Double Outlet Right Ventricle Versus Aortic Dextroposition: Morphologically Distinct Defects

This study concerns the morphological differentiation between double outlet right ventricle (DORV) and aortic dextroposition (AD) defects, namely tetralogy of Fallot and Eisenmenger anomaly. Indeed, despite the similar condition in terms of sequential ventriculo‐arterial connections, DORV and AD are two distinct morphological entities. It is proposed that the borderline between these two groups of malformations is represented by the specific insertion of the infundibular septum into the left anterior cranial division of the septomarginal trabeculation (or septal band) occurring in ADs and lacking in DORV. Furthermore, the spiraliform versus straight parallel arrangement of the great arteries in the two groups of anomalies is emphasized as an additional and distinctive morphological feature. Emphasis is also given to the association of straight parallel great arteries conotruncal malformations, DORV and transposition of the great arteries, with the asplenia type of heterotaxy laterality defects. Within this context, the absence of subaortic ventricular septal defect and concomitantly of spiraliform great arteries in the asplenia group of heterotaxy anomalies, as detected by this study, further substantiates our belief of not mixing collectively the ADs with the DORV in clinico‐pathological diagnosis. Anat Rec, 296:559–563, 2013. © 2013 Wiley Periodicals, Inc.     

Disturbed vagal nerve distribution in embryonic chick hearts after treatment with all-trans retinoic acid

 The distribution of the vagal nerve was studied in whole-mount specimens and serial sections of chick embryos after retinoic acid treatment. White Leghorn chick embryos were treated at stage 15 either with 1 μg all-trans retinoic acid (n=11), or with the solvent dimethylsulphoxide (sham-operated embryos, n=8). Eight embryos served as normal controls. At stage 34 all 27 embryos were examined with a dissecting microscope. In order to reveal the vagal patterning, the hearts were removed and whole-mount stained with the HNK-1 antibody. In three hearts of the retinoic acid-treated group a morphologic intracardiac anomaly – a double outlet right ventricle – was found. To explore in depth the vagal nerve distribution in the heart, a separate set of hearts of retinoic acid embryos (n=5), sham-operated (n=4) and control embryos (n=5), was devised solely for serial sectioning and staining with the HNK-1 antibody. All hearts of retinoic acid-treated embryos showed a disturbed vagal nerve distribution both over the surface of the heart and within the heart wall. The vagal patterning was not altered in the sham-operated embryos compared to controls. It is concluded that retinoic acid disturbs the development of vagal nerve patterning regardless of the concurrent presence of intracardiac malformations. The mechanism and functional implications remain to be investigated. Accepted: 22 January 1998     

176例右心室双出口的手术治疗分析

目的观察并探讨右心室双出口（DORV）手术矫治的疗效和治疗方法。方法分析1998年1月至2010年1月间176例DORV病人手术治疗的疗效。其中男105例,女71例,124例室缺（VSD）位于主动脉口下,12例室缺位于肺动脉口下,32例室缺位于两大动脉开口下,8例室缺远离两大动脉开口。114例建立室缺到主动脉口心内隧道,或者同时行右室流出道加宽,21例行内隧道外管道手术（Rastelli）,18例行改良G lenn分流术,11例行Fontan纠治术,7例行大动脉调转术（Sw itch）。结果住院期间死亡18例;出院后116例获随访,时间为6个月至8年,临床效果满意。结论 DORV解剖类型复杂多样,心室内隧道或补片要简洁,以确保左心室流出道顺畅。室缺位置及左室发育状况决定手术方案及疗效。     

A new anatomic approach of the ventricular septal defect in the interruption of the aortic arch

The aim of this study was to analyse the anatomy of the ventricular septal defect (VSD) in heart specimens with interruption of the aortic arch (IAA) in order to explore the hypothesis of different embryologic mechanisms for the different anatomic types of IAA. We examined 42 human heart specimens, 25 with IAA as the main disease with concordant atrioventricular and ventriculo‐arterial connections and two distinct great arteries, and 17 hearts with IAA associated with other malformations [six common arterial trunk (CAT), five double‐outlet right ventricle (DORV), three transposition of the great arteries (TGA), three atrioventricular septal defect (AVSD)]. The interruption was classified according to Celoria and Patton. We focused on the anatomy of the VSD viewed from the right ventricular side. There were 15 IAA type A, 27 type B, no type C. The VSD in IAA type B was always an outlet VSD, located between the two limbs of the septal band, with posterior malalignment of the outlet septum in hearts with concordant ventriculo‐arterial connections, without any fibrous tricuspid‐aortic continuity. In addition, the aortic arch was always completely absent. Conversely, the VSD in IAA type A could be of any type (outlet in six, muscular in four, central perimembranous in two, inlet in three) and the aortic arch was either atretic or absent. In addition, IAA type B, when found in the setting of another anomaly, was always associated with neural crest‐related anomalies (CAT and DORV), whereas IAA type A was found in association with anomalies not related to the neural crest (TGA and AVSD). These results reinforce the hypothesis that different pathogenic mechanisms are responsible for the two types of IAA, and the inclusion of IAA type B in the group of neural crest defects. Conversely, IAA type A could be due to overlapping mechanisms: flow‐related defect (coarctation‐like) and neural crest contribution.     

Dual role for neural crest cells during outflow tract septation in the neural crest-deficient mutant Splotch2H

Splotch^2H ( Sp^2H ) is a well-recognized mouse model of neural crest cell (NCC) deficiency that develops a spectrum of cardiac outflow tract malformations including common arterial trunk, double outlet right ventricle, ventricular septal defects and pharyngeal arch artery patterning defects, as well as defects in other neural-crest derived organ systems. These defects have been ascribed to reduced NCC in the pharyngeal and outflow regions. Here we provide a detailed map of NCC within the pharyngeal arches and outflow tract of Sp^2H/Sp^2H embryos and fetuses, relating this to the development of the abnormal anatomy of these structures. In the majority of Sp^2H/Sp^2H embryos we show that deficiency of NCC in the pharyngeal region results in a failure to stabilize, and early loss of, posterior pharyngeal arch arteries. Furthermore, marked reduction in the NCC-derived mesenchyme in the dorsal wall of the aortic sac disrupts fusion with the distal outflow tract cushions, preventing the initiation of outflow tract septation and resulting in common arterial trunk. In around 25% of Sp^2H/Sp^2H embryos, posterior arch arteries are stabilized and fusion occurs between the dorsal wall of the aortic sac and the outflow cushions, initiating outflow tract septation; these embryos develop double outlet right ventricle. Thus, NCC are required in the pharyngeal region both for stabilization of posterior arch arteries and initiation of outflow tract septation. Loss of NCC also disrupts the distribution of second heart field cells in the pharyngeal and outflow regions. These secondary effects of NCC deficiency likely contribute to the overall outflow phenotype, suggesting that disrupted interactions between these two cell types may underlie many common outflow defects.     

The ventricular septal defect in complete transposition of the great arteries: pathologic anatomy in 57 cases with emphasis on subaortic, subpulmonary, and aortic arch obstruction

Fifty-seven heart specimens with complete transposition (concordant atrioventricular and discordant ventriculo-arterial connections) and ventricular septal defect were reviewed to establish the spectrum of morphology of the ventricular septal deficiency and to correlate the type of defect with presence of subarterial and aortic arch obstruction. The ventricular septal defect was single in 52 cases (27 perimembranous and 25 muscular) and multiple in five. A normal alignment between the outlet component and the rest of the muscular septum was present in 18 cases (10 perimembranous, five muscular, and three multiple). The defect was the consequence of septal malalignment in the other 39 specimens; 29 with rightward and 10 with leftward displacement of the outlet septum. Rightward displacement led to perimembranous defects in 16 cases and muscular defects in 12. In another instance, a perimembranous malalignment defect was associated with a muscular inlet defect. Subaortic stenosis due to either deviation of the outlet septum or prominence of the ventriculo-infundibular fold and septoparietal trabeculations was observed in 14 cases. Leftward displacement of the outlet septum was associated with one perimembranous and eight muscular defects and with multiple (muscular outlet plus muscular inlet) defects in another case. Of these, five cases showed subpulmonary stenosis. Aortic arch obstructions were present in 19 cases; 14 showed rightward malalignment of the outlet septum, which produced subaortic stenosis. These findings suggest two things: Unlike the situation in hearts with "normally related" great arteries, most defects in complete transposition result from malalignment of the outlet septum, with many being of the muscular type. Rightward or leftward displacement of the outlet septum frequently results in subaortic or subpulmonary stenosis, respectively. Aortic arch obstructions, although frequent, are not always associated with subaortic stenosis.     

镜面右位心的诊断和外科治疗——附11例临床分析

目的：分析镜面有位心病理解剖特点，探讨其临床诊断及外科治疗方法。方法：总结11例镜面右位心临床资料，对其主要的合并畸形、诊断方法和其中6例外科治疗的效果进行比较分析。结果：本组患者包括右心室双出口4例，单心室合并单心房2例，法乐四联征3例，完全性房室间隔缺损2例。合并畸形包括双上腔静脉3例，房间隔缺损3例，部分性肺静脉异位引流2例，三房心1例，动脉导管未闭1例。10例患者合并肺动脉狭窄或右室流出道狭窄，1例重度肺动脉高压。主要根据胸部X线片，超声心动图（UCG）及心导管明确诊断。行右心室双出口矫正术2例，法乐四联征根治术3例，右心室流出道疏通1例。4例存活，2例死亡。结论：（1）镜面右位心多存在复杂心内畸形。（2）UCG仍然是最基本有效的诊断方法，心导管检查是明确诊断的必要辅助手段。（3）外科治疗必须严格把握手术指征。     

Novel ZFPM2/FOG2 variants in patients with double outlet right ventricle

Tan Z-P, Huang C, Xu Z-B, Yang J-F, Yang Y-F. Novel ZFPM2/FOG2 variants in patients with double outlet right ventricle. Congenital heart defects (CHDs) occur in about 0.5-1% of all newborns and are the most common birth defects. Double outlet right ventricle (DORV) accounts for approximately 1-3% of all CHDs. Similar to Tetralogy of Fallot (TOF), DORV is a subtype of contruncal heart defects (CTDs) and is anatomically characterized by a malposition of the great arteries. We described a boy with chromosomal translocation: 46, XY t (8; 18) (q22; q21) that may disrupts the ZFPM2/FOG2 locus. The coding sequences of ZFPM2/FOG2 were determined in 38 patients with sporadic DORV, 95 patients with TOF, and 12 patients with transposition of the great arteries. Five DNA sequence variants affecting variably conserved residues of ZFPM2/FOG2 were identified in patients with TOF type or ventricular septal defect type of DORV. Three novel mutations (p.V339I, p.K737E, and p.A611T) were reported for the first time. The other two mutations (p.M703L and p.Q889E) were reported in patients with congenital diaphragmatic hernia but not in patients with CHD. Our finding suggests that variants of the ZFPM2/FOG2 gene might be a common cause of DORV.     

The pattern of the coronary arterial orifices in hearts with congenital malformations of the outflow tracts: a marker of rotation of the outflow tract during cardiac development?

Outflow tract defects, including cardiac neural crest defects (so-called conotruncal defects) and transposition of the great arteries, are due to an abnormal rotation of the outflow tract during cardiac development. Coronary orifices are often abnormal in outflow tract defects, particularly in common arterial trunk (CAT). A recent study indicates that abnormal coronary artery pattern in a mouse model with common arterial outlet (Tbx1−/− mouse mutant) could be due to a reduced and malpositioned subpulmonary coronary-refractory myocardial domain. The aim of our study was to demonstrate the relation between coronary orifices pattern in outflow tract defects in human and the abnormal embryonic rotation of the outflow tract. We analyzed 101 heart specimens with outflow tract defects: 46 CAT, 15 tetralogy of Fallot (TOF), 29 TOF with pulmonary atresia (TOF-PA), 11 double-outlet right ventricle with subaortic ventricular septal defect (DORV) and 17 controls. The position of left and right coronary orifices (LCO, RCO) was measured in degrees on the aortic/truncal circumference. The anterior angle between LCO and RCO (α) was calculated. The LCO was more posterior in TOF (31 °), TOF-PA (47 °), DORV (44 °), CAT (63 °), compared with controls (0 °, P < 0.05), and more posterior in CAT than in other outflow tract defects (P < 0.05). The RCO was more anterior in TOF (242 °), TOF-PA (245 °) and DORV (271 °) than in controls (213 °, P < 0.05), but not in CAT (195 °). The α angle was similar in TOF, TOF-PA, DORV and controls (149 °, 162 °, 133 °, 147 °), but significantly larger in CAT (229 °, P < 0.0001). In all outflow tract defects but CAT, the displacement of LCO (anterior) and RCO (posterior), while the α angle remains constant, might be due to incomplete rotation of the myocardium at the base of the outflow tract, leading to an abnormally positioned subpulmonary coronary-refractory myocardial domain. The larger α angle in CAT could reflect its dual identity, aortic and pulmonary.     

Conotruncal anomalies in the trisomy 16 mouse: an immunohistochemical analysis with emphasis on the involvement of the neural crest

The trisomy 16 (Ts16) mouse is generally considered a model for human Down's syndrome (trisomy 21). However, many of the cardiac defects in the Ts16 mouse do not reflect the heart malformations seen in patients suffering from this chromosomal disorder. In this study we describe the conotruncal malformations in mice with trisomy 16. The development of the outflow tract was immunohistochemically studied in serially sectioned hearts from 34 normal and 26 Ts16 mouse embryos ranging from 8.5 to 14.5 embryonic days. Conotruncal malformations observed in the Ts 16 embryos included double outlet right ventricle, persistent truncus arteriosus, Tetralogy of Fallot, and right-sided aortic arch. This spectrum of malformations is remarkably similar to that seen in humans suffering from DiGeorge syndrome (DGS). As perturbation of neural crest development has been proposed in the pathogenesis of DGS we specifically focussed on the fate of neural crest derived cells during outflow tract development of the Ts16 mouse using an antibody that enabled us to trace these cells during development. Severe perturbation of the neural crest-derived cell population was observed in each trisomic specimen. The abnormalities pertained to: 1) the size of the columns of neural crest-derived cells (or prongs); 2) the spatial orientation of these prongs within the mesenchymal tissues of the outflow tract; and 3) the location in which the neural crest cells interact with the myocardium. The latter abnormality appeared to be responsible for ectopic myocardialization found in trisomic embryos. Our observations strongly suggest that abnormal neural crest cell behavior is involved in the pathogenesis of the conotruncal malformations in the Ts16 mouse.     

Double outlet right ventricle in a human embryo

Summary A human embryo of 14 mm crown-rump length is described to exemplify the anomaly of double outlet right ventricle with subaortic defect. The configuration of endocardial swellings in the outflow portion of the heart are compatible with the general architecture of full-grown examples of the anomaly. This configuration differs considerably from normal embryonic anatomy, but is still supported by the architecture of the myoepicardial mantle. It is concluded that endocardial swellings play a secondary role in the determination of fullgrown cardiac anatomy.     

Angled aorta ("sigmoid septum") as a cause of hypertrophic subaortic stenosis

Review of the hearts of seven patients in whom hypertrophic obstructive cardiomyopathy had been diagnosed by the usual clinical and morphologic criteria revealed diminished angles between the interventricular septa and ascending aortas in three cases. The angles in these three hearts were 90 to 110 degrees, as compared with a mean value of 145 degrees in the other four hearts with hypertrophic obstructive cardiomyopathy and 140 +/- 14 degrees in 55 control hearts. None of the patients with hypertrophic subaortic stenoses and angled aortic roots died of the heart disease, and none had either asymmetric ventricular hypertrophy or evidence of familial cardiomyopathy. It is proposed that in patients with angled aortic roots and left ventricular hypertrophy, subaortic obstruction may develop due to narrowing of the left ventricular outflow tract, resulting in clinical and morphologic findings of hypertrophic obstructive cardiomyopathy. In hearts with angled aortic roots the top of the ventricular septum is tipped toward the mitral valve, rather than tapered toward the aorta, as in normal hearts. This configuration narrows the outflow tract of the left ventricle and can result in systolic anterior motion of the mitral valve, the illusion of asymmetric septal hypertrophy when studied by M-mode echocardiography, a subaortic pressure gradient, and a subaortic endocardial plaque. This less serious form of hypertrophic subaortic stenosis should be distinguished from other forms of hypertrophic obstructive cardiomyopathy.     

PAGOD syndrome: eighth case and comparison to animal models of congenital vitamin A deficiency

We observed a 46, XY infant with atrophy of the optic nerve, complex congenital heart disease including a double outlet right ventricle, hypoplasia of the right pulmonary artery and lung, eventration of the diaphragm, and ambiguous genitalia. The baby died of cardiac arrhythmias at 204 days. The pattern of malformations was compatible with pulmonary tract and pulmonary artery, agonadism, omphalocele, diaphragmatic defect, and dextrocardia (PAGOD) syndrome. The condition may resemble the malformation complex associated with developmental deficiency of vitamin A or retinoic acid, as described in animal models.     

The position of the left and right ventricular outlets during septation

Summary A comparative study was made of the relative position of the outflow tracts of chicken and rat hearts with respect to the ventricles during septation. For this purpose the position of the left and right ventricular outlet including the aortic and pulmonary valve primordia and the left and right ventricle were established with respect to the midsagittal plane of the embryo, using reconstructions of serial sections of chicken (stage 28–30) and rat (stage 28–30) embryos. In the chicken embryo no rotation of the outflow tract occurs, i.e. the position of the aortic and pulmonary valve primordia with respect to the left and right ventricle remains the same. In the rat embryo a clockwise rotation of the aortic and pulmonary valve primordia with respect to the ventricles does occur. This is in fact a detorsion. The left and right ventricle and the left ventricular outlet do not show change in position with regard to the midsagittal plane. The left ventricular outlet always straddles the interventricular septum, both lying in the midsagittal plane. These interspecies differences in the degree of detorsion of the outflow channels before septation may explain the differences in the extent of the region of contact between the endocardial outflow tract ridges.     

Characterization of conotruncal malformations following ablation of “cardiac” neural crest

Neural crest cells from the cranial region of the neural fold populate the outflow tract of the developing chick heart. Removal of this region of premigratory neural crest has been shown previously to result in a high percentage of conotruncal malformations. The present study was undertaken to define more precisely the regions of premigratory neural crest which are needed for normal conotruncal development. Various regions and lengths of premigratory cranial neural crest were ablated using microcautery. Three defects in conotruncal development were significantly correlated with the neural crest ablation. These were high venticular septal defect, single outflow vessel originating from the right ventricle, and single outflow vessel overriding the ventricular septum.     

Characterization of conotruncal malformations following ablation of "cardiac" neural crest

Neural crest cells from the cranial region of the neural fold populate the outflow tract of the developing chick heart. Removal of this region of premigratory neural crest has been shown previously to result in a high percentage of conotruncal malformations. The present study was undertaken to define more precisely the regions of premigratory neural crest which are needed for normal conotruncal development. Various regions and lengths of premigratory cranial neural crest were ablated using microcautery. Three defects in conotruncal development were significantly correlated with the neural crest ablation. These were high ventricular septal defect, single outflow vessel originating from the right ventricle, and single outflow vessel overriding the ventricular septum.     

Revisiting the anatomy of the right ventricle in the light of knowledge of its development

Controversies continue regarding several aspects of the anatomy of the morphologically right ventricle. There is disagreement as to whether the ventricle should be assessed in bipartite or tripartite fashion, and the number of leaflets to be found in the tricuspid valve. In particular, there is no agreement as to whether a muscular outlet septum is present in the normally constructed heart, nor how many septal components are to be found during normal development. Resolving these issues is of potential significance to those investigating and treating children with congenitally malformed hearts. With all these issues in mind, we have revisited our own experience in investigating the development and morphology of the normal right ventricle. To assess development, we have examined a large number of datasets, prepared by both standard and episcopic microscopy, from human and murine embryos. In terms of gross anatomy, we have compared dissections of normal autopsied hearts with virtual dissections of datasets prepared using computed tomography. Our developmental and postnatal studies, taken together, confirm that the ventricle is best assessed in tripartite fashion, with the three parts representing its inlet, apical trabecular, and outlet components. The ventricular septum, however, has only muscular and membranous components. The muscular part incorporates a small component derived from the muscularised fused proximal outflow cushions, but this part cannot be distinguished from the much larger part that is incorporated within the free-standing muscular infundibular sleeve. We confirm that the tricuspid valve itself has three components, which are located inferiorly, septally, and antero-superiorly.     

Remodeling of the Embryonic Interventricular Communication in Regard to the Description and Classification of Ventricular Septal Defects

Ventricular septal defects are the commonest congenital cardiac malformations. Appropriate knowledge of the steps involved in completion of ventricular septation should provide clues as to the morphology of the different phenotypes. Currently, however, consensus is lacking regarding the components of the developing ventricular septum, and how best to describe the different phenotypes seen in postnatal life. We have reassessed the previous investigations devoted to closure of the embryonic interventricular communication. On this basis, we discuss how studies in the early part of the 20th century correctly identified the steps involved in the remodeling of the embryonic interventricular foramen subsequent to the stage at which the outflow tract arises entirely above the cavity of the developing right ventricle. There has, however, already been remodeling of the foramen from the stage at which the atrioventricular canal is supported exclusively by the developing left ventricle. We show how these temporal changes in morphology can provide explanations for the different ventricular septal defects seen in the clinical setting. Thus, muscular defects represent inappropriate coalescence of muscular ventricular septum. The channels that are perimembranous are due to failure of closure of the persisting embryonic interventricular foramen. Those that are doubly committed and juxta-arterial reflect failure of formation of the free-standing subpulmonary muscular infundibular sleeve. The findings also point to the importance of appropriate alignment, during development, between the developing atrial and ventricular septums, and between the apical component of the ventricular septum and the ventricular outlet components. Anat Rec, 302:19–31, 2019. © 2018 Wiley Periodicals, Inc.     

Cardiac laterality and ventricular looping in retinoic acid-treated rat embryos.

To determine the ventricular looping pattern in relation to cardiac laterality, we studied rat embryos treated with retinoic acid (RA). A total of 243 Wistar rat embryos from an in vivo treated group (a single dose of 20-40 mg/kg all-trans RA administered to pregnant rats on day 6.5 to 9.5) and 29 control embryos were examined on day 13 of gestation. Twenty-nine embryos from the in-vitro treated group (treated by all-trans RA at 2 x 10(-7) M for 6 hr on day 9.0 or 9.5 during the entire embryo culture for 72 hr) and seven control embryos were examined on day 12 of gestation. Abnormalities in cardiac laterality and ventricular looping were found in the in-vivo groups treated on day 8.5 and 8.75 and in the in-vitro group on day 9.0. Among 25 animals with abnormal laterality, right isomerism was the most common feature (22 cases), while the type of ventricular looping varied. Cases with normal laterality had a low incidence of abnormal looping (1.4%). In rat embryos treated with all-trans RA, normal cardiac looping was expected when cardiac laterality was normal. But in cases with abnormal laterality, the type of abnormal ventricular looping was unexpected.     

Clinically diverse and perinatally lethal syndromes with urorectal septum malformation sequence

Urorectal septum malformation sequence (URSMS) is characterized by a spectrum of anomalies of the urogenital system, hindgut and perineum. It is presumed to be a constellation of an embryonic defect. Herein, we analyzed the clinically diverse syndromes associated with URSMS in our perinatal evaluation unit. We reviewed fetuses with URSMS in referrals for perinatal autopsy over a period of 3 years. Chromosomal microarray and genome sequencing were performed whenever feasible. Literature was reviewed for syndromes or malformations with URSMS. We ascertained URSMS in 12 of the 215 (5%) fetuses. Nine fetuses (75%) had complete URSMS and remainder had partial/intermediate URSMS. Eleven fetuses had malformations of other systems that included: cerebral ventriculomegaly; right aortic arch with double outlet right ventricle; microcephaly with fetal akinesia deformation sequence; ventricular septal defect and radial ray anomaly; thoraco-abdominoschisis and limb defects; myelomeningocele; spina bifida and fused iliac bones; omphalocele; occipital encephalocele; lower limb amelia and cleft foot. We report on six fetuses with recurrent and five fetuses with unique malformations/patterns where URSMS is a component. Exome sequencing (one family) and genome sequencing (eight families) were performed and were nondiagnostic. Additionally, we review the literature for genetic basis of this condition. URMS is a clinically heterogeneous condition and is a component of several multiple malformation syndromes. We describe several unique and recurrent malformations associated with URSMS.