通过向猫腓肠肌运动神经元注入斜坡电流来研究其运动单位的动态反应。
The dynamic response of cat gastrocnemius motor units investigated by ramp-current injection into their motoneurones.
作者信息
Baldissera F, Campadelli P, Piccinelli L
机构信息
Instituto di Fisiologia Umana II, Milano, Italy.
出版信息
J Physiol. 1987 Jun;387:317-30. doi: 10.1113/jphysiol.1987.sp016575.
Abstract
- The isometric force developed by single motor units in response to injection of ramp-and-hold currents into their motoneurones was recorded from the common tendon of the gastrocnemius muscles of the cat. The average rate of rise of the force (force-slope) produced by the ramp-evoked discharge, was found to grow almost linearly with the rate of current injection (current-slope) up to a saturation value (maximal force-slope). 2. The slope of the function which links the force slope to the current-slope is the gain (dF/dI) of the motor unit under dynamic conditions. The value of the dynamic gain, measured in the linear region of growth, displays a large variability, i.e. for each nanoampere of current injected, the force developed is as much as 40 times larger in the strongest than in the weakest motor units. Such large gain differences, however, are drastically reduced if the force is expressed as a percentage of the maximal tetanic tension, Ft: per nanoampere injected, most of the units deliver from 1.0 to 3.0% of Ft. 3. The maximal force-slope which each unit could reach exhibits a large variability, ranging from 0.06 to 4.0 g ms-1. Like the dynamic gain, the maximal force-slope is positively related to Ft. 4. It was found that the dynamic sensitivity of the motoneurone, i.e. the increase of the firing rate per unitary increase of the current-slope, governs the fractional growth of the force-slope, whereas the motor unit contraction time determines the firing rate at which maximal force-slope is reached. Together, the two factors co-operate in defining, for each motor unit, the range of input-slopes within which the force-slope is regulated. 5. The motoneurones which supply the weak motor units, those with the lowest dynamic gain, have higher dynamic sensitivity and lower rheobase than those innervating the strong motor units. This suggests that weak motor units need less synaptic current both to be recruited and to reach the maximal speed of force development when their input is supraliminal.
摘要
- 从猫的腓肠肌共同肌腱记录单个运动单位在向其运动神经元注入斜坡-保持电流时产生的等长力。发现斜坡诱发放电产生的力的平均上升速率(力斜率)几乎与电流注入速率(电流斜率)呈线性增长,直至达到饱和值(最大力斜率)。2. 将力斜率与电流斜率联系起来的函数的斜率是运动单位在动态条件下的增益(dF/dI)。在增长的线性区域测量的动态增益值显示出很大的变异性,即对于每注入一纳安电流,最强的运动单位产生的力比最弱的运动单位大40倍。然而,如果将力表示为最大强直张力Ft的百分比,则这种大的增益差异会大大减小:每注入一纳安电流,大多数单位提供Ft的1.0%至3.0%。3. 每个单位能够达到的最大力斜率表现出很大的变异性,范围从0.06到4.0 g·ms⁻¹。与动态增益一样,最大力斜率与Ft呈正相关。4. 发现运动神经元的动态敏感性,即电流斜率每单位增加时放电率的增加,控制着力斜率的分数增长,而运动单位收缩时间决定了达到最大力斜率时的放电率。这两个因素共同作用,为每个运动单位定义了力斜率受调节的输入斜率范围。5. 支配弱运动单位(即动态增益最低的单位)的运动神经元比支配强运动单位的运动神经元具有更高的动态敏感性和更低的基强度。这表明,当弱运动单位的输入超过阈限时,它们在被募集和达到最大力发展速度时都需要较少的突触电流。
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