Abstract
Background/Objectives: Neck muscle vibration alters neural processing, sensorimotor integration, and proprioception in healthy adults. Significant differential changes in the N18 and N24 somatosensory evoked potential (SEP) peak amplitudes, coupled with altered motor learning, occurred when completion of a force-matching task took place following neck muscle vibration. It is currently unknown if neck muscle vibration also impacts acquisition of skills from visuomotor tracking tasks, a gap this research addresses. Methods: A total of 25 right-handed, healthy participants were divided into vibration (age: 21.7 ± 1.89, n = 13; 8 females) (V) and no-vibration (NV) control (age: 21.2 ± 3.03, n = 12; 6 females) groups. The vibration was device applied over the right sternocleidomastoid and left cervical extensor muscles. The participants underwent right-median-nerve stimulation at 2.47 Hz and 4.98 Hz to elicit SEPs. A total of 1000 sweeps were recorded and averaged using an ANT Neuro Waveguard 64-lead EEG cap (ANT Neuro, the Netherlands, Manufactured by Eemagine, Berlin, Germany)pre- and post-completion of a novel visuomotor tracing task (MTT). Post-acquisition, the NV group had a 10 min rest, and the V group received 10 min of vibration at 60 Hz before motor task completion, followed immediately by post-acquisition and retention 24 h after. Results: N18 peak: The V group exhibited a proportional amplitude increase of 19%, while the NV group exhibited a 36% decrease. There was a trend toward decreased retention in the V group. P25 showed a significant effect of time, with increases of 11% for V and 9% for NV. Conclusions: V resulted in N18 SEP changes post-MTT-skill-acquisition. Both groups appeared to learn, with the V trending towards less retention.
Authors
Kalogerakis, A., Yielder, P., Tabbert, H., & Murphy, B.
https://doi.org/10.3390/brainsci15121311