Pollok Bettina, Gross Joachim, Dirks Martin, Timmermann Lars, Schnitzler Alfons
Department of Neurology, Heinrich-Heine University, Moorenstrasse 5, 40225 Duesseldorf, Germany.
J Physiol. 2004 Feb 1;554(Pt 3):871-8. doi: 10.1113/jphysiol.2003.051235. Epub 2003 Nov 28.
It has recently been shown that resting tremor in Parkinson's disease is associated with oscillatory neural coupling in an extensive cerebral network comprising a cerebello-diencephalic-cortical loop and cortical motor, somatosensory and posterior parietal areas contralateral to the tremor hand. The aim of the present study was to investigate whether this oscillatory brain network exclusively reflects a pathophysiological state in parkinsonian resting tremor or whether it constitutes a fundamental feature of physiological motor control. We investigated cerebro-muscular and cerebro-cerebral coupling in 11 healthy subjects imitating typical antagonistic parkinsonian tremor. We recorded brain activity with a 122-channel whole-head neuromagnetometer and surface EMGs of the forearm extensor. Analysis of cerebro-muscular and cerebro-cerebral coherence revealed oscillatory coupling in the same brain structures that comprise the oscillatory network of parkinsonian resting tremor. Interestingly, similar to parkinsonian resting tremor, cerebro-cerebral coherences often showed a significant peak at twice the simulated tremor frequency. The most striking differences between parkinsonian patients, as investigated in a previous study and healthy subjects imitating the antagonistic resting tremor were a reduction of the coupling between primary sensorimotor cortex and a diencephalic structure--most likely the thalamus--and an enhancement of the coupling between premotor and primary sensorimotor cortex. Our results indicate that the coupling of oscillatory activity within a cerebello-diencephalic-cortical loop constitutes a basic feature of physiological motor control. Thus, our data are consistent with the hypothesis that parkinsonian resting tremor involves oscillatory cerebro-cerebral coupling in a physiologically pre-existing network.
最近的研究表明,帕金森病的静止性震颤与一个广泛的脑网络中的振荡性神经耦合有关,该网络包括一个小脑-间脑-皮质环路以及与震颤手对侧的皮质运动区、体感区和顶叶后部区域。本研究的目的是调查这种振荡性脑网络是否仅反映帕金森病静止性震颤的病理生理状态,或者它是否构成生理运动控制的一个基本特征。我们对11名模仿典型帕金森病拮抗震颤的健康受试者的脑-肌肉和脑-脑耦合进行了研究。我们用122通道全脑神经磁强计记录脑活动,并记录前臂伸肌的表面肌电图。脑-肌肉和脑-脑相干性分析揭示了在构成帕金森病静止性震颤振荡网络的相同脑结构中的振荡耦合。有趣的是,与帕金森病静止性震颤相似,脑-脑相干性通常在模拟震颤频率的两倍处显示出一个显著的峰值。在先前的一项研究中对帕金森病患者进行调查,与模仿拮抗静止性震颤的健康受试者之间最显著的差异是初级感觉运动皮层与一个间脑结构(很可能是丘脑)之间的耦合减少,以及运动前区与初级感觉运动皮层之间的耦合增强。我们的结果表明,小脑-间脑-皮质环路内振荡活动的耦合构成了生理运动控制的一个基本特征。因此,我们的数据与以下假设一致,即帕金森病静止性震颤涉及在生理上预先存在的网络中的振荡性脑-脑耦合。