AUTHOR=Tatti Elisa , Ricci Serena , Nelson Aaron B. , Mathew Dave , Chen Henry , Quartarone Angelo , Cirelli Chiara , Tononi Giulio , Ghilardi Maria Felice TITLE=Prior Practice Affects Movement-Related Beta Modulation and Quiet Wake Restores It to Baseline JOURNAL=Frontiers in Systems Neuroscience VOLUME=14 YEAR=2020 URL=https://www.frontiersin.org/journals/systems-neuroscience/articles/10.3389/fnsys.2020.00061 DOI=10.3389/fnsys.2020.00061 ISSN=1662-5137 ABSTRACT=

Beta oscillations (13.5−25 Hz) over the sensorimotor areas are characterized by a power decrease during movement execution (event-related desynchronization, ERD) and a sharp rebound after the movement end (event-related synchronization, ERS). In previous studies, we demonstrated that movement-related beta modulation depth (peak ERS-ERD) during reaching increases within 1-h practice. This increase may represent plasticity processes within the sensorimotor network. If so, beta modulation during a reaching test should be affected by previous learning activity that engages the sensorimotor system but not by learning involving other systems. We thus recorded high-density EEG activity in a group of healthy subjects performing three 45-min blocks of motor adaptation task to a visually rotated display (ROT) and in another performing three blocks of visual sequence-learning (VSEQ). Each block of either ROT or VSEQ was followed by a simple reaching test (mov) without rotation. We found that beta modulation depth increased with practice across mov tests. However, such an increase was greater in the group performing ROT over both the left and frontal areas previously involved in ROT. Importantly, beta modulation values returned to baseline values after a 90-min of either nap or quiet wake. These results show that previous practice leaves a trace in movement-related beta modulation and therefore such increases are cumulative. Furthermore, as sleep is not necessary to bring beta modulation values to baseline, they could reflect local increases of neuronal activity and decrease of energy and supplies.