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Transcatheter closure of a large aortopulmonary window using a Lifetech™ Konar-MF occluder device

Published online by Cambridge University Press:  15 November 2024

Kanupriya Chaturvedi*
Affiliation:
Department of Pediatric Cardiac Sciences, Mahatma Gandhi Medical College and Hospital, Jaipur, RJ, India
Prashant Thakur
Affiliation:
Sri Sathya Sai Sanjeevani Hospital for Child Heart Care, Naya Raipur, India
Sunil Kumar Gupta
Affiliation:
Sri Sathya Sai Sanjeevani Hospital for Child Heart Care, Naya Raipur, India
*
Corresponding author: Kanupriya Chaturvedi; Email: [email protected]
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Abstract

Aortopulmonary window is a rare CHD, which comprises a communication between the ascending aorta and the pulmonary artery. The standard treatment of aortopulmonary window is surgical; however, few cases are amenable to closure via percutaneous intervention. We present a case of aortopulmonary window closure using Lifetech™ Konar-MF occluder device (Lifetech Scientific Co. Ltd., Shenzhen).

Type
Brief Report
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Introduction

Aortopulmonary window is a rare form of CHD with a prevalence of about 0.1–0.2%.Reference Samanek and Voriskova1,Reference Talner and Fyler2 The standard treatment of aortopulmonary window is surgical; however, few cases are amenable to percutaneous device closure.Reference Naik, Chandra and Shenoy3,Reference Atiq, Rashid, Kazmi and Qureshi4 So far, there have been reports in literature on percutaneous device closure of aortopulmonary windows commonly using duct occluders and muscular Ventricular Septal Defect devices.Reference Naik, Chandra and Shenoy3,Reference Atiq, Rashid, Kazmi and Qureshi4,Reference Sivakumar and Francis6,Reference Trehan, Nigam and Tyagi7 We report the case of a 10-month-old infant who underwent percutaneous device closure of aortopulmonary window using a Lifetech™ Konar-MF occluder device.

Case report

A 10-month-old infant was referred to our centre in view of frequent chest infections and poor weight gain. On physical examination, she was between the 3rd and 10th centile for weight, had a 4/6 systolic murmur at the upper left sternal border, bounding peripheral pulses and a saturation of 98%. X-ray showed cardiomegaly and increased bronchovascular markings. On transthoracic echocardiogram, she was found to have a type 1 aortopulmonary window, measuring about 7–8 mm and distant from the semilunar valves and pulmonary artery bifurcation with predominant left to right shunt across it (Figure 1). There was left-sided volume overload with dilation of left atrium and left ventricle, mild mitral regurgitation, and no associated structural cardiac anomalies.

Figure 1. Parasternal short axis view of 2D echocardiogram demonstrating the aortopulmonary window and predominant left to right shunt across it.

After obtaining informed consent from caregivers, patient was taken to the catheterisation laboratory for haemodynamic cardiac catheterisation and potential device closure of the aortopulmonary window. The procedure was performed under general anaesthesia. Right-sided femoral vessels were accessed and 4 Fr and 6 Fr sheaths were placed in the right femoral artery and vein respectively, followed by 100 IU/Kg of heparin administration. Haemodynamic catheterisation was performed which demonstrated a pulmonary artery pressure of 50/25 mmHg (mean ∼ 30 mmHg) with a simultaneous ascending aorta pressure of 80/30 mmHg (mean ∼ 48 mmHg). An aortic root angiogram was performed using a 4 Fr Pigtail catheter, which showed a proximal aortopulmonary window measuring about 8 mm and distant from the semilunar valves, pulmonary artery bifurcation, and coronary arteries (Figure 2).

Figure 2. Aortic angiogram (LAO 30) demonstrating the aortopulmonary window with opacification of the pulmonary artery.

The defect was crossed retrograde using 4 Fr JR catheter over Terumo wire and an Arterio-venous loop was created via a 6 Fr snare and a 5 Fr Multipurpose angiographic catheter placed in the main pulmonary artery. The right femoral venous sheath was upsized to a 7 Fr delivery sheath and was advanced antegrade and positioned into the proximal descending aorta. Size 12 mm x 10 mm Lifetech™ Konar-MF occluder device (Lifetech Scientific Co. Ltd., Shenzhen) was chosen and advanced into the delivery sheath. The aortic disc was deployed in the ascending aorta and the entire assembly was pulled back. After confirming the location of the device on the roadmap of aortic angiogram, the pulmonary disc was deployed (Figure 3). Pullback gradients and angiograms (Figure 4) were performed in the aorta and pulmonary arteries, and the device was released after there was no obstruction documented in the ascending aorta and pulmonary artery (Figure 5). Patient tolerated the procedure well and there were no complications. She was extubated after the procedure and was discharged the next day after a post-procedure echocardiogram showed the device in good position and with no gradients across the ascending aorta and pulmonary artery. The infant is doing well at one-month follow-up and is gaining weight.

Figure 3. Deployment of the left disc in the ascending aorta.

Figure 4. Aortic angiogram demonstrating no flow into the pulmonary artery after device deployment.

Figure 5. Final device position after release.

Discussion

Aortopulmonary window is a rare CHD, which requires early treatment and is most often treated surgically. Its classification as given by Mori et al. divides aortopulmonary window into three types. Type I is a proximal defect located in the ascending aorta midway between the semilunar valves and pulmonary bifurcation. Types II is a distal defect that is located in the distal portion of the ascending aorta. Type III is a defect that is large and involves the majority of the ascending aorta, pulmonary trunk, and the right pulmonary artery.Reference Mori, Ando and Takao5

Type I defects, which are typically midway between the semilunar valves and pulmonary artery bifurcation and those with no associated cardiac anomalies, can be suitable percutaneous closure.

There have been case reports and case series in literature that have demonstrated percutaneous device closure of this lesion with muscular Ventricular Septal Defect devices and duct occluders.Reference Naik, Chandra and Shenoy3,Reference Atiq, Rashid, Kazmi and Qureshi4,Reference Sivakumar and Francis6,Reference Trehan, Nigam and Tyagi7 In our patient, we decided to opt for a Konar-MF occluder due to its softer, low-profile design, and the advantage of the device requiring smaller sheath sizes, rendering it safer for smaller infants.Reference Ibrahim, Osman and Murat8

In our patient, a Lifetech™ Konar-MF occluder device was used for closure of an aortopulmonary window. The first case of the use of this device for aortopulmonary window was reported by Abdelrazek Ali Y, et al; Reference Abdelrazek Ali, Nour and Rashad9 however, our patient is the youngest to undergo percutaneous device closure of an aortopulmonary window by a Konar-MF occluder.

In the ever-evolving field of paediatric cardiac interventions, aortopulmonary window is one of the lesions that requires further studies and cohort analyses for standard guidelines for percutaneous device closure. Although our patient has so far had device in stable position, we cannot overemphasise the need for regular follow-up, since there have been no cohort studies to demonstrate the long-term safety profile of percutaneous closure of aortopulmonary window.

Conclusion

We conclude that it is safe to perform transcatheter closure of an aortopulmonary window, provided the lesion has a suitable anatomy and there are no associated cardiac anomalies. There are several devices available to choose from according to operator preference and anatomy; however, in our case, we found the Lifetech™ Konar-MF occluder device to be a good option for consideration for percutaneous closure of an aortopulmonary window.

References

Samanek, M, Voriskova, M. Congenital heart disease among 815,569 children born between 1980 and 1990 and their 15-year survival: a prospective Bohemia survival study. Pediatr Cardiol 1999; 20: 411417.CrossRefGoogle ScholarPubMed
Talner, CN, Fyler, MD. Report of the new England regional infant cardiac program, by Donald C. Pediatrics 1980; 65 (suppl-1): 375461.Google Scholar
Naik, GD, Chandra, VS, Shenoy, A, et al. Transcatheter closure of aortopulmonary window using Amplatzer device. Catheter Cardiovasc Interv 2003; 59: 402405.CrossRefGoogle ScholarPubMed
Atiq, M, Rashid, N, Kazmi, KA, Qureshi, SA. Closure of aortopulmonary window with amplatzer duct occluder device. Pediatr Cardiol 2003; 24: 298299.CrossRefGoogle ScholarPubMed
Mori, K, Ando, M, Takao, A, et al. Distal type of aortopulmonary window: report of 4 cases. Br Heart J 1978; 40: 681689.CrossRefGoogle ScholarPubMed
Sivakumar, K, Francis, E. Transcatheter closure of distal aortopulmonary window using Amplatzer device. Congenit Heart Dis 2006; 1: 321323.CrossRefGoogle ScholarPubMed
Trehan, V, Nigam, A, Tyagi, S. Percutaneous closure of nonrestrictive aortopulmonary window in three infants. Catheter Cardiovasc Interv 2008; 71: 405411.CrossRefGoogle ScholarPubMed
Ibrahim, CT, Osman, B, Murat, S, et al. Use of lifetechTM Konar-MF, a device for both perimembranous and muscular ventricular septal defects: a multicentre study. Int J Cardiol 2020; 310: 4350.Google Scholar
Abdelrazek Ali, Y, Nour, A, Rashad, M, et al. Transcatheter closure of a large aortopulmonary window with the novel device multifunctional occluder (Konar) under TEE guidance (A case report). J Cardiol 2022; 25: 370372.Google ScholarPubMed
Figure 0

Figure 1. Parasternal short axis view of 2D echocardiogram demonstrating the aortopulmonary window and predominant left to right shunt across it.

Figure 1

Figure 2. Aortic angiogram (LAO 30) demonstrating the aortopulmonary window with opacification of the pulmonary artery.

Figure 2

Figure 3. Deployment of the left disc in the ascending aorta.

Figure 3

Figure 4. Aortic angiogram demonstrating no flow into the pulmonary artery after device deployment.

Figure 4

Figure 5. Final device position after release.