Horak F B, Shupert C L, Dietz V, Horstmann G
R.S. Dow Neurological Sciences Institute, Good Samaritan Hospital, Portland, OR 97209.
Exp Brain Res. 1994;100(1):93-106. doi: 10.1007/BF00227282.
The relative contribution of vestibular and somatosensory information to triggering postural responses to external body displacements may depend on the task and on the availability of sensory information in each system. To separate the contribution of vestibular and neck mechanisms to the stabilization of upright stance from that of lower body somatosensory mechanisms, responses to displacements of the head alone were compared with responses to displacements of the head and body, in both healthy subjects and in patients with profound bilateral vestibular loss. Head displacements were induced by translating two 1-kg weights suspended on either side of the head at the level of the mastoid bone, and body displacements were induced translating the support surface. Head displacements resulted in maximum forward and backward head accelerations similar to those resulting from body displacements, but were not accompanied by significant center of body mass, ankle, knee, or hip motions. We tested the effect of disrupting somatosensory information from the legs on postural responses to head or body displacements by sway-referencing the support surface. The subjects' eyes were closed during all testing to eliminate the effects of vision. Results showed that head displacements alone can trigger medium latency (48-84 ms) responses in the same leg and trunk muscles as body displacements. Nevertheless, it is unlikely that vestibular signals alone normally trigger directionally specific postural responses to support surface translations in standing humans because: (1) initial head accelerations resulting from body and head displacements were in opposite directions, but were associated with activation of the same leg and trunk postural muscles; (2) muscle responses to displacements of the head alone were only one third of the amplitude of responses to body displacements with equivalent maximum head accelerations; and (3) patients with profound bilateral vestibular loss showed patterns and latencies of leg and trunk muscle responses to body displacements similar to those of healthy subjects. Altering somatosensory information, by sway-referencing the support surface, increased the amplitude of ankle muscle activation to head displacements and reduced the amplitude of ankle muscle activation to body displacements, suggesting context-specific reweighting of vestibular and somatosensory inputs for posture. In contrast to responses to body displacements, responses to direct head displacements appear to depend upon a vestibulospinal trigger, since trunk and leg muscle responses to head displacements were absent in patients who had lost vestibular function as adults.(ABSTRACT TRUNCATED AT 400 WORDS)
前庭和躯体感觉信息对触发针对身体外部位移的姿势反应的相对贡献可能取决于任务以及每个系统中感觉信息的可获取性。为了将前庭和颈部机制对直立姿势稳定的贡献与下半身躯体感觉机制的贡献区分开来,我们比较了健康受试者和双侧前庭功能严重丧失患者对单独头部位移的反应与对头部和身体位移的反应。通过在乳突骨水平移动悬挂在头部两侧的两个1千克重物来诱发头部位移,通过移动支撑面来诱发身体位移。头部位移导致的最大向前和向后头部加速度与身体位移导致的相似,但不伴有明显的身体重心、脚踝、膝盖或髋部运动。我们通过使支撑面随身体摆动来测试破坏来自腿部的躯体感觉信息对头部或身体位移姿势反应的影响。在所有测试过程中受试者双眼闭合以消除视觉影响。结果表明,单独的头部位移能够在与身体位移相同腿部和躯干肌肉中触发中等潜伏期(48 - 84毫秒)的反应。然而,仅前庭信号正常情况下不太可能触发站立人体对支撑面平移的方向特异性姿势反应,原因如下:(1)身体和头部位移产生的初始头部加速度方向相反,但与相同腿部和躯干姿势肌肉的激活相关;(2)单独头部位移时肌肉反应的幅度仅为同等最大头部加速度下身体位移反应幅度的三分之一;(3)双侧前庭功能严重丧失的患者对身体位移的腿部和躯干肌肉反应模式及潜伏期与健康受试者相似。通过使支撑面随身体摆动来改变躯体感觉信息,增加了脚踝肌肉对头部位移激活的幅度,并降低了脚踝肌肉对身体位移激活的幅度,这表明前庭和躯体感觉输入针对姿势进行了特定情境下的重新加权。与对身体位移的反应不同,对直接头部位移的反应似乎依赖于前庭脊髓触发,因为成年后丧失前庭功能的患者对头部位移没有躯干和腿部肌肉反应。(摘要截选至400字)
