大鼠比目鱼肌在高缩短速度下的力-速度关系。
The force-velocity relationship at high shortening velocities in the soleus muscle of the rat.
作者信息
Claflin D R, Faulkner J A
机构信息
Department of Physiology, University of Michigan, Ann Arbor 48109.
出版信息
J Physiol. 1989 Apr;411:627-37. doi: 10.1113/jphysiol.1989.sp017595.
Abstract
- In intact skeletal muscle fibres, estimates of unloaded shortening velocity obtained from slack test measurements (V0) have been shown to exceed, by approximately 7%, estimates obtained from extrapolation of velocities measured during isotonic releases (Vmax). In contrast, published values for the V0 of whole soleus muscles of rats exceed Vmax by 56%. In the present study, we tested the hypothesis that this difference between whole muscles and single fibres is due to a difference in their respective force-velocity relationships at loads less than 5% of maximum isometric tetanic force (P0). In addition, we examined, by computer simulation, the effect of inter-fibre heterogeneity on the force-velocity characteristics of a whole muscle. 2. The force-velocity relationship of soleus muscles of rats was determined at low loads, in vitro at 20 degrees C, by recording force maintained during controlled shortening at constant velocities. The relationship was simulated by assigning a hyperbolic force-velocity curve to each motor unit and summing the force contributions of individual units at each of a series of velocities. 3. When measurements from low loads were included, the force-velocity relationship intersected the velocity axis at V0 (5.0 +/- 0.1 fibre lengths/s, mean +/- S.E.M., n = 10), not Vmax (3.1 +/- 0.1 fibre lengths/s). The simulated and measured force-velocity relationships agreed at all loads, supporting the premise that the deviation from hyperbolic form responsible for the large disparity between V0 and Vmax of whole muscles is a consequence of heterogeneity in shortening velocity among fibres.
摘要
- 在完整的骨骼肌纤维中,通过松弛试验测量得到的无负荷缩短速度估计值(V0)已被证明比通过等张释放过程中测量速度外推得到的估计值(Vmax)高出约7%。相比之下,已发表的大鼠比目鱼肌整体的V0值比Vmax高出56%。在本研究中,我们检验了这样一个假设,即整块肌肉和单根纤维之间的这种差异是由于它们在小于最大等长强直力(P0)的5%的负荷下各自的力-速度关系不同所致。此外,我们通过计算机模拟研究了纤维间异质性对整块肌肉力-速度特性的影响。2. 在体外20摄氏度下,通过记录在恒定速度下控制缩短过程中维持的力,测定了大鼠比目鱼肌在低负荷下的力-速度关系。通过为每个运动单位赋予一条双曲线力-速度曲线,并在一系列速度中的每一个速度下将各个单位的力贡献相加,来模拟这种关系。3. 当纳入低负荷测量值时,力-速度关系在V0(5.0±0.1纤维长度/秒,平均值±标准误,n = 10)处与速度轴相交,而非Vmax(3.1±0.1纤维长度/秒)。模拟和测量的力-速度关系在所有负荷下均一致,支持了这样一个前提,即导致整块肌肉V0和Vmax之间存在巨大差异的偏离双曲线形式是纤维间缩短速度异质性的结果。
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The maximum speed of shortening in living and skinned frog muscle fibres.活的和去皮的青蛙肌肉纤维的最大缩短速度。
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