| Abstract|| |
We present three unusual cases of total anomalous systemic venous drainage (TASVD) where all the systemic veins were abnormally connected to the atrium that drained into the left ventricle (LV). All three patients had features consistent with left atrial isomerism. Based on the available evidence and review of literature we propose that TASVD be included as a part of the syndrome of left atrial isomerism. A classification for TASVD is also proposed with surgical implications.
Keywords: Heterotaxy syndrome, left isomerism, total anomalous systemic venous drainage
|How to cite this article:|
Awasthy N, Radhakrishnan S, Kaushal S, Sharma R. Total anomalous systemic venous drainage to the left atrium: An entity reviewed and investigated. Ann Pediatr Card 2014;7:98-102
|How to cite this URL:|
Awasthy N, Radhakrishnan S, Kaushal S, Sharma R. Total anomalous systemic venous drainage to the left atrium: An entity reviewed and investigated. Ann Pediatr Card [serial online] 2014 [cited 2019 Sep 21];7:98-102. Available from: http://www.annalspc.com/text.asp?2014/7/2/98/132476
| Introduction|| |
Total anomalous systemic venous drainage (TASVD) is an exceptional form of congenital heart disease, wherein all systemic venous flow, including the right superior vena cava (RSVC), persistent left SVC (LSVC), inferior vena cava (IVC) (which may be interrupted), and coronary sinus, drain into the atrium draining into the morphologic left ventricle (LV). We describe three patients of this rare entity. Available literature is reviewed and a classification proposed.
| Case Reports|| |
A 5-year-old girl was admitted to our hospital for evaluation of mild cyanosis with a room air oxygen saturation of 86%. There was no evidence of congestive heart failure. Her height and weight both ranked in the 90 th percentile. Echocardiography revealed left atrial isomerism [Figure 1]. There was ventriculo-arterial concordance. Left atrium and LV were dilated (LV end diastolic Z score +2.8) [Figure 2]. The branch pulmonary arteries were normal in size. All the pulmonary veins and systemic veins including the hepatic veins drained into the left-sided atrium and connected to the LV. A sizable fossa ovalis atrial septal defect was seen. The aortic arch was right sided (the features have been highlighted in [Table 1]. Findings were confirmed by computerized tomography (CT) scan [Figure 3], [Table 2], [Table 3]. The child underwent biventricular repair via an atrial septation and a baffle, which routed venous drainage to appropriate ventricles. At surgery, both atrial appendages were left sided in morphology. At 1-year follow-up, the child was doing well with normal oxygen saturation and unobstructed systemic venous drainage.
|Figure 1: Two-dimensional (2D) echocardiography with substernal coronal view showing the relationship of the aorta and inferior vena cava (IVC) suggestive of left isomerism|
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|Figure 2: 2D echocardiography with four-chamber apical view showing dilated left atrium and left ventricle. This image is suggestive of left ventricle volume overload (in case 1)|
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|Figure 3: Computerized tomography (CT) of case 1 with coronal view showing the drainage of left superior vena cava (LSVC) and the hepatic veins into the left atrium|
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|Table 1: Echocardiographic features of the three patients with Total Anomalous Systemic Venous Drainage (n = 3)|
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|Table 2: Ultrasonological and computerized tomography (CT) scan profile of our patients (N = 3)|
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A 5-year-old child was observed to have cyanosis (oxygen saturation of 68%). There was no evidence of congestive heart failure. Echocardiography showed left isomerism with levocardia. There was a large atrial septal defect that shunted from left to right. The IVC was interrupted and left and RSVC drained into the left-sided atrium. All the four pulmonary veins formed a confluence and also drained to the left sided atrium. There was double outlet of the right ventricle (RV) with side-by-side great vessels. Nonrestrictive perimembranous ventricular septal defect was routable to aorta, with bidirectional shunting. Aortic arch was right sided. There was severe pulmonary stenosis with confluent and normal branch pulmonary artery sizes. CT scan confirmed the echocardiographic findings [Figure 4]a and b [Table 2], [Table 3]. The child underwent successful LV to aorta tunneling with an RV to pulmonary artery conduit along with atrial septation. Morphology of both the atrial appendages at surgery was left sided.
|Figure 4: (a) 3D reconstructive CT images of case 2 showing the drainage of bilateral SVC and IVC in the left-sided atrium. (b) The same image as observed from the posterior aspect shows drainage of pulmonary veins in the same chamber (left sided atrium) as that of the systemic veins|
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A 2-year-old boy was incidentally found to be cyanotic with oxygen saturation of 75%. Echocardiographic examination showed left atrial isomerism with pulmonary veins draining to the left-sided atrium. Hepatic vein and bilateral SVC also drained to the left-sided atrium. The IVC ascended on the right of the spine, but crossed the midline and drained to the left sided atrium. There was a small fossa ovalis atrial septal defect with left to right shunt, ventriculo-arterial concordance, D-loop ventricles, and confluent and adequate sized branch pulmonary arteries. The RV was hypoplastic and bipartite. Ventricular function was normal (elaborated under [Table 1]). CT scan showed a midline liver with polysplenia, with associated agenesis of the tail of the pancreas [Table 2]. Rest of the cardiac findings was same as that described in echocardiographic evaluation [Figure 5]a and b. The child underwent bidirectional Glenn shunt and atrial septectomy with banding of the main pulmonary artery. He has been doing well at 4 years follow-up and is now planned for Fontan conversion.
|Figure 5: (a) 3D reconstructive images of the patient (case 3) showing IVC interruption and its continuation as azygous and drainage into the right SVC (RSVC). Note also the drainage of the LSVC into the same chamber. (b) Shows the same image from the anterior aspect showing drainage of pulmonary veins also in the left-sided atrial chamber as that of the systemic veins|
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| Discussion|| |
TASVD defies the guiding rule that the drainage of IVC serves as a reliable indicator for the chamber to be classified as right atrium. Although one exceptional case was reported where all systemic venous blood returned to the coronary sinus,  the openings of total anomalous systemic veins are much more commonly connected to the left atrium. ,,,,,,,,
All of our cases had features consistent with left isomerism. Literature review provides 14 cases of TASVD [Table 4]. Five of the seven cases reported in the recent literature (after 1980, when the concept of isomerism was described) had features of left isomerism. Thus, it would be reasonable to suggest that the diagnosis of TASVD in any patient should be pointer to the presence of left isomerism. The lack of commitment regarding features of isomerism prior to 1980 is probably on account of the lack of awareness of the concept of isomerism prior to the period 12 (the same has been highlighted in [Table 4]).
|Table 4: Comparison and evaluation of the reported cases of total anomalous systemic venous connection|
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Most of the cases were elegantly compiled by Zhang et al., and the present review owes much to their contribution.  We propose a modification of Zhang's classification of TASVD. This has implication in planning cardiopulmonary bypass for the surgical management of the lesion. There are three subsets of TASVD, based on the site of drainage of IVC. These may be further subdivided into type A and B based on the site of drainage of hepatic veins. Extending the proposed classification by Zhang et al., who classified TASVD into two types, according to the type of vena cava cannulation we would like to add a third type. In type I, the IVC is not interrupted and conventional cardiopulmonary bypass can be instituted. In type II, the IVC is interrupted, and single cannulation of the SVC would suffice for venous drainage. In type 3: With IVC drainage to an accessory chamber like coronary sinus. The accessory chamber may be cannulated or total circulatory arrest instituted for adequate visualization. These three types are further subdivided into type A where the hepatic veins too drained separately to the left-sided atrium and type B where the hepatic veins would drain to an alternative site and need to be specifically looked for.
Proposed classification (modified from Zhang et al.):
- IVC to left-sided atrium: Type 1
- IVC interruption: Type 2
- IVC to accessory chamber (like coronary sinus): Type 3
- Type A: Hepatic veins to left-sided atrium
- Type B: Hepatic veins to other site
The embryologic basis is hypothesized as follows. TASVD may occur because of the failure of regression of the right valve of systemic venous sinus (sinus venosus) or because of the systemic venous sinus being incorporated into the left atrium. As for the clinical presentation, these systemic venous anomalies are a rare cause of cyanotic congenital heart disease, with unremarkable precordial examination. Associated cardiac lesions predominantly dictate the clinical features.
Hemodynamically, the left atrium forms the mixing chamber in the circuit, and hence, similar to the case of a total anomalous pulmonary venous drainage, oxygen saturation is equal in all the chambers. Although echocardiography is able to delineate most of the observations, a CT scan helps confirm drainage of all veins concerned to facilitate surgical intervention.
Surgical intervention is guided by associated cardiac morphology. In the presence of isolated TASVD, atrial septation with appropriate routing of veins suffices. In the presence of associated lesions a more complex intracardiac repair with rerouting of the veins may be done. In the presence of associated extreme ventricular imbalance, a univentricular pathway may need to be resorted to.
All three of our cases had bilateral left atrial appendages. Available literature does not always comment on atrial morphology. Hence in such cases, it was impossible to decide laterality, or the lack of it. However, most described cases of TASVD do gravitate into bilateral left sidedness. On the basis of this experience and review of literature, we suggest that that presence of TASVD indicates a strong likelihood of left isomerism.
| Acknowledgment|| |
Mr. Vinay Kumar (CT technician) for 3D reconstructive images.
| References|| |
|1.||Kadletz M, Black MD, Smallhorn J, Freedom RM, Van Praagh S. Total anomalous systemic venous drainage to the coronarysinus in association with hypoplastic left heart disease: More than a mere coincidence. J Thorac Cardiovasc Surg 1997;114:282-4. |
|2.||Krayenbuhl CU, Lincoln JC. Total anomalous systemic venous connection, common atrium, and partial atrio-ventricular canal. A case report of successful surgical correction. J ThoracCardiovasc Surg 1977;73:686-9. |
|3.||Danielson GK, McMullan MH, Kinsley RH, DuShane JW. Successfulr epair of complete atrioventricular canal associated with dextroversion, common atrium, and total anomalous systemic venous return. J Thorac Cardiovasc Surg 1973;66:817-22. |
|4.||Johnson TR, Schamberger MS, Brown JW, Girod DA. Resolution of acquired pulmonary arteriovenous malformations in a patient with total anomalous systemic venous return. Pediatr Cardiol 2002;23:210-2. |
|5.||Roberts KD, Edwards JM, Astley R. Surgical correction of total anomalous systemic venous drainage. J Thorac Cardiovasc Surg 1972;64:803-10. |
|6.||Gueron M, Hirsh M, Borman J. Total anomalous systemic venous drainage into the left atrium. Report of a case of successful surgical correction. J Thorac Cardiovasc Surg 1969;58:570-4. |
|7.||Miller GA, Ongley PA, Rastelli GC, Kirklin JW. Surgical correction of total anomalous systemic venous connection: Report of case. Mayo Clin Proc 1965;40:532-8. |
|8.||Viart P, Le Clerc JL, Primo G, Polis O. Total anomalous systemic venous drainage. Am J Dis Child 1977;131:195-8. |
|9.||Turkoz R, Ayabakan C, Vuran C, Omay O. Intraatrial baffle repair of anomalous systemic venous return without hepatic venous drainagein heterotaxy syndrome. Pediatr Cardiol 2010;31:865-7. |
|10.||Barrea C, Biard JM, Hutchings G, Bernard P. Prenatal diagnosis of isolated total anomalous systemic venous return to the coronary sinus. Ultrasound Obstet Gynecol 2010;35:117-9. |
|11.||Khandenahally RS, Deora S, Math RS. Total anomalous systemic venous drainage in left hetrotaxy syndrome. Cardiol Young 2013;23:284-6. |
|12.||Van Praagh S, Kreutzer J, Alday L, Van Praagh R. Systemic and pulmonary venous connection in visceral hetrotaxy, with emphasis on the diagnosis of the atrial situs: A study of 109 postmortem cases. In: Clark EB, Takao A, editors. Developmental Cardiology: Morphogenesis and function. New York: Futura Publishing; 1990. p. 671-727. |
|13.||Zhang ZW, Duan QJ, Gao Z, Ru W, Ying LY. Total anomalous systemic venous drainage to the left atrium. Ann Thorac Surg 2009;87:1599-601-13. |
|14.||Pearl WR and Spicer MJ. Total anomalous systemic venous return. South Med J 1980;73: 259-61. |
|15.||Lazzarin O, De Rossi R. Total anomalous systemic venous drainage. A case report. Surgical considerations. Revista Argent Card 2009;77:5-6. |
Consultant, Department of Pediatric Cardiology, Fortis Escorts Heart Institute, Okhla Road, New Delhi - 110 025
Source of Support: None, Conflict of Interest: None
[Figure 1], [Figure 2], [Figure 3], [Figure 4], [Figure 5]
[Table 1], [Table 2], [Table 3], [Table 4]