固定电荷和移动离子影响可测量的机械-电化学性质的带电水合生物组织:关节软骨范例。

L. Wan, Chester Miller, X. Guo, V. Mow
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引用次数: 18

摘要

三相本构律[Lai, Hou和Mow(1991)]已经在一些特殊的一维情况下被证明可以成功地模拟带电水合的、多孔渗透的、柔软的生物组织的变形和运输行为,如关节软骨。由于这些方程的非线性和其他数学复杂性,这类材料的变形问题很少得到解析解决。在二维无侧限压缩试验条件下,我们利用微扰方法对三相方程进行了线性化处理,得到了平衡解和力学-电化学(MEC)场的边界层解。结果表明,决定变形行为的关键物理参数是渗透压扰动与弹性应力的比值,它会导致可测弹性系数的变化。从短时边界层解可以看出,横向膨胀和外加荷载均随时间的平方根而减小。预测的变形、流场和应力与短时间和平衡双相(即固体基体不附带电荷)的分析一致[Armstrong, Lai和Mow(1984)]。这些结果更好地理解了组织内固定电荷和移动离子对观察到的材料响应的影响。
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Fixed electrical charges and mobile ions affect the measurable mechano-electrochemical properties of charged-hydrated biological tissues: the articular cartilage paradigm.
The triphasic constitutive law [Lai, Hou and Mow (1991)] has been shown in some special 1D cases to successfully model the deformational and transport behaviors of charged-hydrated, porous-permeable, soft biological tissues, as typified by articular cartilage. Due to nonlinearities and other mathematical complexities of these equations, few problems for the deformation of such materials have ever been solved analytically. Using a perturbation procedure, we have linearized the triphasic equations with respect to a small imposed axial compressive strain, and obtained an equilibrium solution, as well as a short-time boundary layer solution for the mechano-electrochemical (MEC) fields for such a material under a 2D unconfined compression test. The present results show that the key physical parameter determining the deformational behaviors is the ratio of the perturbation of osmotic pressure to elastic stress, which leads to changes of the measurable elastic coefficients. From the short-time boundary layer solution, both the lateral expansion and the applied load are found to decrease with the square root of time. The predicted deformations, flow fields and stresses are consistent with the analysis of the short time and equilibrium biphasic (i.e., the solid matrix has no attached electric charges) [Armstrong, Lai and Mow (1984)]. These results provide a better understanding of the manner in which fixed electric charges and mobile ions within the tissue contribute to the observed material responses.
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