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2/2023
vol. 98 Case report
Echocardiographic features in infants with dilated cardiomyopathy treated with reversible pulmonary banding: a preliminary single-centre experience
Alicja Mirecka-Rola
1
,
Monika Kowalczyk-Domagała
1
,
Anna Brodzikowska-Pytel
1
,
Andrzej Kansy
2
,
Grażyna Brzezińska-Rajszys
3
,
Lidia Ziółkowska
1
Pediatr Pol 2023; 98 (2): 161-165
Online publish date: 2023/06/15
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INTRODUCTIONDilated cardiomyopathy (DCM) is the most common form of paediatric cardiomyopathy, with a reported annual incidence of 0.58–0.78 cases per 100,000 children [1]. Dilated cardiomyopathy is defined as left ventricle (LV) dilatation and LV dysfunction in the absence of abnormal loading conditions or coronary artery abnormalities. Epidemiological studies have reported that most children with DCM present under the age of one year and up to 93% are symptomatic, with features of congestive heart failure (HF) at presentation. The aetiology of DCM is heterogeneous, particularly in the paediatric population, and it includes acquired and inherited causes.The basic echocardiographic parameters confirming the diagnosis of DCM are left ventricle end diastole diameter (LVEDD) and left ventricle end systole diameter Z-score ≥ 2 (determined as more than 2 standard deviations from the mean value for the population corrected for body surface area [BSA]) and decreased systolic function [2]. Recent literature reports indicate that the left ventricle global longitudinal peak strain (LVGLS) may be useful in diagnosis as well as in predicting outcomes in children with DCM [3]. Reversible pulmonary artery banding (rPAB) is a novel therapeutic strategy proposed in children younger than 3 years of age with end-stage HF due to DCM and preserved right ventricle (RV) function, which improves LV parameters by ventriculo-ventricular interaction. The reversible pulmonary artery banding is performed to obtain a RV pressure equal to 60% of systemic blood pressure, as recommended in the literature [4]. This surgical procedure allows the avoidance or delay of heart transplantation (HTx) in paediatric DCM [4, 5]. The aim of our report was to present the predictive value of LVGLS in assessing the efficacy of rPAB in 2 infants with DCM. MATERIAL AND METHODSThe transthoracic (TTE) and transoesophageal echocardiography were obtained on a Philips Epiq7 (Philips Medical Systems, Bothell, WA). Myocardial strain analysis was performed from 2-dimensional (2-D) imaging using Philips Software. In the described 2 children, we evaluated conventional RV and LV global systolic function parameters and speckle tracking analysis of 2-D left ventricle global longitudinal strain (2-D LVGLS) before and after rPAB. Our patients fulfilled the inclusion criteria for rPAB recommended in the literature [4]: age < 3 years, severe LV systolic dysfunction (EF < 30% calculated by the Simpson method), LVEDD Z-score > 4, preserved RV function, and no efficacy of pharmacological treatment of HF, including inotropic positive drugs. Congenital heart disease and pathology of the coronary arteries were excluded in both infants. The echocardiographic diagnosis of DCM was confirmed by cardiovascular magnetic resonance imaging. Genetic testing using the next-generation sequencing technique and panel of 57 genes related to the aetiology of DCM was performed in both children. Each patient was also screened for metabolic disorders. Patients were followed prospectively for 15 months. Clinical examination, evaluation of somatic growth and symptoms of HF (Ross classification), and the value of biomarker NT-proBNP were repeatedly performed during the follow-up period. Transthoracic was performed on hospital admission and on bi-monthly visits during follow-up. Cardiac catheterization was performed in case 1. Transoesophageal echocardiography was done during the rPAB procedure to allow tightening of the band until re-shifting of the interventricular septum to the midline position (evaluated by eye-ball assessment and measuring of right ventricle mid cavity diameter [RVD2]). Detailed echocardiographic data on hospital admission and during follow-up are presented in Tables 1 and 2.CASES REPORTSCase 1A 6-month-old male infant (M.B.) was transferred from regional hospital to our paediatric cardiology department with progressive symptoms of HF (Ross class IV). The boy was treated with oral HF medications (lisinopril, carvedilol, spironolactone, furosemide). From the age of 5 months his parents observed progressive lethargy and increased work of breathing. There was no recent history of respiratory infections. Family history of metabolic disorders and cardiomyopathies was negative. Initial TTE showed markedly enlarged LV with reduced EF and 2-D LVGLS and moderate mitral regurgitation (MR). The right ventricle was compressed by an enlarged LV, but RV systolic function was preserved. The value of NT-proBNP was highly increased. Viral polymerase chain reaction testing for myocarditis and metabolic tests results were negative. Genetic testing revealed that the patient is a heterozygous carrier of a new pathogenic molecular variant in the actin α cardiac muscle 1 (ACTC1) gene associated with the DCM phenotype. The patient received inotropic support in standard doses (dopamine, milrinone, one cycle of levosimendan infusion). The transcatheter atrial septostomy was performed to decrease left atrial pressure and pulmonary congestion. Because there was no improvement in the patient’s clinical condition, he was qualified for rPAB. Shortly after the surgery it was possible to stop inotropic support and continue oral HF therapy. During first 5 months of follow-up there were no considerable changes in LV and RV echocardiographic parameters, but there was significant clinical improvement (Ross class from IV to class II). During a routine follow-up visit, in TTE, an increase of pressure gradient across the PAB (60% above systemic arterial pressure) with deterioration of RV function was found. The partial PA debanding by the percutaneous balloon angioplasty was performed twice (on the 5th and 7th month) resulting in the establishment of optimal pressure gradient across the rPAB. After the procedure, improvement of RV function and normalization of NT-proBNP were observed (Figure 1).In the further follow-up period, improvement in the clinical condition (Ross class I), LV systolic function (EF and 2-D LVGLS), and an increase of right ventricle mid-cavity diameter (RVD2) were noticed (Figure 2). Weight changes of patient 1 treated with rPAB are presented in Figure 3. Case 2A 8-month-old female infant (M.A.) was admitted to our paediatric cardiology department from a regional hospital with symptoms of end-stage HF (Ross class IV). She received inotropic support (milrinone, dopamine). In the previous 2 weeks she was hospitalized because of mild upper respiratory infection and diarrhoea of adenovirus aetiology. There was no family history of cardiomyopathy or metabolic diseases. Genetic testing revealed that the patient was a heterozygous carrier of a new pathogenic molecular variant in the myosin-binding protein C (MYBPC3) gene correlating with DCM. Metabolic tests results were negative. Initial TTE demonstrated LV dilatation, and reduced EF and 2-D LVGLS with moderate MR. The right ventricle was compressed by an enlarged left ventricle, but its systolic function was preserved. After 2 cycles of levosimendan infusion and continuous treatment with intravenous inotropic drugs, no significant clinical or echocardiographic improvement was observed. A rapid increase of NT-proBNP value was found. Patient was qualified for rPAB. During follow-up, a gradual improvement of LVEF and 2-D LVGLS was noted (Figure 2). The RV was less compressed by the LV and the RVD2 diameter increased. The significant decrease of NT-proBNP values and improvement of the patient’s clinical status (Ross class I) were observed (Figure 1). Weight changes of patient 2 treated with rPAB are presented in Figure 3.DISCUSSIONDilated cardiomyopathy is the most frequent form of cardiomyopathy and a common cause of cardiac trans- plantation in the paediatric population. Literature reports indicate that 1- and 5-year rates of death or HTx were 31% and 46%, respectively [1]. The aetiology of childhood DCM is highly heterogeneous, but the most common causes are myocarditis, and metabolic (including mitochondrial) and idiopathic cases. Genetic tests and application of a panel consisting of genes associated with DCM enables the identification of pathogenic variants in about 30–50% of patients [2].It should be emphasized that in both of our patients genetic tests showed the presence of pathogenic molecular variants correlating with DCM. Literature reports showed that risk factors for death or HTx in childhood DCM include age at diagnosis (< 4 weeks and > 5 years), the presence of familial DCM, and severity of LV systolic dysfunction at baseline [5]. Our patients, like the majority of children with DCM, presented with severe congestive HF and high NT-proBNP values and were treated with ACE inhibitors, ß-blockers, mineralocorticoids, and less often diuretics, as recommended in the literature [6]. The ineffectiveness of pharmacological treatment prompted us to make further therapeutic decisions. In one child percutaneous transcatheter atrial septostomy and left atrial decompression were performed as a bridge to HTx or recovery, as described in the literature [7]. The concept of rPAB in end-stage DCM in children < 3 years of age was introduced by the Paediatric Heart Centre in Giessen [4]. The main aim of this treatment strategy is to support functional recovery of LV in DCM patients. Placement of PAB increases RV pressure, which gradually induces RV hypertrophy, and consequently, by shifting the interventricular septum towards the LV, it changes its morphology (from round to ellipsoidal) and improves LV systolic function. This surgical procedure was performed on both of our infants. It should be stressed that in echocardiography we observed a septal shift in both patients. Post-operatively, our patients underwent echocardiographic follow-up to assess myocardial recovery. It is particularly important to look for signs of RV pressure overload such as RV dilation or onset or worsening of tricuspid valve regurgitation. In such cases the PAB may be loosened in stages during a balloon catheter-based procedure to accomplish the optimal mild residual RV-PA pressure gradient of 15–30 mm Hg. In case 1, percutaneous loosening of the rPAB was performed twice. Based on our experience, we concluded that RVD2 will be the best parameter for assessment of the ventriculo- ventricular interaction. In both our cases the RVD2 diameter increased gradually during follow-up. Den Boer et al. [3] reported that, in paediatric DCM, 2-D LVGLS was a useful additional parameter and predictive of death and HTx. To our knowledge, this clinical report is the first in the literature which describes changes and improvement of 2-D LVGLS after rPAB. It should be noted that during 15 months of follow-up, clinical improvement, and a tendency for decreased NT-proBNP values and echocardiographic parameters were markedly improved (reduction of LVEDD, increasing of EF, 2-D LVGLS, and RVD2) in our patients.CONCLUSIONSOur early experience with rPAB in young children with end-stage DCM, like the results of other authors [4, 8, 9], indicates that this palliative therapeutic strategy is an effective alternative to mechanical support, HTx, and improves their clinical and haemodynamic status.DISCLOSUREThe authors declare no conflict of interest.REFERENCES1. Towbin JA, Lowe AM, Colan SD, et al. Incidence, causes, and outcomes of dilated cardiomyopathy in children. JAMA 2006; 296: 1867-1876. 2.
Lipshultz SE, Law YM, Asante-Korang A, et al. Cardiomyopathy in children: classification and diagnosis: a scientific statement from the American Heart Association. Circulation 2019; 140: e9-e68. 3.
Den Boer SL, du Marchie Sarvaas GJ, Klitsie LM, et al. Longitudinal strain as risk factor for outcome in pediatric dilated cardiomyopathy. JACC Cardiovasc Imaging 2016; 9: 1121-1122. 4.
Schranz D, Rupp S, Müller M, et al. Pulmonary artery banding in infants and young children with left ventricular dilated cardiomyopathy: a novel therapeutic strategy before heart transplantation. J Heart Lung Transplant 2013; 32: 475-481. 5.
Alvarez JA, Orav EJ, Wilkinson JD, et al. Competing risks for death and cardiac transplantation in children with dilated cardiomyopathy: results from the pediatric cardiomyopathy registry. Circulation 2011; 124: 814-823. 6.
Schranz D, Voelkel NF. “Nihilism” of chronic heart failure therapy in children and why effective therapy is withheld. Eur J Pediatr 2016; 175: 445-455. 7.
Bauer A, Khalil M, Schmidt D, et al. Transcatheter left atrial decompression in patients with dilated cardiomyopathy: bridging to cardiac transplantation or recovery. Cardiol Young 2019; 29: 355-362. 8.
Schranz D, Akintuerk H, Bailey L. Pulmonary artery banding for functional regeneration of end-stage dilated cardiomyopathy in young children: World Network Report. Circulation 2018; 137: 1410-1412. 9.
Di Candia A, Castaldi B, Bordin G, et al. Pulmonary artery banding for ventricular rehabilitation in infants with dilated cardiomyopathy: early results in a single-center experience. Front Ped 2020; 8: 347.
Copyright: © 2023 Polish Society of Paediatrics. 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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