@article {SakataENEURO.0183-17.2017, author = {Honami Sakata and Kosuke Itoh and Yuji Suzuki and Katsuki Nakamura and Masaki Watanabe and Hironaka Igarashi and Tsutomu Nakada}, title = {Slow Accumulations of Neural Activities in Multiple Cortical Regions Precede Self-Initiation of Movement: An Event-Related fMRI Study}, volume = {4}, number = {5}, elocation-id = {ENEURO.0183-17.2017}, year = {2017}, doi = {10.1523/ENEURO.0183-17.2017}, publisher = {Society for Neuroscience}, abstract = {The neural processes underlying self-initiated behavior (behavior that is initiated without an external stimulus trigger) are not well understood. This event-related fMRI study investigated the neural origins of self-initiated behaviors in humans, by identifying brain regions that increased in neural activities several seconds prior to self-initiated movements. Subjects performed a hand grasping task under two conditions: a free-timing and cued timing condition. The supplementary motor area (SMA) began to activate several seconds prior to self-initiated movement (accounting for hemodynamic delay), representing a potential blood oxygenation level-dependent (BOLD) signal correlate of the readiness potential (RP) on electroencephalogram (EEG), referred to here as {\textquotedblleft}readiness BOLD signals.{\textquotedblright} Significant readiness BOLD signals were also observed in the right frontoparietal areas, precuneus, and insula, all of which are known to contribute to internally-generated behaviors, but with no prior evidence for such early and slow accumulation of neural activities. Moreover, visual and auditory cortices also exhibited clear readiness BOLD signals with similar early onsets, even absent external stimulation. Slow accumulation of neural activities throughout distributed cortical areas, including sensory, association, and motor cortices, underlies the generation of self-initiated behaviors. These findings warrant reconsideration of the prevailing view that the SMA or some other specific locus in frontoparietal cortex serves as the ultimate neural origin of self-initiated movement.}, URL = {https://www.eneuro.org/content/4/5/ENEURO.0183-17.2017}, eprint = {https://www.eneuro.org/content/4/5/ENEURO.0183-17.2017.full.pdf}, journal = {eNeuro} }