二尖瓣叶不完全对合机制——腱索约束与二尖瓣叶对合几何形状变化的相互作用。来自力平衡前提体外验证的见解。

Mechanism of incomplete mitral leaflet coaptation--interaction of chordal restraint and changes in mitral leaflet coaptation geometry. Insight from in vitro validation of the premise of force equilibrium.

作者信息

Nielsen Sten Lyager, Nygaard Hans, Mandrup Lars, Fontaine Arnold A, Hasenkam J Michael, He Shengqui, Yoganathan Ajit P

机构信息

Department of Cardiothoracic and Vascular Surgery, Institute of Experimental Clinical Research, Skejby Sygehus, Aarhus University Hospital, Denmark.

出版信息

J Biomech Eng. 2002 Oct;124(5):596-608. doi: 10.1115/1.1500741.

DOI:10.1115/1.1500741

PMID:12405603

Abstract

Clinically observed incomplete mitral leaflet coaptation was reproduced in vitro by altering the balance of the chordal tethering and chordal coapting force components. Mitral leaflet coaptation geometry was distorted by changes of the spatial relations between the papillary muscles and the mitral valve as well as hemodynamics. Mitral leaflet malalignment was accentuated by a redistribution of the chordal tethering and coapting force components. For the overall assessment of systolic mitral leaflet configuration in functional mitral regurgitation it is important to consider the interaction between chordal restraint and an altered mitral leaflet coaptation geometry.

摘要

通过改变腱索束缚力和弦索贴合力成分之间的平衡，在体外再现了临床上观察到的二尖瓣叶不完全贴合。二尖瓣叶的贴合几何形状因乳头肌与二尖瓣之间的空间关系以及血流动力学的变化而扭曲。腱索束缚力和弦索贴合力成分的重新分布加剧了二尖瓣叶的错位。对于功能性二尖瓣反流中收缩期二尖瓣叶形态的整体评估，考虑腱索约束与改变的二尖瓣叶贴合几何形状之间的相互作用很重要。

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二尖瓣叶不完全对合机制——腱索约束与二尖瓣叶对合几何形状变化的相互作用。来自力平衡前提体外验证的见解。

Mechanism of incomplete mitral leaflet coaptation--interaction of chordal restraint and changes in mitral leaflet coaptation geometry. Insight from in vitro validation of the premise of force equilibrium.

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