Waters Sheena, Wiestler Tobias, Diedrichsen Jörn
Institute of Cognitive Neuroscience.
Institute of Neurology, and.
J Neurosci. 2017 Aug 2;37(31):7500-7512. doi: 10.1523/JNEUROSCI.3414-16.2017. Epub 2017 Jul 3.
What is the role of ipsilateral motor and premotor areas in motor learning? One view is that ipsilateral activity suppresses contralateral motor cortex and, accordingly, that inhibiting ipsilateral regions can improve motor learning. Alternatively, the ipsilateral motor cortex may play an active role in the control and/or learning of unilateral hand movements. We approached this question by applying double-blind bihemispheric transcranial direct current stimulation (tDCS) over both contralateral and ipsilateral motor cortex in a between-group design during 4 d of unimanual explicit sequence training in human participants. Independently of whether the anode was placed over contralateral or ipsilateral motor cortex, bihemispheric stimulation yielded substantial performance gains relative to unihemispheric or sham stimulation. This performance advantage appeared to be supported by plastic changes in both hemispheres. First, we found that behavioral advantages generalized strongly to the untrained hand, suggesting that tDCS strengthened effector-independent representations. Second, functional imaging during speed-matched execution of trained sequences conducted 48 h after training revealed sustained, polarity-independent increases in activity in both motor cortices relative to the sham group. These results suggest a cooperative rather than competitive interaction of the two motor cortices during skill learning and suggest that bihemispheric brain stimulation during unimanual skill learning may be beneficial because it harnesses plasticity in the ipsilateral hemisphere. Many neurorehabilitation approaches are based on the idea that is beneficial to boost excitability in the contralateral hemisphere while attenuating that of the ipsilateral cortex to reduce interhemispheric inhibition. We observed that bihemispheric transcranial direct current stimulation (tDCS) with the excitatory anode either over contralateral or ipsilateral motor cortex facilitated motor learning nearly twice as strongly as unihemispheric tDCS. These increases in motor learning were accompanied by increases in fMRI activation in both motor cortices that outlasted the stimulation period, as well as increased generalization to the untrained hand. Collectively, our findings suggest a cooperative rather than a competitive role of the hemispheres and imply that it is most beneficial to harness plasticity in both hemispheres in neurorehabilitation of motor deficits.
同侧运动区和运动前区在运动学习中起什么作用?一种观点认为,同侧活动会抑制对侧运动皮层,因此,抑制同侧区域可以改善运动学习。另一种观点认为,同侧运动皮层可能在单侧手部运动的控制和/或学习中发挥积极作用。我们通过在人类参与者进行4天的单手动明确序列训练期间,采用组间设计,对双侧运动皮层施加双盲双半球经颅直流电刺激(tDCS)来探讨这个问题。不管阳极是置于对侧还是同侧运动皮层,双半球刺激相对于单半球或假刺激都产生了显著的表现提升。这种表现优势似乎得到了两个半球可塑性变化的支持。首先,我们发现行为优势强烈地推广到了未训练的手,这表明tDCS加强了与效应器无关的表征。其次,在训练后48小时进行的速度匹配的训练序列执行过程中的功能成像显示,相对于假刺激组,两个运动皮层的活动持续且与极性无关地增加。这些结果表明,在技能学习过程中,两个运动皮层之间存在合作而非竞争的相互作用,并表明在单手动技能学习期间进行双半球脑刺激可能是有益的,因为它利用了同侧半球的可塑性。许多神经康复方法基于这样的理念,即增强对侧半球的兴奋性同时减弱同侧皮层的兴奋性以减少半球间抑制是有益的。我们观察到,将兴奋性阳极置于对侧或同侧运动皮层的双半球经颅直流电刺激(tDCS)促进运动学习的效果几乎是单半球tDCS的两倍。这些运动学习的增加伴随着两个运动皮层中功能磁共振成像激活的增加,这种增加在刺激期之后仍然持续,并且对未训练手的泛化也增加。总的来说,我们的研究结果表明半球之间存在合作而非竞争的作用,并意味着在运动缺陷的神经康复中利用两个半球的可塑性是最有益的。
