AFNI: software for analysis and visualization of functional magnetic resonance neuroimages
Computers and Biomedical Research
Specialized Neural Systems Underlying Representations of Sequential Movements
Journal of Cognitive Neuroscience
Cerebellar Contributions to Motor Timing: A PET Study of Auditory and Visual Rhythm Reproduction
Journal of Cognitive Neuroscience
Intermanual Differences in Movement-related Interhemispheric Inhibition
Journal of Cognitive Neuroscience
Intercerebellar Coupling Contributes to Bimanual Coordination
Journal of Cognitive Neuroscience
Hybrid ICA-seed-based methods for fMRI functional connectivity assessment: a feasibility study
Journal of Biomedical Imaging
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Studies in brain damaged patients conclude that the left hemisphere is dominant for controlling heterogeneous sequences performed by either hand, presumably due to the cognitive resources involved in planning complex sequential movements. To determine if this lateralized effect is due to asymmetries in primary sensorimotor or association cortex, whole-brain functional magnetic resonance imaging was used to measure differences in volume of activation while healthy right-handed subjects performed repetitive (simple) or heterogeneous (complex) finger sequences using the right or left hand. Advanced planning, as evidenced by reaction time to the first key press, was greater for the complex than simple sequences and for the left than right hand. In addition to the expected greater contralateral activation in the sensorimotor cortex (SMC), greater left hemisphere activation was observed for left, relative to right, hand movements in the ipsilateral left superior parietal area and for complex, relative to simple, sequences in the left premotor and parietal cortex, left thalamus, and bilateral cerebellum. No such volumetric asymmetries were observed in the SMC. Whereas the overall MR signal intensity was greater in the left than right SMC, the extent of this asymmetry did not vary with hand or complexity level. In contrast, signal intensity in the parietal and premotor cortex was greater in the left than right hemisphere and for the complex than simple sequences. Signal intensity in the caudal anterior cerebellum was greater bilaterally for the complex than simple sequences. These findings suggest that activity in the SMC is associated with execution requirements shared by the simple and complex sequences independent of their differential cognitive requirements. In contrast, consistent with data in brain damaged patients, the left dorsal premotor and parietal areas are engaged when advanced planning is required to perform complex motor sequences that require selection of different effectors and abstract organization of the sequence, regardless of the performing hand.