青蛙肌肉中肌膜和肌浆的力学特性与肌节长度的关系。

Mechanical properties of the sarcolemma and myoplasm in frog muscle as a function of sarcomere length.

作者信息

Rapoport S I

出版信息

J Gen Physiol. 1972 May;59(5):559-85. doi: 10.1085/jgp.59.5.559.

DOI:10.1085/jgp.59.5.559

PMID:4537306

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2203191/

Abstract

The elastimeter method was applied to the single muscle fiber of the frog semitendinosus to obtain the elastic moduli of the sarcolemma and myoplasm, as well as their relative contributions to resting fiber tension at different extensions. A bleb which was sucked into a flat-mouthed pipette at the fiber surface separated into an external sarcolemmal membrane and a thick inner myoplasmic region. Measurements showed that the sarcolemma does not contribute to intact fiber tension at sarcomere lengths below 3 micro. It was estimated that the sarcolemma contributed on the order of 10% to intact fiber tension at sarcomere lengths between 3 and 3.75 micro, and more so with further extension. Between these sarcomere lengths, the sarcolemma can be linearly extended and has a longitudinal elastic modulus of 5 x 10(6) dyne/cm(2) (assuming a thickness of 0.1 micro). Resistance to deformation of the inner bleb region is due to myoplasmic elasticity. The myoplasmic elastic modulus was estimated by use of a model and was used to predict a fiber length-tension curve which agreed approximately with observations.

摘要

采用弹性测量法对青蛙半腱肌的单根肌纤维进行研究，以获取肌膜和肌浆的弹性模量，以及它们在不同拉伸程度下对静息纤维张力的相对贡献。在纤维表面，被吸入平口移液管的一个小泡分离为外部的肌膜和内部较厚的肌浆区域。测量结果表明，在肌节长度低于3微米时，肌膜对完整纤维张力没有贡献。据估计，在肌节长度为3至3.75微米之间时，肌膜对完整纤维张力的贡献约为10%，且随着进一步拉伸贡献更大。在这些肌节长度之间，肌膜可线性拉伸，其纵向弹性模量为5×10⁶达因/平方厘米（假设厚度为0.1微米）。内部小泡区域的抗变形能力源于肌浆弹性。通过使用一个模型估算了肌浆弹性模量，并用于预测与观察结果大致相符的纤维长度-张力曲线。

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