膜粘塑性流动

Membrane viscoplastic flow.

作者信息

Evans E A, Hochmuth R M

出版信息

Biophys J. 1976 Jan;16(1):13-26. doi: 10.1016/S0006-3495(76)85659-7.

DOI:10.1016/S0006-3495(76)85659-7

PMID:1244887

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1334810/

Abstract

In this paper, a theory of viscoplasticity formulated by Prager and Hohenemser is developed for a two-dimensional membrane surface and applied to the analysis of the flow of "microtethers" pulled from red blood cells attached to glass substrates. The viscoplastic flow involves two intrinsic material constants: yield shear and surface viscosity. The intrinsic viscosity for plastic flow of membrane is calculated to be 1 X 10(-2) dyn-s/cm from microtether flow experiments, three orders of magnitude greater than surface viscosities of lipid membrane components. The fluid dissipation is dominated by the flow of a structural matrix which has exceeded its yield shear. The yield shear is the maximum shear resultant that the membrane can sustain before it begins to deform irreversibly. The yield shear is found to be in the range 2-8 X 10(-2) dyn/cm, two or three orders of magnitude smaller than the isotropic tension required to lyse red cells.

摘要

在本文中，由普拉格（Prager）和霍赫内姆泽尔（Hohenemser）提出的粘塑性理论被拓展至二维膜表面，并应用于分析从附着在玻璃基板上的红细胞拉出的“微系链”的流动。粘塑性流动涉及两个固有材料常数：屈服剪切力和表面粘度。通过微系链流动实验计算得出，膜塑性流动的固有粘度为1×10⁻²达因·秒/厘米，比脂质膜成分的表面粘度大三个数量级。流体耗散主要由超过其屈服剪切力的结构基质的流动主导。屈服剪切力是膜在开始不可逆变形之前能够承受的最大剪切合力。研究发现，屈服剪切力范围为2 - 8×10⁻²达因/厘米，比裂解红细胞所需的各向同性张力小两到三个数量级。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8b39/1334810/c6fb77bb11a2/biophysj00309-0019-a.jpg

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膜粘塑性流动

Membrane viscoplastic flow.

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