细胞和组织调节的机械化学基础。

D. Ingber
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引用次数: 5

摘要

这篇文章是2004年2月在加州大学欧文分校举行的“生物系统的力学和化学”研讨会上为纪念冯永昌教授所作演讲的摘要。本文综述了我们实验室的工作,重点关注机械和化学信号相互作用的机制,以控制单个细胞如何决定生长、分化、移动或死亡,从而促进组织形态发生过程中的模式形成。为了应对这一挑战,需要开发和应用新的微技术、理论公式、计算模型和生物信息学工具。这些方法已被用于对特定细胞表面分子施加受控的机械应力,并测量机械和生化反应;独立控制细胞形状,不受化学因素影响;以及处理活细胞的结构、层次和信息复杂性。这些研究结果改变了我们对细胞和组织如何控制其形状和机械特性的看法,并导致发现整合素和细胞骨架在细胞机械转导中起核心作用。认识到力学和细胞生物化学之间的这些关键联系,应该会导致开发新药和工程组织的新策略,以及在活组织环境中更有效地发挥作用的仿生微设备和纳米技术。
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The mechanochemical basis of cell and tissue regulation.
This article is a summary of a lecture presented at a symposium on "Mechanics and Chemistry of Biosystems" in honor of Professor Y.C. Fung that convened at the University of California, Irvine in February 2004. The article reviews work from our laboratory that focuses on the mechanism by which mechanical and chemical signals interplay to control how individual cells decide whether to grow, differentiate, move, or die, and thereby promote pattern formation during tissue morphogenesis. Pursuit of this challenge has required development and application of new microtechnologies, theoretical formulations, computational models and bioinformatics tools. These approaches have been used to apply controlled mechanical stresses to specific cell surface molecules and to measure mechanical and biochemical responses; to control cell shape independently of chemical factors; and to handle the structural, hierarchical and informational complexity of living cells. Results of these studies have changed our view of how cells and tissues control their shape and mechanical properties, and have led to the discovery that integrins and the cytoskeleton play a central role in cellular mechanotransduction. Recognition of these critical links between mechanics and cellular biochemistry should lead to novel strategies for the development of new drugs and engineered tissues, as well as biomimetic microdevices and nanotechnologies that more effectively function within the context of living tissues.
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