Fluid–structure interaction and multi-body contact: Application to aortic valves

Astorino, Matteo; Gerbeau, Jean-Frédéric; Pantz, Olivier; Traoré, Karim-Frédéric

doi:10.1016/j.cma.2008.09.012

Cited by 101 publications

(114 citation statements)

References 32 publications

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“…Other IB techniques were developed and used by Tai et al (2007), De Tullio et al (2009 and Xia et al (2009). Also, the fictitious domain (FD) method can be used to simulate flexible heart valves (De Hart et al, 2000Diniz dos Santos et al, 2008;Astorino et al, 2009). This fixed grid method uses Lagrange multipliers to impose the kinematic constraints.…”

Section: Fixed Grid Techniques Versus Moving Grid Techniquesmentioning

confidence: 99%

“…Partitioned simulations of heart valves using the Aitken Δ 2 relaxation method are reported in Borazjani et al (2008), Diniz dos Santos et al (2008), and Astorino et al (2009). More recently, however, a (quasi-Newton) method with a dynamically changing relaxation matrix has been developed Dahl et al, 2010) and subsequently optimized in Annerel et al (2011).…”

Section: Solve Flow Equations Calculatementioning

confidence: 99%

See 1 more Smart Citation

State-Of-The-Art Methods for the Numerical Simulation of Aortic BMHVs

Annerel¹,

Claessens²,

Ransbeeck³

et al. 2011

Aortic Valve

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Section: Fixed Grid Techniques Versus Moving Grid Techniquesmentioning

confidence: 99%

Section: Solve Flow Equations Calculatementioning

confidence: 99%

State-Of-The-Art Methods for the Numerical Simulation of Aortic BMHVs

Annerel¹,

Claessens²,

Ransbeeck³

et al. 2011

Aortic Valve

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“…In many situations, complex nonlinear models that include large displacements and deformations have to be considered. This is, for example, the case for valve simulation [1, 2,3,4] or in the aorta [5,6,7]. It is well-known that these simulations are very demanding, and in spite of the progress achieved in recent years ( [8,9,10] to name but a few), they remain challenging and the subject of active research.…”

Section: Introductionmentioning

confidence: 99%

A simplified fluid–structure model for arterial flow. Application to retinal hemodynamics

Aletti

Gerbeau

Lombardi

2016

Computer Methods in Applied Mechanics and Engineering

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A simplified fluid-structure model for arterial flow.Application to retinal hemodynamics. AbstractWe propose a simplified fluid-structure interaction model for applications in hemodynamics. This work focuses on simulating the blood flow in arteries, but it could be useful in other situations where the wall displacement is small. As in other approaches presented in the literature, our simplified model mainly consists of a fluid problem on a fixed domain, with Robin-like boundary conditions and a first order transpiration. Its main novelty is the presence of fibers in the solid. As an interesting numerical side effect, the presence of fibers makes the model less sensitive than others to strong variations or inaccuracies in the curvatures of the wall. An application to retinal hemodynamics is investigated.

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“…Recent advances in the field of numerical analysis and the increase in computer power enable detailed, three-dimensional (3D) fluid-structure interaction (FSI) simulations of, for example, heart valves [2] and aneurysms in large arteries [13,19]. In these FSI simulations, the interaction between the blood flow and the surrounding tissue is taken into account.…”

Section: Introductionmentioning

confidence: 99%

Inverse modelling of an aneurysm’s stiffness using surrogate-based optimization and fluid-structure interaction simulations

Degroote

Couckuyt

Vierendeels

et al. 2012

Struct Multidisc Optim

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Characterization of the mechanical properties of arterial tissues is highly relevant. In this work, we apply an inverse modelling approach to a model accounting for an aneurysm and the distal part of the circulation which can be modified using two independent stiffness parameters. For given values of these parameters, the position of the arterial wall as a function of time is calculated using a forward simulation which takes the fluid-structure interaction (FSI) into account. Using this forward simulation, the correct values of the stiffness parameters are obtained by minimizing a cost function, which is defined as the difference between the forward simulation and a measurement. The minimization is performed by means of surrogate-based optimization using a Kriging model combined with the expected improvement infill criterion. The results show that the stiffness parameters converge to the correct values, both for a zero-dimensional and for a three-dimensional model of the aneurysm.

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Fluid–structure interaction and multi-body contact: Application to aortic valves

Cited by 101 publications

References 32 publications

State-Of-The-Art Methods for the Numerical Simulation of Aortic BMHVs

State-Of-The-Art Methods for the Numerical Simulation of Aortic BMHVs

A simplified fluid–structure model for arterial flow. Application to retinal hemodynamics

Inverse modelling of an aneurysm’s stiffness using surrogate-based optimization and fluid-structure interaction simulations

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