1998
DOI: 10.1523/jneurosci.18-05-01827.1998
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Transition of Brain Activation from Frontal to Parietal Areas in Visuomotor Sequence Learning

Abstract: We studied the neural correlates of visuomotor sequence learning using functional magnetic resonance imaging (fMRI). In the test condition, subjects learned, by trial and error, the correct order of pressing two buttons consecutively for 10 pairs of buttons (2 x 10 task); in the control condition, they pressed buttons in any order. Comparison between the test condition and the control condition revealed four brain areas specifically related to learning: the dorsolateral prefrontal cortex (DLPFC), the presupple… Show more

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Cited by 429 publications
(314 citation statements)
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References 71 publications
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“…Most interestingly for us, all involved brain areas, but particularly premotor areas, have been reported also to underlie the planning and production of motor sequences that follow an external sequential target stimulus, as particularly evident from imaging studies using the serial reaction task paradigm (Gordon et al, 1995;Grafton et al, 1995;Hazeltine et al, 1997;Hikosaka et al, 1998Hikosaka et al, , 1996Honda et al, 1998;Sadato et al, 1996;Sakai et al, 1998;Toni et al, 1998). As expected, the present outcome indicates that an attentively observed sequential signal can be a stimulus sufficient to elicit activations within a brain network closely related to that one that participates in sequential motor behavior.…”
Section: Discussionsupporting
confidence: 76%
“…Most interestingly for us, all involved brain areas, but particularly premotor areas, have been reported also to underlie the planning and production of motor sequences that follow an external sequential target stimulus, as particularly evident from imaging studies using the serial reaction task paradigm (Gordon et al, 1995;Grafton et al, 1995;Hazeltine et al, 1997;Hikosaka et al, 1998Hikosaka et al, , 1996Honda et al, 1998;Sadato et al, 1996;Sakai et al, 1998;Toni et al, 1998). As expected, the present outcome indicates that an attentively observed sequential signal can be a stimulus sufficient to elicit activations within a brain network closely related to that one that participates in sequential motor behavior.…”
Section: Discussionsupporting
confidence: 76%
“…The theory explains how each component contributes different eompcteneies, all of whieh appear necessary when attempting to explain the brain system responsible t(Jr serial learning and production. The involvement of multiple substrates is now well c;;t:~blished (e.g., Hikosaka ct al., 1999;Sakai et al, 1998 as noted above). Of special interest is the rn()(lel's incorporation of parallel and serial representations within a consistent and unified framework) lx~cause it all0\'\ 1 S a reconciliation of mechanisms previously treated as exclusive alternatives.…”
Section: · a Contemporary (Partial) Synthesis: Then-streams Modelmentioning
confidence: 78%
“…Finally, while the FEF plays a key role in complex saccadic eye movement tasks and is essential for certain tasks such as working memory-guided tasks and complex visually-guided tasks (Deng eta!., 1986; Pierrot-Deseilligny eta!., !993), it may be less essential for some visually-guided tasks once they are overtrained. Chen and Wise (1995b) have shown that some frontal eye field cells are selectively active early in training, and Sakai et a!. ( 1998) have likewise shown with functional imaging that the cortical locus of saccade-related activity shifts from frontal to posterior saccade-related areas as learning progresses.…”
Section: Discussionmentioning
confidence: 94%