Moisa Marius, Polania Rafael, Grueschow Marcus, Ruff Christian C
Laboratory for Social and Neural Systems Research, Department of Economics, University of Zurich, CH-8006 Zurich, Switzerland, and
Institute for Biomedical Engineering, University and ETH of Zurich, CH-8092 Zurich, Switzerland.
J Neurosci. 2016 Nov 23;36(47):12053-12065. doi: 10.1523/JNEUROSCI.2044-16.2016.
Gamma and beta oscillations are routinely observed in motor-related brain circuits during movement preparation and execution. Entrainment of gamma or beta oscillations via transcranial alternating current stimulation (tACS) over primary motor cortex (M1) has opposite effects on motor performance, suggesting a causal role of these brain rhythms for motor control. However, it is largely unknown which brain mechanisms characterize these changes in motor performance brought about by tACS. In particular, it is unclear whether these effects result from brain activity changes only in the targeted areas or within functionally connected brain circuits. Here we investigated this issue by applying gamma-band and beta-band tACS over M1 in healthy humans during a visuomotor task and concurrent functional magnetic resonance imaging (fMRI). Gamma tACS indeed improved both the velocity and acceleration of visually triggered movements, compared with both beta tACS and sham stimulation. Beta tACS induced a numerical decrease in velocity compared with sham stimulation, but this was not statistically significant. Crucially, gamma tACS induced motor performance enhancements correlated with changed BOLD activity in the stimulated M1. Moreover, we found frequency- and task-specific neural compensatory activity modulations in the dorsomedial prefrontal cortex (dmPFC), suggesting a key regulatory role of this region in motor performance. Connectivity analyses revealed that the dmPFC interacted functionally with M1 and with regions within the executive motor system. These results suggest a role of the dmPFC for motor control and show that tACS-induced behavioral changes not only result from activity modulations underneath the stimulation electrode but also reflect compensatory modulation within connected and functionally related brain networks. More generally, our results illustrate how combined tACS-fMRI can be used to resolve the causal link between cortical rhythms, brain systems, and behavior.
Recent research has suggested a causal role for gamma oscillations during movement preparation and execution. Here we combine transcranial alternating current stimulation (tACS) with functional magnetic resonance imaging (fMRI) to identify the neural mechanisms that accompany motor performance enhancements triggered by gamma tACS over the primary motor cortex. We show that the tACS-induced motor performance enhancements correlate with changed neural activity in the stimulated area and modulate, in a frequency- and task-specific manner, the neural activity in the dorsomedial prefrontal cortex. This suggests a regulatory role of this region for motor control. More generally, we show that combined tACS-fMRI can elucidate the causal link between brain oscillations, neural systems, and behavior.
在运动准备和执行过程中,γ和β振荡通常在与运动相关的脑回路中被观察到。通过经颅交流电刺激(tACS)作用于初级运动皮层(M1)来夹带γ或β振荡,对运动表现有相反的影响,这表明这些脑节律在运动控制中具有因果作用。然而,很大程度上未知哪些脑机制表征了由tACS引起的这些运动表现变化。特别是,尚不清楚这些效应是否仅由目标区域内的脑活动变化导致,还是由功能连接的脑回路内的变化引起。在这里,我们通过在健康人类进行视觉运动任务和同步功能磁共振成像(fMRI)期间,对M1施加γ波段和β波段tACS来研究这个问题。与β波段tACS和假刺激相比,γ波段tACS确实改善了视觉触发运动的速度和加速度。与假刺激相比,β波段tACS导致速度在数值上有所下降,但这在统计学上并不显著。至关重要的是,γ波段tACS引起的运动表现增强与受刺激M1中血氧水平依赖(BOLD)活动的变化相关。此外,我们在背内侧前额叶皮层(dmPFC)发现了频率和任务特异性的神经代偿活动调制,表明该区域在运动表现中起关键调节作用。连通性分析显示,dmPFC在功能上与M1以及执行运动系统内的区域相互作用。这些结果表明dmPFC在运动控制中的作用,并表明tACS诱导的行为变化不仅源于刺激电极下方的活动调制,还反映了连接的和功能相关的脑网络内的代偿调制。更一般地说,我们的结果说明了如何使用联合tACS-fMRI来解析皮层节律、脑系统和行为之间的因果联系。
最近的研究表明γ振荡在运动准备和执行过程中具有因果作用。在这里,我们将经颅交流电刺激(tACS)与功能磁共振成像(fMRI)相结合,以确定伴随初级运动皮层上γ波段tACS触发的运动表现增强的神经机制。我们表明,tACS诱导的运动表现增强与受刺激区域神经活动的变化相关,并以频率和任务特异性的方式调节背内侧前额叶皮层的神经活动。这表明该区域对运动控制具有调节作用。更一般地说,我们表明联合tACS-fMRI可以阐明脑振荡、神经系统和行为之间的因果联系。