Localisation of ventricular septal defects by simultaneous display of superimposed colour Doppler and cross sectional echocardiographic images

Precise non-invasive localisation of the site of a small ventricular septal defect was attempted using a new technique that simultaneously combines conventional cross sectional echocardiography with a Doppler system by superimposing the colour coded direction and velocity of blood flow directly on to real time ultrasound images. Twenty three patients with unoperated ventricular septal defects and a further eight after surgical closure were studied; 12 children with normal hearts served as controls. A colour coded blood flow jet entering the right ventricle during systole was identified in all 23 unoperated patients, in 11 of whom the defect was too small to be visualised by conventional cross sectional echocardiography. The colour Doppler technique precisely located 19 perimembranous and five trabecular defects (one patient had two defects). Five of the postoperative patients were without clinical evidence of a significant shunt but had pansystolic murmurs. In each of these five, trans-septal shunt blood flow as demonstrated by colour Doppler images whereas in only three of these patients was the residual defect large enough to be visualised by conventional cross sectional echocardiography. Three postoperative patients had no murmurs and showed no residual shunt on colour Doppler images. This was confirmed at cardiac catheterisation. There were no false positive results among the controls. This technique is useful for the more accurate diagnosis and location of ventricular septal defects and may help in assessing their natural or surgical closure.     

Localisation of ventricular septal defects by simultaneous display of superimposed colour Doppler and cross sectional echocardiographic images.

Precise non-invasive localisation of the site of a small ventricular septal defect was attempted using a new technique that simultaneously combines conventional cross sectional echocardiography with a Doppler system by superimposing the colour coded direction and velocity of blood flow directly on to real time ultrasound images. Twenty three patients with unoperated ventricular septal defects and a further eight after surgical closure were studied; 12 children with normal hearts served as controls. A colour coded blood flow jet entering the right ventricle during systole was identified in all 23 unoperated patients, in 11 of whom the defect was too small to be visualised by conventional cross sectional echocardiography. The colour Doppler technique precisely located 19 perimembranous and five trabecular defects (one patient had two defects). Five of the postoperative patients were without clinical evidence of a significant shunt but had pansystolic murmurs. In each of these five, trans-septal shunt blood flow as demonstrated by colour Doppler images whereas in only three of these patients was the residual defect large enough to be visualised by conventional cross sectional echocardiography. Three postoperative patients had no murmurs and showed no residual shunt on colour Doppler images. This was confirmed at cardiac catheterisation. There were no false positive results among the controls. This technique is useful for the more accurate diagnosis and location of ventricular septal defects and may help in assessing their natural or surgical closure.     

Evolution of ventricular septal defects. Relation to echocardiographic anatomy]

The aim of this study was to analyse the outcome of membranous ventricular septal defects (VSD) with respect to the echocardiographic data obtained during the first year of life. This retrospective series included patients born between January 1st 1986 and December 31st 1995, in the Indre et Loire department, with membranous ventricular septal defects alone or associated with minor abnormalities. The initial echocardiography, an echocardiography performed 2 to 6 months later, one a year later and the final echocardiography were compared. Three groups of VSD were constituted according to their diameter: group I (< or = 3 mm), group II (3-6 mm), and group III (> 6 mm). Depending on the outcome, the patients were classified as spontaneous closure (group A), surgical closure (group B) or persistent VSD (group C). The population comprised 84 children. There were 6 spontaneous deaths, three of which were unexplained, and 7 children were lost to follow-up. After the initial echocardiography, the VSD were classified as group I (38%), group II (26.2%) and group III (35.7%). After the second echocardiogram, 24 VSD changed group (31.5%), by increase (N = 10) or decrease (N = 14) in diameter. Aneurysms of the membranous septum were observed during the first two echocardiographies in 31.2% and 79.3% of VSDs of group I, 31.8% and 70% of VSDs of group II and 6.6% and 3.3% of VSDs of group III (p < 0.01). The average follow-up was 3.1 years (range 1 month-10 years). In group A (N = 22), the mean age of closure of the VSD was 26 months (3 months-7 years). In group B (N = 28), surgery was undertaken at an average age of 10 months (range 3 months-5 years). In group C (N = 21), the VSDs were classified as group I (N = 19) or group II (N = 2) at the last echocardiography. The frequency of aneurysms of the membranous septum in groups A, B and C were respectively 100%, 7.1% and 66.6% (p < 0.01). At the second echocardiographic examination, a significant relationship (p < 0.001) was observed between the diameter of the VSDs and their outcome. The VSDs of group A were associated with aneurysms of the membranous septum more often than those of group C (p < 0.005). The authors conclude that surgery is required in about one third of membranous VSD. At medium term, the others either close spontaneously or become smaller in comparable numbers. The outcome is directly related to the diameter of the VSD and the development of an aneurysm of the membranous septum. During the first 6 months, the dimensions of membranous VSDs change in about 30% of cases with an increase in frequency of aneurysms of the membranous septum.     

Traumatic ventricular septal defects

Two previously unreported cases of traumatic ventricular septal defect are presented. One, which is an unusual occurrence, has been diagnosed on clinical evidence as a ventricular septal defect resulting from a gunshot wound of the chest. The defect has been successfully repaired in one of the patients. The etiology, prognosis and indications for operation in these cases are briefly discussed.     

Classification of ventricular septal defects]

The hearts were examined from 125 patients with isolated ventricular septal defects (VSD) who had died at the age of 0-14 years before or without operation. One hundred twenty five heart showed 178 defects: 103 with isolated, 22 with multiple VSD. Five major defect types were identified: (1) perimembranous; (2) sinus; (3) central trabecular; (4) boundary muscular trabecular; (5) infundibular. According to the relevance of fibrous skeleton and cardiac conduction system, the defects of various sites are divided into 2 large groups: 1) unadjacent to them (muscular) and 2) adjacent. In terms of septal geometry, there are also two large groups: 1) those located in the inflow portion of the septum and 2) those located in the outflow portion.     

Transcatheter closure of ventricular septal defects

Between January and October, 1987, we attempted percutaneous transcatheter closure of seven ventricular septal defects (VSD) in six patients; none of the patients was a candidate for operative management. Patients' ages ranged from 8 months to 82 years (6.0-70 kg); diagnoses included postinfarction VSD (n = 4), congenital VSD (n = 1), and postoperative congenital VSD (n = 2). Indications for VSD closure were shock or respiratory failure (n = 5) or multiple episodes of endocarditis (n = 1). Closure was attempted with a Rashkind double umbrella: VSDs were crossed via the left ventricle and a guide wire was advanced to the right heart, snared with a venous catheter, and used to direct a long sheath (and ultimately the double umbrella) across the VSD. We crossed the VSD in all seven attempts, and a 17-mm double umbrella was successfully placed in each VSD. In the first (postinfarction) patient with the largest (12 mm) VSD, the umbrella embolized after 20 seconds to the pulmonary artery (without reducing flow). The other six umbrellas remained in position, either diminishing or abolishing the left-to-right shunts. Postinfarction patients had increasing VSD shunting over the next several days and died; at postmortem, the umbrellas remained well positioned in the septum, with other VSDs present. All three congenital VSDs had absent or diminished shunts after umbrella closure. These preliminary data indicate that transcatheter VSD closure is feasible in selected cases.     

Classification of ventricular septal defects.

A classification with clinical significance is proposed for ventricular septal defect based on the study of 220 hearts with defects of the ventricular septum. All had atrioventricular and ventriculoarterial concordance with normal relations of cardiac structure. For the purpose of classification, the ventricular septum was considered as possessing muscular and membranous portions, the muscular septum itself being divided into inlet, trabecular, and outlet (or infundibular) components. Defects were observed in the area of the membranous septum, termed perimembranous defects; within the muscular septum, termed muscular defects; or in the area of septum subjacent to the arterial valves, termed subarterial infundibular defects. Perimembranous defects were found extending either into the inlet, trabecular, or infundibular septa. Muscular defects were found in or between the inlet septum, trabecular septum, or infundibular septum. Review of the angiograms showed that the classification was easy to use in the catheterisation laboratory, and our observations suggest that the precision thus obtained has considerable surgical significance.     

Echocardiographic evaluation of ventricular septal defects

Ventricular septal defects (VSDs) are the most common forms of acyanotic congenital heart disease accounting for 37% of congenital heart disease in children. A VSD is defined by parts of the ventricular septum involved. There are four major types of VSDs: perimembranous, muscular, outlet, and inlet VSDs. Echocardiography is the most important clinical tool to help diagnose and characterize a VSD. Although most VSDs are clinically nonsignificant or close on their own, echocardiography with Doppler and color flow mapping can be used to provide accurate anatomic and hemodynamic evaluation of VSDs in order to determine if surgical or transcatheter-based intervention is needed. Hence, understanding how to use echocardiography to characterize VSDs is of crucial importance when caring for patients with adult congenital heart disease.     

Percutaneous closure of ventricular septal defects

BACKGROUND: Surgical closure of ventricular septal defects has been performed for many years, and is considered as the gold standard for treatment. It remains associated with morbidity and mortality. Transcatheter techniques have been developed in the last 10 years as a possible alternative to conventional surgery. METHODS: The procedure is performed under general anaesthesia, and with continuous fluoroscopic and transesophageal echocardiographic guidance. Devices of the Amplatzer family, two in particular, have achieved a large popularity in clinical practice, and are currently the devices most commonly used to close muscular and perimembranous ventricular septal defect percutaneously. RESULTS: Data from literature show that successful closure of muscular defects is obtained in around 96% of patients, with a rate of major complication of around 2%. Pooling data from the literature shows that successful closure of perimembranous defects is also obtained in 96% of patients, again with major acute complications in around 2%. The major problem is the occurrence of complete atrioventricular block, reported in 1.7% of subjects. Acquired defects can occur as residual leaks after surgical closure, or as consequence of myocardial infarction. There are very few data concerning percutaneous closure of postoperative residual defects. As for the surgical approach, in patients with post-myocardial defects the success rate of percutaneous closure is around 88%, with a mortality of 22%. CONCLUSIONS: Nowadays, in experienced hands, percutaneous closure is a safe and effective procedure. In selected patients, closure of congenital or acquired muscular and perimembranous ventricular septal defects can be considered a real alternative to the standard surgical approach, with the advantage of a significantly reduced rate of mortality and complications.