Abstract
Rhythm is an essential element of dancing and music. To investigate the neural mechanisms underlying how rhythm is learned, we recorded electroencephalographic (EEG) data during a rhythm-reproducing task that asked participants to memorize an auditory stimulus and reproduce it via tapping. Based on the behavioral results, we divided the participants into Learning and No-learning groups. EEG analysis showed that error-related negativity (ERN) in the Learning group was larger than in the No-learning group. Time-frequency analysis of the EEG data showed that the beta power in right and left temporal area at the late learning stage was smaller than at the early learning stage in the Learning group. Additionally, the beta power in the temporal and cerebellar areas in the Learning group when learning to reproduce the rhythm were larger than in the No Learning group. Moreover, phase synchronization between frontal and temporal regions and between temporal and cerebellar regions at late stages of learning were larger than at early stages. These results indicate that the frontal-temporal-cerebellar beta neural circuits might be related to auditory-motor rhythm learning.
Highlights
Rhythm is an essential element of dancing and music
Prefrontal-parietal-cerebellar neural circuits play important roles in rhythm encoding and memory[4,5], while the cerebellum and motor areas are proposed to be involved in reproducing rhythms[6,7,8]
This study suggests that brain networks among the frontal, temporal, and cerebellar cortices are involved in rhythm learning
Summary
Rhythm is an essential element of dancing and music. To investigate the neural mechanisms underlying how rhythm is learned, we recorded electroencephalographic (EEG) data during a rhythm-reproducing task that asked participants to memorize an auditory stimulus and reproduce it via tapping. Phase synchronization between frontal and temporal regions and between temporal and cerebellar regions at late stages of learning were larger than at early stages These results indicate that the frontal-temporal-cerebellar beta neural circuits might be related to auditory-motor rhythm learning. Prefrontal-parietal-cerebellar neural circuits play important roles in rhythm encoding and memory[4,5], while the cerebellum and motor areas are proposed to be involved in reproducing rhythms[6,7,8]. These studies have compared brain activity of well-trained individuals when listening to rhythms as well as that from naïve participants. We focused on differences in brain activity between www.nature.com/scientificreports/
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