Hemodynamic performance of Edwards Intuity valve in a compliant aortic root model

Numerous designs of bioprosthetic valves exist. The sutureless surgical valve is a newer design concept which combines elements of the transcatheter valve technology with surgical valves. This design aims at shorter and easier implantation. It was the aim of this study to perform hemodynamic and kin...

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Main Authors: Jahren, S. E., Heinisch, P. P., Wirz, J., Winkler, B. M., Carrel, T., Obrist, D.
Format: Conference Proceeding
Language:English
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Fluids
Heart
Hemodynamics
In vitro
Kinematics
Surgery
Valves
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creator Jahren, S. E.
Heinisch, P. P.
Wirz, J.
Winkler, B. M.
Carrel, T.
Obrist, D.
description Numerous designs of bioprosthetic valves exist. The sutureless surgical valve is a newer design concept which combines elements of the transcatheter valve technology with surgical valves. This design aims at shorter and easier implantation. It was the aim of this study to perform hemodynamic and kinematic measurements for this type of valves to serve as a baseline for following studies which investigate the effect of the aortic root on the valve performance. To this end, the Edwards Intuity aortic valve was investigated in a new in vitro flow loop mimicking the left heart. The valve was implanted in a transparent, compliant aortic root model, and the valve kinematics was investigated using a high speed camera together with synchronized hemodynamic measurements of pressures and flows. The valve closure was asynchronous (one by one leaflet), and the valve started to close before the deceleration of the fluid. The aortic root model showed a dilation of the sinuses which was different to the ascending aorta, and the annulus was found to move towards the left ventricle during diastole and towards the aorta during systole.
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source IEEE Electronic Library (IEL) Conference Proceedings
subjects Fluids
Heart
Hemodynamics
In vitro
Kinematics
Surgery
Valves
title Hemodynamic performance of Edwards Intuity valve in a compliant aortic root model
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