通过对人类运动皮层进行经颅磁刺激揭示的自主运动活动抑制。
Suppression of voluntary motor activity revealed using transcranial magnetic stimulation of the motor cortex in man.
作者信息
Davey N J, Romaiguère P, Maskill D W, Ellaway P H
机构信息
Department of Physiology, Charing Cross and Westminster Medical School, London.
出版信息
J Physiol. 1994 Jun 1;477(Pt 2):223-35. doi: 10.1113/jphysiol.1994.sp020186.
Abstract
- Suppression of voluntary muscle activity of hand and arm muscles in response to transcranial magnetic stimulation (TMS) of the motor cortex has been investigated in man. 2. Suppression could be elicited by low levels of TMS without any prior excitatory response. The latency of the suppression was 3-8 ms longer than the excitation observed at a higher stimulus intensity. The duration of the suppression ranged from 8 to 26 ms. 3. A circular stimulating coil was used to determine threshold intensity for excitation and suppression of contraction of thenar muscles in response to TMS at different locations over the motor cortex. The locations for lowest threshold excitation coincided with those for lowest threshold suppression. Suppression was elicited at a lower threshold than excitation at all locations. 4. A figure-of-eight stimulating coil was positioned over the left motor cortex at the lowest threshold point for excitation of the right thenar muscles. The orientation for the lowest threshold excitatory and inhibitory responses was the same for all subjects. That orientation induced a stimulating current travelling in an antero-medial direction. Suppression was invariably elicited at lower thresholds than excitation. 5. When antagonistic muscles (second and third dorsal interosseus) were co-contracted, TMS evoked coincident suppression of voluntary EMG in the two muscles without prior excitation of either muscle. This suggests that the suppression is not mediated via corticospinal activation of spinal interneurones. 6. Test responses to electrical stimulation of the cervical spinal cord were evoked in both relaxed and activated thenar muscles. In the relaxed muscle, prior TMS at an intensity that would suppress voluntary activity failed to influence the test responses, suggesting absence of inhibition at a spinal level. However, in the activated muscle, prior TMS could reduce the test response. This may be explained by disfacilitation of motoneurones due to inhibition of corticospinal output. 7. We propose that suppression of voluntary muscle activity by TMS is due in large part to activation of a mechanism within the motor cortex that reduces the corticospinal output to the muscle. It is concluded that TMS evokes excitation and inhibition via neuronal structures lying close to one another and having similar orientations.
摘要
- 人们已经对人类运动皮层经颅磁刺激(TMS)引起的手部和手臂肌肉随意肌活动抑制进行了研究。2. 低强度TMS即可引发抑制,且无任何先前的兴奋反应。抑制的潜伏期比在较高刺激强度下观察到的兴奋长3 - 8毫秒。抑制的持续时间为8至26毫秒。3. 使用圆形刺激线圈确定运动皮层不同位置经颅磁刺激时激发和抑制鱼际肌收缩的阈值强度。最低阈值激发的位置与最低阈值抑制的位置重合。在所有位置,抑制均在低于激发的阈值下引发。4. 将8字形刺激线圈置于左侧运动皮层上激发右侧鱼际肌的最低阈值点。所有受试者最低阈值兴奋和抑制反应的方向相同。该方向诱导刺激电流沿前内侧方向传播。抑制总是在低于激发的阈值下引发。5. 当拮抗肌(第二和第三背侧骨间肌)共同收缩时,经颅磁刺激在两块肌肉中同时引发随意肌电图的抑制,而两块肌肉均无先前的兴奋。这表明抑制不是通过脊髓中间神经元的皮质脊髓激活介导的。6. 在放松和激活的鱼际肌中均诱发了对颈脊髓电刺激的测试反应。在放松的肌肉中,以抑制随意活动的强度进行的先前经颅磁刺激未能影响测试反应,表明在脊髓水平不存在抑制。然而,在激活的肌肉中,先前的经颅磁刺激可降低测试反应。这可能是由于皮质脊髓输出的抑制导致运动神经元去易化来解释。7. 我们提出,经颅磁刺激对随意肌活动的抑制在很大程度上是由于运动皮层内一种机制的激活,该机制减少了向肌肉的皮质脊髓输出。得出的结论是,经颅磁刺激通过彼此靠近且方向相似的神经元结构引发兴奋和抑制。
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