The present study evaluated the neural changes due to effector use (unimanual left, unimanual right, and bimanual) and visuomotor conflict induced by mirror-reversed vision during drawing behavior. EEG phase synchronization, expressing interregional communication, showed that visuomotor incongruence perturbed information processing in both hemispheres. Furthermore, it was observed that the left hemisphere became temporally dominant when movements were executed with visuomotor conflict, independent of the performing hand(s). This observation emphasizes the superiority of the left hemisphere to control complex movements. In addition, the functional interactions between the hemispheres were also perturbed due to visuomotor discordance, indicating the crucial role of interhemispheric communication for movement control. These results highlight that functional connectivity patterns provide higher-order coding mechanisms of information processing. The data further underline the significance of the left hemisphere for intricate visuomotor skills.
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This study was supported by grants from the Biotechnology and Biological Sciences Research Council (BB/F012454/1) and Research Committee (NRF) of the University of Nottingham. Thanks to E. Georgiadi for initial assistance.
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Serrien, D.J., Spapé, M.M. The role of hand dominance and sensorimotor congruence in voluntary movement. Exp Brain Res 199, 195 (2009). https://doi.org/10.1007/s00221-009-1998-8
- Functional connectivity
- Phase synchronization