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Auteurs principaux: Zingaro, Alberto, Burba, Irmantas, Oks, David, Fontana, Mauro, Samaniego, Cristóbal, Bischofberger, Micha, de Boeck, Bart, Douverny, Andre, Karakas, Özge, Toggweiler, Stefan, Arzamendi-Aizpurua, Dabit, Gülan, Utku, Vázquez, Mariano
Format: Preprint
Publié: 2024
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Accès en ligne:https://arxiv.org/abs/2404.08632
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author Zingaro, Alberto
Burba, Irmantas
Oks, David
Fontana, Mauro
Samaniego, Cristóbal
Bischofberger, Micha
de Boeck, Bart
Douverny, Andre
Karakas, Özge
Toggweiler, Stefan
Arzamendi-Aizpurua, Dabit
Gülan, Utku
Vázquez, Mariano
author_facet Zingaro, Alberto
Burba, Irmantas
Oks, David
Fontana, Mauro
Samaniego, Cristóbal
Bischofberger, Micha
de Boeck, Bart
Douverny, Andre
Karakas, Özge
Toggweiler, Stefan
Arzamendi-Aizpurua, Dabit
Gülan, Utku
Vázquez, Mariano
contents Systematic in vivo validations of computational models of the aortic valve remain scarce, despite successful validation against in vitro data. Utilizing a combination of computed tomography and 4D flow magnetic resonance imaging data, we developed patient-specific fluid-structure interaction models of the aortic valve immersed in the aorta for five patients in the pre-transcatheter aortic valve replacement configuration. Incorporating also an in vitro setup of the valve, our computational models are subjected to rigorous validation against 4D flow measurements. Our results demonstrate the models' capacity to accurately replicate flow dynamics within established ranges of uncertainties mainly arising from 4D flow noise. In addition, we illustrate how computational models can serve as valuable cross-checks to reduce noise and erratic behaviour of in vivo data. This study represents a significant step towards integrating in silico technologies into real clinical contexts, providing a robust framework for improving aortic stenosis diagnosis and the design of next-generation aortic valve bioprostheses.
format Preprint
id arxiv_https___arxiv_org_abs_2404_08632
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Advancing aortic stenosis assessment: validation of fluid-structure interaction models against 4D flow MRI data
Zingaro, Alberto
Burba, Irmantas
Oks, David
Fontana, Mauro
Samaniego, Cristóbal
Bischofberger, Micha
de Boeck, Bart
Douverny, Andre
Karakas, Özge
Toggweiler, Stefan
Arzamendi-Aizpurua, Dabit
Gülan, Utku
Vázquez, Mariano
Fluid Dynamics
Systematic in vivo validations of computational models of the aortic valve remain scarce, despite successful validation against in vitro data. Utilizing a combination of computed tomography and 4D flow magnetic resonance imaging data, we developed patient-specific fluid-structure interaction models of the aortic valve immersed in the aorta for five patients in the pre-transcatheter aortic valve replacement configuration. Incorporating also an in vitro setup of the valve, our computational models are subjected to rigorous validation against 4D flow measurements. Our results demonstrate the models' capacity to accurately replicate flow dynamics within established ranges of uncertainties mainly arising from 4D flow noise. In addition, we illustrate how computational models can serve as valuable cross-checks to reduce noise and erratic behaviour of in vivo data. This study represents a significant step towards integrating in silico technologies into real clinical contexts, providing a robust framework for improving aortic stenosis diagnosis and the design of next-generation aortic valve bioprostheses.
title Advancing aortic stenosis assessment: validation of fluid-structure interaction models against 4D flow MRI data
topic Fluid Dynamics
url https://arxiv.org/abs/2404.08632