Discrete-to-continuum models of pre-stressed cytoskeletal filament networks

arXiv - QuanBio - Subcellular Processes Pub Date : 2023-09-02 DOI:arxiv-2309.01034

J. Köry, N. A. Hill, X. Y. Luo, P. S. Stewart

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Abstract

We introduce a mathematical model for the mechanical behaviour of the eukaryotic cell cytoskeleton. This discrete model involves a regular array of pre-stressed protein filaments that exhibit resistance to enthalpic stretching, joined at crosslinks to form a network. Assuming that the inter-crosslink distance is much shorter than the lengthscale of the cell, we upscale the discrete force balance to form a continuum system of governing equations and deduce the corresponding macroscopic stress tensor. We use these discrete and continuum models to analyse the imposed displacement of a bead placed in the domain, characterising the cell rheology through the force-displacement curve. We further derive an analytical approximation to the stress and strain fields in the limit of small bead radius, predicting the net force required to generate a given deformation and elucidating the dependency on the microscale properties of the filaments. We apply these models to networks of the intermediate filament vimentin and demonstrate good agreement between predictions of the discrete, continuum and analytical approaches. In particular, our model predicts that the network stiffness increases sublinearly with the filament pre-stress and scales logarithmically with the bead size.

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预应力细胞骨架细丝网络的离散-连续模型

我们介绍了真核细胞骨架力学行为的数学模型。这个离散模型包括一个有规则的预应力蛋白丝阵列，这些蛋白丝表现出对焓拉伸的抵抗力，通过交联连接形成一个网络。假设交联距离远小于胞体的长度尺度，将离散力平衡提升为连续统控制方程组，并推导出相应的宏观应力张量。我们使用这些离散和连续模型来分析放置在域中的头的施加位移，通过力-位移曲线表征细胞流变学。我们进一步推导了在小珠半径极限下的应力和应变场的解析近似，预测了产生给定变形所需的净力，并阐明了对细丝微观尺度特性的依赖。我们将这些模型应用于中间丝状静脉网络，并证明了离散、连续和分析方法预测之间的良好一致性。特别是，我们的模型预测网络刚度随丝预应力的增加呈亚线性增长，并随珠尺寸的增加呈对数比例增长。

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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arXiv - QuanBio - Subcellular Processes

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