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A Cavopulmonary Assist Device for Long-Term Therapy of Fontan Patients

Andreas Escher, Carsten Strauch, Emanuel J. Hubmann, Michael Hübler, Dominik Bortis, Bente Thamsen, Marc Mueller, Ulrich Kertzscher, Paul Uwe Thamsen, Johann W. Kolar, Daniel Zimpfer, Marcus Granegger

2021Seminars in Thoracic and Cardiovascular Surgery25 citationsDOIOpen Access PDF

Abstract

Treatment of univentricular hearts remains restricted to palliative surgical corrections (Fontan pathway). The established Fontan circulation lacks a subpulmonary pressure source and is commonly accompanied by progressively declining hemodynamics. A novel cavopulmonary assist device (CPAD) may hold the potential for improved therapeutic management of Fontan patients by chronic restoration of biventricular equivalency. This study aimed at translating clinical objectives toward a functional CPAD with preclinical proof regarding hydraulic performance, hemocompatibility and electric power consumption. A prototype composed of hemocompatible titanium components, ceramic bearings, electric motors, and corresponding drive unit was manufactured for preclinical benchtop analysis: hydraulic performance in general and hemocompatibility characteristics in particular were analyzed in-silico (computational fluid dynamics) and validated in-vitro. The CPAD's power consumption was recorded across the entire operational range. The CPAD delivered pressure step-ups across a comprehensive operational range (0–10 L/min, 0–50 mm Hg) with electric power consumption below 1.5 W within the main operating range. In-vitro hemolysis experiments (N = 3) indicated a normalized index of hemolysis of 3.8 ± 1.6 mg/100 L during design point operation (2500 rpm, 4 L/min). Preclinical investigations revealed the CPAD's potential for low traumatic and thrombogenic support of a heterogeneous Fontan population (pediatric and adult) with potentially accompanying secondary disorders (e.g., elevated pulmonary vascular resistance or systemic ventricular insufficiency) at distinct physical activities. The low power consumption implied adequate settings for a small, fully implantable system with transcutaneous energy transfer. The successful preclinical proof provides the rationale for acute and chronic in-vivo trials aiming at the confirmation of laboratory findings and verification of hemodynamic benefit. Treatment of univentricular hearts remains restricted to palliative surgical corrections (Fontan pathway). The established Fontan circulation lacks a subpulmonary pressure source and is commonly accompanied by progressively declining hemodynamics. A novel cavopulmonary assist device (CPAD) may hold the potential for improved therapeutic management of Fontan patients by chronic restoration of biventricular equivalency. This study aimed at translating clinical objectives toward a functional CPAD with preclinical proof regarding hydraulic performance, hemocompatibility and electric power consumption. A prototype composed of hemocompatible titanium components, ceramic bearings, electric motors, and corresponding drive unit was manufactured for preclinical benchtop analysis: hydraulic performance in general and hemocompatibility characteristics in particular were analyzed in-silico (computational fluid dynamics) and validated in-vitro. The CPAD's power consumption was recorded across the entire operational range. The CPAD delivered pressure step-ups across a comprehensive operational range (0–10 L/min, 0–50 mm Hg) with electric power consumption below 1.5 W within the main operating range. In-vitro hemolysis experiments (N = 3) indicated a normalized index of hemolysis of 3.8 ± 1.6 mg/100 L during design point operation (2500 rpm, 4 L/min). Preclinical investigations revealed the CPAD's potential for low traumatic and thrombogenic support of a heterogeneous Fontan population (pediatric and adult) with potentially accompanying secondary disorders (e.g., elevated pulmonary vascular resistance or systemic ventricular insufficiency) at distinct physical activities. The low power consumption implied adequate settings for a small, fully implantable system with transcutaneous energy transfer. The successful preclinical proof provides the rationale for acute and chronic in-vivo trials aiming at the confirmation of laboratory findings and verification of hemodynamic benefit. Central MessageA novel cavopulmonary assist device showed little traumatic potential at low power consumption and across a comprehensive clinically relevant range of hemodynamic conditions in Fontan patients.Perspective StatementLong-term cavopulmonary support remains in its infancy. This study presents a novel cavopulmonary assist device for chronic support in an inclusive Fontan patient population. In-silico and in-vitro analysis delivered the preclinical proof for a fully implantable, hemocompatible device design. Acute and chronic in-vivo trials are proposed to support laboratory findings. A novel cavopulmonary assist device showed little traumatic potential at low power consumption and across a comprehensive clinically relevant range of hemodynamic conditions in Fontan patients. Long-term cavopulmonary support remains in its infancy. This study presents a novel cavopulmonary assist device for chronic support in an inclusive Fontan patient population. In-silico and in-vitro analysis delivered the preclinical proof for a fully implantable, hemocompatible device design. Acute and chronic in-vivo trials are proposed to support laboratory findings.

Topics & Concepts

MedicineFontan procedurePopulationHemodynamicsCardiologyBiomedical engineeringInternal medicineSurgeryHeart diseaseEnvironmental healthMechanical Circulatory Support DevicesCongenital Heart Disease StudiesCardiac Structural Anomalies and Repair
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