Cheney P D, Fetz E E
J Physiol. 1984 Apr;349:249-72. doi: 10.1113/jphysiol.1984.sp015155.
To test the hypothesis that a transcortical reflex contributes to the stretch-evoked long-latency electromyographic (e.m.g.) response we documented the responses of identified corticomotoneuronal (c.m.) cells and their target muscles to perturbations of active wrist movements. Macaque monkeys performed ramp-and-hold wrist movements against elastic loads, alternating between flexion and extension zones; brief (25 ms) torque pulses were intermittently applied during the hold period. C.m. cells were identified by a clear post-spike facilitation in spike-triggered averages of forelimb muscle e.m.g. activity. Activity of c.m. cells and twelve wrist and digit flexor and extensor muscles was recorded during: (a) active ramp-and-hold wrist movements, (b) passive ramp-and-hold wrist movements, and (c) torque perturbations applied during the hold phase of active flexion and extension which either lengthened or shortened the c.m. cell's target muscles. Muscle-lengthening perturbations evoked a reproducible pattern of average e.m.g. activity in the stretched muscles, consisting of two peaks: the first response (M1) had an onset latency of 11.2 +/- 2.1 ms (mean +/- S.D.), and the second (M2) began at 27.9 +/- 5.1 ms. Torque perturbations which shortened the active muscles also evoked a characteristic e.m.g. response consisting of an initial cessation of activity at 13.5 +/- 3.4 ms followed by a peak beginning at 33.9 +/- 3.0 ms. The responses of twenty-one c.m. cells which facilitated wrist muscles were documented with torque pulse perturbations applied during active muscle contraction. Twenty of twenty-one c.m. cells responded at short latency (23.4 +/- 8.8 ms) to torque perturbations which stretched their target muscles. For each c.m. cell-target muscle pair, transcortical loop time was calculated as the sum of the onset latency of the c.m. cell's response to lengthening perturbations (afferent time) and the onset latency of post-spike facilitation (efferent time). The mean transcortical loop time was 30.4 +/- 10.2 ms, comparable to the mean onset latency of the M2 peak (27.9 +/- 5.1). The duration of a c.m. cell's response to torque perturbations provides a further measure of the extent of its potential contribution to the M2 muscle response. In all cases but two, the c.m. cell response, delayed by the latency of the post-spike facilitation, overlapped the M2 e.m.g. peak.
为了验证经皮质反射有助于牵张诱发的长潜伏期肌电图(e.m.g.)反应这一假说,我们记录了已识别的皮质脊髓运动神经元(c.m.)细胞及其靶肌肉对主动腕部运动扰动的反应。猕猴在弹性负荷下进行斜坡-保持腕部运动,在屈曲和伸展区域之间交替;在保持期间歇性施加短暂(25毫秒)的扭矩脉冲。通过在前肢肌肉e.m.g.活动的触发平均中明显的峰后易化来识别c.m.细胞。在以下期间记录c.m.细胞以及十二块腕部和手指屈肌与伸肌的活动:(a)主动斜坡-保持腕部运动,(b)被动斜坡-保持腕部运动,以及(c)在主动屈曲和伸展的保持阶段施加的扭矩扰动,这些扰动会使c.m.细胞的靶肌肉变长或变短。肌肉拉长扰动在被拉长的肌肉中诱发了可重复的平均e.m.g.活动模式,由两个峰值组成:第一个反应(M1)的起始潜伏期为11.2±2.1毫秒(平均值±标准差),第二个(M2)在27.9±5.1毫秒开始。缩短主动肌肉的扭矩扰动也诱发了一种特征性的e.m.g.反应,包括在13.5±3.4毫秒时活动的初始停止,随后在33.9±3.0毫秒开始出现一个峰值。在主动肌肉收缩期间施加扭矩脉冲扰动,记录了二十一个易化腕部肌肉的c.m.细胞的反应。二十一个c.m.细胞中有二十个对拉伸其靶肌肉的扭矩扰动有短潜伏期(23.4±8.8毫秒)反应。对于每对c.m.细胞-靶肌肉,经皮质环路时间计算为c.m.细胞对拉长扰动的反应起始潜伏期(传入时间)与峰后易化起始潜伏期(传出时间)之和。平均经皮质环路时间为30.4±10.2毫秒,与M2峰值的平均起始潜伏期(27.9±5.1)相当。c.m.细胞对扭矩扰动的反应持续时间进一步衡量了其对M2肌肉反应潜在贡献的程度。除了两例之外,在所有情况下,c.m.细胞的反应在峰后易化潜伏期延迟后,与M2 e.m.g.峰值重叠。
