用于模拟生物组织固体基质的反应性约束混合物
Reactive Constrained Mixtures for Modeling the Solid Matrix of Biological Tissues.
作者信息
Nims Robert J, Ateshian Gerard A
机构信息
Columbia University, 500 West 120th St, MC4703, New York, NY 10027, USA.
出版信息
J Elast. 2017 Dec;129(1-2):69-105. doi: 10.1007/s10659-017-9630-9. Epub 2017 Mar 1.
Abstract
This article illustrates our approach for modeling the solid matrix of biological tissues using reactive constrained mixtures. Several examples are presented to highlight the potential benefits of this approach, showing that seemingly disparate fields of mechanics and chemical kinetics are actually closely interrelated and may be elegantly expressed in a unified framework. Thus, constrained mixture models recover classical theories for fibrous materials with bundles oriented in different directions or having different reference configurations, that produce characteristic fiber recruitment patterns under loading. Reactions that exchange mass among various constituents of a mixture may be used to describe tissue growth and remodeling, which may also alter the material's anisotropy. Similarly, reactions that describe the breaking and reforming of bonds may be used to model free energy dissipation in a viscoelastic material. Therefore, this framework is particularly well suited for modeling biological tissues.
摘要
本文阐述了我们使用反应性约束混合物对生物组织固体基质进行建模的方法。文中给出了几个例子以突出这种方法的潜在优势,表明看似不同的力学和化学动力学领域实际上紧密相关,并且可以在一个统一的框架中得到优雅的表达。因此,约束混合物模型恢复了针对纤维材料的经典理论,这些纤维材料的束具有不同的取向或不同的参考构型,在加载时会产生特征性的纤维募集模式。混合物各成分之间进行质量交换的反应可用于描述组织生长和重塑,这也可能改变材料的各向异性。同样,描述键的断裂和重新形成的反应可用于对粘弹性材料中的自由能耗散进行建模。因此,这个框架特别适合对生物组织进行建模。
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