Anodal tDCS over primary motor cortex provides no advantage to learning motor sequences via observation
Research output: Contribution to journal › Article › peer-review
Standard Standard
In: Neural Plasticity, Vol. 2018, 1237962, 2018.
Research output: Contribution to journal › Article › peer-review
HarvardHarvard
APA
CBE
MLA
VancouverVancouver
Author
RIS
TY - JOUR
T1 - Anodal tDCS over primary motor cortex provides no advantage to learning motor sequences via observation
AU - Apsvalka, Dace
AU - Ramsey, Richard
AU - Cross, Emily
PY - 2018
Y1 - 2018
N2 - When learning a new motor skill, we benefit from watching others. It has been suggested that observation of others' actions can build a motor representation in the observer, and as such, physical and observational learning might share a similar neural basis. If physical and observational learning share a similar neural basis, then motor cortex stimulation during observational practice should similarly enhance learning by observation as it does through physical practice. Here we used transcranial direct current stimulation (tDCS) to address whether anodal stimulation to M1 during observational training facilitates skill acquisition. Participants learned keypress sequences across four consecutive days of observational practice whilst receiving active or sham stimulation over M1. The results demonstrated that active stimulation provided no advantage to skill learning over sham stimulation. Further, Bayesian analyses revealed evidence in favour of the null hypothesis across our dependent measures. Our findings therefore provide no support for the hypothesis that excitatory M1 stimulation can enhance observational learning in a similar manner to physical learning. More generally, the results add to a growing literature that suggests the effects of tDCS tend to be small, inconsistent and hard to replicate. Future tDCS research should consider these factors when designing experimental procedures.
AB - When learning a new motor skill, we benefit from watching others. It has been suggested that observation of others' actions can build a motor representation in the observer, and as such, physical and observational learning might share a similar neural basis. If physical and observational learning share a similar neural basis, then motor cortex stimulation during observational practice should similarly enhance learning by observation as it does through physical practice. Here we used transcranial direct current stimulation (tDCS) to address whether anodal stimulation to M1 during observational training facilitates skill acquisition. Participants learned keypress sequences across four consecutive days of observational practice whilst receiving active or sham stimulation over M1. The results demonstrated that active stimulation provided no advantage to skill learning over sham stimulation. Further, Bayesian analyses revealed evidence in favour of the null hypothesis across our dependent measures. Our findings therefore provide no support for the hypothesis that excitatory M1 stimulation can enhance observational learning in a similar manner to physical learning. More generally, the results add to a growing literature that suggests the effects of tDCS tend to be small, inconsistent and hard to replicate. Future tDCS research should consider these factors when designing experimental procedures.
KW - tDCS
KW - observational learning
KW - primary motor cortex
KW - motor learning
M3 - Article
VL - 2018
JO - Neural Plasticity
JF - Neural Plasticity
SN - 2090-5904
M1 - 1237962
ER -