Fluid–structure interaction modeling of bi-leaflet mechanical heart valves using smoothed particle hydrodynamics

Laha, Sumanta; Fourtakas, Georgios; Das, Prasanta Kuamr; Keshmiri, Amir

doi:10.1063/5.0172043

Physics of Fluids

2023

DOI: 10.1063/5.0172043

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Fluid–structure interaction modeling of bi-leaflet mechanical heart valves using smoothed particle hydrodynamics

Sumanta Laha,

Georgios Fourtakas,

Prasanta Kuamr Das

et al.

Abstract: Heart valves are essential for maintaining unidirectional blood flow, and their failure can severely affect cardiac functions. The use of artificial heart valves as replacement has proven to be a reliable and effective solution. Computational fluid dynamics has emerged as a powerful numerical tool for investigating the design, performance, and malfunctioning of mechanical heart valves without the need for invasive procedures. In this study, we employed smoothed particle hydrodynamics (SPH) in an open-source co… Show more

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2024

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Cited by 8 publications

References 63 publications

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Towards the estimation of wall shear stress in smoothed particle hydrodynamics

Laha,

Fourtakas,

Das

et al. 2024

Comp. Part. Mech.

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Over the past few decades, smoothed particle hydrodynamics (SPH) has emerged as an alternative computational fluid dynamics (CFD) technique, yet the estimation of wall shear stress lacks adequate standardisation. Wall shear stress is a critical metric in numerous applications, and hence, this is the focus of this paper. The present study proposes a novel SPH-based method for estimating wall shear stress using velocity data from the fluid particles adjacent to the wall. Wall shear stress is then calculated at the wall based on the wall shear stress data of the neighbouring fluid particles. For laminar flow, wall shear stress is estimated directly from velocity gradients, while for turbulent flow, the Smagorinsky large eddy simulation (LES) model with eddy viscosity is used. The results obtained from the model are rigorously validated against experimental, simulation and analytical data, confirming its effectiveness across different flow conditions. This validation highlights the reliability of the proposed model for fluid dynamics and bio-fluid mechanics research.

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Towards the estimation of wall shear stress in smoothed particle hydrodynamics

Laha,

Fourtakas,

Das

et al. 2024

Comp. Part. Mech.

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Hemodynamics past a dysfunctional bileaflet mechanical heart valve

Chauhan,

Sasmal

2024

International Journal of Engineering Science

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Smoothed particle hydrodynamics based FSI simulation of the native and mechanical heart valves in a patient-specific aortic model

Laha,

Fourtakas,

Das

et al. 2024

Sci Rep

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The failure of the aortic heart valve is common, resulting in deterioration of the pumping function of the heart. For the end stage valve failure, bi-leaflet mechanical valve (most popular artificial valve) is implanted. However, due to its non-physiological behaviour, a significant alteration is observed in the normal haemodynamics of the aorta. While in-vivo experimentation of a human heart valve (native and artificial) is a formidable task, in-silico study using computational fluid dynamics (CFD) with fluid structure interaction (FSI) is an effective and economic tool for investigating the haemodynamics of natural and artificial heart valves. In the present work, a haemodynamic model of a natural and mechanical heart valve has been developed using meshless particle-based smoothed particle hydrodynamics (SPH). In order to further enhance its clinical relevance, this study employs a patient-specific vascular geometry and presents a successful validation against traditional finite volume method and 4D magnetic resonance imaging (MRI) data. The results have demonstrated that SPH is ideally suited to simulate the heart valve function due to its Lagrangian description of motion, which is a favourable feature for FSI. In addition, a novel methodology for the estimation of the wall shear stress (WSS) and other related haemodynamic parameters have been proposed from the SPH perspective. Finally, a detailed comparison of the haemodynamic parameters has been carried out for both native and mechanical aortic valve, with a particular emphasis on the clinical risks associated with the mechanical valve.

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Fluid–structure interaction modeling of bi-leaflet mechanical heart valves using smoothed particle hydrodynamics

Cited by 8 publications

References 63 publications

Towards the estimation of wall shear stress in smoothed particle hydrodynamics

Towards the estimation of wall shear stress in smoothed particle hydrodynamics

Hemodynamics past a dysfunctional bileaflet mechanical heart valve

Smoothed particle hydrodynamics based FSI simulation of the native and mechanical heart valves in a patient-specific aortic model

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