Right ventricular outflow tract landing zone perimeter / circularised diameter - new imaging standards in pulmonary valve replacement reporting.

BACKGROUND: Right ventricular outflow tract intervention spans transcatheter, surgical, or hybrid pulmonary valve replacement methodologies. Standardised pre-procedure workup includes cardiac MRI to identify an intended valve site (landing zone). Our institutional practice includes measurement of the right ventricular outflow tract perimeter (circumference) of this site in end-systole. Our primary aim was to compare patients by their perimeter values to the palliative interventions performed (transcatheter versus surgical/hybrid methodologies). METHODS: Retrospective review of patients undergoing pulmonary valve replacement from January 2017 to 2021. We performed perimeter measurements at the intended valve site on advanced imaging; the outcomes of interventions were outlined via descriptive and statistical analyses. RESULTS: A total of 37 patients underwent pulmonary valve replacement that met study criteria - 21 transcatheter, 7 surgical, and 9 hybrid. Median age at intervention was 26 years (range 8-70). The mean end-systolic perimeter of the transcatheter cohort was 88.9 ± 8.7 mm and in the surgical/hybrid cohort measured 106.6 ± 7.5 mm. For the transcatheter cohort, the median "circularised" diameter derived from the perimeter measurement (divided by π) was 27.7 mm (range 24.3-32.4). Notably, this correlated (r = 0.93, p < 0.01) with the median diameter of the narrowest region during actual transcatheter right ventricular outflow tract balloon sizing (lateral imaging) of 27.1 mm (range 23.2-30.1). CONCLUSIONS: Right ventricular outflow tract perimeter measurement to determine circularised diameter is useful in planning pulmonary valve replacement in terms of candidacy of transcatheter versus the need for a surgical/hybrid approach. The circularised diameter correlates with transcatheter right ventricular outflow tract balloon sizing.

Nomenclature for Pediatric and Congenital Cardiac Care: Unification of Clinical and Administrative Nomenclature - The 2021 International Paediatric and Congenital Cardiac Code (IPCCC) and the Eleventh Revision of the International Classification of Diseases (ICD-11).

Substantial progress has been made in the standardization of nomenclature for paediatric and congenital cardiac care. In 1936, Maude Abbott published her Atlas of Congenital Cardiac Disease, which was the first formal attempt to classify congenital heart disease. The International Paediatric and Congenital Cardiac Code (IPCCC) is now utilized worldwide and has most recently become the paediatric and congenital cardiac component of the Eleventh Revision of the International Classification of Diseases (ICD-11). The most recent publication of the IPCCC was in 2017. This manuscript provides an updated 2021 version of the IPCCC.The International Society for Nomenclature of Paediatric and Congenital Heart Disease (ISNPCHD), in collaboration with the World Health Organization (WHO), developed the paediatric and congenital cardiac nomenclature that is now within the eleventh version of the International Classification of Diseases (ICD-11). This unification of IPCCC and ICD-11 is the IPCCC ICD-11 Nomenclature and is the first time that the clinical nomenclature for paediatric and congenital cardiac care and the administrative nomenclature for paediatric and congenital cardiac care are harmonized. The resultant congenital cardiac component of ICD-11 was increased from 29 congenital cardiac codes in ICD-9 and 73 congenital cardiac codes in ICD-10 to 318 codes submitted by ISNPCHD through 2018 for incorporation into ICD-11. After these 318 terms were incorporated into ICD-11 in 2018, the WHO ICD-11 team added an additional 49 terms, some of which are acceptable legacy terms from ICD-10, while others provide greater granularity than the ISNPCHD thought was originally acceptable. Thus, the total number of paediatric and congenital cardiac terms in ICD-11 is 367. In this manuscript, we describe and review the terminology, hierarchy, and definitions of the IPCCC ICD-11 Nomenclature. This article, therefore, presents a global system of nomenclature for paediatric and congenital cardiac care that unifies clinical and administrative nomenclature.The members of ISNPCHD realize that the nomenclature published in this manuscript will continue to evolve. The version of the IPCCC that was published in 2017 has evolved and changed, and it is now replaced by this 2021 version. In the future, ISNPCHD will again publish updated versions of IPCCC, as IPCCC continues to evolve.

Myocardial stress perfusion magnetic resonance in children with hypertrophic cardiomyopathy.

BACKGROUND: Microvascular dysfunction in hypertrophic cardiomyopathy has been associated with poor clinical outcome. Several studies have demonstrated a reduced perfusion reserve proportional to the magnitude of the hypertrophy. We investigated the utility of stress perfusion cardiac MRI to detect microvascular dysfunction in children with hypertrophic cardiomyopathy. METHODS: From January 2016 to January 2017, 13 patients, with a mean age of 15.3 years, with hypertrophic cardiomyopathy underwent regadenoson stress perfusion cardiac MRI (1.5-T Siemens Aera). A single-shot, T1-weighted saturation recovery gradient echo was used for first-pass perfusion in a multiple-slices group, including three short-axis slices and one four-chamber slice. Coronary vasodilatory stress was achieved using bolus injection of regadenoson (lexiscan 0.4 mg/5 ml) and dynamic perfusion during rest and stress performed by administering 0.05 mmol/kg of gadolinium contrast agent (gadoteridol) injected at a rate of 3.5 ml/s, followed by assessment of viability using two-dimensional phase-sensitive inversion recovery of the entire myocardium. RESULTS: All patients completed protocols with no interruptions. In all, seven patients developed perfusion defects after the administration of regadenoson. Asymmetric septal hypertrophy was the most common pattern of hypertrophic cardiomyopathy (n=4) in those with abnormal perfusion. A total of four patients with perfusion defects had a maximum wall thickness <30 mm. The finding of perfusion defects in areas without late gadolinium enhancement in some of our patients indicates that gadolinium enhancement by itself could underestimate the true extension of microvascular disease. Out of seven patients, five patients with positive stress cardiac MRI have undergone implantable cardioverter defibrillator placement based on current guidelines. CONCLUSIONS: Regadenoson stress cardiac MRI is feasible and clinically valuable in paediatric patients. It is particularly effective in unmasking abnormal myocardial perfusion in the presence of microvascular dysfunction in children with hypertrophic cardiomyopathy.

Synthetic hematocrit derived from the longitudinal relaxation of blood can lead to clinically significant errors in measurement of extracellular volume fraction in pediatric and young adult patients.

BACKGROUND: Extracellular volume fraction (ECV) is altered in pathological cardiac remodeling and predicts death and arrhythmia. ECV can be quantified using cardiovascular magnetic resonance (CMR) T1 mapping but calculation requires a measured hematocrit (Hct). The longitudinal relaxation of blood has been used in adults to generate a synthetic Hct (estimate of true Hct) but has not been validated in pediatric populations. METHODS: One hundred fourteen children and young adults underwent a total of 163 CMRs with T1 mapping. The majority of subjects had a measured Hct the same day (N = 146). Native and post-contrast T1 were determined in blood pool, septum, and free wall of mid-LV, avoiding areas of late gadolinium enhancement. Synthetic Hct and ECV were calculated and intraclass correlation coefficient (ICC) and linear regression were used to compare measured and synthetic values. RESULTS: The mean age was 16.4 ± 6.4 years and mean left ventricular ejection fraction was 59% ± 9%. The mean measured Hct was 41.8 ± 3.0% compared to the mean synthetic Hct of 43.2% ± 2.9% (p < 0.001, ICC 0.46 [0.27, 0.52]) with the previously published model and 41.8% ± 1.4% (p < 0.001, ICC 0.28 [0.13, 0. 42]) with the locally-derived model. Mean measured mid-free wall ECV was 30.5% ± 4.8% and mean synthetic mid-free wall ECV of local model was 29.7% ± 4.6% (p < 0.001, ICC 0.93 [0.91, 0.95]). Correlations were not affected by heart rate and did not significantly differ in subpopulation analysis. While the ICC was strong, differences between measured and synthetic ECV ranged from -8.4% to 4.3% in the septum and -12.6% to 15.8% in the free wall. Using our laboratory's normal cut-off of 28.5%, 59 patients (37%) were miscategorized (53 false negatives, 6 false positives) with published model ECV. The local model had 37 miscategorizations (20 false negatives, 17 false positives), significantly fewer but still a substantial number (23%). CONCLUSIONS: Our data suggest that use of synthetic Hct for the calculation of ECV results in miscategorization of individual patients. This difference may be less significant once synthetic ECV is calculated and averaged over a large research cohort, making it potentially useful as a research tool. However, we recommend formal measurement of Hct in children and young adults for clinical CMRs.

Crossed pulmonary arteries with hypoplasia of the transverse aortic arch.

BACKGROUND: The entity of crossed pulmonary arteries was first described by Jue, Lockman, and Edwards in 1966, in a patient with trisomy 18. Since then, several series have been described, both in terms of the isolated anatomic variant, or its association with other intracardiac or extracardiac anomalies. We describe a rare association that has previously not been reported. Methods and results Institutional Review Board approval for a retrospective chart review was obtained. Over the period 2011 through 2013, we have encountered six patients in whom the crossed origins of the pulmonary arteries from the pulmonary trunk were associated with hypoplasia of the transverse aortic arch, an association that, to the best of our knowledge, has previously not been reported. In all of the patients, the isthmic component of the aortic arch was inserted in an end-to-side manner into the ductal arch, with additional discrete coarctation in half of the patients. CONCLUSION: To the best of our knowledge, no cases of crossed pulmonary arteries have been described in association with hypoplasia of the transverse aortic arch. We draw comparisons between the cases with exclusively tubular hypoplasia, and those with the added problem of the more typical isthmic variant of aortic coarctation. In all cases, the ability to reconstruct cross-sectional images added significantly to the diagnosis and understanding of these complex lesions. These findings have specific surgical implications, which are discussed.

Takotsubo cardiomyopathy: how much do we know of this syndrome in children and young adults?

Since Takotsubo cardiomyopathy was first described by Sato in 1990, multiple cases have been reported, but only few in children, among whom this type of cardiomyopathy is to some extent underappreciated. A series of children with this syndrome were therefore reviewed, drawing comparison with cases reported by others. The review addresses the current challenges in diagnosis, presentation, triggers, clinical course, management, and possible pathogenic mechanisms of the entity.

Atrioventricular septal defect with an imperforate right-sided component of the common atrioventricular valve: anatomic and embryologic considerations.

We describe an atypical case of an atrioventricular septal defect with a common atrioventricular junction in which the right-sided component of the common atrioventricular valve was imperforate, producing tricuspid atresia with a severely hypoplastic right ventricle and an ostium primum defect. We discuss the implications of the anatomic findings with regard to concepts of cardiac development, drawing a comparison with similar cases previously reported.

Nomenclature for Pediatric and Congenital Cardiac Care: Unification of Clinical and Administrative Nomenclature - The 2021 International Paediatric and Congenital Cardiac Code (IPCCC) and the Eleventh Revision of the International Classification of Diseases (ICD-11).

Substantial progress has been made in the standardization of nomenclature for paediatric and congenital cardiac care. In 1936, Maude Abbott published her Atlas of Congenital Cardiac Disease, which was the first formal attempt to classify congenital heart disease. The International Paediatric and Congenital Cardiac Code (IPCCC) is now utilized worldwide and has most recently become the paediatric and congenital cardiac component of the Eleventh Revision of the International Classification of Diseases (ICD-11). The most recent publication of the IPCCC was in 2017. This manuscript provides an updated 2021 version of the IPCCC.The International Society for Nomenclature of Paediatric and Congenital Heart Disease (ISNPCHD), in collaboration with the World Health Organization (WHO), developed the paediatric and congenital cardiac nomenclature that is now within the eleventh version of the International Classification of Diseases (ICD-11). This unification of IPCCC and ICD-11 is the IPCCC ICD-11 Nomenclature and is the first time that the clinical nomenclature for paediatric and congenital cardiac care and the administrative nomenclature for paediatric and congenital cardiac care are harmonized. The resultant congenital cardiac component of ICD-11 was increased from 29 congenital cardiac codes in ICD-9 and 73 congenital cardiac codes in ICD-10 to 318 codes submitted by ISNPCHD through 2018 for incorporation into ICD-11. After these 318 terms were incorporated into ICD-11 in 2018, the WHO ICD-11 team added an additional 49 terms, some of which are acceptable legacy terms from ICD-10, while others provide greater granularity than the ISNPCHD thought was originally acceptable. Thus, the total number of paediatric and congenital cardiac terms in ICD-11 is 367. In this manuscript, we describe and review the terminology, hierarchy, and definitions of the IPCCC ICD-11 Nomenclature. This article, therefore, presents a global system of nomenclature for paediatric and congenital cardiac care that unifies clinical and administrative nomenclature.The members of ISNPCHD realize that the nomenclature published in this manuscript will continue to evolve. The version of the IPCCC that was published in 2017 has evolved and changed, and it is now replaced by this 2021 version. In the future, ISNPCHD will again publish updated versions of IPCCC, as IPCCC continues to evolve.

Takotsubo cardiomyopathy: an unusual cardiomyopathy at an unusual age.

We describe an atypical presentation of stress-induced cardiomyopathy - Takotsubo cardiomyopathy - in a 16-month-old boy previously diagnosed with cyclic vomiting and episodic hypertension. He developed features of cardiac failure and his echocardiogram showed left ventricular wall motion abnormality accompanied with elevated cardiac enzymes. Cardiac catheterisation showed no coronary arterial abnormality. Complete spontaneous recovery occurred 2 weeks after admission.

Global Left Ventricular Relaxation: A Useful Echocardiographic Marker of Heart Transplant Rejection and Recovery in Children.

BACKGROUND: Tissue Doppler velocities are impaired after heart transplantation and further diminished in acute rejection. METHODS: Left ventricular relaxation index (LVRI) was calculated as the sum of E' of the left ventricular lateral, septal and posterior walls divided by left ventricular posterior wall (LVPW) thinning (LVRI = E' lateral + E' septal + E' posterior/[systolic LVPW - diastolic LVPW/systolic LVPW]). On the basis of a prior study, LVRI > 0.8 was considered normal after transplantation. Serial LVRI measurements (n = 941) were analyzed in a total of 35 patients who underwent transplantation. The sensitivity and specificity of LVRI < 0.8 for detecting rejection were calculated. LVRI was compared at baseline, at diagnosis of rejection, and at recovery after rejection treatment for each patient. The potential role of ischemic graft time, pretransplantation waiting period, and pretransplantation diagnosis on LVRI recovery was also assessed. RESULTS: LVRI was low early after transplantation (mean, 0.69) normalizing (mean, 0.91) at a median of 39.6 days (range, 5-115 days) after transplantation. Fifteen episodes of rejection were seen in 11 patients. LVRI was lower at diagnosis of rejection compared with baseline (P = .0013). LVRI < 0.8 had 93.3% sensitivity (95% CI, 68%-99.8%) and 89.5% specificity (95% CI, 67%-99%) for detecting all rejection. LVRI recovered at a mean of 28.3 days after onset of treatment. No correlation was found to ischemic graft time, to pretransplantation waiting period, or to pretransplantation diagnosis. CONCLUSION: After the early posttransplantation period, serial measurements of LVRI appear to be a useful echocardiographic marker of heart transplantation rejection in children and of the effectiveness of rejection treatment. As such, this method may be of value in the ongoing clinical management of these difficult patients.

Novel Loss of Function in the AGK Gene: Rare Cause of End-Stage Heart Failure.

The authors present a case of mitochondrial cardiomyopathy due to a novel mutation of AGK gene that led to progressive heart failure. The cardiac magnetic resonance image findings of diffusely elevated relaxation time and increase in extracellular volume in the myocardium without early or late gadolinium enhancement may suggest mitochondrial cardiomyopathy. The authors emphasized the multidisciplinary team approach in the care of patients with mitochondrial cardiomyopathies. (Level of Difficulty: Advanced.).

Global left ventricular relaxation: A novel tissue Doppler index of acute rejection in pediatric heart transplantation.

BACKGROUND: Serial invasive cardiac catheterization with endomyocardial biopsies (EMBs) is the current standard of reference for evaluation after orthotopic heart transplant (OHTx). We developed a novel, non-invasive echocardiographic index of global left ventricular relaxation (LVRI) and assessed its sensitivity, specificity and predictive value for detecting rejection compared with EMB results in a prospective study conducted from September 2012 through May 2014. METHODS: LVRI was calculated as the sum of diastolic tissue Doppler imaging (TDI) velocities (E') of the left ventricular lateral, septal and posterior walls divided by the percentage of left ventricular posterior wall (LVPW) thinning by M-mode. LVRI was measured in 47 OHTx patients and 50 patients with normal hearts. Of the 33 patients who underwent clinically indicated EMB, 22 patients had Grade 0R EMB, 6 had Grade 1R and 5 had Grade 2R to 3R biopsy results. Sensitivity, specificity and predictive value of LVRI for discriminating Grade 1R to 3R EMB were calculated. The LVRI was compared before and after OHTx rejection treatment and during the early and late post-transplant period. To characterize LVRI, 1-way analysis of variance was used to compare all groups, including non-OHTx patients. RESULTS: LVRI was lower in patients with Grade 0R EMBs compared with non-OHTx patients. Patients with Grade 1R to 3R EMBs had lower LVRI than those with Grade 0R EMBs. LVRI recovered after treatment for rejection. LVRI appeared to normalize between 40 and 90 days post-transplantation. After 90 days, sensitivity was 100% and specificity was 90.9% for detecting patients with Grade 1R to 3R EMBs using an LVRI of 0.8. CONCLUSION: LVRI, a novel, non-invasive TDI index of global left ventricular diastolic dysfunction, appears to be useful for detecting rejection in children beyond 3 months post-OHTx.

The Right Subclavian Artery Arising as the First Branch of a Left-Sided Aortic Arch.

We describe an unusual pattern of branching of a left-sided aortic arch in which the first branch is the right subclavian artery, followed by the common carotid arteries arising from a common trunk. The patient was born with transposition (concordant atrioventricular and discordant ventriculoarterial connections) and had 18q23 deletion. We discuss the implication of these anatomic findings in the light of inferences currently made by echocardiographers when the first branch of the aortic arch fails to bifurcate. We also relate the findings to the concepts of cardiac development and draw comparisons with previous descriptions, and interpretations of the morphogenesis, of the patterns of branching from the aortic arch.