Nanomechanical Probes of Single Corneal Epithelial Cells: Shear Stress and Elastic Modulus

被引:0
|
作者
Joelle P. Straehla
F. T. Limpoco
Natalia V. Dolgova
Benjamin G. Keselowsky
W. Gregory Sawyer
Scott S. Perry
机构
[1] University of Florida,Materials Science and Engineering
[2] University of Florida,Biomedical Engineering
[3] University of Florida,Mechanical and Aerospace Engineering
来源
Tribology Letters | 2010年 / 38卷
关键词
Atomic force microscopy; Elastic modulus; Shear stress; Friction; Epithelial cells;
D O I
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中图分类号
学科分类号
摘要
Living human corneal epithelial cells have been probed in vitro via atomic force microscopy, revealing the frictional characteristics of single cells. Under cell media, measured shear stresses of 0.40 kPa demonstrate the high lubricity of epithelial cell surfaces in contact with a microsphere probe. The mechanical properties of individual epithelial cells have been further probed through nanometer scale indentation measurements. A simple elastic foundation model, based on experimentally verifiable parameters, is used to fit the indentation data, producing an effective elastic modulus of 16.5 kPa and highlighting the highly compliant nature of the cell surface. The elastic foundation model is found to more accurately fit the experimental data, to avoid unverifiable assumptions, and to produce a modulus significantly higher than that of the widely used Hertz–Sneddon model.
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页码:107 / 113
页数:6
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