Published Paper: Brain Stimulation
"The homeostatic interaction between anodal transcranial direct current stimulation and motor learning in humans is related to GABA-A Activity" - Amadi et al. 2015
We are pleased to announce the publishing of our paper in the journal Brain Stimulation.
The paper is titled "The homeostatic interaction between anodal transcranial direct current stimulation and motor learning in humans is related to GABA-A Activity" and the manuscript can be found online here. Congratulations to the authors: Ugwechi Amadi, Claire Allman, Heidi Johansen-Berg and Charlotte Stagg.
ABSTRACT
Background: The relative timing of plasticity-induction protocols is known to be crucial. For example, anodal transcranial direct current stimulation (tDCS), which increases cortical excitability and typically enhances plasticity, can impair performance if it is applied before a motor learning task. Such timing-dependent effects have been ascribed to homeostatic plasticity, but the specific synaptic site of this interaction remains unknown.
Objective: We wished to investigate the synaptic substrate, and in particular the role of inhibitory signaling, underpinning the behavioral effects of anodal tDCS in homeostatic interactions between anodal tDCS and motor learning.
Methods: We used transcranial magnetic stimulation (TMS) to investigate cortical excitability and inhibitory signaling following tDCS and motor learning. Each subject participated in four experimental sessions and data were analyzed using repeated measures ANOVAs and post-hoc t-tests as appropriate.
Results: As predicted, we found that anodal tDCS prior to the motor task decreased learning rates. This worsening of learning after tDCS was accompanied by a correlated increase in GABAA activity, as measured by TMS-assessed short interval intra-cortical inhibition (SICI).
Conclusion: This provides the first direct demonstration in humans that inhibitory synapses are the likely site for the interaction between anodal tDCS and motor learning, and further, that homeostatic plasticity at GABAA synapses has behavioral relevance in humans.