Timmermann Lars, Gross Joachim, Dirks Martin, Volkmann Jens, Freund Hans-Joachim, Schnitzler Alfons
Department of Neurology, Heinrich-Heine University, Duesseldorf, Germany.
Brain. 2003 Jan;126(Pt 1):199-212. doi: 10.1093/brain/awg022.
Data from experiments in MPTP monkeys as well as from invasive and non-invasive recordings in patients with Parkinson's disease suggest an abnormal synchronization of neuronal activity in the generation of resting tremor in Parkinson's disease. In six patients with tremor-dominant idiopathic Parkinson's disease, we recorded simultaneously surface electromyograms (EMGs) of hand muscles, and brain activity with a whole-head magnetoencephalography (MEG) system. Using a recently developed analysis tool (Dynamic Imaging of Coherent Sources; DICS), we determined cerebro-muscular and cerebro-cerebral coherence as well as the partial coherence between cerebral areas and muscle, and localized coherent sources within the individual MRI scans. The phase lag between the EMG and cerebral activity was determined by means of a Hilbert transform of both signals. After overnight withdrawal from medication, patients showed typical Parkinson's disease resting tremor (4-6 Hz). This tremor was associated with strong coherence between the EMG of forearm muscles and activity in the contralateral primary motor cortex (M1) at tremor frequency but also at double tremor frequency. Phase lags between M1 activity and EMG were between 15 and 25 ms (M1 activity leading) at single, but also at double tremor frequency, corresponding well to the corticomuscular conduction time. Furthermore, significant coherence was observed between M1 and medial wall areas (cingulate/supplementary motor area; CMA/SMA), lateral premotor cortex (PM), diencephalon, secondary somatosensory cortex (SII), posterior parietal cortex (PPC) and the contralateral cerebellum at single tremor and, even stronger at double tremor frequency. Spectra of coherence between thalamic activity and cerebellum as well as several brain areas revealed additional broad peaks around 20 Hz. Power spectral analysis of activity in all central areas indicated the strongest frequency components at double tremor frequency. Partial coherence analysis and the calculation of phase shifts revealed a strong bidirectional coupling between the EMG and diencephalic activity and a direct afferent coupling between the EMG and SII and the PPC. In contrast, the cerebellum, SMA/CMA and PM show little evidence for direct coupling with the peripheral EMG but seem to be connected with the periphery via other cerebral areas (e.g. M1). In summary, our results demonstrate tremor-related oscillatory activity within a cerebral network, with abnormal coupling in a cerebello-diencephalic-cortical loop and cortical motor (M1, SMA/CMA, PM) and sensory (SII, PPC) areas contralateral to the tremor hand. The main frequency of cerebro-cerebral coupling corresponds to double the tremor frequency.
来自MPTP猴子实验的数据以及帕金森病患者的侵入性和非侵入性记录表明,帕金森病静止性震颤产生过程中神经元活动存在异常同步。在6例以震颤为主的特发性帕金森病患者中,我们同时记录了手部肌肉的表面肌电图(EMG)以及使用全头磁脑图(MEG)系统记录大脑活动。使用最近开发的分析工具(相干源动态成像;DICS),我们确定了脑-肌肉和脑-脑相干性以及脑区与肌肉之间的部分相干性,并在个体MRI扫描中定位了相干源。通过对两个信号进行希尔伯特变换来确定EMG与大脑活动之间的相位滞后。在隔夜停药后,患者表现出典型的帕金森病静止性震颤(4 - 6Hz)。这种震颤与前臂肌肉的EMG和对侧初级运动皮层(M1)在震颤频率以及两倍震颤频率时的强烈相干性相关。在单震颤频率以及两倍震颤频率时,M1活动与EMG之间的相位滞后在15至25毫秒之间(M1活动领先),与皮质-肌肉传导时间非常吻合。此外,在单震颤频率时,观察到M1与内侧壁区域(扣带回/辅助运动区;CMA/SMA)、外侧运动前皮层(PM)、间脑、次级体感皮层(SII)、顶叶后皮层(PPC)以及对侧小脑之间存在显著相干性,在两倍震颤频率时相干性更强。丘脑活动与小脑以及几个脑区之间的相干谱在20Hz左右还显示出额外的宽峰。所有中枢区域活动的功率谱分析表明,在两倍震颤频率时频率成分最强。部分相干性分析和相移计算揭示了EMG与间脑活动之间存在强烈的双向耦合,以及EMG与SII和PPC之间存在直接的传入耦合。相比之下,小脑、SMA/CMA和PM几乎没有证据表明与外周EMG有直接耦合,但似乎通过其他脑区(如M1)与外周相连。总之,我们的结果表明在一个脑网络中存在与震颤相关的振荡活动,在小脑-间脑-皮质环路以及与震颤手对侧的皮质运动(M1、SMA/CMA、PM)和感觉(SII、PPC)区域存在异常耦合。脑-脑耦合的主要频率相当于震颤频率的两倍。
