First-in-man use of the EXCOR Venous Cannula for combined cavopulmonary and systemic ventricular support in Fontan circulation failure.

BACKGROUND AND AIM: The Berlin Heart EXCOR system has been developed for mechanical circulatory support (MCS) of pediatric patients with terminal heart failure. A recently introduced iteration of the system (EXCOR Venous Cannula, Berlin Heart GmbH, Berlin, Germany) is dedicated to support patients with univentricular physiologies by facilitating implantation of the EXCOR device into the Fontan pathway. CASE PRESENTATION: We report the worldwide first successful implantation of the EXCOR Venous Cannula in a biventricular support concept for a 12-year-old boy (140 cm, 42.7 kg, body surface area 1.29 m2, Pedimacs Level 2) with severe systemic ventricle dysfunction and failing Fontan circulation. Surgery comprised of standard Berlin Heart EXCOR implantation to support the failing ventricle (12 mm apex / staged 12/9 mm arterial cannula / 50 ml ventricle). Cannulation for subpulmonary EXCOR support was achieved by performing a total cavopulmonary connection takedown with subsequent anastomosis of a staged 12/9 mm outflow cannula to the pulmonary artery and implantation of a 14/18 mm EXCOR Venous Cannula as subpulmonary inflow graft, which was connected to the superior vena cava and Fontan tunnel using GORE-TEX grafts. In the postoperative course, cardiac output and central venous pressures rapidly improved with hepatic and renal functions restoring to age- and condition-specific norm values. CONCLUSION: The Berlin Heart EXCOR Venous Cannula is the first system for standardized mechanical support of Fontan circulatory failure. In our patient, subpulmonary support restoring a biventricular circulation combined with systemic MCS normalized hemodynamics and reversed end-organ dysfunction.

Ten Years of Data Verification: The European Congenital Heart Surgeons Association Congenital Database Audits.

BACKGROUND: Congenital heart surgery databases are tools for internal programmatic evaluation, benchmarking institutional results to multi-institutional aggregate data, and research. Therefore, it is essential to ensure the completeness and accuracy of data. This study analyzes the results of ten years of on-site source data verification of the European Congenital Heart Surgeons Association Congenital Heart Surgery Database (ECHSA CHSD). METHODS: All data forms verified between 2009 and 2018 were analyzed. The data form consists of 12 data elements: dates of birth, admission, surgery, discharge, and death; weight; case category; cardiopulmonary bypass time; aortic cross-clamp time; validation rules; diagnoses; and procedures. Descriptive data calculation and rates of completeness and accuracy were determined. The trend of error rate of seven centers with ≥5 visits was analyzed. RESULTS: Sixty-nine on-site verification visits took place at 17 centers. A total of 26,245 cases were verified; 2,841 of these 26,245 cases (10.8%) showed an error. The total mean error rate of centers for all years was 12.3 ± 2.1%. Rates of completeness and accuracy were 99% and 89.2%, respectively. Coded diagnoses and procedure analysis revealed that 716 (2.7%) and 456 (1.7%) datasets were incorrect, respectively. Rates of completeness and accuracy of dates were 100%, and 97.1%, respectively. Validation fields showed no errors. CONCLUSION: Source data verification is an appropriate tool to determine completeness and accuracy of data. The ECHSA CHSD verification analysis of a ten-year period showed a high level of completeness and accuracy. The verified data of the ECHSA CHSD are well-suited for benchmarking and research.

Copeptin: Prognostic Relevance as a Perioperative Marker in Pediatric Cardiac Surgery.

BACKGROUND: Copeptin is a cleavage product of vasopressin. This study aimed to figure out if copeptin would be a suitable biomarker in patients with congenital heart disease in the postoperative course. METHODS: The primary outcome endpoint of this study was the change in copeptin concentration perioperatively in patients with congenital heart disease after surgery, with the use of a cardiopulmonary bypass. Three blood samples were taken from 81 patients up to 6 years of age in order to evaluate changes in copeptin concentration. RESULTS: Significant increase of copeptin concentration was shown between the first and second blood draws as well as between the first and third blood draws (Ps < .001). Additionally, positive and significant correlations (r ≥ .27) between the cardiopulmonary bypass times, The Society of Thoracic Surgeons and European Association for Cardio-Thoracic Surgery mortality category, the inotropic score, the duration of mechanical ventilation, the length of stay at the intensive care unit (ICU), the length of stay at the hospital, and the preoperative as well as the ICU copeptin levels were found. CONCLUSIONS: Copeptin showed a tendency to predict the clinical outcome of patients after congenital heart surgery. Patients with higher copeptin levels underwent more complex procedures, had longer cardiopulmonary bypass times, required more catecholamine support, needed longer time of invasive ventilation, and had longer overall stay and ICU stay.

Ozaki procedure: Ex vivo simulation.

Replacements for diseased aortic valves are limited. Repair of the aortic valve is performed by only a few surgeons. A novel technique of aortic valve reconstruction using autologous pericardium shows promising results. In this video tutorial, we demonstrate the Ozaki procedure using an ex vivo low fidelity simulation.

Implanting the HeartMate 6 (total artificial heart).

The HeartMate 3 is a ventricular assist device that supports the heart with a centrifugal continuous flow. It contains a fully levitated rotor to minimize hemolysis and was initially designed as an apical intrapericardial implant. It can be used as a bridge to a transplant, to recovery, or to destination therapy. After we excise the ventricles, we implant 2 HeartMate 3 devices as a total artificial heart (HeartMate 6). The patient was 35 years old when the devices were implanted and had been diagnosed with Yamaguchi syndrome (apical hypertrophic cardiomyopathy) at 13 years of age. Being listed for a transplant was not an option due to secondary pulmonary hypertension. Furthermore, the conventional method of apically implanting a left ventricular assist device was not possible due to the underlying pathology. A HeartMate 6 implant as a bridge to transplant therapy was planned. Additionally, a CardioMEMS HF System was implanted to monitor the pulmonary artery pressure. The video tutorial provides step-by-step instructions for implanting 2 HeartMate 3 devices as a total artificial heart.

Surgical stented transcatheter valve-in-valve implantation in atrioventricular position in children.

The Melody valve (Medtronic, Minneapolis, MN, USA) is a stented bovine jugular vein graft that was primarily approved for transcatheter implantation in a pulmonary valve position. The prosthetic valve can also be implanted in an atrioventricular position in infants and young children, and in these cases it must be modified appropriately.  In this tutorial we demonstrate the surgical preparation of a stented transcatheter Melody valve for implantation in the atrioventricular position. Additionally, we present a safe and effective method for surgical valve-in-valve implantation in a 3-year-old patient with hypoplastic left heart syndrome.

Implantation of a decellularized aortic homograft in a child.

The implantation of a decellularized aortic homograft in children and young adults has been shown to be a good alternative to existing surgical approaches. Lower risk of calcification and the potential of growth render a homograft a promising valve substitute. The child presented in this video tutorial is a 10-year-old boy diagnosed with congenital aortic stenosis which was treated by balloon valvuloplasty early in life. Current echocardiographic findings show severe aortic regurgitation and stenosis. The tutorial provides detailed insight into how to implant a decellularized aortic homograft as a total root replacement.

Implantation of the Berlin Heart EXCOR ventricular assist device.

The Berlin Heart EXCOR® is a mechanical, pulsatile ventricular assist device. The paracorporeal assist device is pneumatically driven and can be used for long-term bridging therapy of one or both ventricles (LVAD, BIVAD, RVAD). It is specifically designed for pediatric patients and can be used in neonates as well as juveniles and adults.  The infant presented in this video tutorial was diagnosed with myocarditis leading to end-stage heart failure and severe mitral valve regurgitation. A bridging therapy was indicated and a Berlin Heart EXCOR® VAD was implanted. This tutorial provides detailed insight on how to perform this procedure. In addition, a safe and effective way of extending the outflow cannula is demonstrated.

Reinforcement of the pulmonary autograft root in the Ross operation.

In this video tutorial we demonstrate our technique of root reinforcement of the pulmonary autograft in a Ross operation. This technique is being used with increasing frequently to prevent the formation of an aneurysm of the pulmonary autograft.  The patient presented in the video has a bicuspid aortic valve with severe symptomatic aortic valve stenosis and moderate regurgitation. After harvesting, the pulmonary autograft it is sized and a 3- or 5-mm oversized Valsalva vascular prosthesis is chosen for reinforcement and to prevent formation of an aneurysm. Sizing depends on the amount and thickness of muscle in the pulmonary autograft.

The Konno-Rastan procedure.

The Konno-Rastan procedure is an anterior aortoventriculoplasty that has  the aim of relieving subvalvar, valvar, and supravalvar stenosis. It can be helpful for patients with aortic stenosis at any level and also for those with a prior implanted aortic and/or mitral prosthesis.  The patient presented in this video tutorial had a history of rheumatic heart disease with previously implanted mechanical prostheses in the aortic as well as the mitral position. We provide detailed insight on how to perform the Konno incision safely and demonstrate the reconstruction of the aortic root, as well as the ventricular septum and the right ventricular outflow tract using a patch of bovine pericardium.