单根蛙肌纤维固定端收缩期间肌节间动力学的定量模型。

A quantitative model of intersarcomere dynamics during fixed-end contractions of single frog muscle fibers.

作者信息

Morgan D L, Mochon S, Julian F J

出版信息

Biophys J. 1982 Aug;39(2):189-96. doi: 10.1016/S0006-3495(82)84507-4.

DOI:10.1016/S0006-3495(82)84507-4

PMID:6981436

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1328931/

Abstract

A numerical model of a muscle fiber as 400 sarcomeres, identical except for their initial lengths, was used to simulate fixed-end tetanic contractions of frog single fibers at sarcomere lengths above the optimum. The sarcomeres were represented by a lumped model, constructed from the passive and active sarcomere length-tension curves, the force-velocity curve, and the observed active elasticity of a single frog muscle fiber. An intersarcomere force was included to prevent large disparities in lengths of neighboring sarcomeres. The model duplicated the fast rise, slow creep rise, peak, and slow decline of tension seen in tetanic contractions of stretched living fibers. Decreasing the initial non-uniformity of sarcomere length reduced the rate of rise of tension during the creep phase, but did not decrease the peak tension reached. Limitations of the model, and other processes that might contribute to the shape of the fixed end tetanic tension record are discussed. Taking account of model and experimental results, it is concluded that the distinctive features of the tension records of fixed end tetanic contraction at lengths beyond optimum can be explained by internal motion within the fiber.

摘要

一个由400个肌节组成的肌肉纤维数值模型被用来模拟青蛙单纤维在肌节长度超过最佳长度时的固定端强直收缩，这些肌节除了初始长度外均相同。肌节由一个集总模型表示，该模型由被动和主动肌节长度-张力曲线、力-速度曲线以及观察到的单个青蛙肌肉纤维的主动弹性构建而成。包含了肌节间力以防止相邻肌节长度出现大的差异。该模型重现了拉伸的活纤维强直收缩中所见到的张力的快速上升、缓慢蠕变上升、峰值和缓慢下降。减少肌节长度的初始不均匀性降低了蠕变阶段张力的上升速率，但并未降低所达到的峰值张力。讨论了该模型的局限性以及其他可能对固定端强直张力记录形状有贡献的过程。考虑到模型和实验结果，得出结论：在长度超过最佳长度时固定端强直收缩的张力记录的独特特征可以通过纤维内部的运动来解释。

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