ACTIVE REMODELLING OF TISSUES TO DESCRIBE BIPHASIC RHEOLOGICAL RESPONSES

The ANZIAM journal Pub Date : 2024-02-26 DOI:10.1017/s1446181123000226

DOMENIC P. J. GERMANO, STEPHANIE KHUU, ADRIANNE L. JENNER, JAMES M. OSBORNE, MARY R. MYERSCOUGH, MARK B. FLEGG

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Abstract

Tissues form from collections of cells that interact together mechanically via cell-to-cell adhesion, mediated by transmembrane cell adhesion molecules. Under a sufficiently large amount of induced stress, these tissues can undergo elastic deformation in the direction of tension, where they then elongate without any topological changes, and experience plastic deformation within the tissue. In this work, we present a novel mathematical model describing the deformation of cells, where tissues are elongated in a controlled manner. In doing so, the cells are able to undergo remodelling through elastic and then plastic deformation, in accordance with experimental observation. Our model describes bistable sizes of a cell that actively deform under stress to elongate the cell. In the absence of remodelling, the model reduces to the standard linear interaction model. In the presence of instant remodelling, we provide a bifurcation analysis to describe the existence of the bistable cell sizes. In the case of general remodelling, we show numerically that cells within a tissue may populate both the initial and elongated cell sizes, following a sufficiently large degree of stress.

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用组织的主动重塑来描述双相流变反应

组织由细胞集合而成，这些细胞通过跨膜细胞粘附分子介导的细胞间粘附进行机械相互作用。在足够大的诱导应力作用下，这些组织会沿张力方向发生弹性变形，然后在不改变拓扑结构的情况下伸长，并在组织内部发生塑性变形。在这项工作中，我们提出了一种描述细胞变形的新型数学模型，在该模型中，组织以受控方式伸长。这样，细胞就能根据实验观察结果，通过弹性变形和塑性变形进行重塑。我们的模型描述了细胞的双稳态尺寸，这种尺寸在应力作用下会主动变形以拉长细胞。在没有重塑的情况下，该模型简化为标准的线性相互作用模型。在存在瞬时重塑的情况下，我们通过分岔分析来描述双稳态细胞尺寸的存在。在一般重塑的情况下，我们用数值表明，在足够大的应力作用下，组织内的细胞可能同时具有初始和拉长的细胞尺寸。

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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