A Practical Guide to Fetal Echocardiography, 4e By Rabih Chaoui, Alfred Abuhamad

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Book Quality Bookshare is interested in improving book quality over time, if you can help us by providing any book quality feedback, we'll work hard to make those changes and republish the books. Report book quality issue See all reported book quality issues Begin Content A Practical Guide to Fetal Echocardiography NORMAL AND ABNORMAL HEARTS FOURTH EDITION Acquisitions Editor: Chris Teja Development Editor: Thomas Celona Editorial Coordinator: Vinodhini Varadharajalu Editorial Assistant: Maribeth Wood Marketing Manager: Kirsten Watrud Production Project Manager: Catherine Ott Design Coordinator: Stephen Druding Art Director, Illustration: Jennifer Clements Illustrator: Patricia Gast Manufacturing Coordinator: Beth Welsh Prepress Vendor: S4Carlisle Publishing Services Fourth edition Copyright © 2022 Wolters Kluwer. Copyright © 2016 Wolters Kluwer. Copyright © 2010 Lippincott Williams & Wilkins, a Wolters Kluwer business. All rights reserved. This book is protected by copyright. No part of this book may be reproduced or transmitted in any form or by any means, including as photocopies or scanned-in or other electronic copies, or utilized by any information storage and retrieval system without written permission from the copyright owner, except for brief quotations embodied in critical articles and reviews. Materials appearing in this book prepared by individuals as part of their official duties as U.S. government employees are not covered by the above-mentioned copyright. To request permission, please contact Wolters Kluwer at Two Commerce Square, 2001 Market Street, Philadelphia, PA 19103, via email at permissions@lww.com , or via our website at shop.lww.com (products and services). 987654321 Printed in China Library of Congress Cataloging-in-Publication Data ISBN-13: 978-1-975126-81-0 Cataloging in Publication data available on request from publisher This work is provided “as is,” and the publisher disclaims any and all warranties, express or implied, including any warranties as to accuracy, comprehensiveness, or currency of the content of this work. This work is no substitute for individual patient assessment based upon healthcare professionals’ examination of each patient and consideration of, among other things, age, weight, gender, current or prior medical conditions, medication history, laboratory data and other factors unique to the patient. The publisher does not provide medical advice or guidance and this work is merely a reference tool. Healthcare professionals, and not the publisher, are solely responsible for the use of this work including all medical judgments and for any resulting diagnosis and treatments. Given continuous, rapid advances in medical science and health information, independent professional verification of medical diagnoses, indications, appropriate pharmaceutical selections and dosages, and treatment options should be made and healthcare professionals should consult a variety of sources. When prescribing medication, healthcare professionals are advised to consult the product information sheet (the manufacturer’s package insert) accompanying each drug to verify, among other things, conditions of use, warnings and side effects and identify any changes in dosage schedule or contraindications, particularly if the medication to be administered is new, infrequently used or has a narrow therapeutic range. To the maximum extent permitted under applicable law, no responsibility is assumed by the publisher for any injury and/or damage to persons or property, as a matter of products liability, negligence law or otherwise, or from any reference to or use by any person of this work. shop.lww.com Dedication This book is dedicated in loving memory of Zouheir Abuhamad & Nouhad Chaoui Our parents whom we lost while preparing this 4th edition. We owe our achievements and success to their unfailing lifelong direction, commitment, and sacrifices in our support. Preface It is with great pleasure that we bring to you this fourth edition of A Practical Guide to Fetal Echocardiography: Normal and Abnormal Hearts , building on the great success of the third edition, the winner of the 2016 Book of the Year Award by the British Medical Association. Big thanks to our readers who complemented the third edition of this book and who informed us consistently of the value that the book plays in their day-to-day practice. These statements were indeed the primary stimulus that encouraged us to take on this daunting task of writing the fourth edition and providing the most up-to-date and comprehensive reference on this subject. We strived to ensure that this fourth edition is written in the same easy-to-read style and illustrated with the most informative figures and schematic drawings. In order to maintain the widely successful systematic, homogeneous, and methodical approach of the third edition of this book, we chose again the difficult path of writing and illustrating this fourth edition in its entirety without outside collaboration. Now, how do we improve on an already very successful book? We did so by updating and rewriting almost all chapters with the most up-to-date references; expanding the content from 33 chapters in the third edition to 47 chapters in this fourth edition; adding numerous schematic drawings and ultrasound figures to illustrate key ultrasound findings; and including a highly clinically relevant flow chart section that accompanies each chapter on cardiac malformation, showing the step-by-step Approach to Diagnosis . We are hopeful that the readers will find these 31 new flow charts on the Approach to Diagnosis as highly useful aids in the ultrasound diagnosis of complex cardiac malformations. Overall, the book is divided into three main sections. Section one covers the general aspects of fetal cardiac malformations with 4 chapters on epidemiology, genetic aspects of cardiac malformations, cardiac embryology, and anatomy. Section two is composed of 14 chapters on the guidelines for cardiac screening and echocardiography; the technical aspects of the fetal cardiac examination; the detailed sonographic anatomy of the heart, great vessels, and venous systems; and cardiac function. Section three includes 29 chapters on fetal cardiac malformations, presented in a uniform format that includes the definition, spectrum of disease and incidence, the use of grayscale, color Doppler, three-dimensional, and early gestation ultrasound in the diagnosis of each cardiac abnormality, followed by the differential diagnosis, prognosis, outcome, and Approach to Diagnosis . A comprehensive section on reference ranges of cardiac measurements is presented in a graphic and tabular format in the appendix. Congenital heart disease is the most common congenital malformation with a significant impact on neonatal morbidity and mortality. Prenatal diagnosis of congenital heart disease has been suboptimal over the years, owing in large part to the complexity of cardiac anatomy and the inherent difficulty of the ultrasound examination of the fetal heart. We feel that this fourth edition provides a comprehensive reference to the practitioners involved in cardiac imaging, and we sincerely hope that this book enhances the detection rate of congenital heart disease, which should translate into improved outcome for our smallest patients. We did most of the writing for this book during the COVID-19 pandemic and thus cannot but reflect on the impact that the pandemic had on the world and on the millions of people who died or were severely harmed from it. We stand in awe of the thousands of healthcare workers who worked tirelessly and endangered their lives to support others. They are indeed our true heroes. We owe many thanks to those who helped to support us in this endeavor. First and foremost, our families who unselfishly allowed us to spend long evenings and most weekends away from them in completing this task; the artistic talents of Ms. Patricia Gast, who performed all the superb drawings in this book in an efficient and accurate manner; Dr. Elena Sinkovskaya (for Dr. Abuhamad) and Dr. Kai-Sven Heling (for Dr. Chaoui) for the collegiality and cooperation throughout the years, and the professional editorial and production teams at Wolters Kluwer. In closing, we continue to owe a great debt of gratitude to two giants in the field of ultrasound, Dr. John Hobbins (for Dr. Abuhamad) and Dr. Rainer Bollmann (for Dr. Chaoui), who believed in us, gave us our ultrasound roots, and provided long-lasting mentorship and guidance. Finally, we sincerely hope that this fourth edition of A Practical Guide to Fetal Echocardiography: Normal and Abnormal Hearts becomes your daily companion in the ultrasound suite, providing you with the knowledge and necessary tools to expand your abilities in screening for and diagnosing abnormal fetal cardiac conditions. Alfred Abuhamad, MD Rabih Chaoui, MD Contents SECTION one General Aspects CHAPTER 1 • CHAPTER 2 • CHAPTER 3 • CHAPTER 4 • Epidemiology of Congenital Heart Disease Genetic Aspects of Congenital Heart Disease Embryology of the Heart Cardiac Anatomy SECTION two Technical Aspects CHAPTER 5 • CHAPTER 6 • CHAPTER 7 • CHAPTER 8 • CHAPTER 9 • CHAPTER 10 • CHAPTER 11 • CHAPTER 12 • CHAPTER 13 • CHAPTER 14 • CHAPTER 15 • CHAPTER 16 • CHAPTER 17 • CHAPTER 18 • Guidelines for Fetal Cardiac Imaging Fetal Situs The Cardiac Chambers The Great Vessels The Three-Vessel-Trachea View The Venous System Fetal Heart in Early Gestation Grayscale in Fetal Cardiac Imaging Color Doppler in Fetal Cardiac Imaging Spectral Doppler in Fetal Cardiac Imaging M-Mode in Fetal Cardiac Imaging Three- and Four-Dimensional Ultrasound in Fetal Cardiac Imaging Biometry in Fetal Cardiac Imaging Fetal Cardiac Function SECTION three The Abnormal Heart CHAPTER 19 • Atrial Septal Defects CHAPTER 20 • Ventricular Septal Defects CHAPTER 21 • Atrioventricular Septal Defects CHAPTER 22 • CHAPTER 23 • CHAPTER 24 • CHAPTER 25 • CHAPTER 26 • CHAPTER 27 • CHAPTER 28 • CHAPTER 29 • CHAPTER 30 • CHAPTER 31 • CHAPTER 32 • CHAPTER 33 • CHAPTER 34 • CHAPTER 35 • CHAPTER 36 • CHAPTER 37 • CHAPTER 38 • CHAPTER 39 • CHAPTER 40 • CHAPTER 41 • CHAPTER 42 • CHAPTER 43 • CHAPTER 44 • CHAPTER 45 • CHAPTER 46 • CHAPTER 47 • Double Inlet Ventricle Tricuspid Atresia Ebstein Anomaly and Tricuspid Valve Dysplasia Tricuspid Valve Regurgitation Pulmonary Stenosis Pulmonary Atresia with Intact Ventricular Septum Tetralogy of Fallot Pulmonary Atresia with Ventricular Septal Defect Absent Pulmonary Valve Syndrome Aortic Stenosis and Bicuspid Aortic Valve Hypoplastic Left Heart Syndrome and Critical Aortic Stenosis Coarctation of the Aorta Interrupted Aortic Arch Common Arterial Trunk Double-Outlet Right Ventricle Transposition of the Great Arteries Corrected Transposition of the Great Arteries Right Aortic Arch, Double Aortic Arch, and Aberrant Subclavian Artery Abnormal Fetal Heart Position Fetal Heterotaxy Syndrome Anomalies of Systemic Venous Connections Anomalies of Pulmonary Venous Connections Fetal Cardiomyopathies Fetal Cardiac Tumors Fetal Arrhythmias Rare Cardiac Anomalies APPENDIX • INDEX Graph Legends S E C T I O N o n e General Aspects CHAPTER 1 • Epidemiology of Congenital Heart Disease CHAPTER 2 • Genetic Aspects of Congenital Heart Disease CHAPTER 3 • Embryology of the Heart CHAPTER 4 • Cardiac Anatomy C H A P T E R 1 Epidemiology of Congenital Heart Disease INCIDENCE OF CONGENITAL HEART DISEASE Congenital heart disease (CHD) is the most common severe congenital abnormality ( 1 ) as it accounts for over half of deaths from congenital abnormalities in childhood ( 1 ). Moreover, CHD results in the most costly hospital admissions for birth defects in the United States ( 2 ). The incidence of CHD is dependent on the age at which the population is initially examined and the definition of CHD used. Inclusion of a large number of premature neonates in a study may increase the incidence of CHD as both patent ductus arteriosus and ventricular septal defects are common in premature infants. A representative incidence of CHD of 8 to 9 per 1000 live births has been reported in large population studies ( 1 ). The incidence of CHD is also influenced by the inclusion of bicuspid aortic valve, the incidence of which is estimated at 10 to 20 per 1000 live births ( 3 ). Furthermore, accounting for subtle anomalies such as persistent left superior vena cava (5-10 per 1000 live births) and isolated aneurysm of the atrial septum (5-10 per 1000 live births) results in an overall incidence of CHD approaching 50 per 1000 live births ( 4 ). CHD remains the most common severe abnormality in the newborn; its prenatal diagnosis allows for better pregnancy counseling and improved neonatal outcome. Table 1.1 lists the incidence of CHD by various subtypes ( 5 ). Several risk factors for CHD have been identified and include fetal and parental risk factors, which are discussed in detail in the following sections. Table 1.1 • Types and Incidence of Human Congenital Heart Disease Defect Incidence per 1000 live births VSD 3.570 PDA 0.799 ASD 0.941 AVSD 0.348 PS 0.729 AS 0.401 CoA 0.409 TOF 0.421 D-TGA 0.315 HRH 0.222 Tricuspid atresia 0.079 Ebstein anomaly 0.114 Pulmonary atresia 0.132 HLH 0.266 Truncus 0.107 DORV 0.157 SV 0.106 TAPVC 0.094 AS, aortic stenosis; ASD, atrial septal defect; AVSD, atrioventricular septal defect; CoA, coarctation of the aorta; DTGA, complete transposition of the great arteries; DORV, double-outlet right ventricle; HLH, hypoplastic left heart; HRH, hypoplastic right heart; PDA, patent ductus arteriosus; PS, pulmonary stenosis; SV, single ventricle; TAPVC, total anomalous pulmonary venous connection; TOF, tetralogy of Fallot; VSD, ventricular septal defect. Modified from Hoffman JI, Kaplan S. The incidence of congenital heart disease. J Am Coll Cardiol . 2002;39:18901900, with permission from Elsevier. RISK FACTORS FOR CHD Fetal and parental risk factors and fetal echocardiography indications are determined when the risk of CHD is elevated above that of the general population, taking into account the level of risk, regional resources, and the availability of expert fetal echocardiographers. It is important to note, however, that most cases of CHD are suspected on the fetal anatomic survey and in the absence of apparent risk factors. When an abnormal fetal heart is suspected at the time of a basic or detailed anatomic ultrasound examination, referral for fetal echocardiography is warranted as the risk for CHD is increased in such setting. Fetal and parental risk factors for CHD are discussed in detail in the following sections, and indications for fetal echocardiography and detailed cardiac screening are shown in Tables 1.2 to 1.6 . Table 1.2 • Fetal Factors in Which Fetal Echocardiography Is Indicated Suspected cardiac structural anomaly Suspected abnormality in cardiac function Hydrops fetalis Persistent fetal tachycardia (heart rate >180 beats/min) Persistent fetal bradycardia (heart rate <120 beats/min) or a suspected heart block Frequent episodes of a persistently irregular cardiac rhythm Major fetal extracardiac anomaly Nuchal translucency of 3.5 mm or greater or at or above the 99th percentile for gestational age Chromosomal abnormality by invasive genetic testing or with cell-free fetal DNA screening Monochorionic twinning Modified from AIUM practice parameters for the performance of fetal echocardiography. J Ultrasound Med . 2020;39:E5-E16. Table 1.3 • Fetal Factors in Which Fetal Echocardiography May Be Considered Systemic venous anomaly (e.g., a persistent right umbilical vein, left superior vena cava, or absent ductus venosus) Greater-than-normal nuchal translucency measurement between 3.0 and 3.4 mm Modified from AIUM practice parameters for the performance of fetal echocardiography. J Ultrasound Med . 2020;39:E5-E16. Table 1.4 • Maternal/Familial Disease or Maternal Environmental Exposure Factors in Which Fetal Echocardiography Is Indicated Pregestational diabetes regardless of the hemoglobin A1c level Gestational diabetes diagnosed in the first or early second trimester In vitro fertilization, including intracytoplasmic sperm injection Phenylketonuria (unknown status or a periconceptional phenylalanine level >10 mg/dL) Autoimmune disease with anti-Sjögren syndrome–related antigen A antibodies and with a prior affected fetus First-degree relative of a fetus with congenital heart disease (parents, siblings, or prior pregnancy) First- or second-degree relative with disease of Mendelian inheritance and a history of childhood cardiac manifestations Retinoid exposure First-trimester rubella infection Modified from AIUM practice parameters for the performance of fetal echocardiography. J Ultrasound Med . 2020;39:E5-E16. Table 1.5 • Maternal/Familial Disease or Maternal Environmental Exposure Factors in Which Fetal Echocardiography May Be Considered Selected teratogen exposure (e.g., paroxetine, carbamazepine, or lithium) Antihypertensive medication limited to angiotensin-converting enzyme inhibitors Autoimmune disease with Sjögren syndrome–related antigen A positivity and without a prior affected fetus Second-degree relative of a fetus with congenital heart disease Modified from AIUM practice parameters for the performance of fetal echocardiography. J Ultrasound Med . 2020;39:E5-E16. Table 1.6 • Maternal and Fetal Factors in Which a Detailed Second Trimester Ultrasound Examination Is Indicated Obesity (body mass index ≥ 30 kg/m 2 ) Selective serotonin reuptake inhibitor antidepressant exposure other than paroxetine Noncardiac “soft marker” for aneuploidy in the absence of karyotype information Abnormal maternal serum analytes (e.g., α-fetoprotein level) Isolated single umbilical artery Gestational diabetes diagnosed after the second trimester Warfarin exposure Alcohol exposure Echogenic intracardiac focus Maternal fever or viral infection with seroconversion only Isolated congenital heart disease in a relative further removed from second degree to the fetus Modified from AIUM practice parameters for the performance of fetal echocardiography. J Ultrasound Med . 2020;39:E5-E16. FETAL RISK FACTORS AND INDICATIONS OF ECHOCARDIOGRAPHY Extracardiac Anatomic Abnormalities The presence of a major extracardiac anatomic abnormality in a fetus is frequently associated with CHD and is thus an indication for fetal echocardiography ( Table 1.2 ). The risk of CHD with fetal extracardiac abnormalities is increased even in the presence of normal karyotype ( 6 ). The risk of CHD is dependent on the specific type of fetal malformation. Abnormalities detected in more than one organ system increase the risk of CHD and also of concomitant chromosomal abnormalities ( 7 ). Nonimmune hydrops in the fetus is frequently associated with CHD and thus is an indication for fetal echocardiography ( Table 1.2 ). Incidence of abnormal cardiac anatomy is reported in about 10% to 20% of fetuses with nonimmune hydrops ( 8 , 9 ). The presence of a persistent left superior vena cava is associated with an increased risk for associated cardiac and extracardiac abnormalities and thus fetal echocardiography may be considered in such cases ( Table 1.3 ) ( 10 ). Other systemic venous anomalies such as a persistent right umbilical vein or absent ductus venosus have also been shown to be associated with a coexisting cardiac malformation, and therefore consideration should be given to fetal echocardiography in such cases ( Table 1.3 ) ( 11 ). Fetal Cardiac Arrhythmia The presence of fetal cardiac rhythm disturbances may be associated with an underlying structural heart disease. The association of CHD with fetal arrhythmia is dependent on the type of cardiac rhythm disturbances. Overall, about 1% of fetal cardiac arrhythmias are associated with CHD ( 8 ). Fetal tachycardia and isolated extrasystoles are rarely associated with CHD. Complete heart block, on the other hand, resulting from abnormal atrioventricular (AV) node conduction, is associated with structural cardiac abnormalities in about 50% of fetuses, with the remaining pregnancies associated with the presence of maternal Sjögren antibodies ( 12 , 13 ). A fetal echocardiogram should be performed in all fetuses with persistent fetal tachycardia (heart rate >180 beats/min), persistent fetal bradycardia (heart rate <120 beats/min), or suspected heart block in order to assess cardiac structure and function ( Table 1.2 ). The presence of frequent episodes or a persistent pattern of irregular fetal rhythm, such as that caused by frequent extrasystoles, is also an indication for fetal echocardiography, as this may be the harbinger of more malignant arrhythmias if it is persistent ( Table 1.2 ) ( 14 ). In fetuses with less frequent extrasystoles, a fetal echocardiogram is reasonable to perform, especially if the ectopic beats persist beyond 1 to 2 weeks ( 15 ). In pregnancies with autoimmune disease with anti-Sjögren syndrome–related antigen A antibodies and with a prior affected fetus, fetal echocardiography is indicated given the increased risk of fetal rhythm abnormalities ( Table 1.4 ). Fetal echocardiography may be indicated in the presence of Sjögren syndrome–related antigen A positivity and without a prior affected fetus ( Table 1.5 ). Sjögren syndrome–related antigen B positivity is not an indication for fetal echocardiography given the absence of associated fetal risk. Diagnosis and management of fetal cardiac rhythm disturbances are discussed in detail in Chapter 46 . Suspected Cardiac Anomaly on Routine Ultrasound A risk factor with one of the highest yields for CHD is the suspicion for the presence of a cardiac abnormality during routine ultrasound scanning. Fetal echocardiogram should therefore be performed in all fetuses with a suspected cardiac abnormality noted on obstetric ultrasound ( Table 1.2 ). CHD is confirmed in about 40% to 50% of pregnancies referred with this finding ( 8 , 9 ). In view of this and the fact that most infants born with CHD are born to mothers without risk factors, ultrasound evaluation of the fetal heart should not be limited to pregnant mothers with known risk factors. Indeed recent guidelines of cardiac screening have been expanded to include evaluation of the great vessels ( 16 - 19 ). The value of routine ultrasound in the screening for CHD is discussed in Chapter 5 . Known or Suspected Chromosomal or Genetic Abnormality The presence of a fetal genetic or chromosomal abnormality by invasive genetic testing or with cell-free DNA testing is associated with a high risk for cardiac and extracardiac defects and thus a fetal echocardiogram is indicated ( Table 1.2 ). Please refer to Chapter 2 on the genetics of CHD for a more comprehensive discussion on the topic. Thickened Nuchal Translucency Measurement of fetal nuchal translucency (NT) thickness in the late first and early second trimesters of pregnancy is currently established as an effective method for individual risk assessment for fetal chromosomal abnormalities. Several reports have noted an association between increased NT and genetic syndromes and major fetal malformations including cardiac defects ( 20 - 23 ). The prevalence of major cardiac defects increases exponentially with fetal NT thickness, without an obvious predilection to a specific type of CHD ( 21 ). An NT thickness of greater than or equal to 3.5 mm or at or above the 99th percentile for gestational age in a chromosomally normal fetus has been correlated with an increased risk of CHD, that is, higher than pregnancies with a family history of CHD ( 20 , 21 , 23 , 24 ). In this setting of an NT that is greater than or equal to 3.5 mm or at or above the 99th percentile for gestational age, referral for fetal echocardiography is thus warranted ( Table 1.2 ), and this may also lead to an earlier diagnosis of all major types of CHD ( 25 ). When the NT is increased and measures between 3.0 and 3.4 mm, fetal echocardiography may be considered in this setting given an increased risk of CHD above the background population risk ( Table 1.3 ). Chapter 11 provides a more detailed discussion on the ultrasound examination of the fetal heart in early gestation. Monochorionic Placentation The incidence of CHD in fetuses of monochorionic placentation is increased ( 26 , 27 ) and is estimated at 2% to 9% ( 26 , 28 , 29 ). Twin–twin transfusion syndrome (TTTS), a complication of monochorionic twin placentation, has been reported to occur in about 10% of cases. TTTS has been associated with acquired cardiac abnormalities to include right ventricular outflow tract obstruction, which occurs in about 10% of recipient twin fetuses ( 30 ). The increased risk of CHD in fetuses of monochorionic placentation is noted even after excluding cardiac effects of TTTS ( 27 ). In a cohort study of 165 sets of monochorionic twins, the overall risk of at least one of a twin pair having a structural CHD was 9.1% ( 27 ). This risk was 7% for monochorionic– diamniotic twins and 57.1% for at least one twin member of monochorionic–monoamniotic twins ( 27 ). If one twin member is affected, the risk that the other twin member is also affected is 26.7% ( 27 ). A systemic literature review of 830 fetuses from monochorionic–diamniotic twin pregnancies confirmed an increased risk for CHD independent of TTTS ( 26 ). Ventricular septal defects were the most common type of CHD in non-TTTS fetuses, and pulmonary stenosis and atrial septal defects were significantly more prevalent in fetuses of pregnancies complicated with TTTS ( 26 , 31 ). Fetal echocardiogram is therefore recommended in all monochorionic twin gestations ( Table 1.2 ). PARENTAL RISK FACTORS AND INDICATIONS OF ECHOCARDIOGRAPHY Maternal Metabolic Disease Maternal metabolic disorders, primarily including pregestational diabetes mellitus and phenylketonuria, have a significant effect on the incidence of CHD. In the presence of maternal metabolic disease, preconception counseling and tight metabolic control immediately prior to and during organogenesis are recommended in order to reduce the incidence of fetal CHD. Diabetes Mellitus The incidence of CHD is fivefold higher in infants of pregestational diabetic mothers when compared to controls, with a higher relative risk noted for specific cardiac defects, including 6.22 for heterotaxy, 4.72 for truncus arteriosus, 2.85 for transposition of the great arteries, and 18.24 for single ventricle defects ( 32 ). Poor glycemic control in the first trimester of gestation, as evidenced by an elevated glycohemoglobin (HbA1c) level, has been strongly correlated with an increased risk of structural defects in infants of diabetic mothers ( 33 , 34 ). Although some studies have identified a level of HbA1c above which the risk for fetal structural abnormalities is increased ( 33 ), other studies have failed to identify a critical level of HbA1c that provides an optimal predictive power for CHD screening ( 35 ). Therefore, it appears that although the risk may be highest in those with increased HbA1c levels >8.5%, all pregnancies of pregestational diabetic women are at some increased risk. Given this information, a fetal echocardiogram is indicated in all women with pregestational diabetes mellitus ( Table 1.4 ). Gestational diabetes diagnosed in the first and early second trimesters of pregnancy is also an indication for fetal echocardiography, as the presence of hyperglycemia during organogenesis cannot be ruled out ( Table 1.4 ). Gestational diabetes, which is diagnosed beyond the first or early second trimester of pregnancy, does not increase the risk of CHD in the fetus and thus a fetal echocardiogram is not indicated for these pregnancies. Fetal ventricular hypertrophy in late gestation (third trimester) is a complication of poor glycemic control in pregestational and gestational diabetic pregnancies and the degree of hypertrophy is related to the level of glycemic control. Consideration should be given for fetal echocardiogram in the third trimester to assess for ventricular hypertrophy for pregestational and gestational diabetic pregnancies with elevated HbA1c in the second trimester of pregnancy ( 36 ). Phenylketonuria Another metabolic disorder that is associated with CHD is phenylketonuria. Women with phenylketonuria should be aware of the association of fetal CHD with elevated maternal phenylalanine levels ( 37 ). This is particularly important as phenylketonurics usually follow unrestricted dietary regimens in adulthood. Fetal exposure during organogenesis to maternal phenylalanine levels exceeding 15 mg/dL is associated with a 10- to 15-fold increase in CHD ( 38 ). Other fetal abnormalities in phenylketonurics include microcephaly and growth restriction ( 37 ). The risk for CHD in fetuses has been reported to be 12% if maternal dietary control is not achieved by 10 weeks of gestation ( 39 ). With maternal phenylalanine levels at <6 mg/dL before conception and during early organogenesis, the risk of CHD was noted to be no different than that for controls in a large prospective study ( 40 ). Unless you have evidence of strict dietary control in the periconceptional period with phenylalanine levels at <10 mg/dL, fetal echocardiogram is recommended in phenylketonurics ( 15 ). Pregnancies of Assisted Reproductive Technology Infants born to pregnancies of assisted reproductive technology are more likely to be born preterm, of low birth weight, and small for gestational age ( 41 ). This increased neonatal morbidity applies to multiple and singleton births ( 42 ). The evidence relating to the risk of birth defects is somewhat less clear. A report of systematically reviewed and pooled epidemiologic data assessing the risk of birth defects suggests a 30% to 40% increase following assisted reproductive technologies (in vitro fertilization [IVF] and/or intracytoplasmic sperm injection [ICSI]) ( 43 ). Another population-based study on congenital malformations in children born after IVF with matched controls noted a fourfold increase in CHD in the IVF population, with the majority of cardiac anomalies representing atrial and ventricular septal defects ( 44 ). This same rate of fourfold increase in CHD was also noted in pregnancies conceived through ICSI ( 45 ). In a recent systematic review and meta-analysis of 41 studies including both singleton and multiple gestations, total CHD events were noted in 1.30% of IVF/ICSI pregnancies as compared to 0.68% in the spontaneous conception group, with a pooled odds ratio (OR) of 1.45 (95% confidence interval [CI], 1.20-1.76) ( 46 ). In a recent cross-sectional analysis of live births in the United States from 2011 to 2014, an increased risk of cyanotic CHD was noted for infants conceived after all forms of infertility treatment when compared to natural conceptions ( 47 ). Cyanotic CHD prevalence in assisted reproductive technology fertility treatments (IVF, ICSI), nonassisted reproductive technology fertility treatments (medical treatment and intrauterine insemination), and natural conception groups were 0.39%, 0.26% and 0.08%, respectively ( 47 ). In view of these findings, fetal echocardiogram is currently indicated in pregnancies of assisted reproductive technologies ( Table 1.3 ). Familial Cardiac Disease The risk of recurrence of CHD is increased in the presence of nonsyndromic or nonchromosomal CHD in the family. It is twofold higher if the mother is affected versus a sibling or a father ( 48 , 49 ). For the majority of maternal CHD, the risk of recurrence is in the range of 3% to 7%; for an affected sibling, the risk of recurrence is at 2% to 6%; and for paternal CHD, the risk of recurrence is at 2% to 3% ( 50 - 52 ). There is an increased risk, however, with some specific cardiac malformations such as aortic stenosis or AV septal defect ( 48 , 52 ). Overall, the risk of recurrence is low with isolated CHD in second- or third-degree relatives. The genetic aspect of CHD is discussed in more detail in Chapter 2 . Fetal echocardiogram is indicated in the presence of first-degree relative of a fetus with CHD (parents, siblings, or prior pregnancy) or first- or second-degree relative with disease of Mendelian inheritance and a history of childhood cardiac Get Complete eBook Download Link below for instant download https://browsegrades.net/documents/2 86751/ebook-payment-link-for-instantdownload-after-payment manifestations ( Table 1.3 ). Fetal echocardiography may be considered in the presence of CHD in a second-degree relative of a fetus ( Table 1.4 ). Maternal Teratogen Exposure (Drug-Related CHD) The effects of maternal exposure to drugs during cardiogenesis have been widely studied. Numerous drugs have been implicated as cardiac teratogens. Evidence suggests that the overall contribution of teratogens to CHD is small ( 53 ). Details on various maternal medication exposures and associations with CHD are discussed in the following sections. Lithium Initial retrospective reports regarding the teratogenic risk of lithium treatment in pregnancy showed a strong association between lithium use and Ebstein anomaly in the fetus ( 54 ). More recent controlled studies, however, have consistently reported a lower risk for CHD in exposed fetuses. Four case–control studies of Ebstein anomaly involving a total of 208 affected children found no association with maternal lithium intake in pregnancy ( 55 - 57 ). A cohort study on the effect of lithium exposure in pregnancy showed no significant risk to the fetus ( 58 ). These findings suggest that the teratogenic risk of lithium exposure is significantly lower than previously reported, and that the risk/benefit ratio of prescribing lithium in pregnancy should be evaluated in light of this modified risk estimate. Fetal echocardiogram may be considered in pregnancies exposed to lithium during embryogenesis, although its usefulness has not been established given a very low likelihood of CHD ( Tables 1.5 and 1.6 ). Anticonvulsants Anticonvulsants, a class of drugs that includes hydantoin/phenytoin, carbamazepine, trimethadione, and sodium valproate, among others, are occasionally used in the treatment of epilepsy or pain management in pregnancy. An incidence of congenital defects varying from 2.2% to 26.1% has been noted in pregnancies exposed to phenytoin ( 59 ). Some evidence suggests that the teratogenic effect of phenytoin is related to elevated amniotic fluid levels of oxidative metabolites secondary to low activity of the clearing enzyme epoxide hydrolase ( 60 ). A fetal hydantoin syndrome consisting of variable degrees of hypoplasia and ossification of distal phalanges and craniofacial abnormalities has been described ( 61 ). CHD is often observed in conjunction with this syndrome ( 62 ). Trimethadione, an anticonvulsant primarily used in the treatment of petit mal seizures, is associated with a high incidence of congenital defects. Defects include craniofacial deformities, growth abnormalities, mental retardation, limb abnormalities, and genitourinary abnormalities ( 62 ). Cardiac abnormalities are common, with septal defects occurring in about 20% of exposed fetuses ( 62 ). Sodium valproate has also been associated with congenital defects, with the most serious abnormality being neural tube defects (1%-2%) ( 62 ). Although some reports have suggested an increased risk of CHD in fetuses exposed to valproate ( 63 ), others could not establish a causal relationship ( 64 ). Carbamazepine has been associated with 1.8% risk for CHD in one study when compared to controls ( 65 ). In a study of a large primary care database including 258,591 singleton live-born children of mothers aged 15 to 44 years from 1990 to 2013, anticonvulsant exposure of mothers in the first trimester of pregnancy was associated with a twofold increased risk of major congenital anomalies compared to those unexposed, with the highest system-specific risks for heart anomalies (adjusted OR 2.49, 1.47-4.21) ( 66 ). Compared with children of mothers without anticonvulsant exposures, the adjusted ORs of overall congenital malformations were statistically significant for valproate (2.63, 95% CI 1.46-4.73), lamotrigine (2.01, 1.12-3.59), and other older anticonvulsants (2.67, 1.18-6.04) but not for carbamazepine (1.58, 0.86-2.89) and other newer anticonvulsants (1.44, 0.57-3.65) ( 66 ). The study also found no evidence that periconceptional high-dose folic acid, as was prescribed in this population, reduced the malformation risk associated with anticonvulsants, although this may reflect late prescribing or selective prescribing to women with severe conditions. The risk was not increased for anticonvulsant exposure later in pregnancy ( 66 ). In view of these findings, there appears to be a link between some anticonvulsant use in the first trimester and an increased risk of CHD. Fetal echocardiogram may therefore be considered in pregnancies exposed to anticonvulsants in early gestation ( Table 1.5 ). Alcohol The fetal alcohol syndrome, consisting of facial abnormalities, growth restriction, mental retardation, and cardiac abnormalities, has been well described in women consuming heavy amounts of alcohol in pregnancy ( 67 ). Cardioteratogenic effects of ethanol in the chick embryo have been confirmed in concentrations comparable to human blood alcohol levels ( 68 ). CHD has been identified in 25% to 30% of infants with fetal alcohol syndrome, with septal defects representing the most common lesions ( 67 , 69 ). Fetal echocardiogram is recommended for pregnancies with suspected fetal alcohol syndrome. There have been conflicting results regarding maternal regular alcohol consumption before and during pregnancy and the risk of CHD. The summary of 23 studies related to this topic indicated an overall pooled relative risk of 1.13 (95% CI: 0.96, 1.29) among mothers drinking before or during pregnancy with statistically significant heterogeneity in the data ( 70 ). This meta-analysis provided no positive association between maternal alcohol consumption and the risk of CHD ( 70 ), and therefore, a detailed ultrasound examination rather than fetal echocardiography is indicated in this setting ( Table 1.6 ). Retinoic Acid Retinoic acid is a vitamin A derivative prescribed for the treatment of severe cystic acne. Since its introduction, several reports have appeared in the literature describing the teratogenic effect of this medication. A characteristic pattern of malformations is observed, which includes central nervous system, craniofacial, branchial arch, and cardiovascular abnormalities ( 71 ). Cardiac abnormalities are usually conotruncal defects and aortic arch abnormalities ( 62 , 72 ). The mechanism of teratogenicity is probably related to free radical generation by metabolism with prostaglandin synthase ( 73 ). Fetal echocardiogram is recommended for exposure to retinoic acid in pregnancy ( Table 1.4 ). Nonsteroidal Anti-inflammatory Agents Nonsteroidal anti-inflammatory agents (NSAIDs) are used in the treatment of preterm labor or in pain control in pregnancy. Indomethacin is an NSAID that is commonly used for tocolysis in the second and third trimesters of pregnancy. In the fetus, indomethacin therapy may lead to premature constriction of the ductus arteriosus. Doppler evidence of ductal constriction is evident in up to 50% of fetuses exposed to indomethacin in late second and third trimesters of pregnancy ( 74 , 75 ). Typically, the ductal constriction is mild and resolves with drug discontinuation. Ductal constriction may also occur with the use of other NSAIDs ( 76 ). Several neonatal complications, which appear to be limited to indomethacin exposure beyond 32 weeks of gestation, include oliguria, necrotizing enterocolitis, and intracranial hemorrhage ( 77 ). Cardiovascular complications include a higher risk for patent ductus arteriosus requiring surgical ligation in indomethacin-exposed infants ( 77 ). Therefore, fetal echocardiogram is recommended with extended NSAID use in the late second or third trimester of pregnancy. Angiotensin-Converting Enzyme Inhibitors Angiotensin-converting enzyme inhibitors (ACE inhibitors) are commonly used antihypertensive medications. Fetal exposure to ACE inhibitors in the first trimester of pregnancy has been associated with an increased risk of major congenital malformation that was 2.7 times greater than the background risk or the risk of fetuses exposed to other antihypertensive medications ( 78 ). The increase in major malformations primarily affects the cardiovascular (risk ratio, 3.72) and central nervous systems (risk ratio, 4.39) ( 78 ). Atrial and ventricular septal defects represent the most common cardiac abnormalities ( 78 ). Fetal exposure to ACE inhibitors in the second and third trimesters of pregnancy is associated with “ACE inhibitor fetopathy,” which includes oligohydramnios, intrauterine growth restriction, hypocalvaria, renal failure, and death ( 79 ). Fetal echocardiogram may be considered for pregnancies exposed to ACE inhibitors ( Table 1.5 ). Selective Serotonin Reuptake Inhibitors Selective serotonin reuptake inhibitors (SSRIs) represent a class of antidepressants that has gained wide acceptance for the treatment of depression and anxiety during pregnancy ( 80 ). Specific SSRI medications include citalopram (Celexa), fluoxetine (Prozac), paroxetine (Paxil), and sertraline (Zoloft). Pregnancies exposed to SSRIs in the first trimester have shown an increased risk of congenital heart defects in some studies ( 81 - 83 ). Paroxetine has been singled out as the SSRI with the greatest association with congenital heart malformations, primarily atrial and ventricular septal defects ( 83 ). A meta-analysis of seven studies noted a significant overall increased risk of 74% for cardiac malformations in women exposed to paroxetine in the first trimester of pregnancy ( 84 ). Large population studies have provided conflicting information with regard to the association of other SSRIs with CHD. The risk of major CHD among infants born to women who took antidepressants during the first trimester was compared to the risk among infants born to women who did not use antidepressants in a large cohort of 949,504 pregnant women from Medicaid data for the period of 2000 through 2007 ( 85 ). When the data were fully adjusted for confounding variables, no substantial increase in the risk of cardiac malformations attributable to antidepressant use during the first trimester was noted. SSRI exposure after the 20th week of gestation has been associated with an increased risk of persistent pulmonary hypertension of the newborn (PPHN) ( 86 ). PPHN occurs in 1 to 2 per 1000 live births and is associated with increased morbidity and mortality. SSRI exposure increases this risk to about 6 to 12 per 1000 neonates, a sixfold increase over the background risk ( 86 ). Possible mechanisms of action include an accumulation of serotonin in the lung in exposed fetuses ( 87 ). Serotonin has vasoconstrictor properties and a mitogenic effect on pulmonary smooth muscle cells, which may result in the proliferation of smooth muscle cells, the characteristic histologic pattern in PPHN ( 88 , 89 ). In general, in women suffering from major depression and responding to a pharmacologic treatment, introduction or continuation of an SSRI should be encouraged in order to prevent maternal complications and to preserve maternal–infant bonding ( 90 ). Overall, it should be recognized that the specific defects implicated are rare and the absolute risks are small ( 91 , 92 ). Given the more consistent association of paroxetine use in the first trimester and CHD, performing a fetal echocardiogram may be indicated in pregnant women exposed to paroxetine in early gestation. Maternal Obesity The prevalence of obesity, which is defined as a body mass index (BMI) greater than or equal to 30 kg/m 2 , is increasing at an exponential rate. An established association between neural tube defects and prepregnancy maternal obesity exists ( 55 ). Several studies have noted an increased risk of congenital heart defects in obese pregnant mothers when compared to average-weight mothers ( 93 , 94 ). This increased risk is relatively small: 1.18-fold for the obese mother and 1.40-fold for the morbidly obese mother (BMI > 35 kg/m 2 ). Atrial and ventricular septal defects contribute to the majority of this increased risk ( 94 ). Given the small increased risk of CHD in obese pregnant women, performing detailed cardiac screening rather than fetal echocardiogram is considered reasonable ( Table 1.6 ). PREVENTION OF CHD Current evidence suggests that folic acid supplementation taken preconceptionally significantly reduces the risk of CHD ( 95 - 98 ). Analysis of a randomized controlled trial evaluating the efficacy of 0.8 mg of folic acid showed a 50% reduction in risk for a range of cardiac malformations ( 95 ). Other studies have shown a significant reduction in conotruncal abnormalities in newborns of pregnant women who took folic acid prenatally ( 96 , 97 ). The mechanism of action of the effect of folic acid on the reduction in the risk of cardiac malformations has not been elucidated. Methylenetetrahydrofolate reductase (MTHFR) enzyme activity may be involved in this process ( 99 ). An association exists between homocysteine elevations, MTHFR gene variants, and CHD ( 99 - 101 ). In a controlled study, fasting homocysteine levels have been shown to be higher in mothers of infants affected by CHD ( 95 ). Current data support folic acid as the active ingredient involved in fetal cardiac embryogenesis and that periconceptional folic acid use may reduce the risk for congenital cardiac malformations. KEY POINTS ■ Epidemiology of CHD The incidence of CHD is around 8 to 9 per 1000 live births. The overall incidence of CHD may be in the order of 50 per 1000 live births if all subtle cardiac anomalies are counted including bicuspid aortic valve, aneurysm of the atrial septum, and persistent superior vena cava. The presence of extracardiac abnormalities in a fetus is frequently associated with CHD even in the presence of normal karyotype. The incidence of CHD is reported in 10% to 20% of fetuses with nonimmune hydrops. Complete heart block in a fetus is associated with CHD in about 50% of cases and the overall risk for CHD with fetal arrhythmia is about 1%. The suspicion for CHD during a routine ultrasound is a risk factor with the highest yield for CHD (40%-50%). The presence of a fetal genetic or chromosomal abnormality is associated with a high risk for cardiac and extracardiac defects. Most infants born with CHD are born to pregnancies without risk factors. An NT thickness that is greater than or equal to 3.5 mm or at or above the 99th percentile for gestational age warrants referral for fetal echocardiography. The incidence of CHD in fetuses of monochorionic placentation is increased and is estimated at 2% to 9%. TTTS has been associated with acquired cardiac abnormalities to include right ventricular outflow tract obstruction, which occurs in about 10% of recipient twin fetuses. The incidence of CHD is fivefold higher in infants of pregestational diabetic mothers with a higher relative risk for heterotaxy, truncus arteriosus, transposition of the great arteries, and single ventricle defects. Gestational diabetes diagnosed in the first and early second trimesters of pregnancy is an indication for fetal echocardiography. Fetal ventricular hypertrophy in late gestation (third trimester) is a complication of poor glycemic control in pregestational and gestational diabetic pregnancies. Fetal echocardiogram in the third trimester to assess for ventricular hypertrophy is recommended for pregestational and gestational diabetic pregnancies if the HbA1c is greater than 6% in the second trimester. Fetal exposure in the first trimester to maternal phenylalanine levels exceeding 15 mg/dL is associated with a 10- to 15-fold increase in CHD. The risk of lithium exposure to the fetus is lower than previously reported. Paroxetine exposure during the first trimester of pregnancy confers significant risk of CHD to the fetus. CHD has been identified in 25% to 30% of infants with fetal alcohol syndrome, with septal defects representing the most common lesions. 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First-trimester use of selective serotonin-reuptake inhibitors and the risk of birth defects. N Engl J Med. 2007;356:2675-2683. 92 .Alwan S, Reefhuis J, Rasmussen SA, Olney RS, Friedman JM. Use of selective serotonin-reuptake inhibitors in pregnancy and the risk of birth defects. N Engl J Med. 2007;356:2684-2692. 93 .Watkins ML, Rasmussen SA, Honein MA, Botto LD, Moore CA. Maternal obesity and risk for birth defects. Pediatrics. 2003;111: 1152-1158. 94 .Cedergren MI, Kallen BA. Maternal obesity and infant heart defects. Obes Res. 2003;11:1065-1071. 95 .Czeizel AE. Periconceptional folic acid-containing multivitamin supplementation for the prevention of neural tube defects and cardiovascular malformations. Ann Nutr Metab. 2011;59:38-40. 96 .Shaw GM, O’Malley CD, Wasserman CR, Tolarova MM, Lammer EJ. Maternal periconceptional use of multivitamins and reduced risk for conotruncal heart defects and limb deficiencies among offspring. Am J Med Genet. 1995;59:536-545. 97 .Scanlon KS, Ferencz C, Loffredo CA, et al. Preconceptional folate intake and malformations of the cardiac outflow tract. Baltimore-Washington Infant Study Group. Epidemiology. 1998;9:95-98. 98 .Botto LD, Mulinare J, Erickson JD. Occurrence of congenital heart defects in relation to maternal mulitivitamin use. Am J Epidemiol. 2000;151:878-884. 99 .Junker R, Kotthoff S, Vielhaber H, et al. Infant methylenetetrahydrofolate reductase 677TT genotype is a risk factor for congenital heart disease. Cardiovasc Res. 2001;51:251-254. 100 .Kapusta L, Haagmans ML, Steegers EA, Cuypers MH, Blom HJ, Eskes TK. Congenital heart defects and maternal derangement of homocysteine metabolism. J Pediatr. 1999;135:773-774. 101 .Wenstrom KD, Johanning GL, Johnston KE, DuBard M. Association of the C677T methylenetetrahydrofolate reductase mutation and elevated homocysteine levels with congenital cardiac malformations. Am J Obstet Gynecol. 2001;184:806-812; discussion 812-807. C H A P T E R 2 Genetic Aspects of Congenital Heart Disease INTRODUCTION For almost four decades, genetic evaluation of congenital heart disease (CHD) could only be assessed by conventional karyotyping, primarily revealing numeric chromosomal abnormalities (e.g., trisomy 21), and by the description of syndromic conditions in infants with CHD and associated extracardiac anomalies (e.g., Holt–Oram syndrome, DiGeorge syndrome). Furthermore, the association of CHD with genetic abnormalities was underestimated, and was assumed to be around 10% to 15% ( 1 ), with the majority of defects thought to result from multifactorial causes. The rapid advent of new genetic technologies in the last two decades has enabled the decoding of the human genome and has afforded a better understanding and classification of many anomalies. Microarray techniques have allowed for the evaluation of submicroscopic copy number variants (CNV). In addition to microarray, the increasing use of targeted sequencing (cardiac panels) and the sequencing of whole exome sequencing (WES) or whole genome sequencing (WGS) has shown a much higher association of CHD with genetic abnormalities, in the order of 30% of cases ( 2 ). In the last decade, several genetic studies have been performed on large cohorts of children with CHD that have identified a host of new genes responsible for nonsyndromic cardiac malformations ( 3 , 4 ). These discoveries are enabling the ability to fine-tune genetic testing with a better understanding of the genes responsible for cardiac anomalies, thus enhancing patient counseling. The field of human cardiovascular genetics is progressing at a rapid pace, and novel genetic tests for various forms of cardiac abnormalities are regularly being introduced to clinical medicine. In this chapter, we will first discuss the principles of currently available genetic techniques and then expand on the following three main groups of genetic anomalies: ( 1 ) chromosomal aneuploidies detected with conventional karyotype, ( 2 ) deletions and duplications detected on microarray analysis, and ( 3 ) single-gene defects detected via cardiac panels or exome sequencing. Conventional Karyotyping and Chromosomal Analysis Chromosomal analysis is done on cell cultures that are treated to arrest growth in the metaphase when the chromosomes are visible. Special banding techniques (usually G-banding) are used to identify individual chromosomes by their specific pattern of light and dark bands. The analysis is performed under the microscope and the chromosomes are classified into seven groups, A to G, based on their length and centromere position. Nomenclature designates the centromere as “cen” and the telomere (terminal structure) as “ter.” The short arm of each chromosome is designated as “p” (petit) and the long arm as “q” (queue). Each arm is subdivided into a number of bands and sub-bands. This traditional karyotyping technique identifies the majority (>75%) of clinically significant chromosomal abnormalities including trisomies 21, 18, and 13, triploidy, and aneuploidies involving the sex chromosomes, such as monosomy X (Turner syndrome) and XXY (Klinefelter syndrome). With light microscopy, large balanced or unbalanced translocations can also be diagnosed in addition to rare mosaic trisomies and structurally abnormal chromosomes. Large chromosomal deletions (>5-10 million base [MB] pairs) can also be identified, such as the majority of deletions 4p- (Wolf–Hirschhorn syndrome) or deletions 5p- (Cri-du-Chat syndrome). Small deletions, termed microdeletions, such as microdeletion 22q11.2 (DiGeorge syndrome; discussed later), are typically too small to be identified by this method. Microdeletions can be detected by the use of selective fluorescence in situ hybridization (FISH) when such conditions are suspected (e.g., FISH for deletion 22q11.2 in conotruncal anomalies) or by examining the complete set of chromosomes using comparative genomic hybridization (CGH) (microarray; discussed later). FISH Technique FISH is a cytogenetic technique that uses specific fluorescent probes, which are applied to detect and localize the presence or absence of specific DNA regions on chromosomes. FISH uses a single DNA strand, called a probe, corresponding to a specific locus and only binding to the corresponding complementary part on the chromosome. Fluorescence with various colors is used to enable visualization under the fluorescence microscope. FISH can be directly used on cells during cell division, and is typically applied antenatally for a rapid diagnosis of trisomies. The FISH technique used for the identification of microdeletions is also performed directly on metaphase chromosomes with the addition of FISH probes. In general, two probes are used. The first probe (green) is a control probe used for the identification of both copies of the target chromosome. The second probe (red-magenta) hybridizes to the sequence of the region of interest on the target chromosome. In the presence of a deletion, which is typically on one of the paired chromosomes, a lack of the red signal is noted, as the probe cannot bind to the target region on the chromosome. When a specific cardiac anomaly is diagnosed in the fetus and an invasive procedure is performed, it has become customary to offer FISH to check for microdeletion 22q11.2 in addition to chromosome karyotyping. Array CGH (Microarray) and CNV Array CGH, or microarray, is a sensitive technique that compares the patient’s DNA (comprising all the chromosomes) with a control DNA sample, for the identification of variances between the two sets. Imbalances in the patient’s DNA, called CNV include losses (deletions) and gains (duplications) and can be identified with this technique. Instead of examining one deletion, such as with FISH, all possible regions of the chromosomes are examined for deletions and duplications. An explanation of the technical aspects of CGH is beyond the scope of this book, but it is important to state that CGH detects DNA imbalances in chromosomes above a certain size (e.g., a cutoff of 50 Kb), some of which may have unclear clinical significance. This microarray technique has become popular in the last few years despite its high cost and limitations. Some centers offer CGH as a first-line option for genetic testing after chorionic villus sampling or amniocentesis, while others restrict its use to when DNA imbalance is suspected, or as a second-line test following normal karyotype analysis. In one meta-analysis of Jansen et al. ( 5 ), it was shown that for fetal heart defects, CGH detected an additional 7% of chromosomal abnormalities after excluding aneuploidies and deletion 22q11.2. With this finding, it has become reasonable to discuss the option for CGH with patients when fetal malformations, and particularly CHD, is diagnosed. The availability and cost of CGH should also be factored into this decision. Next-Generation Sequencing, Exome Sequencing, and Single-Gene Defects Until recently, seeking genetic mapping for a single-gene defect was limited to families that had several siblings affected with a known gene defect. With rapid evolution in genetic testing, especially with advances in DNA sequencing, the gene defect(s) in many clinical genetic diseases have been identified and now can be tested within days. The technique is generally called next-generation sequencing (NGS) or massively parallel sequencing to emphasize that it is new and rapid, in comparison to the earlier Sanger sequencing (first-generation sequencing), which allows the analysis of only one specific gene region and is more time-consuming. The advent of affordable and rapid NGS has revolutionized genetics of human malformations and has led to a better understanding of the pathways of many diseases. Some anomalies that were earlier being considered as separate entities have now been reclassified into groups of anomalies with common clinical and genetic features. For instance, Noonan syndrome (discussed later in this chapter), which was considered a distinct genetic syndrome, now belongs to a group of genetic syndromes known as RASopathies, and includes defects in 17 genes. Another group of genetic syndromes are now known as ciliopathies and have in common the mutations of genes involved in cilia development and function. Over the past decade, genetic studies on children and fetuses with CHD have elucidated the etiology of CHD in many conditions. Noninvasive Prenatal Testing Noninvasive prenatal testing (NIPT) is a genetic test that is offered as a screening test in the first and second trimesters of pregnancy for trisomies 21, 13, and 18, monosomy X, and sex chromosomes abnormalities. The test is based on the presence of fetal cell-free DNA (cfDNA) in the maternal circulation primarily from placental cell apoptosis ( 6 ). Placental cell apoptosis releases into the maternal circulation small DNA fragments that can be detected from about 4 to 7 gestation of weeks ( 7 ). It is estimated that about 2% to 20% of circulating cfDNA in the maternal circulation is fetal in origin ( 7 ). The half-life of cfDNA is short and is typically undetectable within hours after delivery ( 8 ). Details of the technical aspects of NIPT are beyond the scope of this book, but the various tests that are clinically available are based on the isolation and counting of cfDNA using sequencing methods. NIPT has very good performance with regard to screening for trisomy 21. In published studies, the detection rate for trisomy 21 is at 99% for a false-positive rate of 0.16% ( 9 ). The detection rate for trisomy 18 is at 97% for a false-positive rate of 0.15% ( 9 ). To date, NIPT is recommended as a screening test for high-risk populations. Given a very small false-positive rate, incorporating NIPT for screening for trisomy 21 in high-risk populations reduces the need for unnecessary invasive testing. Recently, testing for deletion 22q11.2 has been included in NIPT and shows a sensitivity of 70% to 75% with a specificity of 99.5% ( 10 ). It should be emphasized that NIPT is a screening test and not a diagnostic test, and, thus, caution should be used when NIPT is incorporated in the genetic evaluation of CHD. Given the relatively high association of CHD with chromosomal imbalance, the significance of a normal NIPT result in the setting of CHD should be explained to the patient and further invasive diagnostic testing should be recommended. NIPT technology is now expanding to allow for the screening of chromosomal deletions and duplications. The authors believe that invasive diagnostic testing is more appropriate in the setting of CHD given the high association with genetic malformations. Nondirective genetic counseling is important in this setting in order to provide a comprehensive menu of options to the family faced with the prenatal diagnosis of CHD. SONOGRAPHIC EVALUATION OF THE FETUS WITH CHD IN SUSPECTING GENETIC DISEASE The antenatal detection of CHD in a fetus necessitates a detailed ultrasound evaluation, given a high association of CHD with extracardiac anomalies, ranging between 30% and 50% in some series. Establishing whether the CHD is isolated, or part of a genetic syndrome, is essential for patient counseling and for the assessment of long-term prognosis. On rare occasions, the type of CHD by itself provides enough information about associations, or lack thereof, to allow for patient counseling. For instance, this is for cardiac rhabdomyomas and their associations with tuberous sclerosis complex (TSC) or the commonly isolated simple transposition of the great arteries. For most CHDs, however, there is a wide range of possible associations and detailed fetal evaluation is therefore warranted. Usually, the first step in the ultrasound evaluation is to look for the presence of additional soft markers and/or extracardiac malformations that suggest the presence of one of the common numerical chromosomal anomalies that can be detected by karyotyping. Furthermore, a detailed sonographic evaluation of the fetus is essential with a thorough search for markers of associated genetic syndromes. This can only be achieved if the examiner is aware of various associations and the phenotypic aspects of various syndromes. In case of a normal fetal karyotype, a discussion on the benefit of additional genetic testing should be undertaken with the patient. Tables on various associations of CHD with genetic abnormalities are available and have traditionally guided clinical management in such cases. The presence of subtle signs on an ultrasound can point the examiner to a genetic association that may not be clearly visible otherwise. Tetralogy of Fallot (TOF) is a typical example as it can be isolated, but also typically associated with trisomies 21 and 18, deletion 22q11.2, Alagille syndrome, CHARGE syndrome, and others. Another example is the presence of atrioventricular septal defect (AVSD), which is associated with either trisomy 21 or 18 in more than 50% of cases, but also can be part of heterotaxy syndrome ( Chapter 41 ), either isolated or in the context of primary ciliary dyskinesia. AVSDs are also observed in deletion 22q11.2 and other deletions, as well as in CHARGE syndrome (13%) ( 11 ). CHD AND NUMERICAL CHROMOSOMAL ANOMALIES The frequency of chromosomal abnormalities in infants with CHD has been estimated at 5% to 15% from postnatal data ( 1 , 12 , 13 ). In a population-based case-control study of 2102 liveborn infants, ascertained by their cardiovascular malformations, chromosomal abnormalities were found in 13% ( 1 ). In this study, Down syndrome occurred in 10.4% of infants with cardiovascular malformations, with the other trisomies each occurring in less than 1% of cases ( 1 ). Similar data was reported from three large registries of congenital malformations, involving 1.27 million births ( 13 ). The frequency of abnormal karyotypes in fetuses with cardiac defects is higher and has been reported to be in the range of 30% to 40% by several studies ( 14 - 16 ). This higher rate of chromosomal abnormalities in fetuses with cardiac defects, when compared to their live-born counterparts, is mainly due to an increased prenatal mortality in fetuses with aneuploidy, which has been estimated at 30% for trisomy 21, 42% for trisomy 13, 68% for trisomy 18, and 75% for Turner syndrome ( 17 ). Keep in mind that earlier studies reported more CHD cases with multiple structural anomalies, which may increase the genetic association. Not only is the association of congenital cardiac defects and chromosomal abnormalities lower in live-born infants than in fetuses, but the distribution of chromosomal abnormalities is also more skewed toward Down syndrome in the neonatal population ( 1 , 13 ), again probably due to the high prenatal mortality of trisomies 18 and 13 and monosomy X. Certain specific cardiac diagnoses are more commonly associated with chromosomal abnormalities than others. Prenatal and postnatal studies are concordant with regard to the specific cardiac diagnoses that are more likely to be associated with chromosomal abnormalities. In general, malformations of the right side of the heart are less commonly associated with karyotype abnormalities. AVSD, ventricular (perimembranous) septal defect (VSD) and atrial septal defect (ASD), TOF, double outlet right ventricle (DORV), and hypoplastic left heart syndrome (HLHS), on the other hand, are more commonly associated with chromosomal abnormalities in the fetus and newborn. Table 2.1 lists specific cardiac diagnoses in infants with noncomplex cardiovascular defects from three large registries ( 13 ) and the corresponding incidence of associated numerical chromosomal abnormalities. Table 2.1 • Number of Infants with Identified Chromosomal Anomalies According to Cardiac Defect Type (Noncomplex Cardiovascular Defects Only) Chromosomal anomaly Cardiovascular defect Corrected transposition No Yes Percentage 16 0 0.0 D-TGA 969 9 0.9 Pulmonary atresia without VSD 195 4 2.0 TAPVC 287 6 2.0 ASD + pulmonary valve stenosis 117 5 4.1 HLHS 799 35 4.2 Tricuspid valve atresia 132 6 4.3 Pulmonary valve stenosis 374 17 4.3 Common arterial trunk 217 10 4.4 Aortic valve stenosis 235 11 4.5 Interrupted aortic arch 179 11 5.8 Ebstein anomaly 110 8 6.8 Coarctation of aorta 403 32 7.4 91 9 9.0 207 21 9.2 1077 123 10.3 174 25 12.6 VSD 2134 474 18.2 ASD 868 319 26.9 VSD + ASD 447 207 31.7 AVSD 317 687 68.4 Single ventricle VSD + coarctation of aorta Tetralogy of Fallot DORV ASD, atrial septal defect; AVSD, atrioventricular septal defect; DORV, double outlet right ventricle; D-TGA, Dtransposition of great arteries; HLHS, hypoplastic left heart syndrome; TAPVR, total anomalous pulmonary venous connection; VSD, ventricular septal defect. Modified by permission from Springer Nature: Harris JA, Francannet C, Pradat P, Robert E. The epidemiology of cardiovascular defects, part 2: a study based on data from three large registries of congenital malformations. Pediatr Cardiol . 2003;24:222-235. Copyright 2003. The majority of fetuses with cardiac defects and chromosomal abnormalities have other associated extracardiac abnormalities, in the order of 50% to 70% ( 14 , 16 ). The distribution of extracardiac abnormalities usually follows the typical pattern noted within each chromosomal syndrome with no predominance of any specific abnormality. In the fetus with an apparently isolated CHD, the incidence of chromosomal abnormalities is still significantly increased (15%-30%) and thus appropriate genetic counseling is warranted ( 14 , 16 ). When the diagnosis of any abnormality in genetic testing is made in a fetus, an echocardiogram is indicated in view of the possible association of cardiac malformations. In the following sections, we will discuss the more common aneuploidies detected in association with CHD in the fetus. Down Syndrome (Trisomy 21) Definition of Disease Down syndrome is caused by the presence of three copies of chromosome 21. It is the most common chromosomal aberration in humans with a mean occurrence of 1:500 in the general population. Since 30% of the fetuses with trisomy 21 die in utero, the prevalence during gestation is higher than at birth. In 95% of cases, trisomy 21 is due to an error in maternal meiosis, which increases with maternal age, while in the remaining 5%, it is due to an unbalanced translocation, which is independent of parental age and can be of maternal or paternal origin. Persons with trisomy 21 have distinctive clinical features associated with mental challenge of variable degree. Structural and immunologic anomalies can also be present. Genetic Diagnosis The genetic diagnosis can be achieved prenatally on fetal tissue collected from an amniocentesis, chorionic villous sampling, or fetal blood sampling. The genetic diagnosis is achieved on karyotyping with G-banding technique. The FISH technique is often used to rapidly confirm the diagnosis. Trisomy 21 can also be suspected on NIPT screening with high accuracy (99%). On prenatal ultrasound, the presence of distinct cardiac and extracardiac structural anomalies, as well as soft markers, can highly suggest the presence of trisomy 21 ( Table 2.1 ) ( Figs. 2.1 to 2.4 ). Figure 2.1: First trimester markers of trisomy 21 include thickened nuchal translucency (NT) (A-short arrow) and absent or hypoplastic nasal bone (NB) (A-long arrow), generalized edema (B and C-arrows), cardiac anomaly (Cstar), most commonly an atrioventricular septal defect (AVSD), abnormal course of the umbilical vein (UV) with an absent or abnormal connection of the ductus venosus (DV), here connecting to the inferior vena cava (IVC) (D-arrow), reverse flow in the DV (E-arrows), and tricuspid regurgitation (F-arrows). Figure 2.2: Cardiovascular abnormalities in trisomy 21 fetuses typically include an atrioventricular septal defect (AVSD) (A-star), ventricular septal defect (VSD) (B-arrow), linear insertion of the AV valves with a cardiac defect (Carrows), aberrant right subclavian artery (ARSA) (D-arrows), with the course of the artery behind the trachea, intracardiac echogenic focus (E-arrow), abnormal course of the umbilical vein (UV) with an absent or abnormal connection of the ductus venosus (DV) (F-arrow). The thymus gland (G-arrows) can be small in fetuses with trisomy 21 with a small thymic–thoracic ratio. Pericardial fluid (H-arrow) can also be found in trisomy 21 fetuses in combination with a cardiac anomaly. Figure 2.3: Trisomy 21 fetuses can show diverse abnormalities including skeletal, such as short femur (A), wide pelvic angle (B-arrows), short hands and fingers with clinodactyly (C), and 11-pair ribs (D). Other anomalies occasionally found include duodenal obstruction as double bubble (E), hydrops (F-arrows), shown here as scalp edema, pyelectasis (G-arrows), and occasionally (H) increased pulsatility index (PI) in the umbilical artery (UA) Doppler with a normal uterine Doppler (not shown). Figure 2.4: Cranial and facial markers in trisomy 21 fetuses including absent nasal bone (A-circle), protruding tongue with an open mouth (A-arrow), prenasal thickness (B-arrow), brachycephaly (C), dilated cavum septi pellucidi (CSP) (C-arrow), nuchal edema (D-arrows), as seen in sagittal (D-left) or axial (D-right) view. The midfacial hypoplasia in trisomy 21 is associated with a short maxilla (E) and small mouth, as microstoma (F). Facial features of trisomy 21 can be recognized on 3D ultrasound and are shown in panel G. A small ear (H) can also be found but is not very specific. Cardiac Findings Cardiac findings in trisomy 21 fetuses are present in more than 50% of cases and include AVSDs, VSDs (inlet or perimembranous), TOF, and other less common anomalies (Ebstein, DORV, coarctation of the aorta [CoA] etc.) ( Fig. 2.2 ). In addition, anatomic variants/markers in the chest can be present in association with trisomy 21 and include an aberrant right subclavian artery, a hyperechogenic intracardiac focus, linear insertion of the atrioventricular valves, pericardial effusion, tricuspid regurgitation, and others. Figure 2.2 shows examples of cardiac findings in several fetuses with trisomy 21. Extracardiac Findings Structural anomalies such as duodenal or esophageal atresia in trisomy 21 are occasionally found ( Fig. 2.3 ), but are much less common than anatomic variants ( Fig. 2.4 ). Anatomic markers associated with trisomy 21 are common and can be seen in several organ systems, including lymphatic, skeletal, cerebral, facial, renal, abdominal, and placental/amniotic fluid. Table 2.2 lists common ultrasound markers associated with trisomy 21. The majority of fetuses with trisomy 21 (>90% of cases) can be detected in early gestation, by the first trimester genetic screening test ( Fig. 2.1 ), which includes maternal age, nuchal translucency (NT) measurement, and biochemical markers. A detailed first trimester anatomy survey can also improve detection of trisomy 21. For more details refer to the authors’ book on first trimester ultrasound ( 18 ). Table 2.2 • Physical Abnormalities in Fetuses with Trisomy 21 Organized by Organ System Organ system Abnormalities in trisomy 21 Cardiac AVSD, VSD, TOF, ARSA, EIF, TR, pericardial effusion, right aortic arch Skeletal Short femur, short humerus, absent or short nasal bone, short head, wide pelvic angle, short maxilla, clinodactyly, short hands, sandal gap Facial Prefrontal skin edema, absent or short nasal bone, flat face, small mouth (microstoma), open mouth with protruding tongue, small ears Lymphatic Thickened nuchal translucency, nuchal edema, ascites Gastrointestinal and renal Esophageal, duodenal and other bowel obstruction, renal pelvis dilation, small omphalocele, echogenic bowel Cerebral Short head (brachycephaly), ventriculomegaly, dilated cisterns magna, dilated CSP, abnormal corpus callosum Get Complete eBook Download Link below for instant download https://browsegrades.net/documents/2 86751/ebook-payment-link-for-instantdownload-after-payment

A Practical Guide to Fetal Echocardiography, 4e By Rabih Chaoui, Alfred Abuhamad

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