Addae-Mensah Kweku A, Wikswo John P
Department of Biomedical Engineering, The Vanderbilt Institute for Integrative Biosystems Research and Education, Vanderbilt University, Nashville, TN 37235-1807, USA.
Exp Biol Med (Maywood). 2008 Jul;233(7):792-809. doi: 10.3181/0710-MR-278. Epub 2008 Apr 29.
Living cells and tissues experience mechanical forces in their physiological environments that are known to affect many cellular processes. Also of importance are the mechanical properties of cells, as well as the microforces generated by cellular processes themselves in their microenvironments. The difficulty associated with studying these phenomena in vivo has led to alternatives such as using in vitro models. The need for experimental techniques for investigating cellular biomechanics and mechanobiology in vitro has fueled an evolution in the technology used in these studies. Particularly noteworthy are some of the new biomicroelectromechanical systems (Bio-MEMS) devices and techniques that have been introduced to the field. We describe some of the cellular micromechanical techniques and methods that have been developed for in vitro studies, and provide summaries of the ranges of measured values of various biomechanical quantities. We also briefly address some of our experiences in using these methods and include modifications we have introduced in order to improve them.
活细胞和组织在其生理环境中会受到机械力的作用,已知这些机械力会影响许多细胞过程。细胞的机械特性以及细胞过程在其微环境中自身产生的微力也很重要。在体内研究这些现象存在困难,这促使人们采用诸如体外模型等替代方法。对体外研究细胞生物力学和力学生物学的实验技术的需求推动了这些研究中所用技术的发展。特别值得注意的是一些已引入该领域的新型生物微机电系统(Bio - MEMS)设备和技术。我们描述了一些为体外研究而开发的细胞微机械技术和方法,并提供了各种生物力学量测量值范围的总结。我们还简要介绍了使用这些方法的一些经验,并包括为改进它们而引入的修改。