轴突切断术对猫运动过程中神经活动的长期影响。
Long-term effects of axotomy on neural activity during cat locomotion.
作者信息
Gordon T, Hoffer J A, Jhamandas J, Stein R B
出版信息
J Physiol. 1980 Jun;303:243-63. doi: 10.1113/jphysiol.1980.sp013283.
Abstract
- Neural activity was recorded from cats during locomotion on a treadmill using electrodes in Silastic cuffs placed around the sciatic nerve and the lateral gastrocnemius-soleus, medial gastrocnemius, common peroneal and tibial nerve branches. Each branch gave characteristic patterns of activity which were studied before and after it was cut distal to the recording cuffs. Sensory and motor components were separated and measured using cross-correlation techniques. The amplitude of the cross-correlation peaks was compared with the amplitude of compound action potentials evoked by electrical stimulation and recorded from the same sites in the anaesthetized animal. 2. Sensory activity declined rapidly following axotomy and did not recover unless reinnervation occurred. Sensory activity even 5 months after nerve section and resuture had recovered to only a fraction of the control values. This reduction is attributed to a decline in the evoked compound potentials and to many fibres being unsuccessful in regenerating to appropriate sensory organs. 3. Motor activity declined more than could be accounted for by a decline in evoked potentials over the first month after axotomy. The extra reduction represents a decline in the number of impulses generated by alpha-motoneurones after axotomy. If regeneration was permitted, motor activity recovered to higher levels than did the evoked potentials for the whole nerve. Even if regeneration was prevented by nerve ligation, motoneurones continued to generate activity at a stable level over a period of months during which whole nerve compound potentials continued to decline. 4. The modulation of motor activity in ligated nerves during the step cycle was still appropriate to the required movement. Thus, activity recorded from severed nerves in human amputees may be useful in controlling powered artificial limbs. The persistence of motor activity may be responsible for the lesser degree of atrophy found in motor fibres than in sensory fibres following ligation (Hoffer, Stein & Gordon, 1979b).
摘要
- 在猫在跑步机上运动时,使用置于坐骨神经、外侧腓肠肌-比目鱼肌、内侧腓肠肌、腓总神经和胫神经分支周围的硅橡胶袖带电极记录神经活动。每个分支都给出了特征性的活动模式,在记录袖带远端切断该分支之前和之后对其进行了研究。使用互相关技术分离并测量感觉和运动成分。将互相关峰值的幅度与在麻醉动物的相同部位通过电刺激诱发并记录的复合动作电位的幅度进行比较。2. 轴突切断后感觉活动迅速下降,除非发生再支配,否则不会恢复。即使在神经切断和重新缝合5个月后,感觉活动也仅恢复到对照值的一小部分。这种减少归因于诱发复合电位的下降以及许多纤维未能成功再生至适当的感觉器官。3. 在轴突切断后的第一个月,运动活动下降的幅度超过了诱发电位下降所能解释的范围。额外的下降代表轴突切断后α运动神经元产生的冲动数量的下降。如果允许再生,运动活动恢复到比整个神经的诱发电位更高的水平。即使通过神经结扎阻止再生,运动神经元在数月内仍继续以稳定水平产生活动,在此期间整个神经复合电位持续下降。4. 在步态周期中,结扎神经中运动活动的调制仍然与所需运动相适应。因此,从人类截肢者切断的神经中记录的活动可能有助于控制动力假肢。运动活动的持续存在可能是结扎后运动纤维萎缩程度低于感觉纤维的原因(霍弗、斯坦因和戈登,1979b)。
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