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细胞与组织动力学的多尺度模型。

Multi-scale models of cell and tissue dynamics.

作者信息

Stolarska Magdalena A, Kim Yangjin, Othmer Hans G

机构信息

Department of Mathematics, University of St Thomas, 2115 Summit Avenue, St Paul, MN 55105, USA.

出版信息

Philos Trans A Math Phys Eng Sci. 2009 Sep 13;367(1902):3525-53. doi: 10.1098/rsta.2009.0095.

DOI:10.1098/rsta.2009.0095
PMID:19657010
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3263796/
Abstract

Cell and tissue movement are essential processes at various stages in the life cycle of most organisms. The early development of multi-cellular organisms involves individual and collective cell movement; leukocytes must migrate towards sites of infection as part of the immune response; and in cancer, directed movement is involved in invasion and metastasis. The forces needed to drive movement arise from actin polymerization, molecular motors and other processes, but understanding the cell- or tissue-level organization of these processes that is needed to produce the forces necessary for directed movement at the appropriate point in the cell or tissue is a major challenge. In this paper, we present three models that deal with the mechanics of cells and tissues: a model of an arbitrarily deformable single cell, a discrete model of the onset of tumour growth in which each cell is treated individually, and a hybrid continuum-discrete model of the later stages of tumour growth. While the models are different in scope, their underlying mechanical and mathematical principles are similar and can be applied to a variety of biological systems.

摘要

细胞和组织运动是大多数生物体生命周期各个阶段的基本过程。多细胞生物的早期发育涉及单个细胞和集体细胞运动;白细胞作为免疫反应的一部分,必须迁移到感染部位;在癌症中,定向运动参与侵袭和转移。驱动运动所需的力来自肌动蛋白聚合、分子马达和其他过程,但了解在细胞或组织的适当位置产生定向运动所需力所必需的这些过程的细胞或组织水平组织是一项重大挑战。在本文中,我们提出了三种处理细胞和组织力学的模型:一个任意可变形单细胞模型、一个肿瘤生长起始的离散模型(其中每个细胞单独处理)以及一个肿瘤生长后期的混合连续体-离散模型。虽然这些模型在范围上有所不同,但其 underlying 力学和数学原理相似,可应用于各种生物系统。 (注:原文中“underlying”未翻译完整,推测可能是“基础的”之类意思,因未明确完整准确含义,保留原文供参考)

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