人类在执行持续性运动任务时运动皮层与脊髓运动神经元池之间的同步性。
Synchronization between motor cortex and spinal motoneuronal pool during the performance of a maintained motor task in man.
作者信息
Conway B A, Halliday D M, Farmer S F, Shahani U, Maas P, Weir A I, Rosenberg J R
机构信息
Bioengineering Unit, University of Strathclyde, Glasgow, UK.
出版信息
J Physiol. 1995 Dec 15;489 ( Pt 3)(Pt 3):917-24. doi: 10.1113/jphysiol.1995.sp021104.
Abstract
- Simultaneous recordings of cortical activity, recorded as the magnetoencephalogram (MEG), and the electromyogram (EMG) of the ipsilateral and contralateral first dorsal interosseous muscles (1DI) were made during maintained voluntary contractions. 2. The MEG recorded from a localized region of the sensorimotor cortex of the dominant hemisphere was coherent with the EMG from the contralateral 1DI muscle over a limited band of frequencies. The peak coherence was confined largely within the beta range of cortical activity (13-35 Hz). Significant cortical activity at 10 Hz and 40-50 Hz was not correlated with motor output. The MEG and EMG from the ipsilateral 1DI muscle were uncorrelated at all frequencies. 3. Significant coherence between the MEG and the EMG was associated with synchronous behaviour between the MEG and EMG in the time domain. 4. The results demonstrate that synchronized cortical activity contributing to MEG activity within the beta range of frequencies during maintained voluntary contractions is coupled to motor output at frequencies of motor-unit activity associated with motor-unit synchronization. This observation provides further evidence for the involvement of cortical neurones in the generation of motor-unit synchronization. 5. We suggest that the coherence between MEG and contralateral EMG observed during maintained isometric contractions may provide an example of binding within the motor system.
摘要
- 在持续的自主收缩过程中,同时记录了作为脑磁图(MEG)的皮质活动以及同侧和对侧第一背侧骨间肌(1DI)的肌电图(EMG)。2. 从优势半球感觉运动皮质的局部区域记录的MEG在有限的频率范围内与对侧1DI肌肉的EMG具有相关性。峰值相关性主要局限于皮质活动的β频段(13 - 35Hz)。10Hz和40 - 50Hz的显著皮质活动与运动输出不相关。同侧1DI肌肉的MEG和EMG在所有频率下均不相关。3. MEG与EMG之间的显著相关性与时域中MEG和EMG之间的同步行为相关。4. 结果表明,在持续的自主收缩过程中,在频率的β范围内对MEG活动有贡献的同步皮质活动与运动单位同步相关的运动单位活动频率下的运动输出相耦合。这一观察结果为皮质神经元参与运动单位同步的产生提供了进一步的证据。5. 我们认为,在持续的等长收缩过程中观察到的MEG与对侧EMG之间的相关性可能提供了运动系统内结合的一个例子。
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