Learning of Sequences of Finger Movements and Timing: Frontal Lobe and Action-Oriented Representation

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Learning of Sequences of Finger Movements and Timing: Frontal Lobe and Action-Oriented Representation

Katsuyuki Sakai,¹ Narender Ramnani,¹^,² and Richard E. Passingham¹^,³

¹Wellcome Department of Imaging Neuroscience, Institute of Neurology, London WC1N 3BG; ²Center for Functional Magnetic Resonance Imaging of the Brain and ³Department of Experimental Psychology, University of Oxford, Oxford OX1 3UD, United Kingdom

Sakai, Katsuyuki, Narender Ramnani, and Richard E. Passingham. Learning of Sequences of Finger Movements and Timing: Frontal Lobe and Action-Oriented Representation. J. Neurophysiol. 88: 2035-2046, 2002. Motor sequence learning involves learning of a sequence of effectors with which to execute a series of movements and learningof a sequence of timings at which to execute the movements. Inthis study, we have segregated the neural correlates of the twolearning mechanisms. Moreover, we have found an interaction betweenthe two learning mechanisms in the frontal areas, which we claimas suggesting action-oriented coding in the frontal lobe. We usedpositron emission tomography and compared three learning conditionswith a visuo-motor control condition. In two learning conditions,the subjects learned either a sequence of finger movements withrandom timing or a sequence of timing with random use of fingers.In the third condition the subjects learned to execute a sequenceof specific finger movements at specific timing; we argue thatit was only in this condition that the motor sequence was codedas an action-oriented representation. By looking for conditionby session interactions (learning vs. control conditions oversessions), we have removed nonspecific time effects and identifiedareas that showed a learning-related increment of activation duringlearning. Learning of a finger sequence was associated with anincrement of activation in the right intraparietal sulcus regionand medial parietal cortex, whereas learning of a timing sequencewas associated with an increment of activation in the lateralcerebellum, suggesting separate mechanisms for learning effectorand temporal sequences. The left intraparietal sulcus region showedan increment of activation in learning of both finger and timingsequences, suggesting an overlap between the two learning mechanisms.We also found that the mid-dorsolateral prefrontal cortex, togetherwith the medial and lateral premotor areas, became increasinglyactive when subjects learned a sequence that specified both fingersand timing, that is, when subjects were able to prepare specificmotor action. These areas were not active when subjects learneda sequence that specified fingers or timing alone, that is, whensubjects were still dependent on external stimuli as to the timingor fingers with which to execute the movements. Frontal areasmay integrate the effector and temporal information of a motorsequence and implement an action-oriented representation so asto perform a motor sequence accurately and quickly. We also foundthat the mid-dorsolateral prefrontal cortex was distinguishedfrom the ventrolateral prefrontal cortex and anterior fronto-polarcortex, which showed sustained activity throughout learning sessionsand did not show either an increment or decrement ofactivation.

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