使用耦合超弹性损伤模型对损伤诱导的脑白质软化行为进行建模。

Ge He, B. Xia, Yuan Feng, Yu Chen, L. Fan, Dongsheng Zhang
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引用次数: 0

摘要

大脑中的白质在结构上是各向异性的,由排列整齐的大束轴突纤维组成。超弹性、横向各向同性本构模型通常用于此类组织的建模和模拟。然而,大多数研究都将材料模型限制在小变形极限下描述白质的力学行为,而没有考虑实验观察到的大应变状态下的损伤萌生和损伤诱导的材料软化。在这项研究中,我们在热力学框架内,通过将白质的横向各向同性超弹性模型与损伤方程耦合,并使用连续损伤力学方法,扩展了先前开发的白质的横观各向同性超弹模型。使用两个均匀变形案例来证明所提出的模型在单轴载荷和简单剪切下捕捉白质损伤诱导软化行为的能力,以及纤维取向对这种行为和材料刚度的影响。作为非均匀变形的演示案例,所提出的模型也被实现为有限元代码,以再现猪白质压痕配置的实验数据(非线性材料行为和损伤起始)。数值结果与实验数据之间取得了良好的一致性,表明了所提出的模型在表征考虑大应变损伤的白质力学行为方面的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Modeling the damage-induced softening behavior of brain white matter using a coupled hyperelasticty-damage model.
White matter in the brain is structurally anisotropic consisting of large bundle of aligned axonal fibers. Hyperelastic, transversely isotropic constitutive models are typically used in the modeling and simulation of such tissues. However, most studies constrain the material models to describe the mechanical behavior of white matter in the limit of small deformation, without considering the experimentally observed damage initiation and damage-induced material softening in large strain regime. In this study, we extend a previously developed transversely isotropic hyperelasticity model for white matter by coupling it with damage equations within the framework of thermodynamics and using continuum damage mechanics method. Two homogeneous deformation cases are used to demonstrate the proposed model's capability in capturing the damage-induced softening behaviors of white matter under uniaxial loading and simple shear, along with the investigation of fiber orientation effect on such behaviors and material stiffness. As a demonstration case of inhomogeneous deformation, the proposed model is also implemented into finite element codes to reproduce the experimental data (nonlinear material behavior and damage initiation) from an indentation configuration of porcine white matter. Good agreement between numerical results and experimental data is achieved indicating the potential of the proposed model in characterizing the mechanical behaviors of white matter considering damage at large strain.
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