FSI simulation of intra-ventricular flow in patient-specific ventricular model with both mitral and aortic valves

Zhong, Liang; Su, Boyang; Zhang, Junmei; Leo, Hwa Liang; Tan, Ru San

doi:10.1109/embc.2013.6609597

2013 35th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC) 2013

DOI: 10.1109/embc.2013.6609597

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FSI simulation of intra-ventricular flow in patient-specific ventricular model with both mitral and aortic valves

Liang Zhong

Boyang Su

Junmei Zhang

et al.

Abstract: Investigating the intra-ventricular flow is the most important to understand the left ventricular function. In this study, we proposed a fluid-structure interaction (FSI) approach to simulate the blood flow in patient-specific model by combining both mitral and aortic valves. To accommodate the large mesh deformation, moving arbitrary Lagrangian-Eulerian (ALE) meshes were used for moving ventricular wall and rotating leaflets of valves. The left ventricular wall was predescribed according to the points acquire… Show more

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Cited by 2 publications

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The construction of a two-dimensional reproducing kernel function and its application in a biomedical model

Guo

Shen

2016

THC

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Abstract.BACKGROUND: There are two major classes of cardiac tissue models: the ionic model and the FitzHugh-Nagumo model. During computer simulation, each model entails solving a system of complex ordinary differential equations and a partial differential equation with non-flux boundary conditions. The reproducing kernel method possesses significant applications in solving partial differential equations. The derivative of the reproducing kernel function is a wavelet function, which has local properties and sensitivities to singularity. Therefore, study on the application of reproducing kernel would be advantageous. OBJECTIVE: Applying new mathematical theory to the numerical solution of the ventricular muscle model so as to improve its precision in comparison with other methods at present. METHODS: A two-dimensional reproducing kernel function inspace is constructed and applied in computing the solution of two-dimensional cardiac tissue model by means of the difference method through time and the reproducing kernel method through space. RESULTS: Compared with other methods, this method holds several advantages such as high accuracy in computing solutions, insensitivity to different time steps and a slow propagation speed of error. It is suitable for disorderly scattered node systems without meshing, and can arbitrarily change the location and density of the solution on different time layers. CONCLUSIONS: The reproducing kernel method has higher solution accuracy and stability in the solutions of the twodimensional cardiac tissue model.

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The construction of a two-dimensional reproducing kernel function and its application in a biomedical model

Guo

Shen

2016

THC

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Clinical Impact of Computational Heart Valve Models

et al. 2022

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This paper provides a review of engineering applications and computational methods used to analyze the dynamics of heart valve closures in healthy and diseased states. Computational methods are a cost-effective tool that can be used to evaluate the flow parameters of heart valves. Valve repair and replacement have long-term stability and biocompatibility issues, highlighting the need for a more robust method for resolving valvular disease. For example, while fluid–structure interaction analyses are still scarcely utilized to study aortic valves, computational fluid dynamics is used to assess the effect of different aortic valve morphologies on velocity profiles, flow patterns, helicity, wall shear stress, and oscillatory shear index in the thoracic aorta. It has been analyzed that computational flow dynamic analyses can be integrated with other methods to create a superior, more compatible method of understanding risk and compatibility.

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FSI simulation of intra-ventricular flow in patient-specific ventricular model with both mitral and aortic valves

Cited by 2 publications

References 14 publications

The construction of a two-dimensional reproducing kernel function and its application in a biomedical model

The construction of a two-dimensional reproducing kernel function and its application in a biomedical model

Clinical Impact of Computational Heart Valve Models

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