由于主动机械传感导致的软介质中的细胞组织。

Cell organization in soft media due to active mechanosensing.

作者信息

Bischofs I B, Schwarz U S

机构信息

Max Planck Institute of Colloids and Interfaces, 14424 Potsdam, Germany.

出版信息

Proc Natl Acad Sci U S A. 2003 Aug 5;100(16):9274-9. doi: 10.1073/pnas.1233544100. Epub 2003 Jul 25.

DOI:10.1073/pnas.1233544100

PMID:12883003

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC170908/

Abstract

Adhering cells actively probe the mechanical properties of their environment and use the resulting information to position and orient themselves. We show that a large body of experimental observations can be consistently explained from one unifying principle, namely that cells strengthen contacts and cytoskeleton in the direction of large effective stiffness. Using linear elasticity theory to model the extracellular environment, we calculate optimal cell organization for several situations of interest and find excellent agreement with experiments for fibroblasts, both on elastic substrates and in collagen gels: cells orient in the direction of external tensile strain; they orient parallel and normal to free and clamped surfaces, respectively; and they interact elastically to form strings. Our method can be applied for rational design of tissue equivalents. Moreover, our results indicate that the concept of contact guidance has to be reevaluated. We also suggest that cell-matrix contacts are up-regulated by large effective stiffness in the environment because, in this way, build-up of force is more efficient.

摘要

黏附细胞会主动探测其周围环境的力学特性，并利用所获得的信息来确定自身的位置和方向。我们发现，大量的实验观察结果可以从一个统一的原理得到一致的解释，即细胞会在有效刚度较大的方向上加强接触和细胞骨架。利用线性弹性理论对细胞外环境进行建模，我们计算了几种感兴趣情况下的最佳细胞组织排列，并发现与成纤维细胞在弹性基质和胶原凝胶中的实验结果高度吻合：细胞沿外部拉伸应变方向排列；它们分别平行于自由表面和垂直于固定表面排列；并且它们通过弹性相互作用形成细胞链。我们的方法可用于合理设计组织工程替代物。此外，我们的结果表明，接触导向的概念必须重新评估。我们还提出，细胞与基质的接触会因环境中较大的有效刚度而上调，因为这样力的积累更有效。

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