4.5 Article

Cortico-muscular coherence of time-frequency and spatial characteristics under movement observation, movement execution, and movement imagery

Journal

COGNITIVE NEURODYNAMICS
Volume -, Issue -, Pages -

Publisher

SPRINGER
DOI: 10.1007/s11571-023-09970-y

Keywords

Electroencephalography (EEG); Movement observation (MO); Movement execution (ME); Movement imagery (MI); Cortico-muscular coherence

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Studies show that movement observation, movement imagery, or movement execution based brain-computer interface systems are promising in promoting the rehabilitation and reorganization of damaged motor function. This study aimed to explore and compare the motor function rehabilitation mechanism among these three methods. The results indicate that the cortico-muscular beta-lh band plays a critical role in the synchronous coupling between cortex and muscle. Additionally, specific regions in the brain are associated with each method, but their pathways for regulating muscles differ. Overall, this study contributes to a better understanding of the motor function rehabilitation mechanism.
Studies show that movement observation (MO), movement imagery (MI), or movement execution (ME) based brain-computer interface systems are promising in promoting the rehabilitation and reorganization of damaged motor function. This study was aimed to explore and compare the motor function rehabilitation mechanism among MO, MI, and ME. 64-channel electroencephalogram and 4-channel electromyogram data were collected from 39 healthy participants (25 males, 14 females; 18-23 years old) during MO, ME, and MI. We analyzed and compared the inter-cortical, inter-muscular, cortico-muscular, and spatial coherence under MO, ME, and MI. Under MO, ME, and MI, cortico-muscular coherence was strongest at the beta-lh band, which means the beta frequency band for cortical signals and the lh frequency band for muscular signals. 56.25-96.88% of the coherence coefficients were significantly larger than 0.5 (ps < 0.05) at the beta-lh band. MO and ME had a contralateral advantage in the spatial coherence between cortex and muscle, while MI had an ipsilateral advantage in the spatial coherence between cortex and muscle. Our results show that the cortico-muscular beta-lh band plays a critical role in the synchronous coupling between cortex and muscle. Also, our findings suggest that the primary motor cortex (M1), dorsolateral prefrontal cortex (DLPFC), supplementary motor area (SMA), and premotor cortex (PMC) are the specific regions of MO, ME, and MI. However, their pathways of regulating muscles are different under MO, ME, and MI. This study is important for better understanding the motor function rehabilitation mechanism in MO, MI, and ME.

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