Fluid–structure interaction modeling of a patient-specific cerebral aneurysm: influence of structural modeling

Fluid–structure interaction (FSI) simulations of a cerebral aneurysm with the linearly elastic and hyper-elastic wall constitutive models are carried out to investigate the influence of the wall-structure model on patient-specific FSI simulations. The maximum displacement computed with the hyper-ela...

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Veröffentlicht in:	Computational mechanics 2008-12, Vol.43 (1), p.151-159
Hauptverfasser:	Torii, Ryo, Oshima, Marie, Kobayashi, Toshio, Takagi, Kiyoshi, Tezduyar, Tayfun E.
Format:	Artikel
Sprache:	eng
Schlagworte:	Blood flow Classical and Continuum Physics Computational Science and Engineering Computer simulation Constitutive models Engineering Fluid-structure interaction Interaction models Mathematical models Modelling Original Paper Theoretical and Applied Mechanics Wall shear stresses
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container_title	Computational mechanics
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creator	Torii, Ryo Oshima, Marie Kobayashi, Toshio Takagi, Kiyoshi Tezduyar, Tayfun E.
description	Fluid–structure interaction (FSI) simulations of a cerebral aneurysm with the linearly elastic and hyper-elastic wall constitutive models are carried out to investigate the influence of the wall-structure model on patient-specific FSI simulations. The maximum displacement computed with the hyper-elastic model is 36% smaller compared to the linearly elastic material model, but the displacement patterns such as the site of local maxima are not sensitive to the wall models. The blood near the apex of an aneurysm is likely to be stagnant, which causes very low wall shear stress and is a factor in rupture by degrading the aneurysmal wall. In this study, however, relatively high flow velocities due to the interaction between the blood flow and aneurysmal wall are seen to be independent of the wall model. The present results indicate that both linearly elastic and hyper-elastic models can be useful to investigate aneurysm FSI.
doi_str_mv	10.1007/s00466-008-0325-8
format	Article
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The maximum displacement computed with the hyper-elastic model is 36% smaller compared to the linearly elastic material model, but the displacement patterns such as the site of local maxima are not sensitive to the wall models. The blood near the apex of an aneurysm is likely to be stagnant, which causes very low wall shear stress and is a factor in rupture by degrading the aneurysmal wall. In this study, however, relatively high flow velocities due to the interaction between the blood flow and aneurysmal wall are seen to be independent of the wall model. 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subjects	Blood flow Classical and Continuum Physics Computational Science and Engineering Computer simulation Constitutive models Engineering Fluid-structure interaction Interaction models Mathematical models Modelling Original Paper Theoretical and Applied Mechanics Wall shear stresses
title	Fluid–structure interaction modeling of a patient-specific cerebral aneurysm: influence of structural modeling
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