新型经导管二尖瓣装置与瓣下结构相互作用的数值生物力学模型。

Numerical Biomechanics Models of the Interaction Between a Novel Transcatheter Mitral Valve Device and the Subvalvular Apparatus.

机构信息

26745 School of Mechanical Engineering, Tel Aviv University, Israel.

The Sheba Fund for Health Services and Research, Tel Hashomer, Israel.

出版信息

Innovations (Phila). 2021 Jul-Aug;16(4):327-333. doi: 10.1177/1556984521999362. Epub 2021 Apr 5.

DOI:10.1177/1556984521999362

PMID:33818178

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8414811/

Abstract

OBJECTIVE

Mitral valve regurgitation (MR) is a common valvular heart disease where improper closing causes leakage. Currently, no transcatheter mitral valve device is commercially available. Raanani (co-author) and colleagues have previously proposed a unique rotational implantation, ensuring anchoring by metallic arms that pull the chordae tendineae. This technique is now being implemented in a novel device design. The aim of this study is to quantify the rotational implantation effect on the mitral annulus kinematics and on the stresses in the chordae and papillary muscles.

METHODS

Finite element analysis of the rotational step of the implantation in a whole heart model is employed to compare 5 arm designs with varying diameters (25.9 mm to 32.4 mm) and rotation angles (up to 140°). The arm rotation that grabs the chordae was modeled when the valve was in systolic configuration.

RESULTS

An increase in the rotation angle results in reduced mitral annulus perimeters. Larger rotation angles led to higher chordae stresses with the 29.8 mm experiencing the maximum stresses. The calculated chordae stresses suggest that arm diameter should be <27.8 mm and the rotation angle <120°.

CONCLUSIONS

The upper limit of this diameter range is preferred in order to reduce the stresses in the papillary muscles while grabbing more chords. The findings of this study can help improving the design and performance of this unique device and procedural technique.

摘要

目的

二尖瓣反流（MR）是一种常见的瓣膜性心脏病，其瓣膜关闭不当会导致渗漏。目前，尚无商业可用的经导管二尖瓣装置。Raanani（共同作者）及其同事先前提出了一种独特的旋转植入方法，通过拉动腱索的金属臂来确保锚固。这项技术现在正在一种新型装置设计中实施。本研究的目的是量化旋转植入对二尖瓣瓣环运动学以及腱索和乳头肌内应力的影响。

方法

采用整体心脏模型的旋转步骤有限元分析，比较了 5 种臂设计，直径（25.9 毫米至 32.4 毫米）和旋转角度（最高 140°）不同。当瓣膜处于收缩构型时，模拟了抓取腱索的臂旋转。

结果

旋转角度的增加导致二尖瓣瓣环周长减小。较大的旋转角度导致腱索的应力更高，29.8 毫米处的腱索经历最大的应力。计算出的腱索应力表明，臂直径应<27.8 毫米，旋转角度应<120°。

结论

为了在抓取更多腱索的同时减少乳头肌的应力，优选这个直径范围的上限。本研究的结果可以帮助改进这种独特装置和手术技术的设计和性能。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4fb1/8414811/a980b01bc85f/10.1177_1556984521999362-fig1.jpg

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新型经导管二尖瓣装置与瓣下结构相互作用的数值生物力学模型。

Numerical Biomechanics Models of the Interaction Between a Novel Transcatheter Mitral Valve Device and the Subvalvular Apparatus.

机构信息

出版信息

OBJECTIVE

METHODS

RESULTS

CONCLUSIONS

目的

方法

结果

结论

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