Three-dimensional modelling of aortic leaflet coaptation and load-bearing surfaces: in silico design of aortic valve neocuspidizations.

0 CARDIAC & CARDIOVASCULAR SYSTEMS
Loïc Georges Macé, Tom Fringand, Isabelle Cheylan, Laurent Sabatier, Laurent Meille, Marien Lenoir, Julien Favier
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Abstract

Objectives: Three-dimensional (3D) modelling of aortic leaflets remains difficult due to insufficient resolution of medical imaging. We aimed to model the coaptation and load-bearing surfaces of the aortic leaflets and adapt this workflow to aid in the design of aortic valve neocuspidizations.

Methods: Geometric morphometrics, using landmarks and semilandmarks, was applied to the geometric determinants of the aortic leaflets from computed tomography, followed by an isogeometric analysis using Non-Uniform Rational Basis Splines (NURBS). Ten aortic valve models were generated, measuring determinants of leaflet geometry defined as 3D NURBS curves, and leaflet coaptation and load-bearing surfaces were defined as 3D NURBS surfaces. Neocuspidizations were obtained by either shifting the upper central coaptation landmark towards the sinotubular junction or using parametric neo-landmarks placed on a centreline drawn between the centroid of the aortic root base and centroid of a circle circumscribing the 3 upper commissural landmarks.

Results: The ratio of the leaflet free margin length to the geometric height was 1.83, whereas the ratio of the commissural coaptation height to the central coaptation height was 1.93. The median coaptation surface was 137 mm2 (IQR 58) and the median load-bearing surface was 203 mm2 (60) per leaflet. Neocuspidization multiplied the central coaptation height by 3.7 and the coaptation surfaces by 1.97 and 1.92 using the native coaptation axis and centroid coaptation axis, respectively.

Conclusions: Geometric morphometrics reliably defined the coaptation and load-bearing surfaces of aortic leaflets, enabling an experimental 3D design for the in silico neocuspidization of aortic valves.

主动脉瓣叶贴合和承重表面的三维建模:主动脉瓣新瓣膜的硅设计。
目的:由于医学成像的分辨率不足,主动脉瓣叶的三维建模仍然很困难。我们的目标是对主动脉瓣叶的合瓣面和承载面进行建模,并调整这一工作流程,以帮助设计主动脉瓣新瓣:方法:使用地标和半地标对计算机断层扫描中主动脉瓣叶的几何决定因素进行几何形态计量学分析,然后使用非均匀有理基样条(NURBS)进行等几何分析。生成了 10 个主动脉瓣模型,测量了定义为三维 NURBS 曲线的瓣叶几何决定因素,并定义了定义为三维 NURBS 曲面的瓣叶自合面和承重面。通过将上部中央瓣合地标向窦管交界处移动,或使用在主动脉根底中心点与环绕三个上部瓣合地标的圆中心点之间绘制的中心线上放置的参数化新地标,获得了新瓣膜:瓣叶游离缘长度与几何高度的比值为1.83,而枢纽瓣合高度与中心瓣合高度的比值为1.93。每片瓣叶的中位合翼面为 137 平方毫米(IQR 58),中位承载面为 203 平方毫米(60)。使用原生瓣合轴线和中心瓣合轴线,Neocuspidization 将中心瓣合高度乘以 3.7,瓣合表面乘以 1.97 和 1.92:几何形态计量学可靠地定义了主动脉瓣叶的合瓣面和承载面,从而实现了主动脉瓣硅学新缩窄的三维实验设计。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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