Abstract
Short-term motor adaptation to novel movement dynamics has been shown to involve at least two concurrent learning processes: a slow process that responds weakly to error but retains information well, and a fast process that responds strongly to error but has poor retention. This modeling framework can explain several properties of motion-dependent motor adaptation (e.g., 24-hour retention). An important assumption of this computational framework is that learning is only based on the experienced movement error, and the effect of noise (either internally generated or externally applied) is not considered. We examined the respective error sensitivity by quantifying adaptation in three subject groups distinguished by the noise added to the motion-dependent perturbation (magnitudes of 0, 3 or 7N, at a frequency of 10 Hz, 20 subjects/group). We assessed the feedforward adaptive changes in motor output and examined the adaptation rate, retention and decay of learning. Applying a two-state modeling framework showed that the applied noise during training mainly affected the fast learning process, with the slow process largely unaffected; participants in the higher noise groups demonstrated a reduced force profile following training, but the decay rate across groups was similar, suggesting that the slow process was unimpaired across conditions. Collectively, our results provide evidence that noise significantly decreases motor adaptation, but this reduction may be due to its influence over specific learning mechanisms. Importantly, this may have implications for how the motor system compensates for random fluctuations, especially when affected by brain disorders that result in movement tremor (e.g., Essential Tremor).
Significance statement Short-term motor adaptation to novel movement dynamics has been shown to involve at least two concurrent learning processes: a slow process that responds weakly to error but retains information well, and a fast process that responds strongly to error but has poor retention. This computational framework assumes that learning is only based on the movement error, and the effect of noise is not considered. We found that as the magnitude of externally-generated noise increased, the overall learning rate decreased. We found that this overall decrease in adaptation could be explained specifically by impairments to the fast learning process. The applied motor noise had little effect on the retention and decay of adaptation— aspects that mainly involve the slow learning process.
Footnotes
This work was supported by a grant from the National Science Foundation (1553895) to WMJ.
Authors declare no conflict of interest
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