一种纳入角向纤维分布的胶原性心血管组织的结构本构模型。

A structural constitutive model for collagenous cardiovascular tissues incorporating the angular fiber distribution.

作者信息

Driessen Niels J B, Bouten Carlijn V C, Baaijens Frank P T

机构信息

Eindhoven University of Technology, Department of Biomedical Engineering, PO Box 513, 5600 MB Eindhoven, The Netherlands.

出版信息

J Biomech Eng. 2005 Jun;127(3):494-503. doi: 10.1115/1.1894373.

DOI:10.1115/1.1894373

PMID:16060356

Abstract

Accurate constitutive models are required to gain further insight into the mechanical behavior of cardiovascular tissues. In this study, a structural constitutive framework for cardiovascular tissues is introduced that accounts for the angular distribution of collagen fibers. To demonstrate its capabilities, the model is applied to study the biaxial behavior of the arterial wall and the aortic valve. The pressure-radius relationships of the arterial wall accurately describe experimentally observed sigma-shaped curves. In addition, the nonlinear and anisotropic mechanical properties of the aortic valve can be analyzed with the proposed model. We expect that the current model offers strong possibilities to further investigate the complex mechanical behavior of cardiovascular tissues, including their response to mechanical stimuli.

摘要

需要精确的本构模型来进一步深入了解心血管组织的力学行为。在本研究中，引入了一种考虑胶原纤维角分布的心血管组织结构本构框架。为了展示其能力，该模型被应用于研究动脉壁和主动脉瓣的双轴行为。动脉壁的压力-半径关系准确地描述了实验观察到的西格玛形曲线。此外，利用所提出的模型可以分析主动脉瓣的非线性和各向异性力学特性。我们期望当前的模型为进一步研究心血管组织的复杂力学行为，包括它们对机械刺激的反应，提供了很大的可能性。

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一种纳入角向纤维分布的胶原性心血管组织的结构本构模型。

A structural constitutive model for collagenous cardiovascular tissues incorporating the angular fiber distribution.

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