On the chordae structure and dynamic behaviour of the mitral valve.

Liuyang Feng,Xiaoyu Luo,Hao Gao,Mariano Vazquez,Boyce E Griffith,Wei Sun,Nan Qi

doi:10.1093/imamat/hxy035

Abstract

We develop a fluid–structure interaction (FSI) model of the mitral valve (MV) that uses an anatomically and physiologically realistic description of the MV leaflets and chordae tendineae. Three different chordae models—complex, ‘pseudo-fibre’ and simplified chordae—are compared to determine how different chordae representations affect the dynamics of the MV. The leaflets and chordae are modelled as fibre-reinforced hyperelastic materials, and FSI is modelled using an immersed boundary–finite element method. The MV model is first verified under static boundary conditions against the commercial finite element software ABAQUS and then used to simulate MV dynamics under physiological pressure conditions. Interesting flow patterns and vortex formulation are observed in all three cases. To quantify the highly complex system behaviour resulting from FSI, an energy budget analysis of the coupled MV FSI model is performed. Results show that the complex and pseudo-fibre chordae models yield good valve closure during systole but that the simplified chordae model leads to poorer leaflet coaptation and an unrealistic bulge in the anterior leaflet belly. An energy budget analysis shows that the MV models with complex and pseudo-fibre chordae have similar energy distribution patterns but the MV model with the simplified chordae consumes more energy, especially during valve closing and opening. We find that the complex chordae and pseudo-fibre chordae have similar impact on the overall MV function but that the simplified chordae representation is less accurate. Because a pseudo-fibre chordal structure is easier to construct and less computationally intensive, it may be a good candidate for modelling MV dynamics or interaction between the MV and heart in patient-specific applications.

Highlights

Mitral valve (MV) dysfunction, including MV stenosis, prolapse and regurgitation, is one of the most common valvular heart diseases and has attracted significant research interest
This paper describes an fluid– structure interaction (FSI) model of the MV that uses an anatomically and physiologically realistic description of the MV leaflets and chordae tendineae that is based on an IB method with FE elasticity (Griffith & Luo, 2017)
Several advances have been made compared with our previous studies (Gao et al, 2014a; Ma et al, 2013): (1) we use physiologically detailed MV leaflets and chordae structures that are based on computed tomography (CT) image data, (2) we compared three different chordae structure models and their effects on the MV function and (3) the FSI

Summary

Introduction

Mitral valve (MV) dysfunction, including MV stenosis, prolapse and regurgitation, is one of the most common valvular heart diseases and has attracted significant research interest. Approaches to modelling the MV often fall into two categories: structural analysis and fluid– structure interaction (FSI) analysis The former is simpler and focuses on MV deformation in its fully closed state. The latter focuses on the whole cardiac cycle and is more computationally demanding but provides a more complete description of valvular function Both approaches have been used to study MV dynamics (Einstein et al, 2010; Gao et al, 2014a; Kunzelman et al, 1993, 1997; Kunzelman & Cochran, 1992; Luo et al, 2012; Ma et al, 2013; Watton et al, 2008). We use an immersed boundary–finite element (IB/FE) method (Griffith & Luo, 2017) to develop a dynamic MV FSI model

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