Options for surgical repair in hearts with univentricular atrioventricular connection and subaortic stenosis.

Thirteen patients have undergone surgical treatment because of subaortic obstruction in hearts with a univentricular atrioventricular connection. Nine patients underwent surgical enlargement of the ventricular septal defect and four patients had construction of an aortopulmonary anastomosis and closure of the pulmonary trunk (the Damus-Kaye-Stansel procedure). Two patients undergoing enlargement of the septal defect and two having the Damus-Kaye-Stansel procedure also had a modified Fontan procedure. One patient had complete atrioventricular dissociation after direct enlargement of the ventricular septal defect, which necessitated insertion of an epicardial pacemaker. One patient died within 30 days of the operation after enlargement of the defect and two patients after the Damus-Kaye-Stansel procedure. There was one late death, occurring in a patient who underwent enlargement of the ventricular septal defect. Ten patients have subsequently undergone conventional cardiac catheterization and angiography or transcutaneous Doppler flow studies to assess the relief of the subaortic obstruction. The result has been satisfactory in all. Because of this experience, we now recommend direct surgical enlargement of the restrictive ventricular septal defect for direct relief of subaortic stenosis occurring with a univentricular atrioventricular connection to a dominant left ventricle, inasmuch as it appears to be hemodynamically effective with a low operative mortality and morbidity. The Damus-Kaye-Stansel procedure can also have a role in relieving subaortic stenosis when the atria are connected to a dominant right ventricle.     

Univentricular atrioventricular connection with subaortic stenosis: a staged surgical approach.

A staged surgical approach was developed for the management of hearts with univentricular atrioventricular connection (double-inlet left ventricle or tricuspid atresia) and discordant ventriculoarterial connection with anatomical substrate for the development of subaortic stenosis. This consisted of initial palliation with pulmonary artery banding, followed by early elective relief of subaortic obstruction using a proximal pulmonary artery to ascending aorta anastomosis in infancy. Pulmonary blood flow was maintained at this time by creating a bidirectional superior cavopulmonary anastomosis. Over an 18-month period, 5 children, including 4 seen in the first week of life with aortic arch obstruction, were palliated with this approach. All patients survived operation and are asymptomatic with transcutaneous oxygen saturations of 80% to 85%. Completion of cavopulmonary repair is planned at 2 years of age. Although some authors have considered pulmonary artery banding contraindicated in these infants, the current staged approach offers an attractive alternative to the construction of a pulmonary artery to aorta anastomosis in the neonatal period.     

Efficacy of Damus-Kaye-Stansel procedure in patients with univentricular heart associated with ventriculo-arterial discordance and excessive pulmonary blood flow

Pulmonary artery banding (PAB) and ventriculo-arterial discordance (VAD) were reported to be risk factors of subaortic stenosis in univentricular heart. The aim of this study was to evaluate efficacy of Damus-Kaye-Stansel (DKS) anastomosis. Of all 89 patients undergoing total cavo-pulmonary connection (TCPC) in our center since April 1996, 38 had VAD with high pulmonary blood flow, and had received PAB. Twenty-one of 38 had undergone DKS anastomosis due to subaortic stenosis or due to morphological hypertrophy of the outlet septum (DKS group); the other 17 had not yet (no-DKS group). Percentage end-systolic volume of the systemic ventricle and percentage subaortic lesion in both groups significantly decreased after TCPC (P<0.01). Pressure gradient across systemic outflow tract after TCPC was low in both groups at rest. The gradient in DKS group did not differ from those in control group with ventriculo-arterial concordance (VAC) (P>0.1). Ventricular outflow tract after DKS anastomosis might behave like that of VAC even when dobutamine is loaded, suggesting that the anastomosis should be carried out in many patients with this entity even if stenosis across systemic ventricular outflow is not significant, considering possible stenosis in the future.     

Operations for subaortic stenosis in univentricular hearts

Optimal prevention and treatment of subaortic stenosis (SAS) in the univentricular heart with subaortic outlet chamber and high pulmonary blood flow remains controversial, especially when complicated by aortic arch obstruction. Herein we analyze our surgical results. Group 1 consisted of 11 infants (mean age, 10 days) with univentricular heart and SAS. Ten required repair of interrupted aortic arch (n = 7) or coarctation with hypoplastic arch (n = 7). Four patients had relief of SAS by either Damus-Kaye-Stansel connection (n = 2) or aortopulmonary window (n = 2), with three operative deaths and one late death. Six had one-stage arterial switch and atrial septectomy with arch repair (5/6) with one operative death and one late death. Two survivors have progressed to bidirectional cavopulmonary shunt, a third has had a Fontan operation, and a fourth awaits Fontan. In group 2, 11 children required operation for acquired SAS after pulmonary artery banding. Nine have progressed to Fontan operation with either staged (n = 3) or concurrent (n = 6) relief of SAS by Damus-Kaye-Stansel connection or subaortic resection. Fontan mortality was 11% (70% confidence limits, 2% to 32%). Group 3 consisted of 3 patients without pulmonary artery banding who had SAS diagnosed at Fontan evaluation. All 3 survived Fontan operation and relief of SAS by Damus-Kaye-Stansel connection or subaortic resection. Group 4 consisted of 1 patient with previous pulmonary artery banding (no SAS) who underwent Fontan operation but required Damus-Kaye-Stansel connection 30 months later for SAS.(ABSTRACT TRUNCATED AT 250 WORDS)     

Surgical treatment of interrupted aortic arch in infants under three months of age

From March, 1982, through March, 1988, 8 infants less than 3 months of age underwent surgical treatment of interrupted aortic arch. Five patients had IAA type A and 3 patients had type B. Seven patients with associated VSD underwent staged operations and 1 infant with aortopulmonary window underwent primary repair off cardiopulmonary bypass. Aortic arch reconstruction was by subclavian aortic anastomosis (6) or large tube graft (8 mm) interposition (2) combined with pulmonary artery banding (5). All seven patients with associated VSD survived the first-stage operation. One patient subsequently underwent pulmonary artery banding, two underwent patch aortoplasty and four patients underwent intracardiac repair and removal of a pulmonary artery band, with six survivors (86%). The operative death occurred in an infant in whom modified Damus-Kaye-Stansel operation was carried out for severe subaortic stenosis, which rerouting all left ventricular blood through VSD and the main pulmonary artery into the ascending aorta and reconstructing right ventricular-distal pulmonary artery connection by a valved external conduit. All six surviving patients are doing well at present (mean follow up of 3 years) without any significant pressure gradient between the ascending and thoracic aorta. Based on these data we conclude: (1) Aortic arch reconstruction and pulmonary artery banding can be reliably performed even in critically ill infants with IAA and isolated VSD. (2) The primary repair will provide better chance of survival in infants with IAA associated with significant LVOTO, truncus arteriosus or aortopulmonary window that do not readily lend themselves to pulmonary artery banding.     

Long-term results of relief of subaortic stenosis in univentricular atrioventricular connection with discordant ventriculoarterial connections

BACKGROUND: We set out to examine the long-term results of relief of subaortic stenosis by enlargement of ventricular septal defect in patients with univentricular atrioventricular connection to a dominant left ventricle and discordant ventriculoarterial connections. METHODS: Twenty-four patients underwent enlargement of ventricular septal defect between 1985 and 1998 at a median age of 3.2 years (range, 3 weeks to 14 years). Ten patients were younger than 1 year of age. Eighteen had undergone previous banding of the pulmonary trunk, 9 of whom also required repair of coarctation of the aorta. The median subaortic gradient before enlargement was 46 mm Hg. Twenty-three patients had a patch to enlarge the rudimentary right ventricle. RESULTS: Five patients (21%) died in the early postoperative period. The overall survival at 1 and 3 years was 73%, and at 5 and 10 years was 68% and 60%, respectively. Complete heart block requiring insertion of a pacemaker occurred in 2 patients (8%). A Fontan operation was performed in 10 patients, 5 underwent a bidirectional Glenn procedure, and 2 required cardiac transplantation. Follow-up was complete in all survivors at a median time of 6.7 years (range, 8 months to 13 years). From the earlier part of the series, 3 patients experienced aortic insufficiency and 2 had recurrent obstruction. Factors adversely affecting survival were age younger than 1 year at operation and presence of obstruction within the aortic arch. CONCLUSIONS: Our experience shows that, in patients with univentricular atrioventricular connection to a dominant left ventricle and subaortic stenosis, enlargement of the ventricular septal defect provides satisfactory relief of obstruction except in those younger than 1 year of age, and those who have associated obstruction in the aortic arch.     

Early palliation of univentricular hearts with subaortic stenosis and ventriculoarterial discordance. The arterial switch option.

The optimal Fontan-type operation greatly depends on appropriate initial palliation. Several surgical techniques have been used in infancy to palliate patients with univentricular hearts, ventriculoarterial discordance, and subaortic stenosis. The two most common are pulmonary artery banding and Damus-Norwood procedures. Palliative arterial switch operation is another surgical option that was used in this early series of seven infants. The principle of this operation is to "switch" the subaortic obstruction into a subpulmonary obstruction; the coronary artery relocation on the large pulmonary trunk creates a harmonious aortic root and the connection of the rudimentary ventricular chamber to the pulmonary artery trunk creates a natural protection of the pulmonary vascular bed through the restrictive bulboventricular foramen. Seven infants with univentricular hearts, ventriculoarterial discordance, and subaortic stenosis underwent a palliative arterial switch operation. All infants had an associated aortic arch obstruction of various degrees, including one with interrupted aortic arch, five with coarctation with severe arch hypoplasia, and one with isolated arch hypoplasia. There were three with double-inlet left ventricle, three with tricuspid atresia, and one with transposition of the great arteries with ventricular septal defect and severe right ventricular hypoplasia. The subaortic obstruction was patent at birth in five patients who underwent a palliative switch operation in the first 2 months of life, and rapidly occurred following a previous neonatal pulmonary artery banding associated with arch repair in two patients who underwent a switch operation at 5 and 8 months of age, respectively. The operation includes aortic arch repair without prosthetic material, an atrial septectomy, and the arterial switch. An associated pulmonary shunt was required in five patients and a pulmonary artery banding in one. There was one early death in a patient with [S,L,L] anatomy and congenital atrioventricular block, leading to an early mortality of 14% (95% confidence limits: 1% to 28%). There was one late death. Four survivors are waiting for a Fontan-type procedure, and one survivor had satisfactory right ventricular growth. Early palliative arterial switch operation offers several advantages: reconstruction of a harmonious aortic root, natural protection of the pulmonary bed through the restrictive bulboventricular foramen, prevention of deleterious myocardial hypertrophy, and arch reconstruction without the introduction of a foreign material. This aggressive technique may provide a satisfactory palliation in infants with univentricular hearts and ventriculoarterial discordance, when the bulboventricular foramen/aortic anulus ratio is less than 0.8 or when the subaortic stenosis is severe enough to be associated with an arch obstruction.(ABSTRACT TRUNCATED AT 400 WORDS)     

Single ventricle (single- or double-inlet) complicated by subaortic stenosis: surgical options in infancy

Intracardiac obstruction to the systemic circulation can develop in patients with many forms of congenital heart disease. When transposition of the great arteries accompanies tricuspid atresia, narrowing of the ventricular septal defect (VSD) leads to subaortic stenosis. In a similar fashion, a restrictive bulboventricular foramen compromises systemic arterial outflow in patients who have single left ventricle with subaortic outflow chamber. The same effect can be seen in VSD closure in mitral atresia with normally related great vessels. Although some forms of single ventricle can be treated by ventricular septation, the modified Fontan procedure can be more generally applied to this entity. Pulmonary vascular resistance must be low, however, which excludes the application of the Fontan principle in infants. While pulmonary artery banding may protect the lungs from the development of excessive pulmonary vascular resistance, it may also accelerate the development of subaortic obstruction. We have successfully applied the Norwood operation, as described for hypoplastic left heart syndrome, to palliate subaortic stenosis due to restrictive VSD in 3 infants with single ventricle or atrioventricular valve atresia. Consideration should be given to a primary Norwood procedure in infants with single ventricle in whom subaortic stenosis is likely to develop. Patients who do receive pulmonary artery bands should be followed closely for the development of subaortic stenosis and should undergo an early, physiologically corrective operation if it occurs.     

Damus-Kaye-Stansel connections in children with previously transected pulmonary arteries

BACKGROUND: In patients with a univentricular arteriovenous connection, transection of the main pulmonary artery may be performed as part of a bidirectional cavopulmonary shunt or Fontan procedure. The proximal stump of the pulmonary artery may remain in the systemic circulation. In cases with a discordant ventriculoarterial connection, subsequent restriction of the bulboventricular foramen may lead to subaortic stenosis. The subaortic stenosis can be corrected in some patients by directing the systemic flow through a combined nonobstructed aortopulmonary outlet, as in the Damus-Kaye-Stansel connection. Previous closure of the pulmonary artery has been considered by some investigators to be a relative contraindication to the Damus-Kaye-Stansel procedure, unless an allograft root can be added to the circuit after excision of the closed pulmonary stump. METHODS: Three patients with previously transected pulmonary arteries underwent a modified Damus-Kaye-Stansel connection using the native pulmonary valve and the proximal pulmonary artery stump. RESULTS: The native pulmonary valves have functioned well despite thrombus formation in the proximal stump in 2 patients before Damus conversion. All 3 patients are alive and well after 108, 19, and 3 months, with competent nonobstructed ventriculoarterial connections. CONCLUSIONS: If transection and closure of the pulmonary artery as part of a previous palliation has spared the pulmonary valve, then the native pulmonary outlet might be used for a safe Damus-Kaye-Stansel connection.     

Surgical management of univentricular heart with subaortic obstruction

In children with a univentricular heart and a rudimentary subaortic chamber, surgical relief of subaortic obstruction caused by a restrictive bulboventricular foramen is associated with high morbidity and mortality. A 6-year-old child with a univentricular heart of the left ventricular type, a rudimentary subaortic chamber, and atresia of the left-sided atrioventricular valve had pulmonary artery banding in infancy. Severe subaortic obstruction subsequently developed. At operation, the pulmonary artery was transected and the stump was anastomosed directly to the posterior aspect of the ascending aorta, diverting left ventricular blood into the aorta through the pulmonary valve. The distal pulmonary artery was anastomosed side-to-side to the ascending aorta to provide pulmonary blood flow. Cardiac catheterization fifteen months after the operation demonstrated an excellent hemodynamic result. When the pulmonary artery is adequate in size, a bypass operation by way of an anastomosis between the ascending aorta and the pulmonary artery is a relatively safe and effective means of relieving the ventricular outflow obstruction caused by a restrictive bulboventricular foramen.     

Surgical Treatment of Double Inlet Ventricle ("Single Ventricle")

The surgical techniques described are the result of an evolution over a number of years in the performance of the septation operation and the modified Fontan-Kreutzer repair for patients with double inlet ventricles. Those with associated pulmonary stenosis are best palliated by a classical Blalock-Taussig or Goretex shunt if an operation is required during the first few years of life and later, between two and four years of age, definitive repair by the modified Fontan-Kreutzer operation is advised. Although controversial, we prefer the use of a large nonvalved right atrial-pulmonary artery connection. Ventricular septation remains the best definitive surgical option when pulmonary stenosis is absent or mild. It is contraindicated by severe pulmonary vascular disease and also by less than moderate ventricular enlargement. The need for concomitant AV valve replacement and the use of an extracardiac conduit are associated with increased hospital mortality in our experience. Infants identified during the first year of life who do not have pulmonary stenosis are a difficult subset to manage. If the VSD and subaortic area is large and unobstructed, pulmonary artery banding early in life will control pulmonary vascular resistance and from this standpoint, permit these patients to become ultimately suited to a modified Fontan-Kreutzer repair. Unfortunately, ventricular hypertrophy usually results from pulmonary artery banding and has been associated with higher hospital mortality at the time of definitive repair. When pulmonary artery banding is undertaken for this subset, debanding and definitive repair seems best advised at about two years of age. Pulmonary artery banding is well known to accelerate the development of subaortic stenosis by spontaneous progressive restriction of the VSD. This results in small ventricular cavity size and increased ventricular hypertrophy, which are incremental risk factors for increased hospital mortality by either definitive procedure. When the VSD or subaortic area is narrow and the patient is identified during the first year of life, isolated pulmonary artery banding is inappropriate. The surgical options for these patients include Ebert's two-stage management program consisting of the initial placement of a loose partial septation patch with concomitant pulmonary artery banding, and later debanding and complete septation. Alternatively, a trial of primary complete septation may be warranted, or the use of a procedure consisting of division of the main pulmonary artery with distal closure and anastomosis of the proximal portion to the side of the ascending aorta, coupled with a systemic-pulmonary artery shunt.     

A reconsideration of risk factors for the Fontan operation.

We reviewed our experience in 38 patients who underwent a Fontan operation. In the first five patients ages 7.5 to 23 years (mean, 15 years), a conduit was placed from the right atrium to the small right ventricle or the pulmonary artery (PA). The remaining 33 patients, ages 7 months to 14 years (mean, 4.8 years), had a modified Fontan operation with direct systemic venous or right atrial to PA anastomosis. The diagnoses were tricuspid atresia (n = 14), single ventricle (n = 10), hypoplastic right or left ventricle (n = 9), double-outlet right ventricle with inlet ventricular septal defect and pulmonary atresia or stenosis (n = 3), criss-cross ventricles and transposition of the great arteries (n = 1), and atrioventricular canal and anomalous pulmonary venous connection (n = 1). Thirty-two patients had previous surgery. Other procedures included PA banding (n = 7), systemic to PA shunts (n = 25), Norwood operation (n = 3), and a Damus-Kaye-Stansel anastomosis (n = 1), repair of total anomolous pulmonary venous connection (n = 1), a Blalock-Hanlon atrial septectomy (n = 1), and enlargement of a restrictive ventricular septal defect (n = 1). There were four operative deaths (10.5%), three from low cardiac output and one from subaortic obstruction. There were no deaths in patients younger than 3 years of age (n = 13). Subaortic obstruction developed in six of the seven patients who had pulmonary artery banding and resulted in three deaths. In our experience, diagnosis, previous surgery, type of previous operation, PA pressure, and younger age are not risk factors for early or late death. Subaortic obstruction is a major risk factor for late death. Accordingly we now perform a Damus-Kaye-Stansel anastomosis combined with a systemic to PA shunt in those children with excessive pulmonary blood flow who anatomically are likely to develop subaortic obstruction. A modified Fontan operation can be performed any time after 1 year of age and in some patients after 6 months of age, providing the anatomy and physiology of the patient are acceptable.     

Transposition of the great arteries with straddling tricuspid valve. Report of two rare cases with acquired subaortic stenosis after main pulmonary artery banding

The clinical, hemodynamic, angiocardiographic, and postmortem findings of a previously unreported type of subaortic stenosis are presented in two patients who also had straddling tricuspid valve and transposition of the great arteries. The subaortic stenosis became apparent after banding of the main pulmonary artery and was due to hypertrophy of a probably abnormally positioned moderator band resulting in a double-chambered right ventricle. Fibrous tissue accumulation at the stenotic os infundibuli also contributed to the subaortic obstruction. Both patients had situs solitus of the atria. Patient 1 had ventricular inversion (L-loop ventricles) and atresia of the right-sided mitral valve. Patient 2 had normally positioned ventricles (D-loop) and two atrioventricular valves. The presence of a large left ventricle and a small right ventricle in the angiocardiogram led to the erroneous diagnosis of a single left ventricle with an infundibular outlet chamber in both patients. Consequently, the subaortic obstruction was thought preoperatively to be at the site of a restrictive bulboventricular foramen. Patient 1 died 36 hours after placement of a valved conduit from the left ventricle to the descending aorta. Patient 2 was operated on successfully and the surgical procedures performed are described.     

The recognition, identification of morphologic substrate, and treatment of subaortic stenosis after a Fontan operation. An analysis of twelve patients.

Twelve children were identified with subaortic stenosis after Fontan's operation. All had absent resting and isoproterenol-provoked pressure gradient before the Fontan procedure. Six had a univentricular heart of left ventricular morphology, three had a single ventricle of right ventricular morphology, one had tricuspid atresia with transposition of the great arteries, one had pulmonary atresia, intact ventricular septum, and hypoplastic right ventricle, and one had corrected transposition with hypoplastic systemic ventricle. The median interval between the Fontan operation and the recognition of subaortic stenosis was 2.5 years. Ten patients underwent surgical treatment after a prior Fontan operation: Five had myectomy and enlargement of ventricular septal defect with two operative deaths; two had placement of a valved conduit from the ventricular apex to the descending aorta, and both died postoperatively; two with single ventricle had subaortic myectomy, and one had enlargement of ventricular septal defect and pulmonary aortic connection. Complete heart block developed in only one patient. Postoperative testing with Doppler echocardiography with color flow imaging demonstrated good relief of subaortic stenosis. All six children who survived the operation are well 4 months to 4 years later. Subaortic stenosis is a progressive lesion that may develop after a Fontan operation. Its surgical treatment continues to carry a significant mortality. Myectomy and enlargement of ventricular septal defect achieve direct relief of the obstruction with minimal risk of heart block.     

Surgical treatment of coarctation of the aorta and interrupted aortic arch

From December, 1984, through April, 1987, ten infants with coarctation of the aorta and six with interrupted aortic arch underwent staged repair of aorta and other cardiac lesions. Simultaneous pulmonary artery banding was performed in six of 8 patients with ventricular septal defect (VSD) and in all of seven patients with complex cardiac lesions. With first operation, there were no operative deaths and two late deaths. Eight of 14 survivors underwent total correction of associated lesions at three to 17 months after initial operation. VSD was closed in five patients with one operative death. One patient required pulmonary artery debanding alone because of decrease of VSD size. The Damus-Kaye-Stansel operation was performed successfully in one patient with Taussig-Bing anomaly and the Jatene operation was done in one with transposition of the great arteries. Based on these results, we prefer staged repair with pulmonary artery banding for coarctation or interruption of the aorta associated with complex cardiac lesions.     

Palliative Mustard operation: an expanded horizon

From March 1982 to December 1983, five patients with a mean age 7 years (4 months-16 years) underwent a palliative Mustard operation for complex cardiac anomalies. The diagnoses were: univentricular heart with pulmonary vascular obstructive disease (PVOD) (2 cases); criss-cross heart with intact atrial septum, ventricular septal defect (VSD), transposition of the great arteries (TGA) and moderate pulmonary stenosis: isolated atrioventricular discordance with VSD; TGA, diminutive right ventricle and multiple VSDs. Cardiac catheterization showed unfavourable direction of flow: the oxygen saturation in the aorta was lower than in pulmonary artery, with a mean difference of 13.5% (range 6% to 30%). In no case was anatomical or physiological repair considered advisable because of the unfavourable intracardiac anatomy or the presence of PVOD. In two patients the atrial rerouting was accompanied by pulmonary artery banding. There were no hospital or late deaths in a mean follow-up of 36 months (range 29 to 50 months). The mean post-operative arterial oxygen saturation was 95.4% (range 92% to 99%).     

Ventricular septal defect associated with left ventricular outlfow tract obstruction below the defect

Muscular subaortic stenosis associated with ventricular septal defect (VSD) is a rare but important anomaly. Two types of left ventricular outflow tract (LVOT) obstruction should be distinguished on the basis of morphologic as well as hemodynamic differences, depending on whether the stenosis is localized above (Type I) or below (Type II) the defect. The five cases presented are all in the latter category. In the first two cases the correct diagnosis was not made until after repair of the VSD. Two patients had previously undergone banding of the pulmonary artery (PAB). Marked carotid shudder and a vertical QRS axis in the frontal plane were presented in all cases. For the diagnosis to be established by catheterization, the catheter tip must be maneuvered into the apical part of the left ventricular cavity in order to detect the stenosis on the withdrawal curve. It is difficult to visualize the stenosis by angiography. The surgical approach through the VSD via a right atriotomy is highly recommended for Type II subaortic stenosis.     

Staged surgical repair of functional single ventricle in infants with unobstructed pulmonary blood flow

Objective: The infant with a functional single ventricle (SV) and unobstructed pulmonary blood flow (UPBF) requires early protection of the pulmonary vascular bed to ensure suitability for a subsequent Fontan procedure. Systemic obstruction by aortic arch obstruction, subaortic stenosis, or combination of both, has been widely recognized as an important risk factor for poor outcome in children with SV–UPBF who are palliated with pulmonary artery banding (PAB). We reviewed our experience with primary PAB in the subset of patients with SV–UPBF to identify risk factors for subsequent palliative procedures and Fontan completion. Methods: Between January 1990 and May 2004, 80 patients (median age, 14 days) with functional SV and UPBF underwent PAB as their primary palliative procedure. Thirty-five neonates had concomitant aortic coarctation or interrupted aortic arch repair (44%). A Damus–Kaye–Stansel procedure was subsequently performed in 19 patients, and subaortic resection or ventricular septal defect or bulboventricular foramen enlargement was performed in five. Results: There were 4 operative deaths, and 15 late deaths. The actuarial overall survival is 84% at 1 year, 76% at 5 and 15 years. Follow-up is complete in all but six children at a mean interval of 4.9±3.7 years (range, 2 months–15 years). Thirty-seven patients (49%; 37 of 76) have undergone the hemi-Fontan procedure (with three hospital deaths) and 40 patients (53%; 40 of 76; 12 children without previous hemi-Fontan) have undergone the completion Fontan procedure without mortality or Fontan takedown. Conclusion: In infants with single ventricle physiology with or without systemic outflow obstruction and unobstructed pulmonary blood flow, a strategy of pulmonary artery banding carries acceptable operative and mid-term mortality in a high-risk group of patients. Pulmonary artery banding does not compromise performance of subsequent Damus–Kaye–Stansel procedure or completion Fontan palliation.     

Double-outlet right ventricle with non-committed ventricular septal defect

Objective: The term non-committed was used to define hearts in which the VSD was anatomically related to, or was close to, neither great vessel, being separated from both by considerable muscle. We report our experience of the surgical management of this subset, considered being of particular surgical relevance. Methods: Between January 1987 and December 1997, 23 patients having double-outlet right ventricle (DORV) with non-committed VSD underwent biventricular repair. Nine (39%) had undergone previous palliation. The median age was 20 months and the median weight was 8.5 kg. Two main types of repair were used: intraventricular baffle repair (n=21) and arterial switch operation with VSD to pulmonary artery baffle (n=2). At repair, 12 (52%) patients required concomitant VSD enlargement. In two other patients presenting with restrictive inlet VSD associated with tricuspid attachments, crossing the subaortic pathway biventricular repair was abandoned at operation. Results: There were two hospital deaths (9%, 70% CL: 3–19%). Eight patients (35%, 70% CL: 23–48%) underwent nine reoperations, six for subaortic stenosis. No late death occurred. At last visit, all patients were asymptomatic and only two had cardiac medication. Conclusions: The biventricular repair of DORV with non-committed VSD is feasible in the vast majority of cases with comparable results to other subsets of DORV. After repair, the subaortic region is at risk for development of subaortic stenosis.     

Staged biventricular repair of Taussig-Bing anomaly with subaortic stenosis and coarctation of aorta

We present successful procedures for 2 infants who had the Taussig-Bing anomaly with subaortic stenosis and coarctation of the aorta. The initial procedure was coarctoplasty and the Damus-Kaye-Stansel procedure with modified Blalock-Taussig shunt. The second procedure was intraventricular repair (Kawashima procedure), Damus-Kaye-Stansel take-down and the reuse of native aortic and pulmonary valves 19 and 25 months later. Both patients survived the operations and postoperative hemodynamics were excellent at both 28 and 59 months follow-ups.