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Literature DB >> 22640492

Evaluation of a transient, simultaneous, arbitrary Lagrange-Euler based multi-physics method for simulating the mitral heart valve.

Daniel M Espino¹, Duncan E T Shepherd, David W L Hukins.

Abstract

A transient multi-physics model of the mitral heart valve has been developed, which allows simultaneous calculation of fluid flow and structural deformation. A recently developed contact method has been applied to enable simulation of systole (the stage when blood pressure is elevated within the heart to pump blood to the body). The geometry was simplified to represent the mitral valve within the heart walls in two dimensions. Only the mitral valve undergoes deformation. A moving arbitrary Lagrange-Euler mesh is used to allow true fluid-structure interaction (FSI). The FSI model requires blood flow to induce valve closure by inducing strains in the region of 10-20%. Model predictions were found to be consistent with existing literature and will undergo further development.

Entities: Disease

Keywords: Hertzian contact; fluid–structure interaction; large strain; mitral valve; multi-physics modelling

Mesh：

Year: 2012 PMID： 22640492 DOI： 10.1080/10255842.2012.688818

Source DB: PubMed Journal: Comput Methods Biomech Biomed Engin ISSN： 1025-5842 Impact factor: 1.763

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Cited

6 in total

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4. Dynamic Viscoelasticity and Surface Properties of Porcine Left Anterior Descending Coronary Arteries.

Authors: Hanna E Burton; Jenny M Freij; Daniel M Espino
Journal: Cardiovasc Eng Technol Date: 2016-12-12 Impact factor: 2.495

5. Towards Additive Manufacture of Functional, Spline-Based Morphometric Models of Healthy and Diseased Coronary Arteries: In Vitro Proof-of-Concept Using a Porcine Template.

Authors: Rachel Jewkes; Hanna E Burton; Daniel M Espino
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6 in total