A Constitutive Material Model With Strain-Rate Dependency for Brain Tissue

Volume 3: Biomedical and Biotechnology Engineering Pub Date : 2019-11-11 DOI:10.1115/imece2019-10742

M. H. Farid, M. Ramzanpour, M. Ziejewski, G. Karami

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引用次数: 3

Abstract

In almost all scenarios of traumatic brain injuries (TBIs), the brain tissue goes under mechanical loading at high strain rates. In experimental works, it has also shown that brain tissue behavior is highly rate-dependent. We are presenting here the results of a study on mechanical properties of bovine brain tissue under unconfined compression tests at different rates. The tissue specimens are compressed with deformation rates of 10, 100, and 1000 mm/sec, respectively. We observed the tissue is showing a viscoelastic behavior and become stiffer under increasing strain rates. We developed a nonlinear viscoelastic rate-dependent constitutive model to be calibrated with the test results. The material parameters for this constitutive model have been validated for the above tested results. The model was examined against other rates and agrees well. The study will provide new insight into a better understanding of the rate-dependency behavior of the brain tissue under dynamic conditions. The work is a step forward in understanding the material characteristics of brain tissue for TBI analysis and prediction under loading or high kinematical motions.

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具有应变率依赖性的脑组织本构材料模型

在几乎所有的创伤性脑损伤(tbi)的情况下，脑组织在高应变率下承受机械负荷。在实验工作中，它还表明脑组织行为高度依赖于速率。我们在这里提出了一项研究结果的机械性能的牛脑组织在无侧限压缩试验在不同的速率。组织试样分别以10、100和1000 mm/sec的变形速率压缩。我们观察到组织表现出粘弹性行为，并在增加应变速率下变得更硬。我们开发了一个非线性粘弹性率相关的本构模型，并与试验结果进行了校准。根据上述试验结果，验证了本构模型的材料参数。该模型与其他比率进行了检验，结果吻合良好。该研究将为更好地理解动态条件下脑组织的速率依赖行为提供新的见解。这项工作是在了解脑组织的材料特性，以进行载荷或高运动下的TBI分析和预测方面迈出的一步。

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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Volume 3: Biomedical and Biotechnology Engineering

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