compression. Foreign bodies or parasites may be identified. Hemorrhage or inflammation involving or extending to the large airways may also be seen and localized. Specimen collection techniques performed in conjunction with bronchoscopy are valuable diagnostic tools because they can be used to obtain specimens from deeper regions of the lung than is possible with the tracheal wash technique, and visually directed sampling of specific lesions or lung lobes is also possible. Animals undergoing bronchoscopy must receive general anesthesia, and the presence of the scope within the airways compromises ventilation. Therefore bronchoscopy is contraindicated in animals with severe respiratory tract compromise unless the procedure is likely to be therapeutic (e.g., foreign body removal).

TECHNIQUE Bronchoscopy is technically more demanding than most other endoscopic techniques. The patient is often experiencing some degree of respiratory compromise, which poses increased anesthetic and procedural risks. Airway hyperreactivity may be exacerbated by the procedure, particularly in cats (Kirschvink et╯al, 2005). A small-diameter, flexible endoscope is needed and should be sterilized before use. The

bronchoscopist should be thoroughly familiar with normal airway anatomy to ensure that every lobe is examined. BAL is routinely performed as part of diagnostic bronchoscopy after thorough visual examination of the airways. The reader is referred to chapters in other textbooks for details about performing bronchoscopy and bronchoscopic BAL (Kuehn et╯al, 2004; McKiernan, 2005; Hawkins, 2004; Padrid, 2011). Bronchoscopic images of normal airways are shown in Fig. 20-27. Reported cell counts from bronchoscopically collected BAL fluid are provided in Table 20-3. Abnormalities that may be observed during bronchoscopy and their common clinical correlations are listed in Table 20-4. A definitive diagnosis may not be possible on the basis of the findings yielded by gross examination alone. Specimens are collected through the biopsy channel for cytologic, histopathologic, and microbiologic analysis. Bronchial specimens are obtained by bronchial washing, bronchial brushing, or pinch biopsy. Material for bacterial culture can be collected with guarded culture swabs. The deeper lung is sampled by BAL or transbronchial biopsy. Foreign bodies are removed with retrieval forceps.

THORACOTOMY OR THORACOSCOPY WITH LUNG BIOPSY Thoracotomy and surgical biopsy are performed in animals with progressive clinical signs of lower respiratory tract disease that has not been diagnosed using less invasive means. Although thoracotomy carries a greater risk than the previously mentioned diagnostic techniques, the modern anesthetic agents, surgical techniques, and monitoring capabilities now available have made this procedure routine in many veterinary practices. Analgesic drugs are used to manage postoperative pain, and complication-free animals are discharged as soon as 2 to 3 days after surgery. Surgical biopsy provides excellent-quality specimens for histopathologic analysis and culture. Abnormal lung tissue and accessible lymph nodes are biopsied. Excisional biopsy of abnormal tissue can be therapeutic in animals with localized disease. Removal of localized neoplasms, abscesses, cysts, and foreign bodies can be curative. The removal of large localized lesions can improve the matching of ventilation and perfusion, even in animals with evidence of diffuse lung involvement, thereby improving the oxygenation of blood and reducing clinical signs. In practices where thoracoscopy is available, this less invasive technique can be used for initial assessment of intrathoracic disease. Similarly, a “mini” thoracotomy can be performed through a relatively small incision. If disease is obviously disseminated throughout the lungs such that surgical intervention will not be therapeutic, biopsy specimens of abnormal tissue can be obtained with these methods via small incisions. For patients with questionable findings or apparently localized disease, thoracoscopy or “mini” thoracotomy can be transitioned to a full thoracotomy during the same anesthesia.

CHAPTER 20â•…â•… Diagnostic Tests for the Lower Respiratory Tract

RB4

RB3 L R

RB1

RB2

B

A

LB2 LB1

C FIG 20-27â•…

Bronchoscopic images of normal airways. The labels for the lobar bronchi are derived from a useful nomenclature system for the major airways and their branches presented by Amis et╯al (1986). A, Carina, the division between the right (R) and left (L) mainstem bronchi. B, Right mainstem bronchus. The carina is off the right side of the image. Openings to the right cranial (RB1), right middle (RB2), accessory (RB3), and right caudal (RB4) bronchi are visible. C, Left mainstem bronchus. The carina is off the left side of the image. The openings to the left cranial (LB1) and left caudal (LB2) bronchi are visible. The left cranial lobe (LB1) divides immediately into cranial (narrow arrow) and caudal (broad arrow) branches. (From Amis TC et╯al: Systematic identification of endobronchial anatomy during bronchoscopy in the dog, Am J Vet Res 47:2649, 1986.)

289

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  TABLE 20-4â•… Bronchoscopic Abnormalities and Their Clinical Correlations ABNORMALITY

CLINICAL CORRELATION

Trachea

Hyperemia, loss of normal vascular pattern, excess mucus, exudate

Inflammation

Redundant tracheal membrane

Tracheal collapse

Flattened cartilage rings

Tracheal collapse

Uniform narrowing

Hypoplastic trachea

Strictures

Prior trauma

Mass lesions

Fractured rings, foreign body granuloma, neoplasia

Tears

Usually caused by excessive endotracheal tube cuff pressure

Carina

Widened

Hilar lymphadenopathy, extraluminal mass

Multiple raised nodules

Oslerus osleri

Foreign body

Foreign body

Bronchi

Hyperemia, excess mucus, exudate

Inflammation

Collapse of airway during expiration

Chronic inflammation, bronchomalacia

Collapse of airway, inspiration and expiration, ability to pass scope through narrowed airway

Chronic inflammation, bronchomalacia

Collapse of airway, inspiration and expiration, inability to pass scope through narrowed airway

Extraluminal mass lesions (neoplasia, granuloma, abscess)

Collapse of airway with “puckering” of mucosa

Lung lobe torsion

Hemorrhage

Neoplasia, fungal infection, heartworm, thromboembolic disease, coagulopathy, trauma (including foreign body related)

Single mass lesion

Neoplasia

Multiple polypoid masses

Usually chronic bronchitis; at carina, Oslerus

Foreign body

Foreign body

BLOOD GAS ANALYSIS Indications Measurement of partial pressures of oxygen (Pao2) and carbon dioxide (Paco2) in arterial blood specimens provides information about pulmonary function. Venous blood analysis is less useful because venous blood oxygen pressures are greatly affected by cardiac function and peripheral circulation. Arterial blood gas measurements are indicated to document pulmonary failure, to differentiate hypoventilation from other causes of hypoxemia, to help determine the need for supportive therapy, and to monitor the response to therapy. Respiratory compromise must be severe for abnormalities to be measurable because the body has tremendous compensatory mechanisms.

TECHNIQUES Arterial blood is collected in a heparinized syringe. Dilution of specimens with liquid heparin can alter blood gas

results. Therefore commercially available syringes preloaded with lyophilized heparin are recommended. Alternatively, the procedure for heparinizing syringes as described by Hopper et╯ al (2005) should be followed: 0.5╯ mL of liquid sodium heparin is drawn into a 3-mL syringe with a 25-gauge needle. The plunger is drawn back to the 3╯ mL mark. All air is then expelled from the syringe. This procedure for expelling air and excess heparin is repeated three times. The femoral artery is commonly used (Fig. 20-28). The animal is placed in lateral recumbency. The upper rear limb is abducted, and the rear limb resting on the table is restrained in a partially extended position. The femoral artery is palpated in the inguinal region, close to the abdominal wall, using two fingers. The needle is advanced into the artery between these fingers. The artery is thick walled and loosely attached to adjacent tissues; thus the needle must be sharp and positioned exactly on top of the artery. A short, jabbing motion facilitates entry.

CHAPTER 20â•…â•… Diagnostic Tests for the Lower Respiratory Tract

291

FIG 20-28â•…

Position for obtaining an arterial blood specimen from the femoral artery. The dog is in left lateral recumbency. The right rear limb is being held perpendicular to the table to expose the left inguinal area. The pulse is palpated in the femoral triangle between two fingers to accurately locate the artery. The needle is laid directly on top of the artery, then is stabbed into it with a short, jabbing motion.

The dorsal pedal artery is useful for arterial collection in medium-size and large dogs. The position of the artery is illustrated in Fig. 20-29. Once the needle has penetrated the skin, suction is applied. On entry of the needle into the artery, blood should enter the syringe quickly, sometimes in pulses. Unless the animal is severely compromised, the blood will be bright red compared with the dark red of venous blood. Dark red blood or blood that is difficult to draw into the syringe may be obtained from a vein. Mixed samples from both the artery and the vein can be collected accidentally, particularly from the femoral site. After removal of the needle, pressure is applied to the puncture site for 5 minutes to prevent hematoma formation. Pressure is applied even after unsuccessful attempts if there is any possibility that the artery was entered. All air bubbles are eliminated from the syringe. The needle is covered by a cork or rubber stopper, and the entire syringe is placed in crushed ice unless the blood specimen is to be analyzed immediately. Specimens should be analyzed as soon as possible after collection. Minimal alterations occur in specimens stored on ice during the few hours required to transport the specimen to a human hospital if a blood gas analyzer is not available on site. Because of the availability of reasonably priced blood gas analyzers, pointof-care testing is now possible.

INTERPRETATION OF RESULTS Approximate arterial blood gas values for normal dogs and cats are provided in Table 20-5. More exact values should be obtained for normal dogs and cats using the actual analyzer.

FIG 20-29â•…

Position for obtaining an arterial blood specimen from the dorsal pedal artery. The dog is in left lateral recumbency, with the medial surface of the left leg exposed. A pulse is palpated just below the tarsus on the dorsal surface of the metatarsus between the midline and the medial aspect of the distal limb.

  TABLE 20-5â•… Approximate Ranges of Arterial Blood Gas Values for Normal Dogs and Cats Breathing Room Air MEASUREMENT

ARTERIAL BLOOD

PaO2 (mm╯Hg)

85-100

PaCO2 (mm╯Hg)

35-45

HCO3 (mmol/L) pH

21-27 7.35-7.45

PaO2 and PaCO2 Abnormal Pao2 and Paco2 values can result from technical error. The animal’s condition and the collection technique are considered in the interpretation of blood gas values. For example, an animal in stable condition with normal mucous

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PART IIâ•…â•… Respiratory System Disorders

membrane characteristics that is evaluated for exercise intolerance is unlikely to have a resting Pao2 of 45╯mm╯Hg. The collection of venous blood is a more likely explanation for this abnormal value. Hypoxemia is present if the Pao2 is below the normal range. The oxyhemoglobin dissociation curve describing the relationship between the saturated hemoglobin level and Pao2 is sigmoid in shape, with a plateau at higher Pao2 values (Fig. 20-30). Normal hemoglobin is almost totally saturated with oxygen when the Pao2 is greater than 80 to 90╯mm╯Hg, and clinical signs are unlikely in animals with such values. The curve begins to decrease more quickly at lower Pao2 values. A value of less than 60╯mm╯Hg corresponds to a hemoglobin saturation that is considered dangerous, and treatment for hypoxemia is indicated. (See the section on oxygen content, delivery, and utilization [p. 294] for further discussion.) In general, animals become cyanotic when the Pao2 reaches 50╯mm╯Hg or less, which results in a concentration of nonoxygenated (unsaturated) hemoglobin of 5╯g/dL or more. Cyanosis occurs as a result of the increased concentration of nonoxygenated hemoglobin in the blood and is not a direct reflection of the Pao2. The development of cyanosis depends on the total concentration of hemoglobin, as well as on the oxygen pressure; cyanosis develops more quickly in animals with polycythemia than in animals with anemia. Acute hypoxemia resulting from lung disease more often produces pallor in an animal than cyanosis. Treatment for hypoxemia is indicated for all animals with cyanosis. Determining the mechanism of hypoxemia is useful in selecting appropriate supportive therapy. These mechanisms

include hypoventilation, inequality of ventilation and perfusion within the lung, and diffusion abnormality. Hypoventilation is the inadequate exchange of gases between the outside of the body and the alveoli. Both Pao2 and Paco2 are affected by lack of gas exchange, and hypercapnia occurs in conjunction with hypoxemia. Causes of hypoventilation are listed in Box 20-9. The ventilation and perfusion of different regions of the lung must be matched for the blood leaving the lung to be fully oxygenated. The relationship between ventilation can be described as a ratio (V/Q). and perfusion (Q) (V) Hypoxemia can develop if regions of lung have a low or a high V/Q. Poorly ventilated portions of lung with normal blood flow Regionally decreased ventilation occurs in have a low V/Q. most pulmonary diseases for reasons such as alveolar flooding, alveolar collapse, or small airway obstruction. The flow of blood past totally nonaerated tissue is known as a venous of zero). The alveoli may be unvenadmixture or shunt (V/Q tilated as a result of complete filling or collapse, resulting in physiologic shunts, or the alveoli may be bypassed by true anatomic shunts. Unoxygenated blood from these regions then mixes with oxygenated blood from ventilated portions of the lung. The immediate result consists of decreased Pao2 and increased Paco2. The body responds to hypercapnia by increasing ventilation, effectively returning the Paco2 to normal or even lower than normal. However, increased ventilation cannot correct the hypoxemia because blood flowing by ventilated alveoli is already maximally saturated. Except where shunts are present, the Pao2 can be improved in dogs and cats with lung regions with low

O2 saturation of hemoglobin (%)

100

80

60

40

20

0 0

20

40

60

80

PO2 (mm Hg) FIG 20-30â•…

Oxyhemoglobin dissociation curve (approximation).

100

CHAPTER 20â•…â•… Diagnostic Tests for the Lower Respiratory Tract

  BOX 20-9â•… Clinical Correlations of Blood Gas Abnormalities Decreased PaO2 and Increased PaCO2 (Normal A-a Gradient)

Venous specimen Hypoventilation Airway obstruction Decreased ventilatory muscle function • Anesthesia • Central nervous system disease • Polyneuropathy • Polymyopathy • Neuromuscular junction disorders (myasthenia gravis) • Extreme fatigue (prolonged distress) Restriction of lung expansion • Thoracic wall abnormality • Excessive thoracic bandage • Pneumothorax • Pleural effusion Increased dead space (low alveolar ventilation) • Severe chronic obstructive pulmonary disease/ emphysema End-stage severe pulmonary parenchymal disease Severe pulmonary thromboembolism Decreased PaO2 and Normal or Decreased PaCO2 (Wide A-a Gradient)

) abnormality Ventilation/perfusion ( V/Q Most lower respiratory tract diseases (see Box 19-1, p. 259)

by providing supplemental oxygen therapy adminisV/Q tered by face mask, oxygen cage, or nasal catheter. Positivepressure ventilation may be necessary to combat atelectasis (see Chapter 27). Ventilation of areas of lung with decreased circulation occurs in dogs and cats with thromboembolism. (high V/Q) Initially there may be little effect on arterial blood gas values because blood flow is shifted to unaffected regions of the lung. However, blood flow in normal regions of the lungs is increases with increasing severity of disease, and V/Q decreased enough in those regions that a decreased Pao2 and a normal or decreased Paco2 may occur, as described previously. Both hypoxemia and hypercapnia are seen in the setting of extremely severe embolization. Diffusion abnormalities alone do not result in clinically significant hypoxemia but can occur in conjunction with mismatching in diseases such as idiopathic pulmonary V/Q fibrosis and noncardiogenic pulmonary edema. Gas is normally exchanged between the alveoli and the blood by diffusion across the respiratory membrane. This membrane consists of fluid lining the alveolus, alveolar epithelium, alveolar basement membrane, interstitium, capillary basement membrane, and capillary endothelium. Gases must also diffuse through plasma and red blood cell membranes.

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Functional and structural adaptations that facilitate diffusion between alveoli and red blood cells provide an efficient system for this process, which is rarely affected significantly by disease.

A-a Gradient abnormalities by Hypoventilation is differentiated from V/Q evaluation of the Paco2 in conjunction with the Pao2. Qualitative differences are described in the preceding paragraphs: Hypoventilation is associated with hypoxemia and hyper abnormalities are generally associated with capnia, and V/Q hypoxemia and normocapnia or hypocapnia. It is possible to quantify this relationship by calculating the alveolar-arterial oxygen gradient (A-a gradient), which factors out the effects of ventilation and the inspired oxygen concentration on Pao2 (Table 20-6). The premise of the A-a gradient is that Pao2 (a) is nearly equal (within 10╯mm╯Hg in room air) to the partial pressure of oxygen in the alveoli, PAo2 (A), in the absence of a diffu mismatch. In the presence of a sion abnormality or V/Q mismatch, the difference diffusion abnormality or a V/Q widens (greater than 15╯mm╯Hg in room air). Examination of the equation reveals that hyperventilation, resulting in a lower Paco2, leads to a higher PAo2. Conversely, hypoventilation, resulting in a higher Paco2, leads to a lower PAo2. Physiologically the Pao2 can never exceed the PAo2, however, and the finding of a negative value indicates an error. The error may be found in one of the measured values or in the assumed R value (see Table 20-6). Clinical examples of the calculation and interpretation of the A-a gradient are provided in Box 20-10. Oxygen Content, Delivery, and Utilization The commonly reported blood gas value Pao2 reflects the pressure of oxygen dissolved in arterial blood. This value is critical for assessing lung function. However, the clinician must remember that other variables are involved in oxygen delivery to the tissues besides Pao2, and that tissue hypoxia can occur in spite of a normal Pao2. The formula for calculating the total oxygen content of arterial blood (Cao2) is provided in Table 20-6. The greatest contribution to Cao2 in health is oxygenated hemoglobin. In a normal dog (Pao2, 100╯mm╯Hg; hemoglobin, 15╯g/dL), oxygenated hemoglobin accounts for 20╯mL of O2/dL, whereas dissolved oxygen accounts for only about 0.3╯mL of O2/dL. The quantity of hemoglobin is routinely appraised by the complete blood count. It can also be estimated on the basis of the packed cell volume (by dividing the packed cell volume by 3). The oxygen saturation of hemoglobin (Sao2) is dependent on the Pao2, as depicted by the sigmoid shape of the oxyhemoglobin dissociation curve (see Fig. 20-30). However, the Sao2 is also influenced by other variables that can shift the oxyhemoglobin dissociation curve to the left or right (e.g., pH, temperature, 2,3-diphosphoglycerate concentrations) or interfere with oxygen binding with hemoglobin (e.g., carbon monoxide toxicity, methemoglobinemia). Some laboratories measure Sao2.

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  TABLE 20-6â•… Relationships of Arterial Blood Gas Measurements FORMULA

DISCUSSION

Pao2 ∝ Sao2

Relationship is defined by sigmoid oxyhemoglobin dissociation curve. Curve plateaus at greater than 90% Sao2 with Pao2 values greater than 80╯mm╯Hg. Curve is steep at Pao2 values of between 20 and 60╯mm╯Hg (assuming normal hemoglobin, pH, temperature, and 2,3-diphosphoglycerate concentrations).

Cao2 = (Sao2 × Hgb × 1.34) + (0.003 × Pao2)

Total oxygen content of blood is greatly influenced by Sao2 and hemoglobin concentration. In health, more than 60 times more oxygen is delivered by hemoglobin than is dissolved in plasma (Pao2).

Paco2 = PAco2

These values are increased with hypoventilation at alveolar level and are decreased with hypoventilation.

PAo2 = FIo2 (PB − PH2O) − Paco2/R on room air at sea level: PAo2 = 150╯mm╯Hg − Paco2/0.8

Partial pressure of oxygen in alveolar air available for exchange with blood changes directly with inspired oxygen concentration and inversely with Paco2. R is assumed to mismatch), be 0.8 for fasting animals. With normally functioning lungs (minimal V/Q alveolar hyperventilation results in increased PAo2 and subsequently increased Pao2, whereas hypoventilation results in decreased PAo2 and decreased Pao2.

A-a = PAo2 − Pao2

mismatch by eliminating contribution of alveolar A-a gradient quantitatively assesses V/Q ventilation and inspired oxygen concentration to measured Pao2. Low Pao2, with a normal A-a gradient (10╯mm╯Hg in room air) indicates hypoventilation alone. Low Pao2 with a wide A-a gradient (>15╯mm╯Hg in room air) indicates a component of V/Q mismatch.

Paco2 ∝ 1/pH

Increased Paco2 causes respiratory acidosis; decreased Paco2 causes respiratory alkalosis. Actual pH depends on metabolic (HCO3) status as well.

A-a, Alveolar-arterial oxygen gradient (mm╯Hg); Cao2, oxygen content of arterial blood (mL of O2/dL); FIo2, fraction of oxygen in inspired air (%); Hgb, hemoglobin concentration (g/dL); Paco2, partial pressure of CO2 in arterial blood (mm╯Hg); PAco2, partial pressure of O2 in alveolar air (mm╯Hg); Pao2, partial pressure of O2 in arterial blood (mm╯Hg); PAo2, partial pressure of O2 in alveolar air (mm╯Hg); PB, barometric (atmospheric) pressure (mm╯Hg); PH2O, partial pressure of water in alveolar air (100% humidified) (mm╯Hg); pH, negative logarithm of H+ concentration (decreases with increased H+); R, respiratory exchange quotient (ratio of O2 uptake per CO2 produced); Sao2, amount of hemoglobin saturated with oxygen (%); V /Q , ratio of ventilation to perfusion of alveoli.

  BOX 20-10â•… Calculation and Interpretation of A-a Gradient: Clinical Examples Example 1: A healthy dog breathing room air has a PaO2 of 95╯mm╯Hg and a PaCO2 of 40╯mm╯Hg. His calculated PAO2 is 100╯mm╯Hg. (PAO2 = FIO2 [PB − PH2O] − PaCO2/R = 0.21 [765╯mm╯Hg − 50╯mm╯Hg] − [40╯mm╯Hg/0.8].) The A-a gradient is 100╯mm╯Hg − 95╯mm╯Hg = 5╯mm╯Hg. This value is normal. Example 2: A dog with respiratory depression due to an anesthetic overdose has a PaO2 of 72╯mm╯Hg and a PaCO2 of 56╯mm╯Hg in room air. His calculated PAO2 is 80╯mm╯Hg. The A-a gradient is 8╯mm╯Hg. His hypoxemia can be explained by hypoventilation. Later the same day, the dog develops crackles bilaterally. Repeat blood gas analysis shows a PaO2 of 60╯mm╯Hg and a PaCO2 of 48╯mm╯Hg. His calculated PAO2 is 90╯mm╯Hg. The A-a gradient is 30╯mm╯Hg. Hypoventilation continues to contribute to the hypoxemia, but hypoventilation has improved. The mismatch. This widened A-a gradient indicates V/Q dog has aspirated gastric contents into his lungs.

Oxygen must be successfully delivered to the tissues, and this depends on cardiac output and local circulation. Ultimately, the tissues must be able to effectively use the oxygen— a process interfered with in the presence of toxicities such as carbon monoxide or cyanide poisoning. Each of these processes must be considered when the blood gas values in an individual animal are interpreted.

Acid-Base Status The acid-base status of an animal can be assessed using the same blood sample that is used to measure blood gases. Acidbase status is influenced by the respiratory system (see Table 20-6). Respiratory acidosis results if carbon dioxide is retained as a result of hypoventilation. If the problem persists for several days, compensatory retention of bicarbonate by the kidneys occurs. Excess removal of carbon dioxide by the lungs caused by hyperventilation results in respiratory alkalosis. Hyperventilation is usually an acute phenomenon, potentially caused by shock, sepsis, severe anemia, anxiety, or pain; therefore compensatory changes in the bicarbonate concentration are rarely seen. The respiratory system partially compensates for primary metabolic acid-base disorders, and this can occur quickly.

CHAPTER 20â•…â•… Diagnostic Tests for the Lower Respiratory Tract

Hyperventilation and a decreased Paco2 occur in response to metabolic acidosis. Hypoventilation and an increased Paco2 occur in response to metabolic alkalosis. In most cases, acid-base disturbances can be identified as primarily respiratory or primarily metabolic in nature on the basis of the pH. The compensatory response will never be excessive and alter the pH beyond normal limits. An animal with acidosis (pH of less than 7.35) has a primary respiratory acidosis if the Paco2 is increased and a compensatory respiratory response if the Paco2 is decreased. An animal with alkalosis (pH of greater than 7.45) has a primary respiratory alkalosis if the Paco2 is decreased and a compensatory respiratory response if the Paco2 is increased. If both the Paco2 and the bicarbonate concentration are abnormal, such that both contribute to the same alteration in pH, a mixed disturbance is present. For instance, an animal with acidosis, an increased Paco2, and a decreased HCO3 has a mixed metabolic and respiratory acidosis.

T

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P

PULSE OXIMETRY Indications Pulse oximetry is a method of monitoring the oxygen saturation of blood. The saturation of hemoglobin with oxygen is related to the Pao2 by the sigmoid oxyhemoglobin dissociation curve (see Fig. 20-30). Pulse oximetry is noninvasive, can be used to continuously monitor a dog or cat, provides immediate results, and is affordable for most practices. It is a particularly useful device for monitoring animals with respiratory disease that must undergo procedures requiring anesthesia. It can also be used in some cases to monitor the progression of disease or the response to therapy. More and more clinicians are using these devices for routine monitoring of animals under general anesthesia, particularly if the number of personnel is limited, because alarms can be set to warn of marked changes in values.

METHOD Most pulse oximeters have a probe that is attached to a fold of tissue, such as the tongue, lip, ear flap, inguinal skin fold, toe, or tail (Fig. 20-31). This probe measures light absorption through the tissues. Other models measure reflected light and can be placed on mucous membranes or within the esophagus or rectum. Artifacts resulting from external light sources are minimized in the latter sites. Arterial blood is identified by the oximeter as that component which changes in pulses. Nonpulsatile absorption is considered background. INTERPRETATION Values provided by the pulse oximeter must be interpreted with care. The instrument must record a pulse that matches the palpable pulse of the animal. Any discrepancy between actual pulse and the pulse received by the oximeter indicates an inaccurate reading. Common problems that can interfere with the accurate detection of pulses include the position of

FIG 20-31â•…

Monitoring oxygen saturation in a cat under general anesthesia using a pulse oximeter with a probe (P) clamped onto the tongue (T).

the probe, animal motion (e.g., respirations, shivering), and weak or irregular pulse pressures (e.g., tachycardia, hypovolemia, hypothermia, arrhythmias). The value measured indicates the saturation of hemoglobin in the local circulation. However, this value can be affected by factors other than pulmonary function, such as vasoconstriction, low cardiac output, and local stasis of blood. Other intrinsic factors that can affect oximetry readings include anemia, hyperbilirubinemia, carboxyhemoglobinemia, and methemoglobinemia. External lights and the location of the probe can also influence results. Pulse oximetry readings of oxygen saturation are less accurate when values are below 80%. These sources for error should not discourage the clinician from using this technology, however, because changes in saturation in an individual animal provide valuable information. Rather, results must be interpreted critically. Examination of the oxyhemoglobin dissociation curve (see Fig. 20-30) in normal dogs and cats shows that animals with Pao2 values exceeding 85╯mm╯Hg will have a hemoglobin saturation greater than 95%. If Pao2 values decrease to 60╯mm╯Hg, the hemoglobin saturation will be approximately 90%. Any further decrease in Pao2 results in a precipitous decrease in hemoglobin saturation, as illustrated by the steep portion of the oxyhemoglobin dissociation curve. Ideally, then, hemoglobin saturation should be maintained at greater than 90% by means of oxygen supplementation or ventilatory support (see Chapter 27) or specific treatment of the underlying disease. However, because of the many variables

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associated with pulse oximetry, such strict guidelines are not always valid. In practice, a baseline hemoglobin saturation value is measured, and subsequent changes in that value are then used to assess improvement or deterioration in oxygenation. Ideally, the baseline value is compared with the Pao2 obtained from an arterial blood sample collected concurrently to ensure the accuracy of the readings. Suggested Readings Armbrust LJ: Comparison of three-view thoracic radiography and computed tomography for detection of pulmonary nodules in dogs with neoplasia, J Am Vet Med Assoc 240:1088, 2012. Bowman DD et al: Georgis’ parasitology for veterinarians, ed 9, St Louis, 2009, Saunders Elsevier. Foster S, Martin P: Lower respiratory tract infections in cats: reaching beyond empirical therapy, J Fel Med Surg 13:313, 2011. Hawkins EC: Bronchoalveolar lavage. In King LG, editor: Textbook of respiratory disease in dogs and cats, St Louis, 2004, Elsevier. Hopper K et al: Assessment of the effect of dilution of blood samples with sodium heparin on blood gas, electrolyte, and lactate measurements in dogs, Am J Vet Res 66:656, 2005. Kirschvink N et al: Bronchodilators in bronchoscopy-induced airflow limitation in allergen-sensitized cats, J Vet Intern Med 19:161, 2005. Kuehn NF et al: Bronchoscopy. In King LG, editor: Textbook of respiratory disease in dogs and cats, St Louis, 2004, Elsevier. Lacorcia L et al: Comparison of bronchoalveolar lavage fluid examination and other diagnostic techniques with the Baermann

technique for detection of naturally occurring Aelurostrongylus abstrusus infection in cats, J Am Vet Med Assoc 235:43, 2009. Larson MM: Ultrasound of the thorax (noncardiac), Vet Clin Small Anim 39:733, 2009. McKiernan BC: Bronchoscopy. In McCarthy TC et al, editors: Veterinary endoscopy for the small animal practitioner, St Louis, 2005, Elsevier. Neath PJ et al: Lung lobe torsion in dogs: 22 cases (1981-1999), J Am Vet Med Assoc 217:1041, 2000. Nemanic S et al: Comparison of thoracic radiographs and single breath-hold helical CT for detection of pulmonary nodules in dogs with metastatic neoplasia, J Vet Intern Med 20:508, 2006. Norris CR et al: Use of keyhole lung biopsy for diagnosis of interstitial lung diseases in dogs and cats: 13 cases (1998-2001), J Am Vet Med Assoc 221:1453, 2002. Padrid PA: Laryngoscopy and tracheobronchoscopy of the dog and cat. In Tams TR et al, editors: Small animal endoscopy, ed 3, St Louis, 2011, Elsevier Mosby. Peeters DE et al: Quantitative bacterial cultures and cytological examination of bronchoalveolar lavage specimens from dogs, J Vet Intern Med 14:534, 2000. Sherding RG: Respiratory parasites. In Bonagura JD et al, editors: Kirk’s current veterinary therapy XIV, St Louis, 2009, Saunders Elsevier. Spector D et al: Antigen and antibody testing for the diagnosis of blastomycosis in dogs, J Vet Intern Med 22:839, 2008. Thrall D: Textbook of veterinary diagnostic radiography, ed 6, St Louis, 2013, Saunders Elsevier. Urquhart GM et al: Veterinary parasitology, ed 2, Oxford, 1996, Blackwell Science.

C H A P T E R

21â•…

Disorders of the Trachea and Bronchi

GENERAL CONSIDERATIONS Common diseases of the trachea and bronchi include canine infectious tracheobronchitis, canine chronic bronchitis, feline bronchitis, collapsing trachea, and allergic bronchitis. Oslerus osleri infection is an important consideration in young dogs. Other diseases may involve the airways, either primarily or concurrently with pulmonary parenchymal disease. These diseases, such as viral, mycoplasmal, and bacterial infection; other parasitic infections; and neoplasia are discussed in Chapter 22. Feline bordetellosis can cause signs of bronchitis (e.g., cough) but is more often associated with signs of upper respiratory disease (see the section on feline upper respiratory infection, in Chapter 15) or bacterial pneumonia (see the section on bacterial pneumonia, in Chapter 22). Most dogs infected with canine influenza virus present with signs of canine infectious tracheobronchitis, often with concurrent nasal discharge, as discussed later. Severe canine influenza virus infection can result in pneumonia, and this organism is discussed in further detail in Chapter 22.

CANINE INFECTIOUS TRACHEOBRONCHITIS Etiology and Client Communication Challenges Canine infectious tracheobronchitis, canine infectious respiratory disease complex (CIRDC), or “kennel cough” is a highly contagious, acute disease that is localized in the airways. Many different viral and bacterial pathogens can cause this syndrome (Box 21-1). The role of Mycoplasma spp. in respiratory infection of any kind is likely complex, with frequent isolation of organisms from apparently healthy individuals and potential alterations of the host’s immune response. However, several studies strongly support a role for Mycoplasma cynos, in particular, in canine infectious tracheobronchitis. Canine influenza virus, although discussed as a cause of pneumonia in the next chapter, most often

causes tracheobronchitis and rhinitis. Co-infection with more than one of the organisms listed in Box 21-1 can be identified in a single patient, and such combinations may result in more severe clinical signs. In complicated cases, bacteria not considered to be primary pathogens can result in secondary pneumonia due to the effects of the primary agent. For instance, Bordetella organisms infect ciliated respiratory epithelium (Fig. 21-1) and decrease mucociliary clearance. Fortunately, in most dogs the disease is selflimiting, with resolution of clinical signs in approximately 2 weeks. Many clients have the misunderstanding that kennel cough equals infection with Bordetella bronchiseptica. They believe that the “kennel cough” vaccine (meaning, a Bordetella vaccine) prevents the disease and that antibiotics should cure the disease. They are confused by conflicting information about canine influenza virus infections. Some have read about devastating pneumonia, some have been told by boarding facilities that they must vaccinate their dog before they can use the facility, and some have been told by their veterinarian that vaccination is not indicated. An effective means of educating clients is to compare canine infectious tracheobronchitis with “colds and flu” in people. Many different agents are involved. Being infected with one does not preclude being infected with another. A person is more likely to develop infection if he or she or family members regularly find themselves in group settings (e.g., daycare, working environments with large staff, interaction with the public), just as dogs are more likely to be infected with frequent exposure to other dogs. Most people and dogs recover without antibiotics or supportive care, and in fact, viruses will not respond to antibacterial drugs, but some people and dogs develop pneumonia and require aggressive treatment. Rarely, people and dogs die from their infection or its consequences. Vaccines do not prevent infection, and none is completely effective in preventing signs, just as the seasonal influenza vaccine does not prevent all infections or signs. People and dogs are more likely to become seriously ill if they are compromised in some way before infection, but sometimes a particularly virulent strain of organism 297

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  BOX 21-1â•… Agents Associated with Canine Infectious Tracheobronchitis (Canine Infectious Respiratory Disease Complex; “Kennel Cough”) Viruses

Canine Canine Canine Canine Canine

adenovirus 2 influenza virus (H3N8) parainfluenza virus herpesvirus—type1 respiratory coronavirus

Bacteria

Bordetella bronchiseptica Streptococcus equi, subsp. zooepidemicus Mycoplasma cynos

FIG 21-1â•…

Photomicrograph of a tracheal biopsy specimen from a dog infected with Bordetella bronchiseptica. The organisms are small basophilic rods that are visible along the ciliated border of the epithelial cells. (Giemsa stain courtesy D. Malarkey.)

will arise with severe consequences for even healthy people or dogs. Be aware that, although rare, B. bronchiseptica has been documented to cause infection in people. A discussion regarding the potential exposure of a dog with infectious tracheobronchitis to immunocompromised individuals is warranted. Clinical Features Affected dogs are first seen because of the sudden onset of a severe productive or nonproductive cough, which is often exacerbated by exercise, excitement, or pressure of the collar on the neck. Palpating the trachea easily induces the cough. Gagging, retching, or nasal discharge can also occur. A recent history (i.e., within 2 weeks) of boarding, hospitalization, or exposure to a puppy or dog that has similar signs is common. Puppies recently obtained from pet stores, kennels, or shelters have often been exposed to the pathogens.

Most dogs with infectious tracheobronchitis are considered to have “uncomplicated,” self-limiting disease and do not show signs of systemic illness. Therefore dogs showing respiratory distress, weight loss, persistent anorexia, or signs of involvement of other organ systems, such as diarrhea, chorioretinitis, or seizures, may have some other, more serious disease, such as canine distemper or a mycotic infection. Secondary bacterial pneumonia can develop, particularly in puppies, immunocompromised dogs, and dogs that have preexisting lung abnormalities such as chronic bronchitis. Dogs with chronic airway disease or tracheal collapse can experience an acute, severe exacerbation of their chronic problems, and extended management may be necessary to resolve the signs associated with infection in these animals. B. bronchiseptica infection has been associated with canine chronic bronchitis. Diagnosis Uncomplicated cases of kennel cough are diagnosed on the basis of presenting signs. However, differential diagnoses should also include the early presentation of a more serious disease. Diagnostic testing is indicated for dogs with systemic, progressive, or unresolving signs. Tests to be considered include thoracic radiographs, a complete blood count (CBC), tracheal wash fluid analysis, and polymerase chain reaction (PCR) testing, paired serology, or other tests for the respiratory pathogens listed in Box 21-1. Tracheal wash fluid cytology shows acute inflammation, and bacterial culture of the fluid can be useful for identifying any bacteria involved in the disease and for obtaining antibiotic sensitivity information to guide antibiotic selection. Testing for specific pathogens by serology or PCR rarely provides information that will redirect treatment of an individual dog, but may be helpful in managing outbreaks. Treatment Uncomplicated infectious tracheobronchitis is a self-limiting disease. Rest for at least 7 days, specifically avoiding exercise and excitement, is indicated to minimize the continual irritation of the airways caused by excessive coughing. Cough suppressants are valuable for the same reason but should not be given if the cough is overtly productive, or if exudate is suspected to be accumulating in the lungs on the basis of auscultation or thoracic radiograph findings. As discussed in Chapter 19, it is not always possible to recognize a productive cough in dogs. Therefore cough suppressants should be used judiciously to treat frequent or severe cough, to allow for restful sleep, and to prevent exhaustion. A variety of cough suppressants can be used in dogs (Table 21-1). Dextromethorphan is available in over-thecounter preparations; however, it has questionable efficacy in dogs. Cold remedies with additional ingredients such as antihistamines and decongestants should be avoided. Pediatric liquid preparations are palatable for most dogs, and the alcohol contained in them may have a mild tranquilizing effect. Narcotic cough suppressants are more likely to be effective. Butorphanol is available as a veterinary labeled

CHAPTER 21â•…â•… Disorders of the Trachea and Bronchi

  TABLE 21-1â•… Common Cough Suppressants for Use in Dogs* AGENT

DOSAGE

Dextromethorphan†

1-2╯mg/kg PO q6-8h

Butorphanol

0.5╯mg/kg PO q6-12h

Hydrocodone bitartrate

0.25╯mg/kg PO q6-12h

*Centrally acting cough suppressants are rarely, if ever, indicated for use in cats and can result in adverse reactions. The preceding dosages are for dogs only. † Efficacy is questionable in dogs. PO, By mouth.

product (Torbutrol, Pfizer Animal Health). Hydrocodone bitartrate is a potent alternative for dogs with refractory cough. In theory, antibiotics are not indicated for most dogs with infectious tracheobronchitis for two reasons: (1) The disease is usually self-limiting and tends to resolve spontaneously, regardless of any specific treatment that is implemented, and (2) no antibiotic protocol has been proven to eliminate Bordetella or Mycoplasma organisms from the airways. In practice, however, antibiotics are often prescribed, and their use is justified because of the potential presence of these organisms. Doxycycline (5-10╯mg/kg q12h, followed by a bolus of water) is effective against Mycoplasma spp. and many Bordetella isolates. Although the ability of doxycycline to reach therapeutic concentration within the airways has been questioned because it is highly protein bound in the dog, the presence of inflammatory cells may increase locally available concentrations of the drug and account for its anecdotal success. Amoxicillin with clavulanate (20-25╯mg/kg orally q8h) is effective, in vitro, against many Bordetella isolates. Fluoroquinolones provide the advantage of reaching high concentrations in the airway secretions, but their use is ideally reserved for more serious infections. Bacterial susceptibility data from tracheal wash fluid can be used to guide the selection of an appropriate antibiotic. Antibiotics are administered for 5 days beyond the time the clinical signs resolve, or for at least 14 days. Administration of gentamicin by nebulization can be considered for refractory cases or in outbreaks of infection involving dogs housed together, although no controlled studies have been published. An early study by Bemis et╯al (1977) showed that bacterial populations of Bordetella in the trachea and bronchi were reduced for up to 3 days after treatment with nebulized gentamicin but not orally administered antibiotics, and clinical signs were reduced. Note that the numbers of organisms returned to pretreatment values within 7 days. Some clinicians have since reported success in managing difficult cases and outbreaks with this treatment. The protocol used by Bemis et╯al (1977) consists of 50╯mg of gentamicin sulfate in 3╯mL of sterile water, delivered by nebulizer and face mask (see Fig. 22-1) for 10 minutes every

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12 hours for 3 days. Sterile technique must be maintained to keep from delivering additional bacteria to the airways. Nebulization of drugs has the potential to induce bronchospasms, so dogs should be carefully observed during the procedure. Pretreatment with bronchodilators should be considered, and additional bronchodilators (metered dose inhaler [MDI] and/or injectable) should be at hand for use as needed. Glucocorticoids should not be used. No field studies have demonstrated any benefit of steroid therapy, either alone or in combination with antibiotics. If clinical signs have not resolved within 2 weeks, further diagnostic evaluation is indicated. See Chapter 22 for the management of complicated cases of infectious tracheobronchitis with bacterial pneumonia. Prognosis The prognosis for recovery from uncomplicated infectious tracheobronchitis is excellent. Prevention Canine infectious tracheobronchitis can be prevented by minimizing an animal’s exposure to organisms and by providing vaccination programs. Excellent nutrition, routine deworming, and avoidance of stress improve the dog’s ability to respond appropriately to infection without showing serious signs. Studies in shelters and rehoming facilities have shown that the major variable associated with development of cough in newly arrived dogs is time in the facility. Bordetella may persist in the airways of dogs for up to 3 months after infection. To minimize exposure to Bordetella or respiratory viruses, dogs are kept isolated from puppies or dogs that have been recently boarded. Careful sanitation should be practiced in kenneling facilities. Caretakers should be instructed in the disinfection of cages, bowls, and runs, and everyone working with the dogs must wash their hands after handling each animal. Dogs should not be allowed to have face-to-face contact. Adequate air exchange and humidity control are necessary in rooms housing several dogs. Recommended goals are at least 10 to 15 air exchanges per hour and less than 50% humidity. An isolation area is essential for the housing of dogs with clinical signs of infectious tracheobronchitis. Injectable and intranasal vaccines are available for the three major pathogens involved in canine infectious tracheobronchitis (i.e., canine adenovirus 2 [CAV2], canine parainfluenza virus [PIV], B. bronchiseptica). Injectable modified-live virus vaccines against CAV2 and PIV are adequate for most pet dogs. They are conveniently included in most combination distemper vaccines. Because maternal antibodies interfere with the response to vaccines, puppies must be vaccinated every 2 to 4 weeks, beginning at 6 to 8 weeks of age and through 14 to 16 weeks of age. At least two vaccines must be given initially. For most healthy dogs, a booster is recommended after 1 year, followed by subsequent vaccinations every 3 years (see Chapter 91).

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Dogs at high risk for disease, such as those in kennels where the disease is endemic or those that are frequently boarded, may benefit from vaccines incorporating B. bronchiseptica. These vaccines do not prevent infection but aim to decrease clinical signs should infection occur. They may also reduce the duration of shedding of organisms after infection. A study by Ellis et╯al (2001) indicated that both intranasal and parenteral Bordetella vaccines afford similar protection based on antibody titers, clinical signs, upper airway cultures, and histopathologic examination of tissues after exposure to organisms. The greatest benefit was achieved by administering both forms of vaccine sequentially at 2-week intervals (two doses of parenteral vaccine and then a dose of intranasal vaccine), but such an aggressive schedule is not routinely recommended. Also in experimental settings, protection against challenge following intranasal vaccination against B. bronchiseptica and PIV began by 72 hours (but not earlier) after vaccination and persisted for at least 13 months (Gore, 2005; Jacobs et╯al, 2005). Intranasal Bordetella vaccines occasionally cause clinical signs, predominantly cough. The signs are generally self-limiting but are disturbing to most owners. Canine influenza is discussed in Chapter 22.

CANINE CHRONIC BRONCHITIS Etiology Canine chronic bronchitis is a disease syndrome defined as cough that occurs on most days of 2 or more consecutive months in the past year in the absence of other active disease. Histologic changes in the airways are those of long-term inflammation and include fibrosis, epithelial hyperplasia, glandular hypertrophy, and inflammatory infiltrates. Some of these changes are irreversible. Excessive mucus is present within the airways, and small airway obstruction occurs. In people chronic bronchitis is strongly associated with smoking. It is presumed that canine chronic bronchitis is a consequence of a long-standing inflammatory process initiated by infection, allergy, or inhaled irritants or toxins. A continuing cycle of inflammation likely occurs as mucosal damage, mucus hypersecretion, and airway obstruction impair normal mucociliary clearance, and inflammatory mediators amplify the response to irritants and organisms. Clinical Features Chronic bronchitis occurs most often in middle-aged or older, small-breed dogs. Breeds commonly affected include Terriers, Poodles, and Cocker Spaniels. Small-breed dogs are also predisposed to the development of collapsing trachea and mitral insufficiency with left atrial enlargement causing compression of the mainstem bronchi. These causes for cough must be differentiated, and their contribution to the development of the current clinical features determined, for appropriate management to be implemented. Dogs with chronic bronchitis are evaluated because of loud, harsh cough. Mucus hypersecretion is a component of

the disease, but the cough may sound productive or nonproductive. The cough has usually progressed slowly over months to years, although clients typically report the initial onset as acute. There should be no systemic signs of illness such as anorexia or weight loss. As the disease progresses, exercise intolerance becomes evident; then incessant coughing or overt respiratory distress is seen. Potential complications of chronic bronchitis include bacterial or mycoplasmal infection, tracheobronchomalacia (see p. 309), pulmonary hypertension (see Chapter 22), and bronchiectasis. Bronchiectasis is the term for permanent dilation of the airways (Fig. 21-2; see also Fig. 20-4). Bronchiectasis can be present secondary to other causes of chronic airway inflammation or airway obstruction, and in association with certain congenital disorders such as ciliary dyskinesia (i.e., immotile cilia syndrome). Bronchiectasis caused by traction on the airways, rather than bronchial disease, can be seen with idiopathic pulmonary fibrosis. Generally, all the major airways are dilated in dogs with bronchiectasis, but occasionally the condition is localized. Recurrent bacterial infection and overt bacterial pneumonia are common complications in dogs with bronchiectasis. Dogs with chronic bronchitis are often brought to a veterinarian because of a sudden exacerbation of signs. The change in signs may result from transient worsening of the chronic bronchitis, perhaps after a period of unusual excitement, stress, or exposure to irritants or allergens; from a secondary complication, such as bacterial infection; or from the development of a concurrent disease, such as left atrial enlargement and bronchial compression or heart failure (Box 21-2). In addition to providing a routine complete history, the client should be carefully questioned about the character of the cough and the progression of signs. Detailed information should be obtained regarding the following: environmental conditions, particularly exposure to smoke, other potential irritants and toxins, or allergens; exposure to

FIG 21-2â•…

Photomicrograph of a lung biopsy specimen from a dog with severe bronchiectasis. The airways are filled with exudate and are greatly dilated (hematoxylin and eosin [H&E] stain).

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  BOX 21-2â•… Diagnostic Considerations for Dogs with Signs Consistent with Canine Chronic Bronchitis Other Active Disease (Rather Than Canine Chronic Bronchitis)

Bacterial infection Mycoplasmal infection Bronchial compression (e.g., left atrial enlargement) Pulmonary parasites Heartworm disease Allergic bronchitis Neoplasia Foreign body Chronic aspiration Gastroesophageal reflux*

A

B

FIG 21-3â•…

Bronchoscopic view of the right caudal bronchus of a dog with chronic bronchitis and severe bronchomalacia. The airways appear normal during inspiration (A) but completely collapse during expiration, obliterating the lumen of the airway (B).

Potential Complications of Canine Chronic Bronchitis

Tracheobronchomalacia Pulmonary hypertension Bacterial infection Mycoplasmal infection Bronchiectasis Most Common Concurrent Cardiopulmonary Diseases

Collapsing trachea Bronchial compression (e.g., left atrial enlargement) Heart failure *Gastroesophageal reflux is a common cause of chronic cough in people. Documentation in dogs and cats is limited.

infectious agents, such as boarding or exposure to puppies; and all previous and current medications and responses to treatment. On physical examination, increased breath sounds, crackles, or occasionally wheezes are auscultated in animals with chronic bronchitis. End-expiratory clicks caused by mainstem bronchial or intrathoracic tracheal collapse may be heard in animals with advanced disease. A prominent or split second heart sound occurs in animals with secondary pulmonary hypertension. Dogs with respiratory distress (end-stage disease) characteristically show marked expiratory efforts because of narrowing and collapse of the intrathoracic large airways. The presence of a fever or other systemic signs is suggestive of other disease, such as bacterial pneumonia. Diagnosis Canine chronic bronchitis is defined as a cough that occurs on most days of 2 or more consecutive months in the past year in the absence of other active disease. Therefore chronic bronchitis is diagnosed on the basis of not only clinical signs but also the elimination of other diseases from the list of differential diagnoses (see Box 21-2). The possibility of secondary disease complicates this simple definition.

A bronchial pattern with increased interstitial markings is typically seen on thoracic radiographs, but changes are often mild and difficult to distinguish from clinically insignificant changes associated with aging. Thoracic radiographs are most useful for ruling out other active disease and for identifying concurrent or secondary disease. Tracheal wash or bronchoalveolar lavage (BAL) fluid should be collected at the time of the initial presentation and after a persistent exacerbation of signs. Tracheal wash will usually provide a sufficient specimen in diffuse airway disease. Neutrophilic or mixed inflammation and increased amounts of mucus are usually present. The finding of degenerative neutrophils indicates the possibility of a bacterial infection. Airway eosinophilia is suggestive of a hypersensitivity reaction, as can occur with allergy, parasitism, or heartworm disease. Slides should be carefully examined for organisms. Bacterial cultures are performed and the results interpreted as discussed in Chapter 20. Although the role of Mycoplasma infection in these cases is not well understood, Mycoplasma cultures or PCR are also considered. Bronchoscopy, with specimen collection, is performed in selected cases, primarily to help rule out other diseases. The maximal benefit of bronchoscopy is obtained early in the course of disease, before severe permanent damage has occurred and while the risk of the procedure is minimal. Gross abnormalities visualized by bronchoscopy include an increased amount of mucus, roughened mucosa, and hyperemia. Major airways may collapse during expiration as a result of weakened walls (Fig. 21-3), and polypoid mucosal proliferation may be present. Bronchial dilation is seen in animals with bronchiectasis. Further diagnostic procedures are indicated to rule out other potential causes of chronic cough, and selection of these depends on the presenting signs and results of the previously discussed diagnostic tests. Diagnostic tests to be considered include heartworm tests, fecal examinations for pulmonary parasites, echocardiography, and systemic evaluation (i.e., CBC, serum biochemical panel, urinalysis).

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Echocardiography may reveal evidence of secondary pulmonary hypertension, including right heart enlargement (i.e., cor pulmonale). Ciliary dyskinesia, in which ciliary motion is abnormal, is uncommon but should be considered in young dogs with bronchiectasis or recurrent bacterial infection. Abnormalities exist in all ciliated tissues, and situs inversus (i.e., lateral transposition of the abdominal and thoracic organs, such that left-sided structures are found on the right and vice versa) is seen in 50% of such dogs. Dextrocardia that occurs in association with chronic bronchitis is extremely suggestive of this disease. Sperm motility can be evaluated in intact male dogs. The finding of normal sperm motility rules out a diagnosis of ciliary dyskinesia. The disease is diagnosed on the basis of the rate at which radioisotopes deposited at the carina are cleared and the findings from electron microscopic examination of bronchial biopsy, nasal biopsy, or sperm specimens. Treatment Chronic bronchitis is managed symptomatically, with specific treatment possible only for concurrent or complicating diseases that are identified. Each dog with chronic bronchitis is presented at a different stage of the disease, with or without concurrent or secondary cardiopulmonary disease (see Box 21-2). Hence each dog must be managed individually. Ideally, medications are initiated one at a time to allow assessment of the most effective combination. It will likely be necessary to modify treatment over time.

GENERAL MANAGEMENT Exacerbating factors, either possible or proven, are avoided. Potential allergens are considered in dogs with eosinophilic inflammation and trial elimination pursued (see the section on allergic bronchitis, p. 313). Exposure to irritants such as smoke (from tobacco or fireplace) and perfumed products should be avoided in all dogs. Motivated clients can take steps to improve the air quality in their home through carpet, furniture, and drapery cleaning; cleaning of the furnace and frequent replacement of air filters; and the use of an air cleaner. The American Lung Association has a useful Web site with nonproprietary recommendations for improving indoor air quality (www.lung.org). Excitement or stress can cause an acute worsening of signs in some animals, and short-term tranquilization with acepromazine or sedation with phenobarbital can be helpful in relieving the signs. In rare cases, anxiolytic drugs may be beneficial. It is normal for flora from the oropharynx to be aspirated into the airways. Routine dental prophylaxis and teeth brushing will help maintain a healthy oral flora and may decrease any contributions of normal aspiration to ongoing airway inflammation in patients with reduced mucociliary clearance. Airway hydration should be maintained to facilitate mucociliary clearance. Adequate airway hydration is best achieved by maintaining systemic hydration. Therefore

diuretic therapy is not recommended in these patients. For severely affected dogs, placing the animal in a steamy bathroom or in a room with a vaporizer daily may provide symptomatic relief, although the moisture does not penetrate very deeply into the airways. Nebulization of saline will allow moisture to go more deeply into the lungs. This technique is discussed further in the section on bacterial pneumonia in Chapter 22. Patients that are overweight and/or unfit may benefit from weight loss (see Chapter 54) and exercise. Exercise should be tailored to the dog’s current fitness level and degree of pulmonary dysfunction to keep from causing excessive respiratory efforts or even death. Observing the dog during specific exercise, such as a short walk, while in the client’s presence may be necessary to make initial recommendations. Instructing clients in measurement of respiratory rate, observation of mucous membrane color, and signs of increased respiratory effort will improve their ability to assess the dog’s status during exercise.

DRUG THERAPIES Medications to control clinical signs include bronchodilators, glucocorticoids, and cough suppressants. Theophylline, a methylxanthine bronchodilator, has been used for years for the treatment of chronic bronchitis in people and dogs. This drug became unpopular with physicians when newer bronchodilators with fewer side effects became available. However, research in people suggests that theophylline is effective in treating the underlying inflammation of chronic bronchitis, even at concentrations below those resulting in bronchodilation (hence, reducing side effects), and that the antiinflammatory effects may be synergistic with those of glucocorticoids. Theophylline may also improve mucociliary clearance, decrease fatigue of respiratory muscles, and inhibit the release of mast cell mediators of inflammation. The potential beneficial effects of theophylline beyond bronchodilation may be of particular importance in dogs because their airways are not as reactive (i.e., likely to bronchospasm) as those of cats and people. However, theophylline alone is rarely sufficient to control the clinical signs of chronic bronchitis. Other advantages associated with theophylline include the availability of long-acting preparations that can be administered twice daily to dogs and the fact that plasma concentrations of drug can be easily measured by commercial diagnostic laboratories. A disadvantage of theophylline is that other drugs, such as fluoroquinolones, can delay its clearance, causing signs of theophylline toxicity if the dosage is not reduced by one third to one half. Potential adverse effects include gastrointestinal signs, cardiac arrhythmias, nervousness, and seizures. Serious adverse effects are extremely rare at therapeutic concentrations. Variability in sustained plasma concentrations has been noted for different long-acting theophylline products. Dosage recommendations are currently available for a generic product from a specific manufacturer (Box 21-3). If beneficial effects are not seen, if the patient is predisposed to

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  BOX 21-3â•… Common Bronchodilators for Use in Dogs and Cats Methylxanthines

Aminophylline Cat: 5╯mg/kg PO q12h Dog: 11╯mg/kg PO q8h Theophylline base (immediate release) Cat: 4╯mg/kg PO q12h Dog: 9╯mg/kg PO q8h Long-acting theophylline (Theochron or TheoCap, Inwood Laboratories, Inwood, NY)* Cat: 15╯mg/kg q24h, in evening Dog: 10╯mg/kg q12h Sympathomimetics

Terbutaline Cat: 18 - 14 of 2.5╯mg tablet/cat PO q12h; or 0.01╯mg/kg SC; can repeat once Dog: 1.25-5╯mg/dog PO q8-12h Albuterol Cat and Dog: 20-50╯µg/kg PO q8-12h (0.020.05╯mg/kg), beginning with lower dose *Canine dosage for these products from Inwood Laboratories from Bach JF et╯al: Evaluation of the bioavailability and pharmacokinetics of two extended-release theophylline formulations in dogs, J Am Vet Med Assoc 224:1113, 2004. Feline dosage from Guenther-Yenke CL et╯al: Pharmacokinetics of an extended-release theophylline product in cats, J Am Vet Med Assoc 231:900, 2007. Monitoring of plasma concentrations is recommended in patients at risk for or with signs of toxicity and in patients that fail to respond to treatment. PO, By mouth; SC, subcutaneously.

adverse effects, or if adverse effects occur, plasma theophylline concentrations should be measured. Therapeutic peak concentration for bronchodilation, based on data from people, ranges from 5 to 20╯µg/mL. Plasma is collected during peak concentrations, generally 4 to 5 hours after administration of a long-acting product, or 1.5 to 2 hours after administration of an immediate-release product. Measurement of concentrations immediately before the next scheduled dose might provide useful information regarding duration of therapeutic concentrations. Theophylline and related drugs that are not long acting are useful in specific circumstances but may need to be administered three times daily (see Box 21-3). Palatable elixirs of theophylline derivatives (e.g., oxtriphylline) are convenient for administration to toy breeds. Therapeutic blood concentrations are reached more quickly after the administration of liquids, or tablets or capsules that are not long acting. Measurement of plasma concentrations gives the best information regarding dosing for a particular patient. Sympathomimetic drugs are preferred by some clinicians as bronchodilators (see Box 21-2). Terbutaline and albuterol are selective for β2-adrenergic receptors, lessening their cardiac effects. Potential adverse effects include nervousness,

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tremors, hypotension, and tachycardia. Clinical use of bronchodilators delivered by MDI, such as albuterol and ipratropium (a parasympatholytic), has not been reported in dogs with chronic bronchitis. Glucocorticoids are often effective in controlling the signs of chronic bronchitis and may slow the development of permanent airway damage by decreasing inflammation. They may be particularly helpful in dogs with eosinophilic airway inflammation. Potential negative effects include increased susceptibility to infection in dogs already impaired by decreased airway clearance; a tendency toward obesity, hepatomegaly, and muscle weakness that may adversely affect ventilation; and pulmonary thromboembolism. Therefore short-acting products are used, the dose is tapered to the lowest effective one (when possible, 0.5╯mg/kg orally q48h or less of prednisone), and the drug is discontinued if no beneficial effect is seen. Prednisone is initially given at a dose of 0.5 to 1╯mg/kg orally every 12 hours, with a positive response expected within 1 week. Dogs that require relatively high dosages of prednisone, that have unacceptable adverse effects, or that have conditions for which glucocorticoids are relatively contraindicated (e.g., diabetes mellitus) may benefit from local treatment with MDIs. This route of administration is discussed in greater detail later in this chapter, in the section on feline bronchitis (see p. 304). Cough suppressants are used cautiously because cough is an important mechanism for clearing airway secretions. In some dogs, however, the cough is incessant and exhausting, or ineffective, because of marked tracheobronchomalacia and airway collapse. Cough suppressants can provide significant relief for such animals and may even facilitate ventilation and decrease anxiety. Although the doses given in Table 21-1 are the ones that provide prolonged effectiveness, less frequent administration (i.e., only during times of the day when coughing is most severe) may preserve some beneficial effect of cough. For dogs with severe cough, hydrocodone may provide the greatest relief.

MANAGEMENT OF COMPLICATIONS Antibiotics are often prescribed for dogs with chronic bronchitis. If possible, confirmation of infection and antibiotic sensitivity information should be obtained by culture of an airway specimen (e.g., tracheal wash fluid). Because cough in dogs with chronic bronchitis often waxes and wanes in severity, it is difficult to make a diagnosis of infection on the basis of the patient’s response to therapy. Furthermore, organisms involved in bronchial infections generally originate from the oropharynx. They are frequently gram-negative with unpredictable antibiotic sensitivity patterns. The role of Mycoplasma organisms in canine chronic bronchitis is not well understood. They may be an incidental finding, or they may be pathogenic. Ideally, antibiotic selection is based on results of culture. Antibiotics that are generally effective against Mycoplasma include doxycycline, azithromycin, chloramphenicol, and fluoroquinolones.

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In addition to the susceptibility of identified organisms, the ability of selected antibiotics to penetrate the airway secretions to the site of infection should be considered when selecting an antibiotic. Antibiotics that are likely to reach concentrations effective against susceptible organisms include chloramphenicol, fluoroquinolones, azithromycin, and possibly amoxicillin with clavulanate. β-Lactam antibiotics do not generally reach therapeutic concentrations in airway secretions of healthy (not inflamed) subjects. If used for bronchial infection, the high end of the dosage range should be used. Doxycycline is often recommended because Mycoplasma and many Bordetella isolates are susceptible to this drug. It may confer an additional benefit of mild antiinflammatory properties. The ability of doxycycline to reach therapeutic concentration within the airways is questionable because in the dog it is highly protein bound, but the presence of inflammatory cells may increase locally available concentrations of the drug. It is preferable to reserve fluoroquinolones for cases of serious infection. If an antibiotic is effective, a positive response is generally seen within 1 week. Treatment is then continued for at least 1 week beyond the time when the clinical signs stabilize because complete resolution is unlikely in these animals. Antibiotic treatment usually is necessary for 3 to 4 weeks. Even longer treatment may be necessary in some cases, particularly if bronchiectasis or overt pneumonia is present. The use of antibiotics for the treatment of respiratory tract infection is also discussed in the section on canine infectious tracheobronchitis in this chapter (see p. 297) and in the section on bacterial pneumonia in Chapter 22. Tracheobronchomalacia is discussed on page 309, and pulmonary hypertension is discussed in Chapter 22.

underlying cause cannot be found. However, as with canine chronic bronchitis, a diagnosis of idiopathic feline bronchitis can be made only by ruling out other active disease. Care should be taken when using the terms feline bronchitis or feline asthma to distinguish between a presentation consistent with bronchitis in a broad sense and a clinical diagnosis of idiopathic disease. Cats with idiopathic bronchitis often have some degree of airway eosinophilia, typical of an allergic reaction. This author prefers to reserve the diagnosis of allergic bronchitis for patients who respond dramatically to the elimination of a suspected allergen (see p. 313). A wide variety of pathologic processes can affect individual cats with idiopathic bronchitis. Clinically, the range in severity of signs and responses to therapy shows this diversity. Different combinations of factors that result in small airway obstruction—a consistent feature of feline bronchial disease—are present in each animal (Box 21-4). Some of these factors (e.g., bronchospasm, inflammation) are reversible, and others (e.g., fibrosis, emphysema) are permanent. The classification proposed by Moise et╯al (1989), which was formulated on the basis of similar pathologic processes that occur in people, is recommended as a way to better define bronchial disease in individual cats for the purpose of treatment recommendations and prognostication (Box 21-5). A cat can have more than one type of bronchitis. Although it is not always possible to absolutely determine the type or types of bronchial disease present without performing sophisticated pulmonary function testing, routine clinical data (i.e., history and physical examination findings, thoracic radiographs, analysis of airway specimens, progression of signs) can be used to classify the disease in most cats.

Prognosis Canine chronic bronchitis cannot be completely cured. The prognosis for the control of signs and for a satisfactory quality of life in animals is good if owners are conscientious about performing the medical management aspects of care and are willing to adjust treatment over time and treat secondary problems as they occur.

Clinical Features Idiopathic bronchitis can develop in cats of any age, although it most commonly develops in young adult and middle-aged animals. The major clinical feature is cough or episodic respiratory distress or both. Some clients will confuse cough in cats with attempts to vomit a hairball. Cats that never produce a hairball are likely coughing. Owners may report audible wheezing during an episode. The signs are often slowly progressive. Weight loss, anorexia, depression, and other systemic signs are not present. If systemic signs are identified, another diagnosis should be aggressively pursued. Owners should be carefully questioned regarding an association with exposure to potential allergens or irritants. Irritants in the environment can cause worsening of signs of bronchitis regardless of the underlying cause. Environmental considerations include exposure to new litter (usually perfumed), cigarette or fireplace smoke, carpet cleaners, and household items containing perfumes such as deodorant or hair spray. Clients should also be questioned about whether there has been any recent remodeling or any other change in the cat’s environment. Seasonal exacerbations are suggestive of potential allergen exposure.

FELINE BRONCHITIS (IDIOPATHIC) Etiology Cats with respiratory disease of many origins present with signs of bronchitis or asthma. Cat airways are much more reactive and prone to bronchoconstriction than those of dogs. The common presenting signs of bronchitis (i.e., cough, wheezing, and/or respiratory distress) can occur in cats with diseases as varied as lung parasites, heartworm disease, allergic bronchitis, bacterial or viral bronchitis, toxoplasmosis, idiopathic pulmonary fibrosis, carcinoma, and aspiration pneumonia (Table 21-2). Veterinarians often assume that cats with presenting signs of bronchitis or asthma have idiopathic disease because in most cats an

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  TABLE 21-2â•… Differential Diagnoses (Etiologic) for Cats with Presenting Signs of Bronchitis DIAGNOSIS

DISTINGUISHING FEATURES COMPARED WITH IDIOPATHIC FELINE BRONCHITIS

Allergic bronchitis

Dramatic clinical response to elimination of suspected allergen(s) from environment or diet.

Pulmonary parasites (Aelurostrongylus abstrusus, Capillaria aerophila, Paragonimus kellicotti)

Thoracic radiographs may have a nodular pattern; Larvae (Aelurostrongylus) or eggs identified in tracheal wash or BAL fluid or in the feces. See Chapter 20 for appropriate procedures for fecal testing.

Heartworm disease

Pulmonary artery enlargement may be present on thoracic radiographs; positive heartworm antigen test or identification of adult worm(s) on echocardiography (see Chapter 10).

Bacterial bronchitis

Intracellular bacteria in tracheal wash or BAL fluid and significant growth on culture (see Chapter 20).

Mycoplasmal bronchitis

Positive PCR test or growth of Mycoplasma on specific culture of tracheal wash or BAL fluid (presence may indicate primary infection, secondary infection, or be incidental).

Idiopathic pulmonary fibrosis

Radiographs may show more severe infiltrates than expected in cats with idiopathic bronchitis; diagnosis requires lung biopsy (see Chapter 22).

Carcinoma

Radiographs may show more severe infiltrates than expected in cats with idiopathic bronchitis. Cytologic or histologic identification of malignant cells in tracheal wash or BAL fluid, lung aspirates, or lung biopsy. Histologic confirmation is ideal.

Toxoplasmosis

Systemic signs usually present (fever, anorexia, depression). Radiographs may show more severe infiltrates than expected in cats with idiopathic bronchitis, possibly with a nodular pattern. Diagnosis is confirmed by identification of organisms (tachyzoites) in tracheal wash or BAL fluid. Rising serum antibody titers or elevated IgM concentrations are supportive of the diagnosis (see Chapter 96).

Aspiration pneumonia

Unusual in cats. History supportive of a predisposing event or condition. Radiographs typically show an alveolar pattern, worse in the dependent (cranial and middle) lung lobes. Neutrophilic inflammation, usually with bacteria, in tracheal wash fluid.

Idiopathic feline bronchitis

Elimination of other diseases from the differential diagnoses.

BAL, Bronchoalveolar lavage; PCR, polymerase chain reaction.

  BOX 21-4â•… Factors That Can Contribute to Small Airway Obstruction in Cats with Bronchial Disease Bronchoconstriction Bronchial smooth muscle hypertrophy Increased mucus production Decreased mucus clearance Inflammatory exudate in airway lumens Inflammatory infiltrate in airway walls Epithelial hyperplasia Glandular hypertrophy Fibrosis Emphysema

Physical examination abnormalities result from small airway obstruction. Cats that are in distress show tachypnea. Typically the increased respiratory efforts are more pronounced during expiration, and auscultation reveals expiratory wheezes. Crackles are occasionally present. In some patients in distress, hyperinflation of the lungs due to air trapping may result in increased inspiratory efforts and decreased lung sounds. Physical examination findings may be unremarkable between episodes. Diagnosis The diagnosis of idiopathic feline bronchitis is made on the basis of typical historical, physical examination, and thoracic radiographic findings and the elimination of other possible differential diagnoses (see Table 21-2). A thorough search for

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  BOX 21-5â•… Classification of Feline Bronchial Disease Bronchial Asthma

Predominant feature: reversible airway obstruction primarily resulting from bronchoconstriction Other common features: hypertrophy of smooth muscle, increased mucus production, eosinophilic inflammation Acute Bronchitis

Predominant feature: reversible airway inflammation of short duration (2-3 months) resulting in irreversible damage (e.g., fibrosis) Other common features: increased mucus production; neutrophilic, eosinophilic, or mixed inflammation; isolation of bacteria or Mycoplasma organisms causing infection or as nonpathogenic inhabitants; concurrent bronchial asthma Emphysema

Predominant feature: destruction of bronchiolar and alveolar walls resulting in enlarged peripheral air spaces Other common features: cavitary lesions (bullae); result of or concurrent with chronic bronchitis Adapted from Moise NS et╯al: Bronchopulmonary disease. In Sherding RG, editor: The cat: diseases and clinical management, New York, 1989, Churchill Livingstone.

other diagnoses is highly recommended, even though a specific diagnosis is not commonly found, because identifying a cause for the clinical signs may enable specific treatment and even cure of an individual cat. Factors to consider when developing a diagnostic plan include the clinical condition of the cat and the client’s tolerance for expense and risk. Cats that are in respiratory distress or are otherwise in critical condition should not undergo any stressful testing until their condition has stabilized. Sufficiently stable cats that have any indication of a diagnosis other than idiopathic disease on the basis of presenting signs and thoracic radiographs or any subsequent test results require a thorough evaluation. Certain tests are completely safe, such as fecal testing for pulmonary parasites, and their inclusion in the diagnostic plan is based largely on financial considerations. In most cats with signs of bronchitis, collection of tracheal wash fluid for cytology and culture and tests for pulmonary parasitism and heartworm disease are recommended. A CBC is often performed as a routine screening test. Cats with idiopathic bronchitis are often thought to have peripheral eosinophilia. However, this finding is neither specific nor

sensitive and cannot be used to rule out or definitively diagnose feline bronchitis. Thoracic radiographs from cats with bronchitis generally show a bronchial pattern (see Fig. 20-3). Increased reticular interstitial markings and patchy alveolar opacities may also be present. The lungs may be seen to be overinflated as a result of trapping of air, and occasionally collapse (i.e., ate� lectasis) of the right middle lung lobe is seen (see Fig. 20-9). However, because clinical signs can precede radiographic changes, and because radiographs cannot detect mild airway changes, thoracic radiographs may be normal in cats with bronchitis. Radiographs are also scrutinized for signs of specific diseases (see Table 21-2). Tracheal wash or BAL fluid cytologic findings are generally representative of airway inflammation and consist of increased numbers of inflammatory cells and an increased amount of mucus. Inflammation can be eosinophilic, neutrophilic, or mixed. Although not a specific finding, eosi� nophilic inflammation is suggestive of a hypersensitivity response to allergens or parasites. Neutrophils should be examined for signs of the degeneration suggestive of bacterial infection. Slides should be carefully scrutinized for the presence of organisms, particularly bacteria and parasitic larvae or ova. Fluid should be cultured for bacteria, although it is important to note that the growth of organisms may or may not indicate the existence of true infection (see Chapter 20). Cultures or PCR for Mycoplasma spp. may also prove helpful. Testing for heartworm disease is described in Chapter 10. Multiple fecal examinations using special concentrating techniques are performed to identify pulmonary parasites, particularly in young cats and cats with airway eosinophilia (see Chapter 20). Other tests may be indicated for individual cats. Treatment

EMERGENCY STABILIZATION The condition of cats in acute respiratory distress should be stabilized before diagnostic tests are performed. Successful treatment includes administration of a bronchodilator, rapid-acting glucocorticoids, and oxygen supplementation. Terbutaline can be administered subcutaneously—a route that avoids additional patient stress (see Box 21-3). Prednisolone sodium succinate is the recommended glucoÂ� corticoid for a life-threatening crisis (up to 10╯ mg/kg, administered intravenously). If intravenous administration is too stressful, the drug can be given intramuscularly. Alternatively, dexamethasone sodium phosphate (up to 2╯ mg/ kg, administered intravenously) can be given. After the drugs are administered, the cat is placed in a cool, stress-free, oxygen-enriched environment. If additional bronchodilation is desired, albuterol can be administered by nebulization or MDI. Administration of drugs by MDI is described later in this section. (See Chapter 26 for further discussion of cats with respiratory distress.)

ENVIRONMENT The potential influence of the environment on clinical signs should be investigated. Allergic bronchitis is diagnosed through the elimination of potential allergens from the environment (see the section on allergic bronchitis). How� ever, even cats with idiopathic bronchitis can benefit from improvement in indoor air quality through the reduction of irritants or unidentified allergens. Potential sources of allergens or irritants are determined through careful owner questioning as described in the section on clinical features. Smoke can often aggravate signs through its local irritating effects. The effect of litter perfumes can be evaluated by replacing the litter with sandbox sand or plain clay litter. Indoor cats may show improvement in response to measures taken to decrease the level of dusts, molds, and mildew in the home. Such measures include carpet, furniture, and drapery cleaning; cleaning of the furnace and frequent replacement of air filters; and the use of an air cleaner. The American Lung Association has a useful Web site with nonproprietary recommendations for improving indoor air quality (www.lung.org). Any beneficial response to an environmental change is usually seen within 1 to 2 weeks. GLUCOCORTICOIDS Therapy with glucocorticoids, with or without bronchodilators, is necessary for most cats with idiopathic bronchitis. Results can be dramatic. However, drug therapy can interfere with environmental testing; therefore the ability of the animal to tolerate a delay in the start of drug therapy must be assessed on an animal-by-animal basis. Glucocorticoids can relieve the clinical signs in most cats and may protect the airways from the detrimental effects of chronic inflammation. Short-acting products such as prednisolone are recommended because the dose can be tapered to the lowest effective amount. Anecdotal experience and a preliminary study suggest that prednisolone may be more effective in cats than prednisone (Graham-Mize et╯al, 2004). A dose of 0.5 to 1╯mg/kg is administered orally every 12 hours initially, with the dose doubled if signs are not controlled within 1 week. Once the signs are well controlled, the dose is tapered. A reasonable goal is to administer 0.5╯mg/kg or less every other day. Outdoor cats that cannot be treated frequently can be administered depot steroid products, such as methylprednisolone acetate (10╯mg/cat intramuscularly may be effective for up to 4 weeks). Glucocorticoids, such as fluticasone propionate (Flovent, GlaxoSmithKline), can also be administered locally to the airways by MDI, as is routine for treating asthma in people. Advantages include minimal systemic side effects and relative ease of administration in some cats compared with pilling. Theoretical concerns about the oronasal deposition of the potent glucocorticoid in cats, compared with people, include the high incidence of periodontal disease and latent herpesvirus infections and the inability to effectively rinse the mouth with water after use. Local dermatitis can be

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caused by mites, dermatophytes, or bacteria. However, veterinarians have been using glucocorticoid MDIs to treat idiopathic feline bronchitis for many years without frequent, obvious adverse effects. This author prefers to obtain a clinical remission of signs using orally administered drug first, except in cats with relative contraindications for systemic glucocorticoid therapy, such as diabetes mellitus. Cats that require a relatively low dose of oral glucocorticoids to control clinical signs, that have no noticeable adverse effects, and that can be pilled without difficulty are often well maintained with oral therapy. Otherwise, once signs are in remission, treatment by MDI is initiated and the dosage of oral prednisolone gradually reduced. A spacer must be used for effective administration of drugs by MDI to cats, and the airflow generated by the cat must be sufficient to activate the spacer valve. Padrid (2000) has found the OptiChamber (Respironics, Inc., Pittsburgh, PA) to be effective (Fig. 21-4). A small anesthetic mask, with rubber diaphragm, is attached to the spacer. Widening of the adapter of the anesthetic mask that is inserted into the spacer is necessary to create a snug fit. This can be achieved with standard anesthesia tubing adapters for “FAIR” scavenging containers. Alternatively, a mask with spacer specifically designed for use in cats is available (Aerokat, Trudell Medical International, London, Ontario, Canada). This design includes a plastic tab that moves with each breath, making it easier for the client to determine whether the cat is inhaling the drug. The cat is allowed to rest comfortably on a table or in the client’s lap. The client places his or her arms on either side of the cat or gently steadies the cat’s neck and head to provide restraint (Fig. 21-5). The MDI,

FIG 21-4â•…

Apparatus for administering drugs by metered dose inhaler (MDI) to cats consists of an anesthetic mask, a spacer (OptiChamber, Respironics, Inc., Pittsburgh, PA), and an MDI (Ventolin, GlaxoSmithKline, Research Triangle Park, NC).

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clinical significance of the persistent inflammation is not yet known, but this matter deserves further study.

FIG 21-5â•…

Administering drugs by metered dose inhaler (MDI) to a cat. The mask and chamber apparatus is the Aerokat (Trudell Medical International, London, Ontario, Canada).

attached to the spacer, is actuated (i.e., pressed) twice. The mask is placed immediately on the cat’s face, with the mouth and nose covered completely, and is held in place while the cat takes 7 to 10 breaths, inhaling the drug into its airways. Excellent videotaped examples of clients treating their cats are readily available by web search. The following treatment schedule has been recommended (Padrid, 2000): Cats with mild daily symptoms should receive 220╯ µg of fluticasone propionate by MDI twice daily and albuterol by MDI as needed. The maximal effect of fluticasone is not expected until after 7 to 10 days of treatment. Cats with moderate daily symptoms should receive treatments with MDI as described for mild symptoms; in addition, prednisolone is administered orally for 10 days (1╯ mg/kg every 12 hours for 5 days, then every 24 hours for 5 days). For cats with severe symptoms, dexamethasone is administered once (0.5-1╯ mg/kg, intravenously), albuterol is administered by MDI every 30 minutes for up to 4 hours, and oxygen is administered. Once stabilized, these cats are prescribed 220╯ µg of fluticasone propionate by MDI every 12 hours and albuterol by MDI every 6 hours as needed. Oral prednisolone is administered as needed. Studies using cats with experimentally induced allergic bronchitis have demonstrated beneficial effects with a lower dosage of 44╯µg/puff (Cohn et╯al, 2010). This form of bronchitis may be less complicated than that seen in clinical patients, so I prefer to begin treatment with higher concentrations and then taper to the least effective dose. Fluticasone is also available at 110╯µg/puff, which is a reasonable compromise for clinically stable cats. Disturbing findings were reported from a study by Cocayne et╯al (2011), indicating that 7 of 10 cats with naturally occurring bronchitis that had resolution of clinical signs during treatment with oral prednisolone had detectable airway inflammation based on BAL cytology. The long-term

BRONCHODILATORS Cats that require relatively large quantities of glucocorticoids to control clinical signs, that react unfavorably to glucocorticoid therapy, or that suffer from periodic exacerbations of signs can benefit from bronchodilator therapy. Recommended doses of these drugs are listed in Box 21-3. This author prefers to use theophylline because it is effective and inexpensive and can be given to cats once daily; moreover, the plasma concentrations can be easily measured for monitoring of difficult cases. Additional properties of theophylline, potential drug interactions, and adverse effects are described in the section on canine chronic bronchitis (see p. 300). The pharmacokinetics of theophylline products are different in cats than in dogs, resulting in different dosages (see Box 21-3). Variability in sustained plasma concentrations in both species has been found for different longacting theophylline products. Dosage recommendations are currently available for a generic product from a specific manufacturer (see Box 21-3). However, the individual metabolism of each of the methylxanthines is variable. If beneficial effects are not seen, if the patient is predisposed to adverse effects, or if adverse effects occur, plasma theophylline concentrations should be measured. Therapeutic peak concentrations, based on data from human subjects, are 5 to 20╯ µg/mL. Plasma for determination of these concentrations should be collected 12 hours after the evening dosing of long-acting products and 2 hours after dosing of short-acting products. Measurement of concentrations immediately before the next scheduled dose might provide useful information concerning duration of therapeutic concentrations. Sympathomimetic drugs can also be effective bronchodilators. Terbutaline is selective for β2-adrenergic receptors, lessening its cardiac effects. Potential adverse effects include nervousness, tremors, hypotension, and tachycardia. It can be administered subcutaneously for the treatment of respiratory emergencies; it can also be administered orally. Note that the recommended oral dose for cats (one eighth to one fourth of a 2.5-mg tablet; see Box 21-3) is lower than the commonly cited dose of 1.25╯mg/cat. The subcutaneous dose is lower still: 0.01╯mg/kg, repeated once in 5 to 10 minutes if necessary. Bronchodilators can be administered to cats by MDI for the immediate treatment of acute respiratory distress (asthma attack). Cats with idiopathic bronchitis are routinely prescribed an albuterol MDI, a spacer, and a mask (see the section on glucocorticoids for details) to be kept at home for emergencies. OTHER POTENTIAL TREATMENTS A therapeutic trial with an antibiotic effective against Mycoplasma is considered because of the difficulty in documenting infection with this organism. Doxycycline (5-10╯mg/kg

orally q12h) is administered for 14 days as a therapeutic trial. For cats that are difficult to medicate, azithromycin (5-10╯mg/ kg orally q24h for 3 days, then q48h) can be tried. If a Mycoplasma is isolated from airway specimens or if a therapeutic response is seen, prolonged treatment for months may be required to eliminate infection. Further study is needed. Remember that administration of doxycycline should always be followed by a bolus of water to minimize the incidence of esophageal stricture. In addition to antibacterial effects, evidence is mounting that in people these drugs have antiinflammatory properties. Antihistamines are not recommended for treating feline bronchitis because histamine in some cats produces bronchodilation. However, work done by Padrid et╯al (1995) has shown that the serotonin antagonist, cyproheptadine, has a bronchodilatory effect in vitro. A dose of 2╯mg/cat orally every 12 hours can be tried in cats with signs that cannot be controlled by routine bronchodilator and glucocorticoid therapy. This treatment is not consistently effective. Much interest has been shown among clients and veterinarians in the use of oral leukotriene inhibitors in cats (e.g., Accolate, Singulair, Zyflo). However, the clinician should be aware that in people, leukotriene inhibitors are less effective than glucocorticoids in the management of asthma. Their main advantages for people lie in decreased side effects, compared with glucocorticoids, and ease of administration. To date, toxicity studies have not been performed on these drugs in cats. Furthermore, several preliminary studies suggest that leukotriene inhibition in cats would not be expected to have efficacy comparable with that in people. Therefore routine use of leukotriene inhibitors in cats is not currently advocated. Further investigation into their potential role in treating feline bronchitis is certainly indicated.

FAILURE TO RESPOND The clinician should ask himself or herself the questions listed in Box 21-6 if cats fail to respond to glucocorticoid and bronchodilator therapy, or if exacerbation of signs occurs during long-term treatment. Prognosis The prognosis for the control of clinical signs of idiopathic feline bronchitis is good for most cats, particularly if extensive permanent damage has not yet occurred. Complete cure is unlikely, and most cats require continued medication. Cats that have severe, acute asthmatic attacks are at risk for sudden death. Cats with persistent, untreated airway inflammation can develop the permanent changes of chronic bronchitis and emphysema.

COLLAPSING TRACHEA AND TRACHEOBRONCHOMALACIA Etiology The normal trachea is seen to be circular on cross section (see Figs. 21-8, B, and 20-27, A). An open lumen is

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  BOX 21-6â•… Considerations for Cats with Bronchitis That Fail to Respond to Glucocorticoid and Bronchodilator Therapy Is the Cat Receiving Prescribed Medication?

Measure plasma theophylline concentrations. Initiate trial therapy with repositol glucocorticoids. Was an Underlying Disease Missed on Initial Evaluation?

Repeat diagnostic evaluation, including complete history for potential allergens, thoracic radiographs, tracheal wash fluid analysis, heartworm tests, and fecal examinations for parasites. In addition, perform complete blood count, serum biochemical analysis, and urinalysis. Initiate trial therapy with anti-Mycoplasma drug. Initiate trial environmental manipulations to minimize potential allergen and irritant exposure. Has a Complicating Disease Developed?

Repeat diagnostic evaluation as described in the preceding sections.

maintained during all phases of quiet respiration by the cartilaginous tracheal rings, which are connected by fibroelastic annular ligaments to maintain flexibility, thereby allowing movement of the neck without compromising the airway. The cartilaginous rings are incomplete dorsally. The dorsal tracheal membrane, consisting of the longitudinal tracheal muscle and connective tissue, completes the rings. The term tracheal collapse refers to narrowing of the tracheal lumen resulting from weakening of the cartilaginous rings, redundancy of the dorsal tracheal membrane, or both. This common description of tracheal collapse represents an oversimplification of the disease, which has several clinical pictures. Collapse can be the result of a congenital abnormality of small-breed dogs. In many dogs, a congenital predisposition is exacerbated by subsequent inflammatory disease or other exacerbating factors. Collapse can also occur in dogs of breeds not known to be congenitally predisposed, as a consequence of chronic airway inflammation. Further, the bronchi can be involved along with the trachea or alone, as the bronchial lumen is normally supported by rafts of cartilage within its walls. In human medicine the term tracheobronchomalacia (TBM) is used, and TBM is classified further as primary (congenital) or secondary (acquired). This terminology more accurately describes the range of disease observed in dogs and should be adopted by the veterinary profession. That TBM can have a congenital basis in dogs is supported by its high prevalence in small-breed dogs. Also, several studies have demonstrated ultrastructural differences in the tracheal cartilage of toy breed dogs with collapsed tracheas, compared with those with normal tracheas. Signs may not develop until later in life in many of these dogs.

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Presumably, the onset of signs is initiated by an “acute on chronic” event. An exacerbating problem develops in an affected dog, which results in increased respiratory efforts, airway inflammation, and/or cough. Exacerbating problems could include upper airway obstruction, infectious tracheobronchitis, heart enlargement or failure, or parasitic disease, perhaps with contributions from obesity, exposure to tobacco smoke, or poor oral health. Changes in intrathoracic pressures and airway pressures during increased respiratory efforts or cough contributes to narrowing of the trachea and stretching of the dorsal ligament. With severe collapse, fluttering or physical trauma to the mucosa may further stimulate cough. Inflammation also contributes to an ongoing cycle of cough and collapse. Collagenases and proteases released by inflammatory cells may weaken the structure of the airways. Damage to the tracheal epithelium and changes in mucus composition and secretion impair airway clearance. Previously tolerable irritants and organisms may perpetuate inflammation and cough. If the described exacerbating factors are sufficiently severe or chronic, even dogs without congenitally weak cartilages may develop TBM. Of course it is possible that these dogs, too, have congenital cartilage abnormalities, imbalances in their proinflammatory and antiinflammatory mediators, or other predisposing factors that as yet are not understood. The clinical consequences of TBM include chronic, progressive cough that can ultimately lead to large airway obstruction. In some cases the signs of extrathoracic large airway obstruction predominate in the absence of cough. Most of these dogs develop increased inspiratory efforts with activity or stress, inspiratory stertor, and eventually, episodes of hypoxemia. Because the chronic progressive cough of TBM is similar to that of chronic airway inflammation (e.g., idiopathic chronic bronchitis, eosinophilic bronchopneumopathy, bacterial bronchitis, parasitic disease), and because TBM can be a consequence of (or coincidental with) these conditions, a thorough and careful diagnostic evaluation is essential. The prevalence of TBM in dogs is not known. Studies often originate from referral institutions and may overrepresent dogs with poorly responsive signs, making the diagnosis difficult. In a report of bronchoscopies performed on 58 dogs, half had some form of airway collapse (Johnson et╯al, 2010). Bronchial collapse was reported in 35 of 40 (87.5%) brachycephalic dogs undergoing bronchoscopy (Delorenzi et╯al, 2009). We reported findings from 115 dogs with chronic cough, of which 59 (51%) had tracheobronchomalacia (Hawkins et al, 2010). In addition, 31 of 32 (97%) toy breed dogs had TBM among their diagnoses. Tracheal collapse is rare in cats and most often occurs secondary to a tracheal obstruction such as a tumor or traumatic injury. Clinical Features Tracheobronchomalacia can be primary or secondary and can affect the trachea and/or bronchi. More important, from a clinical perspective, is that collapse may occur

predominantly in either the extrathoracic (cervical trachea and/or thoracic inlet) or intrathoracic (intrathoracic trachea and/or bronchial) airways. Dogs with predominantly extrathoracic tracheal collapse can present with signs of upper airway obstruction, including respiratory distress most pronounced on inspiration and audible stertorous sounds. If respiratory distress occurs in dogs with intrathoracic airway collapse, it tends to be more pronounced on expiration and is usually associated with an audible, loud wheeze/cough. It is possible that a relationship exists whereby extrathoracic airway collapse is more often associated with primary (congenital) TBM, and intrathoracic airway collapse is more often associated with secondary (occurring in a predisposed or non-predisposed breed) TBM. This conjecture is partially supported by a study of tidal breathing flow-volume loops in toy and small-breed dogs with tracheal collapse and no evidence of other respiratory disease, in which abnormalities were seen predominantly in the inspiratory limb (Pardali et╯al, 2010). In a study of 18 dogs with bronchomalacia, but no tracheal collapse, inflammation was identified on bronchoalveolar lavage and bronchial biopsy, and the presenting cough was described as mild and wheezing (AdamamaMoraitou et╯al, 2012). Overall, although any signalment is possible, TBM occurs most commonly in middle-aged toy and miniature dogs. Signs may occur acutely but then may slowly progress over months to years. The primary clinical feature in most dogs is a nonproductive cough, described as a “goose honk.” The cough is worse during excitement or exercise, or when the collar exerts pressure on the neck. Eventually (usually after years of chronic cough), respiratory distress caused by obstruction to airflow may be brought on by excitement, exercise, or overheating. Systemic signs such as weight loss, anorexia, and depression are not expected. As discussed, some dogs are presented primarily for signs of upper airway obstruction without cough, also exacerbated during excitement, exercise, or hot weather. Stertorous sounds may be heard during periods of increased respiratory efforts. Tracheal collapse in cats is rare and usually is secondary to another obstructive disease. Careful questioning regarding possible trauma and exposure to foreign bodies is indicated. On physical examination a cough can usually be elicited by palpation of the trachea, particularly in those dogs presented with cough as the predominant sign. An endexpiratory snap or click may be heard during auscultation as a result of complete intrathoracic collapse. Patients with exercise intolerance or respiratory distress will demonstrate increased inspiratory efforts and stertorous sounds from collapse of the extrathoracic trachea, and an audible expiratory wheeze/cough from collapse of the intrathoracic trachea. It may be helpful to exercise dogs whose signs are moderate or intermittent to identify characteristic breathing patterns or sounds. History and physical examination should also emphaÂ� size a search for exacerbating or complicating disease. The

frequent association with canine chronic bronchitis has been mentioned. Other possibilities include cardiac disease causing left atrial enlargement with bronchial compression or pulmonary edema; airway inflammation caused by bacterial infection, allergic bronchitis, exposure to smoke (e.g., from cigarettes or fireplaces), or recent intubation; upper airway obstruction caused by elongated soft palate, stenotic nares, or laryngeal paralysis or collapse; and systemic disorders such as obesity or hyperadrenocorticism. Diagnosis Collapsing trachea is most often diagnosed on the basis of clinical signs and findings from cervical and thoracic radiography. Radiographs of the neck to evaluate the size of the lumen of the extrathoracic trachea are taken during inspiration (Fig. 21-6), when narrowing caused by tracheal collapse is more evident because of negative airway pressure. Conversely, the size of the lumen of the intrathoracic trachea is evaluated on thoracic radiographs taken during expiration, when increased intrathoracic pressures make collapse more apparent (Fig. 21-7). Radiographs of the thorax should also be taken during inspiration to detect concurrent bronchial or parenchymal abnormalities. (See Chapter 20 for further discussion of radiography.) Fluoroscopic evaluation provides a “motion picture” view of large airway dynamics, making changes in luminal diameter easier to identify than by routine radiography. The sensitivity of fluoroscopy in detecting airway collapse is enhanced if the patient can be induced to cough during the evaluation by pressure applied to the trachea. Some degree of collapse is probably normal during cough, and in people a diagnosis of tracheobronchomalacia is generally made if luminal diameter decreases by more than 70% during forced exhalation. This criterion was recently increased from 50% because studies in people have shown that a strong cough

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can result in near total collapse in some apparently healthy individuals. Bronchoscopy is also useful in the diagnosis of airway collapse (Fig. 21-8; see also Fig. 21-3). The bronchi of smaller dogs may be difficult to evaluate by radiography or fluoroscopy but are easily examined bronchoscopically. Bronchoscopy and the collection of airway specimens (such as by BAL) are useful for identifying exacerbating or concurrent conditions. Bronchoscopy is performed with the patient under general anesthesia, which interferes with the ability to induce cough. However, allowing the patient to reach a light plane of anesthesia while the airways are manipulated will often cause more forceful respirations that increase the likelihood of identifying airway collapse.

A

B FIG 21-7â•… FIG 21-6â•…

Lateral radiograph of the thorax and neck of a dog with collapsing trachea taken during inspiration. The extrathoracic airway stripe is severely narrowed cranial to the thoracic inlet.

Lateral radiographs of a dog with tracheobronchomalacia. During inspiration (A) the trachea and mainstem bronchi are nearly normal. During expiration (B) the intrathoracic trachea and mainstem bronchi are markedly narrowed. Evaluation of the pulmonary parenchyma should not be attempted using films exposed during expiration.

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A

B

FIG 21-8â•…

Bronchoscopic images from a dog with tracheal collapse (A). The dorsal tracheal membrane is much wider than that of a normal dog (B). The airway lumen is greatly compromised.

Additional tests are performed to identify exacerbating or concurrent conditions. Tracheal wash fluid is analyzed by cytology and culture if bronchoscopy and BAL are not done. Other considerations include upper airway examination, cardiac evaluation, and screening for systemic disease. Treatment Medical therapy is adequate treatment for most animals. In a study of 100 dogs by White et╯al (1994), medical therapy resulted in resolution of signs for at least 1 year in 71% of cases. Dogs that are overweight are placed on a weightreducing diet. Harnesses should be used instead of collars, and owners should be counseled to keep their dogs from becoming overheated (e.g., they should not be left in a car). Excessive excitement should be avoided. Sedatives such as phenobarbital are prescribed for some animals, and these can be administered before known stressful events. In some patients, anxiolytic drugs may be beneficial. Cough suppressants are used to control signs and to disrupt the potential cycle of perpetuating cough (see Table 21-1). The dose and frequency of administration of cough suppressants are adjusted as needed. Initially, high, frequent dosing may be needed to break the cycle of coughing. Subsequently, it is often possible to decrease the frequency of administration and the dose. Bronchodilators may be beneficial in dogs with signs of chronic bronchitis (see p. 300). Antiinflammatory doses of glucocorticoids can be given for a short period during exacerbation of signs (prednisone, 0.5-1╯mg/kg orally q12h for 3-5 days, then tapered and discontinued over 3-4 weeks). Long-term use is avoided if possible to prevent potential detrimental side effects such as obesity but is often necessary to control signs, particularly in patients with chronic bronchitis. Inhaled corticosteroids can be tried if a positive therapeutic response is seen, but systemic side effects are a matter of concern (see p. 307). Dogs with signs referable to mitral insufficiency are managed for this disease (see Chapter 6). Dogs with abnormalities causing upper airway obstruction are treated with corrective surgical procedures.

FIG 21-9â•…

Lateral radiograph of the dog with tracheal collapse (shown in Fig. 21-6) after placement of an intraluminal stent. The stent has a mesh-like structure and extends nearly the entire length of the trachea.

Antibiotics are not indicated for the routine management of TBM. Dogs in which tracheal wash or BAL fluid analysis has revealed evidence of infection should be treated with appropriate antibiotics (selected on the basis of the results of sensitivity testing). Because most antibiotics do not reach high concentrations in the airways, relatively high doses of antibiotics should be administered for several weeks, as described for canine chronic bronchitis (see p. 303). Any other potentially related problems identified during the diagnostic evaluation are addressed. A novel approach to treating TBM as reported by Adamama-Moraitou et╯al (2012) uses stanozolol to improve tracheal wall strength. Possible mechanisms include enhanced protein or collagen synthesis, increased chondroitin sulfate content, increased lean body mass, and decreased inflammation. Dogs with tracheal collapse, but not bronchitis, were treated with 0.3╯mg/kg stanozolol divided twice daily for 2 months orally, then tapered for 15 days. Dogs in the stanozolol group had improved clinical signs by some measures after 30 days, and improvement in grade of collapse was seen on tracheoscopy at 75 days. Management of dogs in acute distress with signs of either extrathoracic airway obstruction or intrathoracic large airway obstruction is discussed in Chapter 26. Tracheal stenting should be considered for dogs with TBM that are no longer responsive to medical management, usually because of respiratory difficulty. The introduction of intraluminal tracheal stents has greatly reduced the morbidity and improved the success of surgical intervention. The most commonly used stents are self-expanding and made of nickel-titanium alloys (Fig. 21-9). In experienced hands, these stents are simple to place during a short period of anesthesia under fluoroscopic or bronchoscopic guidance. Minimal morbidity is associated with stent placement, and response is immediate and often dramatic. However, clinical

signs (particularly cough) may not completely resolve, collapse of airways beyond the trachea and concurrent conditions are not directly addressed (nearly always resulting in the continued need for medical management), and complications such as infection, granuloma formation, and stent fracture can occur. Results following stent placement are sufficiently encouraging that motivated clients with a dog that is failing medical management of tracheal collapse should be referred to someone experienced in stent placement for consideration of this option. Extraluminal stenting can also be performed with the use of plastic rings. This procedure provides the benefit of great durability over many years. The procedure is technically more difficult than intraluminal stenting, perioperative morbidity is high as a result of damage to laryngeal nerves or other cervical structures, and only the cervical trachea is readily accessible. However, good success has been reported, even in dogs with intrathoracic collapse (Becker et╯al, 2012). This procedure may be worth considering, particularly in very young dogs that otherwise might be expected to outlive an intraluminal stent. Prognosis In most dogs clinical signs can be controlled with conscientiously performed medical management, with diagnostic evaluations performed during episodes of persistent exacerbation of signs. Animals in which severe signs develop despite appropriate medical care have a guarded prognosis, and motivated clients should be referred for possible stent placement. Sura et╯al (2008) reported survival times of longer than 1 year in 9 of 12 dogs after stent placement, and longer than 2 years in 7 of the dogs.

ALLERGIC BRONCHITIS Allergic bronchitis is a hypersensitivity response of the airways to an allergen or allergens. The offending allergens are presumably inhaled, although food allergens could also be involved. A definitive diagnosis requires identification of allergen(s) and resolution of signs after elimination of the allergen(s). Large controlled studies describing allergic bronchitis in dogs or cats are lacking. A study by Prost (2004) presented as an abstract found that 15 of 20 cats had positive intradermal skin tests to aeroallergens. For cats that reacted to storage mites or cockroach antigen, discontinuation of any dry food was recommended (i.e., only canned food was provided). Remission of signs occurred in 3 cats given only this treatment. Immunotherapy (desensitization) appeared to reduce or eliminate signs in some of the other cats. As a preliminary study, other treatments were also given to the study cats, and a control population was not described. It is likely that some patients with allergic bronchitis are misdiagnosed because of difficulty in identifying specific allergens. In dogs long-standing allergic bronchitis may result in the permanent changes recognized as canine chronic bronchitis. In cats failure to identify specific allergen(s) results in a diagnosis of idiopathic feline bronchitis.

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Allergic bronchitis in dogs may result in acute or chronic cough. Rarely, respiratory distress and wheezing occur. Physical examination and radiographic findings reflect the presence of bronchial disease, as described in the section on canine chronic bronchitis. Eosinophilic inflammation is expected in tracheal wash or BAL fluid. Heartworm tests and fecal examinations for pulmonary parasites are performed to eliminate parasitism as the cause of eosinophilic inflammation. In dogs younger than 2 years of age, bronchoscopic evaluation for O. osleri also should be considered (see the following section). Allergic bronchitis in cats has the same presentation and results of diagnostic testing as described for idiopathic feline bronchitis, with eosinophilia expected in airway specimens. Management of allergic bronchitis is initially focused on identifying and eliminating potential allergens from the environment (see the section on feline bronchitis). Diet trials with novel protein and carbohydrate sources also can be considered. According to the preliminary study previously described, a change in diet to canned food may be beneficial in some cases. Such experimentation with environment and diet is possible only in patients with clinical signs that are sufficiently mild to delay the administration of glucocorticoids and bronchodilators, as described in the sections on canine chronic bronchitis and feline bronchitis (idiopathic). Elimination trials can still be pursued once clinical signs are controlled with medications, but confirmation of a beneficial effect will require discontinuation of the medication and, for a definitive diagnosis to be made, reintroduction of the allergen. The latter may not be necessary or practical in all cases. Specific immunotherapy for cats with artificially induced allergic bronchitis has been reported. Hyposensitization regimens for cats and dogs with naturally occurring allergic bronchitis hold promise, but criteria for patient selection and expected success rate have not been established.

OSLERUS OSLERI Etiology Oslerus osleri is an uncommon parasite of young dogs, usually those younger than 2 years of age. Adult worms live at the carina and mainstem bronchi and cause a local, nodular inflammatory reaction with fibrosis. First-stage larvae are coughed up and swallowed. The main cause of infection in dogs appears to be intimate contact with their dam as puppies. Clinical Features Young affected dogs have an acute, loud, nonproductive cough and occasionally exhibit wheezing. The dogs appear otherwise healthy, making the initial presentation indistinguishable from that of canine infectious tracheobronchitis. However, the cough persists, and eventually airway obstruction occurs as a result of the formation of reactive nodules.

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FIG 21-10â•…

Bronchoscopic view of multiple nodules at the carina of a dog infected with Oslerus osleri.

Diagnosis Nodules at the carina occasionally can be recognized radiographically. Cytologic examination of tracheal wash fluid in some dogs reveals the characteristic ova or larvae, providing the basis for a definitive diagnosis (see Table 20-1). Rarely, larvae are found in fecal specimens with the use of zinc sulfate (specific gravity [s.g.], 1.18) flotation (preferred) or the Baermann technique (see Box 20-8). The most sensitive diagnostic method, bronchoscopy, enables the nodules to be readily seen (Fig. 21-10). Brushings of the nodules are obtained and are immediately evaluated cytologically for detection of the larvae. Material can be examined directly in saline solution or stained with new methylene blue. If a definitive diagnosis is not obtained by analysis of the brushings, biopsy specimens are obtained. Treatment Treatment with ivermectin (400╯µg/kg orally or subcutaneously) is recommended for appropriate breeds of dogs. The same dose is administered again every 3 weeks for four treatments. It cannot be administered to Collies or related breeds. An alternative treatment is fenbendazole (50╯mg/kg q24h for 7-14 days). Prognosis The prognosis for dogs treated with ivermectin is good; the drug appears to be successful in eliminating infection in the limited number of dogs that have been treated. Follow-up of individual patients is indicated to ensure successful elimination. Suggested Readings Adamama-Moraitou KK et al: Conservative management of canine tracheal collapse with stanozolol: a double blinded, placebo control clinical trial, Int J Immunopathol Pharmacol 24:111, 2011. Adamama-Moraitou KK et al: Canine bronchomalacia: a clinicopathological study of 18 cases diagnosed by endoscopy, Vet J 191:261, 2012. American Animal Hospital Association (AAHA) Canine Vaccination Taskforce: 2011 AAHA canine vaccination guidelines, J Am Anim Hosp Assoc 47:1, 2011.

Bach JF et al: Evaluation of the bioavailability and pharmacokinetics of two extended-release theophylline formulations in dogs, J Am Vet Med Assoc 224:1113, 2004. Becker WM et al: Survival after surgery for tracheal collapse and the effect of intrathoracic collapse on survival, Vet Surg 4:501, 2012. Bemis DA et al: Aerosol, parenteral, and oral antibiotic treatment of Bordetella bronchiseptica infections in dogs, J Am Vet Med Assoc 170:1082, 1977. Buonavoglia C et al: Canine respiratory viruses, Vet Res 38:455, 2007. Chalker VJ et al: Mycoplasmas associated with canine infectious respiratory disease, Microbiology 150:3491, 2004. Cocayne CG et al: Subclinical airway inflammation despite highdose oral corticosteroid therapy in cats with lower airway disease, J Fel Med Surg 13:558, 2011. Cohn LA et al: Effects of fluticasone propionate dosage in an experimental model of feline asthma, J Fel Med Surg 12:91, 2010. DeLorenzi D et al: Bronchial abnormalities found in a consecutive series of 40 brachycephalic dogs, J Am Vet Med Assoc 235:835, 2009. Dye JA et al: Chronopharmacokinetics of theophylline in the cat, J Vet Pharmacol Ther 13:278, 1990. Edinboro CH et al: A placebo-controlled trial of two intranasal vaccines to prevent tracheobronchitis (kennel cough) in dogs entering a humane shelter, Prevent Vet Med 62:89, 2004. Ellis JA et al: Effect of vaccination on experimental infection with Bordetella bronchiseptica in dogs, J Am Vet Med Assoc 218:367, 2001. Foster S, Martin P: Lower respiratory tract infections in cats: reaching beyond empirical therapy, J Fel Med Surg 13:313, 2011. Gore T: Intranasal kennel cough vaccine protecting dogs from experimental Bordetella bronchisept