Nuclear Stress-Strain State over Micropillars: A Mechanical In silico Study

Q4 Biochemistry, Genetics and Molecular Biology Molecular & Cellular Biomechanics Pub Date : 2022-01-01 DOI:10.32604/mcb.2022.018958

R. Allena, D. Aubry

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引用次数: 1

Abstract

Cells adapt to their environment and stimuli of different origin. During confined migration through sub-cellular and sub-nuclear pores, they can undergo large strains and the nucleus, the most voluminous and the stiffest organelle, plays a critical role. Recently, patterned microfluidic devices have been employed to analyze the cell mechanical behavior and the nucleus self-deformations. In this paper, we present an in silico model to simulate the interactions between the cell and the underneath microstructured substrate under the effect of the sole gravity. The model lays on mechanical features only and it has the potential to assess the contribution of the nuclear mechanics on the cell global behavior. The cell is constituted by the membrane, the cytosol, the lamina, and the nucleoplasm. Each organelle is described through a constitutive law defined by specific mechanical parameters, and it is composed of a fluid and a solid phase leading to a viscoelastic behavior. Our main objective is to evaluate the influence of such mechanical components on the nucleus behavior. We have quantified the stress and strain distributions in the nucleus, which could be responsible of specific phenomena such as the lamina rupture or the expression of stretch-sensitive proteins.

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微柱上的核应力-应变状态:一个机械的计算机研究

细胞适应不同来源的环境和刺激。在通过亚细胞和亚核孔的受限迁移过程中，它们可以承受较大的应变，而核作为体积最大、最坚硬的细胞器起着至关重要的作用。近年来，图形微流控装置被用于分析细胞的力学行为和细胞核的自变形。在本文中，我们提出了一个硅模型来模拟在鞋底重力作用下细胞与底部微结构衬底之间的相互作用。该模型只考虑力学特征，它有潜力评估核力学对细胞整体行为的贡献。细胞由膜、细胞质、层和核质组成。每个细胞器都通过由特定力学参数定义的本构定律来描述，并且它由流体和固相组成，导致粘弹性行为。我们的主要目的是评估这些机械部件对原子核行为的影响。我们已经量化了核内的应力和应变分布，这可能是导致板断裂或拉伸敏感蛋白表达等特定现象的原因。

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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来源期刊

Molecular & Cellular Biomechanics CELL BIOLOGYENGINEERING, BIOMEDICAL&-ENGINEERING, BIOMEDICAL

CiteScore

1.70

自引率

0.00%

发文量

期刊介绍： The field of biomechanics concerns with motion, deformation, and forces in biological systems. With the explosive progress in molecular biology, genomic engineering, bioimaging, and nanotechnology, there will be an ever-increasing generation of knowledge and information concerning the mechanobiology of genes, proteins, cells, tissues, and organs. Such information will bring new diagnostic tools, new therapeutic approaches, and new knowledge on ourselves and our interactions with our environment. It becomes apparent that biomechanics focusing on molecules, cells as well as tissues and organs is an important aspect of modern biomedical sciences. The aims of this journal are to facilitate the studies of the mechanics of biomolecules (including proteins, genes, cytoskeletons, etc.), cells (and their interactions with extracellular matrix), tissues and organs, the development of relevant advanced mathematical methods, and the discovery of biological secrets. As science concerns only with relative truth, we seek ideas that are state-of-the-art, which may be controversial, but stimulate and promote new ideas, new techniques, and new applications.