人体中在足部主动背屈过程中产生交互抑制的脊髓机制。
Spinal mechanisms in man contributing to reciprocal inhibition during voluntary dorsiflexion of the foot.
作者信息
Crone C, Nielsen J
机构信息
Department of Neurophysiology, University of Copenhagen, Denmark.
出版信息
J Physiol. 1989 Sep;416:255-72. doi: 10.1113/jphysiol.1989.sp017759.
Abstract
- The inhibition of the soleus Hoffmann reflex (H reflex) during voluntary dorsiflexion of the foot--henceforth referred to as 'natural' reciprocal inhibition--was found to be initiated 50 ms before the onset of the EMG activity in the tibialis anterior muscle and to increase gradually during a ramp-and-hold dorsiflexion. There was a positive correlation between strength of tonic dorsiflexion and amount of 'natural' reciprocal inhibition. 2. The change of activity in the disynaptic and a long-latency group Ia inhibitory pathway and the change in presynaptic inhibition of the Ia fibres mediating the soleus H reflex were tested separately during ramp-and-hold dorsiflexion as well as during tonic dorsiflexion of the foot, and the results were compared with the development of the 'natural' reciprocal inhibition of the unconditioned soleus H reflex. 3. The disynaptic group I inhibition of soleus motoneurones was increased, as compared to rest, during the dynamic phase of a ramp-and-hold dorsiflexion movement, but the inhibition generally did not increase during tonic dorsiflexion of the foot. 4. The long-latency group I inhibition was seen only during dorsiflexion of the foot. It appeared around 50 ms before tibial anterior EMG activity and there was a positive correlation between strength of tonic dorsiflexion and amount of this long-latency inhibition. 5. Presynaptic inhibition of Ia afferents terminating on soleus motoneurones was estimated by an indirect method. The increase of presynaptic inhibition started soon after the onset of the ramp-and-hold dorsiflexion, and gradually became more pronounced during the ramp phase. The amount of presynaptic inhibition was positively correlated with strength of tonic dorsiflexion. 6. It is concluded that all investigated mechanisms may contribute to the 'natural' reciprocal inhibition and it seems that the different pathways are used differentially during different types of movement.
摘要
- 在足部主动背屈过程中比目鱼肌霍夫曼反射(H反射)的抑制作用——以下简称“自然”交互抑制——被发现于胫前肌肌电图活动开始前50毫秒启动,并在斜坡-保持背屈过程中逐渐增强。强直性背屈力量与“自然”交互抑制量之间存在正相关。2. 在斜坡-保持背屈以及足部强直性背屈过程中,分别测试了双突触和长潜伏期Ia类抑制通路的活动变化以及介导比目鱼肌H反射的Ia纤维的突触前抑制变化,并将结果与未条件化比目鱼肌H反射的“自然”交互抑制的发展情况进行了比较。3. 与静息状态相比,在斜坡-保持背屈运动的动态阶段,比目鱼肌运动神经元的双突触I类抑制增强,但在足部强直性背屈过程中,这种抑制通常不会增强。4. 长潜伏期I类抑制仅在足部背屈时出现。它在胫前肌肌电图活动前约50毫秒出现,强直性背屈力量与这种长潜伏期抑制量之间存在正相关。5. 通过间接方法估计了终止于比目鱼肌运动神经元的Ia传入纤维的突触前抑制。突触前抑制的增加在斜坡-保持背屈开始后不久就开始了,并在斜坡阶段逐渐变得更加明显。突触前抑制量与强直性背屈力量呈正相关。6. 得出的结论是,所有研究的机制可能都有助于“自然”交互抑制,并且似乎在不同类型的运动中,不同的通路被不同程度地使用。
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