McKinley P A, Smith J L, Gregor R J
Exp Brain Res. 1983;49(2):218-28. doi: 10.1007/BF00238582.
Forces and displacements at the elbow joint have been related to EMG responses of flexor and extensor muscles during landing from jump downs at heights of 1.2 m to 0.6 m in five cats. Prelanding EMG activity consisted of two prelanding extensor bursts. Onset of both bursts was constant across all jump heights with reference to landing and not to take-off, occurring on average 73 +/- 12 ms and 17 +/- 8 ms prior to ground contact for the lateral triceps. Post-landing EMG activity was less than prelanding activity and was often packaged in three bursts, occurring on average at 18 +/- 6, 34 +/- 8 and 50 +/- 9 ms after touchdown. Other measurements from extensor EMG including burst duration and integrated activity pre- and post-landing were also invariant. Across jump heights, maximum flexion angular velocity and elbow displacement were reached on average 28 +/- 5 and 85 +/- 7 ms postlanding, respectively. Although vertical (y) and horizontal (x) ground reaction forces increased with jump height, torque values at the elbow joint were not significantly different and were small in magnitude. At landing an animal typically experienced a 20 ms flexor torque (0.3 Nm/kg b.wt.) followed by an extensor torque (0.4 Nm/kg b.wt.) that continued for the major portion of elbow flexion. The temporal constancy of the kinematic and kinetic data and EMG activity across jump heights suggests that a generalized motor program can be used to activate extensor muscles at the elbow joint during the prelanding phase of self-initiated jumps. Since the onset of extensor activity is related to landing rather than to take-off, it is hypothesized that this activity is triggered by visual cues rather than by vestibular reflexes. After impact, adjustments for slight differences in post-landing torque about the elbow may be accomplished by intrinsic properties of the activated muscle as well as through segmental reflexes.
在五只猫从1.2米至0.6米高度跳下落地过程中,肘关节处的力和位移与屈肌和伸肌的肌电图(EMG)反应相关。着陆前的肌电图活动包括两次着陆前伸肌爆发。两次爆发的起始相对于着陆而非起跳在所有跳跃高度上都是恒定的,外侧三头肌平均在地面接触前73±12毫秒和17±8毫秒出现爆发。着陆后的肌电图活动小于着陆前活动,且常表现为三次爆发,平均在触地后18±6毫秒、34±8毫秒和50±9毫秒出现。伸肌肌电图的其他测量指标,包括爆发持续时间以及着陆前后的积分活动,也都是不变的。在不同跳跃高度下,最大屈曲角速度和肘关节位移分别平均在着陆后28±5毫秒和85±7毫秒达到。尽管垂直(y)和水平(x)地面反作用力随跳跃高度增加,但肘关节处的扭矩值并无显著差异且数值较小。着陆时,动物通常会经历20毫秒的屈肌扭矩(0.3牛米/千克体重),随后是伸肌扭矩(0.4牛米/千克体重),该伸肌扭矩在肘关节屈曲的大部分时间内持续存在。运动学和动力学数据以及肌电图活动在不同跳跃高度下的时间恒定性表明,在自我发起跳跃的着陆前阶段,可以使用一个通用的运动程序来激活肘关节处的伸肌。由于伸肌活动的起始与着陆而非起跳相关,因此推测这种活动是由视觉线索而非前庭反射触发的。撞击后,关于肘关节着陆后扭矩微小差异的调整可能通过激活肌肉的内在特性以及节段反射来完成。
