1/2015
vol. 12
CASE REPORTS Mechanical circulatory support after surgical repair of Bland-White-Garland syndrome.
A study of three cases
Kardiochirurgia i Torakochirurgia Polska 2015; 12 (1): 77-79
Online publish date: 2015/03/31
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Introduction
Bland-White-Garland (BWG) syndrome is a congenital heart defect in which the left coronary artery abnormally branches off the pulmonary trunk. Its prevalence is approximately 1 : 300,000 births, which corresponds to approximately 0.4% of all congenital heart defects [1, 2]. It is the most frequent cause of myocardial infarction in children; mortality among untreated individuals reaches 90%, while the remaining 10% survive due to the existence of collateral circulation from the right coronary artery [2]. Depending on the extent of the connections between the coronary arteries, BWG syndrome may present itself at elderly age or remain asymptomatic throughout the patient’s life [2, 3]. Symptoms of congestive heart failure, myocardial ischemia, left ventricular contractility impairments, or impairments in the functioning of the mitral valve typically appear at approximately 8 weeks of life [1-3]. The syndrome’s subjective manifestations may include dyspnea, fatigability, tearfulness, or paleness [2, 4].
The present study presents cases of two children in whom extracorporeal membrane oxygenation (ECMO) was employed after the surgical repair of BWG syndrome and one child in whom ECMO was not required after this procedure.
Case 1
A 12-year-old boy diagnosed with BWG syndrome and secondary dilated cardiomyopathy was admitted in order to undergo surgical treatment. Physical examination revealed a systolic murmur above the apex of the heart; no other abnormalities were found. Left ventricular contractility was in the lower range of normal levels. The functioning of the mitral valve was normal. During cardiac catheterization, retrograde coronary blood flow was observed from the opening of the left coronary artery in the pulmonary trunk. The location of the coronary opening on the posterolateral wall of the pulmonary trunk precluded coronary artery transplantation. Therefore, using extracorporeal circulation and Takeuchi’s procedure, a tunnel was formed inside the pulmonary artery from the outlet of the left coronary artery to the created aortopulmonary window. The procedure and the postoperative course were uneventful. A control ultrasound examination of the heart was performed, yielding normal results. The patient was discharged on the 9th postoperative day in good general condition.
Case 2
A 4-month-old girl diagnosed with a hemodynamically significant defect – BWG syndrome, third-degree mitral valve insufficiency, and left ventricular heart failure was admitted in order to undergo a repair procedure. Preoperative electrocardiography (ECG) revealed ST-segment elevation in precordial leads V5 and V6 as well as elevation of cardiac markers. The cardiac ejection fraction (EF) was estimated at approx. 38%, and left ventricular end-diastolic (LVED) diameter – at approx. 39 mm. Cardiac catheterization demonstrated that the trunk of the left coronary artery branched off the posterolateral wall of the pulmonary trunk, which, considering the distance, precluded the implantation of a vascular graft into the aorta. The procedure was performed under extracorporeal circulation; the pulmonary artery was incised transversely above the origin of the left coronary artery; subsequently, a strip of the pulmonary trunk was excised together with the outlet of the left coronary artery. A strip of the aorta, pedicled on the posterior wall, was incised and sutured to the pulmonary trunk strip, creating a tunnel from the outlet of the left coronary artery to the ascending aorta, running outside the pulmonary trunk. The defect in the wall of the pulmonary trunk was repaired with preserved bovine pericardium. The procedure also included atrial septal defect (ASD) closure. After clamp removal, the heart resumed sinus rhythm. Postoperatively, on the day of the procedure, significant left ventricular failure was observed along with impairment of contractility – EF 10%. A decision was made to introduce mechanical left ventricular support using venous-arterial extracorporeal circulation. On the 4th postoperative day, circulatory support was disconnected. Due to pneumonitis, the patient remained in the intensive care unit until the 24th postoperative day. A control cardiac echo performed at discharge from the ICU demonstrated EF of 32%, LVED diameter of 36 mm, and mitral insufficiency reduced to the second degree. During the following days, the clinical condition of the child improved as the indices of inflammation subsided systematically. The patient was extubated on the 22nd postoperative day. On the 24th postoperative day, the patient was transferred to the pediatric cardiology ward, where she remained for the next four weeks. She was discharged home on the 51st postoperative day in good general condition and stable circulatory and respiratory status. Although cardiac ultrasonography revealed generalized left ventricular hypokinesia, it also demonstrated a significant improvement of the ejection fraction (EF = 48%) in comparison to previous examinations; the mitral insufficiency was still present, but its gradual regression was observed.
Case 3
A 6-month-old girl with body mass of 4.6 kg was referred to our center in order to undergo surgical repair of BWG syndrome. Her records from the previous hospital included the diagnosis of third-degree mitral insufficiency and left ventricular heart failure. The ejection fraction was 18%; left ventricular dilatation with an akinetic apical aneurysm was observed. Physical examination revealed a quiet systolic murmur audible above the cardiac apex. As in the case of the previous patient, cardiac catheterization demonstrated that the whole left coronary artery branched off the posterolateral wall of the pulmonary trunk. The performed procedure employed the same technique that was used in the case of the previous patient and also involved the closure of ASD. Intraoperative transesophageal cardiac echo demonstrated EF of only 10%. Therefore, a decision was made to introduce mechanical circulatory support instead of extracorporeal circulation and to maintain it during the postoperative period. On the 2nd postoperative day, cardiac echo demonstrated EF of 19%, LVED diameter of 36 mm, and a reduction of mitral insufficiency from the third to second degree. On the 3rd postoperative day, the vent cannula was removed from the left atrium. On the 5th postoperative day, circulatory support was disconnected. On the 6th day, neurological symptoms appeared in the form of pathological muscle tension and eye movements to the right side. At this point, the patient underwent computed tomography of the head. The examination revealed the presence of fresh diffuse ischemic lesions in both temporal, frontal, and occipital lobes (caused by numerous embolisms originating from the akinetic left ventricular apex). The patient was extubated on the 23rd postoperative day. On the 30th day, the patient was transferred to the pediatric cardiology ward, where she continued to undergo catecholamine therapy. A systematic regression of neurological symptoms was noted, but left-sided hemiparesis persisted. After further seven weeks of treatment, the patient was discharged home in good general condition and stable circulatory and respiratory status. The ejection fraction at discharge was 33%. Mitral insufficiency persisted at the second degree according to Simpson. Regular follow-up visits to cardiology and neurology clinics were recommended to the patient.
Discussion
The treatment for BWG syndrome is surgical repair [4]. The following techniques are reported to be feasible in this context: creating a bypass from the aorta to the left coronary artery or the descending branch of the left coronary artery (LAD), transplanting the left coronary artery along with its outlet from the pulmonary trunk to the aorta, or forming a tunnel from the wall of the pulmonary trunk, connecting the left coronary artery with the aorta and running inside the pulmonary trunk – using Takeuchi’s method [5] – or outside the pulmonary trunk [6]. The method which appears to offer best results consists in transplanting the left coronary artery to the aorta. Its use is limited by anatomic variants which preclude repairing the defect in this manner [5, 6]. In this situation, Takeuchi’s technique may be used, or a connecting tunnel may be created outside the pulmonary trunk [5, 6]. This method of repair was used in patients 2 and 3, while Takeuchi’s procedure was employed in patient 1. This technique offers very good early results, but is sometimes followed by long-term complications such as pulmonary artery stenosis or shunt from the tunnel to the lumen of the pulmonary trunk [6].
Although patients 2 and 3 exhibited third-degree mitral insufficiency, no repair procedure was attempted, as the insufficiency was caused by generalized hypokinesia and left ventricular dilatation. In such cases, it is difficult to assess the actual degree of insufficiency.
Although mechanical circulatory support employing extracorporeal circulation has been used for many years in the treatment of heart and lung diseases, clear qualifying criteria for its use are still lacking [7]. The primary reasons for its use in children include a low ejection fraction after cardiac surgery procedures [7, 8]. The most significant complications resulting from using this method include bleeding, sepsis, and ischemic or hemorrhagic changes within the central nervous system [7]. Longer duration of therapy entails a lower chance of recovery and a higher risk of complications [7]. The subject literature features reports of cases similar to ours in that they required the use of mechanical circulatory support after the surgical repair of BWG syndrome [1, 6].
Conclusions
Despite the risk of numerous complications, mechanical circulatory support offers a chance of survival to patients with a low left ventricular ejection fraction. As this is a frequent problem after the surgical repair of BWG syndrome, the authors suggest that such repair should only be performed in centers that are able to provide mechanical circulatory support.
Disclosure
Authors report no conflict of interest.
References
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Copyright: © 2015 Polish Society of Cardiothoracic Surgeons (Polskie Towarzystwo KardioTorakochirurgów) and the editors of the Polish Journal of Cardio-Thoracic Surgery (Kardiochirurgia i Torakochirurgia Polska). This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) License ( http://creativecommons.org/licenses/by-nc-sa/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material, provided the original work is properly cited and states its license.
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