Background: Transcatheter closure of a perimembranous ventricular septal defect (PmVSD) is usually performed with an asymmetric Amplatzer occluder, which is not an ideal device. Experience with the use of the Amplatzer muscular ventricular septal defect occluder (MVSO) to close selected PmVSDs is presented.
Setting: Two tertiary referral centres for paediatric cardiology in two countries.
Objective: To look at the safety and efficacy of the application of the MVSO in patients with appropriate PmVSD anatomy.
Patients and intervention: The procedure was performed in 10 patients aged 3.2–40 (mean 12.5) years. All had a PmVSD with a mean diameter of 5.4 (range 4–11) mm, with an extension towards the muscular septum. The mean distance of the defect from the aortic valve was 5.4 (range 4–6) mm. In all but one patient, the MVSO was introduced in routine antegrade transvenous fashion (4-mm device in one patient, 6-mm device in five, 8 mm in two, 10 mm in one, and 12 mm in one). In one patient, the device was deployed by retrograde implantation.
Results: All procedures except one were performed without complications, and complete closure of the VSD was achieved. One patient with a residual shunt developed haemolysis, which resolved over 10 days. In three patients, trivial, non-progressive tricuspid regurgitation appeared after the procedure. No other complications were observed over 1.7 (range 0.2–3.5) years of follow-up.
Conclusion: Application of the MVSO for closure of selected PmVSDs seems to be a safe and effective treatment option.
- MVSO, Amplatzer muscular ventricular septal defect occluder
- PmVSD, perimembranous ventricular septal defect
- TEE, transoesophageal echocardiographic
- transcatheter closure
- perimembranous ventricular septal defect
- Amplatzer device
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- MVSO, Amplatzer muscular ventricular septal defect occluder
- PmVSD, perimembranous ventricular septal defect
- TEE, transoesophageal echocardiographic
Ventricular septal defects (VSDs) are the most common form of congenital cardiac malformation, comprising 20% of all congenital heart disease; 80% of these defects are perimembranous, involving the membranous septum and usually the adjacent muscular septum. Therefore these defects are commonly termed perimembranous VSDs (PmVSDs). Their surgical closure is safe with a very low mortality. However, residual shunts, tricuspid incompetence, complete heart block, early and late arrhythmias, and post-pericardiotomy syndrome may occur on occasions. Complications of cardiopulmonary bypass and blood priming are well documented, and surgery, although safe, has a degree of morbidity, discomfort for the patient, and a thoracotomy scar. Therefore an alternative—transcatheter closure of the PmVSD—has been attempted with various types of occluding devices. The ideal device has not been invented as yet, and the special asymmetric Amplatzer occluder designed for such purposes is not perfect. The close proximity to the conduction system and the aortic and/or atrioventricular valve apparatus of PmVSD could produce potential complications, such as rhythm disturbances or valve incompetence. In this article, we have compared the occurrence of rhythm disturbances in patients in whom PmVSDs were closed interventionally with an eccentric Amplatzer occluder and the Amplatzer muscular ventricular septal defect occluder (MVSO). However, the main purpose of this study is to report the results of transcatheter closure of PmVSDs in specially selected patients using the MVSO.
The procedure was performed in 10 patients, aged 3.2–40 (mean 12.5, median 8.65) years with mean body weight 31 (median 25.5; range 14–56) kg. They were selected by transthoracic echocardiography based on the distance between the PmVSD and the aortic valve (aortic rim) being ⩾4 mm, with a significant left-to-right shunt, and with documented left ventricular volume overload. All defects were perimembranous inlet or outlet and extended into the muscular part of the septum. In three patients, aneurysm of the interventricular septum was diagnosed by echocardiography and later confirmed by angiography (fig 1A). One of these had two defects. Table 1 shows the clinical and haemodynamic data. We also treated interventionally 14 patients with PmVSD in whom asymmetric Amplatzer devices were used. The mean age of these patients was 13 (5–38) years, body weight 47.5 (19–101) kg, VSD diameter 6 (4 –12) mm, and aortic rim 5 (2–8) mm.
The MVSO (AGA Medical Corporation, Golden Valley, Minnesota, USA) was designed specifically for closure of VSDs located in the muscular septum. The double-disc nitinol plug has a 7-mm long connecting waist; the left retention skirt is 4 mm larger than the waist diameter, and the right retention skirt is 3 mm larger. The MVSO is available in sizes ranging from 4 to 18 mm, in 2-mm waist diameter increments. The device is passed through a standard AGA delivery system and is attached to a delivery cable by a recessed screw.
All the procedures were performed under transoesophageal echocardiographic (TEE) and fluoroscopic monitoring similar to the technique previously described.1,2 Standard right and left heart catheterisation was performed, and a left ventricular angiogram was obtained in the long axial oblique view (fig 1A). The defect was measured at the end of diastole in the view that showed the best profile of the defect. The VSD was crossed in a retrograde fashion using a 5 F or 6 F right coronary Judkins catheter (Cordis Corporation, Miami, Florida, USA) and hydrophilic guide wire. After crossing the defect, the hydrophilic wire was replaced by a soft J-tipped 260-cm exchange 0.035-inch guide wire, which was advanced into the pulmonary artery, where it was snared using a 10–15-mm gooseneck snare (Microvena Corporation, White Bear Lake, Minnesota, USA) and exteriorised through the right femoral vein, creating a stable arteriovenous loop. The retrograde catheter was advanced across the VSD over the exchange wire with its end left in the junction of the inferior vena cava and the right atrium. A trans-septal sheath 6–8 F with 180 degree of distal curve (AGA Medical Corporation) together with a dilator were advanced over the wire from the femoral vein until the tip of the dilator touched the tip of the retrograde catheter (the “kissing catheter” technique). The long sheath was advanced through the VSD to the ascending aorta by pushing the sheath and pulling the arterial catheter. Once the sheath had crossed into the aorta, the wire and the arterial catheter were withdrawn from the arterial side, and a pigtail catheter was introduced into the left ventricle. The dilator was removed from the sheath, and the sheath was flushed with saline. An appropriate sized MVSO was screwed to the tip of the delivery cable, collapsed into a loader, and advanced to the tip of the sheath in the ascending aorta. The MVSO was selected to be equal to or 1–2 mm larger than the PmVSD diameter, estimated by echocardiography and angiography during diastole. The left ventricular disc was partially deployed in the ascending aorta, assuming a “bubble shape”. The whole system was then gently pulled until the device “dropped” through the aortic valve into the left ventricle outflow tract. In this position, the rest of the left ventricular disc was opened and the whole system was withdrawn under TEE monitoring to the mouth of the defect. At this point, a left ventriculogram was performed to assess the position of the device (fig 1B). The right ventricular disc was deployed by gently pulling the sheath over the delivery cable. TEE was then repeated before and after release of the device. In three of our cases in the presence of “aneurysmatic” PmVSD, the MVSO was implanted to stent the left ventricular entrance of the aneurysm. The connecting waist of the device in such circumstances adapted nicely to the depth of the aneurysm. Control aortography after release was performed to exclude aortic regurgitation (fig 1C). In one patient (table 1, number 7) with a 4-mm aortic rim, it was thought that the retrograde arterial method of implantation would be best, as the proximal disc of the device is 1 mm smaller (3 mm) than the distal one (4 mm). In this patient, a Judkins right coronary catheter was placed through the defect in the apex of the right ventricle and over an exchange guide wire replaced by a 7 F and 180° curved trans-septal sheath (without an arteriovenous loop creation). The distal disc of the MVSO was opened in the body of the right ventricle, and the whole system was pulled under TEE guidance to the entrance of the aneurysm of the interventricular septum, and the proximal disc was opened. At the beginning, the proximal disc had a “bubble shape” and failed to conform properly. By repeated pulling on the delivery cable with gentle pushing forward of the sheath against the disc, we finally succeeded in correctly conforming the device in the mouth of the aneurysm. Repeat TEE and angiography were performed through the side arm of the delivery sheath before and then after release of the device to assess the final device position and the presence of a residual shunt. The devices used included a 4-mm MVSO in one patient, a 6-mm device in five, 8 mm in two, 10 mm in one, and 12 mm in one. All the patients, except one with haemolysis observed after implantation, were discharged after 2 days on aspirin for 6 months and advised to use bacterial endocarditis prophylaxis for 6 months. They were reassessed after 1 month, 6 months and once a year thereafter. The fluoroscopy time ranged from 12 to 49 min (mean 22.2, median 19.0).
The procedure was technically successful in all patients, with complete closure of the defect after 24 hours confirmed by transthoracic echocardiography in all but one. One patient with a residual shunt (patient number 6 in table 1) developed moderately severe haemolysis, which resolved spontaneously over 10 days with conservative management. None of the patients had aortic or mitral regurgitation, but tricuspid regurgitation was diagnosed in three (trivial in two and mild in one); this did not progress in severity during follow-up. The only case of mild tricuspid regurgitation was the one in which retrograde implantation of the device was performed and the distal disc was opened in the right ventricle. The likely explanation for the tricuspid regurgitation was some restriction of movement of the tricuspid valve by the right sided disc of the device. In one patient (number 7), transient loss of the femoral pulse occurred and was treated successfully with heparin infusion for 24 h. No other complications, including atrioventricular heart blocks, occurred during 0.2–3.5 (mean 1.7) years of follow-up. In contrast, among the 14 patients in whom the PmVSD was closed with an eccentric device, there were five with major rhythm disturbances during or after the procedure. The more common occurrence of this complication in the asymmetric Amplatzer group compared with the MVSO group was close to significant (p = 0.053; Fisher’s exact test). In the first patient treated with eccentric Amplatzer, the procedure was abandoned when the heart block appeared just after the sheath had been passed through the VSD and directed to the left apex. In the second patient, a rhythm disturbance (first degree atrioventricular block with left bundle branch block and periodically third degree atrioventricular block) appeared in the first week after implantation of the eccentric Amplatzer occluder and resolved after steroid treatment. In the third patient, a third degree atrioventricular block manifested itself immediately after implantation and disappeared after removal of the device. In two other patients, a heart block appeared in the later follow-up (after discharge). In these patients, a permanent pacemaker was implanted after steroid treatment had failed.
Attempts at transcatheter PmVSD closure are not new. They have been performed with several occluding devices such as the Rashkind double umbrella,3–6 coils5,6 and the Button device.7 None of these devices were specifically designed for closure of PmVSDs and none gained wide acceptance, because of technical limitations, significant rate of residual shunts, and complications. A new era of percutaneous treatment appeared with the introduction of specially designed Amplatzer devices. In 1999, the first cases of transcatheter closure of muscular VSDs with an MVSO were reported,1,8 and since then transcatheter closure of PmVSDs with specially designed eccentric Amplatzer devices has also been reported.9–14 The results with these new devices are well documented in the literature.1,8,9,10,11,12,13,14 There are two reasons why we used a muscular device instead of a perimembranous one. At the beginning (in the first two cases), there was only one device available; later it was our choice (after an unfavourable experience with an asymmetric device and conduction problems). Percutaneous closure of the PmVSD remains the biggest challenge for the cardiologist, because of its close proximity to the aortic and tricuspid valves as well as the conduction system, which passes at the posterior border of these defects. The Amplatzer perimembranous ventricular septal defect occluder has a very short connecting waist (1.5 mm) and asymmetric left ventricular disc designed to avoid impingement on the aortic valve. This is accomplished by a comparatively complicated introduction system, which has been described previously.12–14 Owing to the eccentric design of the left ventricular disc, correct orientation of the device has to be achieved for successful deployment. However, a major concern remains, namely the occurrence of complete heart block, which has been reported with the use of the eccentric Amplatzer device by different centres.9,14,15 Although the frequency of the latter complication is reported to be around 3.5% (comparable to surgical results), it is still of concern.15 This complication also occurred in five of our 14 patients treated with this device and in none treated with the MVSO (p = 0.053). It is not known whether complete heart block after use of the asymmetric device is caused by the trauma of the catheterisation with local haematoma formation, an inflammatory response to the device, compression of the interventricular septum between two discs, or the continued mechanical expansion of the nitinol device exerting pressure on the conducting system. These complications may also be explained in part by the fact that sizing of the defects is extremely vague because balloon sizing is not feasible. Consequently, oversized devices are commonly introduced which exert excessive pressure on the bundle of His. Our study, although it includes only a small number of patients, has shown that, in selected cases of PmVSD with a distance of the defect to the aortic valve ⩾4 mm (length of the left retention skirt of the device is 4 mm), a MVSO can be successfully implanted without creation of aortic regurgitation or rhythm disturbances. It is possible that there is less compression of the device on the bundle of His because of increased separation between the two discs of the device, but it has not been experimentally proved. We cannot exclude the possibility that our clinical observation (lack of atrioventricular block in the MVSO group) is related to the slightly different anatomy of the VSD in the specially selected patients. On the other hand, with the 7-mm connecting waist, the right ventricular disc of the MVSO may interfere with tricuspid valve motion. This occurred in three of our patients, causing clinically insignificant tricuspid regurgitation. We have also shown that application of the MVSO is safe and efficient in patients with “aneurysmatic” PmVSD, as it was in three of our cases. In patients with coexisting aneurysms of the interventricular septum, other devices, such as the PFM coil,16 the Amplatzer duct occluder,17 and the wireless Sideris patch,18 have been used, but experience with these devices is very limited.
We have shown that, in some carefully selected cases, the Amplatzer MVSO can be used with good results.
Published Online First 15 September 2006
Competing interests: None.
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