Origin of yield stress and mechanical plasticity in biological tissues

Anh Q. Nguyen, Junxiang Huang, Dapeng Bi
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Abstract

During development and under normal physiological conditions, biological tissues are continuously subjected to substantial mechanical stresses. In response to large deformations cells in a tissue must undergo multicellular rearrangements in order to maintain integrity and robustness. However, how these events are connected in time and space remains unknown. Here, using computational and theoretical modeling, we studied the mechanical plasticity of epithelial monolayers under large deformations. Our results demonstrate that the jamming-unjamming (solid-fluid) transition in tissues can vary significantly depending on the degree of deformation, implying that tissues are highly unconventional materials. Using analytical modeling, we elucidate the origins of this behavior. We also demonstrate how a tissue accommodates large deformations through a collective series of rearrangements, which behave similarly to avalanches in non-living materials. We find that these tissue avalanches are governed by stress redistribution and the spatial distribution of vulnerable spots. Finally, we propose a simple and experimentally accessible framework to predict avalanches and infer tissue mechanical stress based on static images.
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生物组织中屈服应力和机械塑性的起源
在发育过程中和正常生理条件下,生物组织会持续承受巨大的机械应力。为了应对巨大的变形,组织中的细胞必须进行多细胞重排,以保持完整性和稳健性。然而,这些事件在时间和空间上是如何联系在一起的仍是未知数。在这里,我们利用计算和理论建模研究了上皮单层在大变形下的机械可塑性。我们的研究结果表明,组织中的挤压-非挤压(固-流)转变会随着变形程度的不同而发生显著变化,这意味着组织是一种非常规材料。通过分析建模,我们阐明了这种行为的起源。我们还展示了组织如何通过一系列集体重排来适应大变形,其行为类似于非生命材料中的雪崩。我们发现,这些组织雪崩受应力再分布和脆弱点空间分布的制约。最后,我们提出了一个基于静态图像预测雪崩和推断组织机械应力的简单且易于实验的框架。
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