Neuromodulation of premotor and posterior parietal cortices for enhancing explicit motor sequence learning in healthy individuals: a randomized, sham-controlled crossover trial

C. Russo, M. Carneiro, G. Vallar, N. Bolognini
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引用次数: 1

Abstract

Background: Anodal transcranial Direct Current Stimulation (tDCS) has been shown to be effective in improving human motor learning when applied over the contralateral primary motor cortex (M1). However, the stimulation of other cortical areas, such as the posterior parietal (PPC) and premotor (PMC) cortices, may be also beneficial. Methods: The present study (crossover design) investigated the effects of tDCS applied over PPC, PMC, and M1 on the acquisition and retention of a new motor skill, and on the generalization of such learned skill in healthy individuals. During a sequential finger-tapping task (FTT), performed with the non-dominant (left) hand, participants received real or sham anodal tDCS (1.5 mA, 20 min) over PPC, PMC, and the M1 of the right hemisphere. Explicit motor sequence learning was measured online (during the training with tDCS; primary outcome) and 24 hours after tDCS (retention, secondary outcome). A new, untrained, sequence was used to assess generalization effects (secondary outcome). Results: Anodal tDCS of M1 improved both online learning and retention. PMC tDCS facilitated the generalization of the learning effect to the untrained motor sequence. In contrast, neuromodulation of the PPC does not influence motor sequence learning. Conclusions: These findings show that, in addition to M1, higher-order associative cortical regions (PMC and PPC) are involved in explicit online motor sequence learning, retention and generalization playing different roles, as indicated by the differential modulatory effects of anodal tDCS.
运动前和后顶叶皮质神经调控增强健康人外显运动序列学习的随机、sham对照交叉试验
背景:当在对侧初级运动皮层(M1)上应用时,经颅肛门直流电刺激(tDCS)已被证明在改善人类运动学习方面是有效的。然而,刺激其他皮层区域,如后顶叶(PPC)和运动前(PMC)皮层,也可能是有益的。方法:本研究(交叉设计)研究了在PPC、PMC和M1上应用tDCS对一种新的运动技能的获得和保留的影响,以及对健康个体学习技能的泛化的影响。在用非优势(左手)进行的顺序手指敲击任务(FTT)中,参与者通过PPC、PMC和右半球的M1接受真实或假阳极tDCS(1.5mA,20min)。显式运动序列学习是在线测量的(在tDCS训练期间;主要结果)和tDCS后24小时(保留,次要结果)。使用一个新的、未经训练的序列来评估泛化效果(次要结果)。结果:M1的匿名tDCS改善了在线学习和保留。PMC tDCS有助于将学习效果推广到未训练的运动序列。相反,PPC的神经调控并不影响运动序列学习。结论:这些发现表明,除了M1之外,高阶联想皮层区域(PMC和PPC)也参与了显式在线运动序列学习、保持和泛化,发挥着不同的作用,阳极tDCS的差异调节作用表明了这一点。
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