自主收缩对清醒人类经颅刺激诱发的下行冲动的影响。
Effects of voluntary contraction on descending volleys evoked by transcranial stimulation in conscious humans.
作者信息
Di Lazzaro V, Restuccia D, Oliviero A, Profice P, Ferrara L, Insola A, Mazzone P, Tonali P, Rothwell J C
机构信息
Istituto di Neurologia, Università Cattolica, L.go A. Gemelli 8, 00168 Rome, Italy.
出版信息
J Physiol. 1998 Apr 15;508 ( Pt 2)(Pt 2):625-33. doi: 10.1111/j.1469-7793.1998.625bq.x.
Abstract
- The spinal volleys evoked by single transcranial magnetic or electric stimulation over the cerebral motor cortex were recorded from a bipolar electrode inserted into the cervical epidural space of three conscious human subjects. These volleys were termed direct (D) and indirect (I) waves according to their latency. 2. We measured the size and number of volleys elicited by magnetic stimulation at various intensities with subjects at rest and during 20 or 100 % maximum contraction of the contralateral first dorsal interosseous muscle (FDI). Surface EMG activity was also recorded. 3. Electrical stimulation evoked a D-wave volley. Magnetic stimulation at intensities up to about 15 % of stimulator output above threshold evoked only I-waves. At higher intensities, a D-wave could be seen in two of the three subjects. 4. At all intensities tested, voluntary contraction increased the number and size of the I-waves, particularly during maximum contractions. However, there was only a small effect on the threshold for evoking descending activity. Voluntary contraction produced large changes in the size of EMG responses recorded from FDI. 5. Because the recorded epidural activity is destined for muscles other than the FDI, it is impossible to say to what extent increased activity contributes to voluntary facilitation of EMG responses. Indeed, our results suggest that the main factor responsible for enhancing EMG responses in the transition from rest to activity is likely to be increased excitability of spinal motoneurones, rather than increases in the corticospinal volley. The latter may be more important in producing EMG facilitation at different levels of voluntary contraction.
摘要
- 从插入三名清醒人类受试者颈段硬膜外间隙的双极电极记录了经颅磁刺激或电刺激大脑运动皮层所诱发的脊髓冲动。根据其潜伏期,这些冲动被称为直接(D)波和间接(I)波。2. 我们测量了在受试者休息时以及对侧第一背侧骨间肌(FDI)进行20%或100%最大收缩时,不同强度磁刺激诱发的冲动的大小和数量。还记录了表面肌电图活动。3. 电刺激诱发了D波冲动。刺激强度达到阈值以上约15%的刺激器输出时,磁刺激仅诱发I波。在更高强度时,三名受试者中有两名可见D波。4. 在所有测试强度下,随意收缩增加了I波的数量和大小,尤其是在最大收缩期间。然而,对诱发下行活动的阈值只有很小的影响。随意收缩使从FDI记录的肌电图反应大小发生了很大变化。5. 由于记录的硬膜外活动是针对FDI以外的肌肉,因此无法确定活动增加在多大程度上有助于肌电图反应的随意易化。事实上,我们的结果表明,在从休息到活动的转变中,增强肌电图反应的主要因素可能是脊髓运动神经元兴奋性的增加,而不是皮质脊髓冲动的增加。后者在不同程度的随意收缩中产生肌电图易化可能更为重要。
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