Coordinate processing during the left-to-right hand transfer investigated by EEG

Information about visuomotor tasks is coded in extrinsic, object-centered and intrinsic, body-related coordinates. For the reproduction of a trained task in mirror orientation with the opposite untrained hand, acquired extrinsic coordinates must be transformed. In contrast, intrinsic coordinates have to be modified during the execution of the originally oriented task. As shown recently, processes of coordinate transformations during the right-to-left hand transfer are associated with movement preparation and occur preferentially in the left hemisphere. Here, movement-related potentials, EEG power, and EEG coherence were recorded during the repetition of a drawing task previously trained by the nondominant left hand (Learned-task) and its execution in original and mirror orientation by the right hand (Normal- and Mirror-task). To identify EEG correlates of coordinate processing during intermanual transfer rather than effects due to the use of the right versus left hand, only those EEG data were analyzed which differed between the Normal- and Mirror-tasks. Whereas the Normal-task did not differ from the Learned-task in any of these predefined EEG parameters, beta coherence increased in the Mirror-task in the period ranging from 1 to 2 s after movement onset. These increases were especially prominent between hemispheres but were also observed symmetrically in the parieto-frontal electrode pairs of both hemispheres. Behavioral data revealed that the performance in the Learned- and both transfer tasks improved after left-hand training. Results of the present study indicate that coordinate transformation during the left-to-right hand transfer occurs in the phase of movement execution and affects predominantly extrinsic coordinates. Intrinsic coordinates are presumably mainly used in their original form. The modification of extrinsic coordinates is accompanied by increased information flow between both hemispheres; thereby inter-hemispheric connections—as mediated via the corpus callosum—seem to play a central role.

[1]  D Elliott,et al.  Manual asymmetries in the performance of sequential movement by adolescents and adults with Down syndrome. , 1985, American journal of mental deficiency.

[2]  F. Lacquaniti,et al.  Short-Term Memory for Reaching to Visual Targets: Psychophysical Evidence for Body-Centered Reference Frames , 1998, The Journal of Neuroscience.

[3]  Christoph Braun,et al.  EEG correlates of coordinate processing during intermanual transfer , 2004, Experimental Brain Research.

[4]  R. Andersen,et al.  Multimodal representation of space in the posterior parietal cortex and its use in planning movements. , 1997, Annual review of neuroscience.

[5]  Marcel Kinsbourne,et al.  Asymmetrical transfer of braille acquisition between hands , 1990, Brain and Language.

[6]  Gregor Thut,et al.  Intermanual transfer of proximal and distal motor engrams in humans , 1996, Experimental Brain Research.

[7]  Gregor Thut,et al.  What is the role of the corpus callosum in intermanual transfer of motor skills? A study of three cases with callosal pathology , 1997, Experimental Brain Research.

[8]  C Gerloff,et al.  Coherence of sequential movements and motor learning. , 1999, Journal of clinical neurophysiology : official publication of the American Electroencephalographic Society.

[9]  D. Elliott,et al.  Asymmetries in intermanual transfer of training and motor overflow in adults with Down's syndrome and nonhandicapped children. , 1989, Journal of clinical and experimental neuropsychology.

[10]  P. Brown,et al.  Influence of working memory on patterns of motor related cortico-cortical coupling , 2004, Experimental Brain Research.

[11]  A. E. Schulman,et al.  Functional coupling of human cortical sensorimotor areas during bimanual skill acquisition. , 1999, Brain : a journal of neurology.

[12]  C. Gross,et al.  Spatial maps for the control of movement , 1998, Current Opinion in Neurobiology.

[13]  M. Hallett,et al.  Integrative visuomotor behavior is associated with interregionally coherent oscillations in the human brain. , 1998, Journal of neurophysiology.

[14]  F. Lacquaniti,et al.  Viewer-centered frame of reference for pointing to memorized targets in three-dimensional space. , 1997, Journal of neurophysiology.

[15]  K M Heilman,et al.  Left-hemisphere motor dominance in righthanders. , 1980, Cortex; a journal devoted to the study of the nervous system and behavior.

[16]  R. E. Hicks,et al.  Asmmetry of Bilateral Transfer. , 1974 .

[17]  Robert L Sainburg,et al.  Nondominant arm advantages in load compensation during rapid elbow joint movements. , 2003, Journal of neurophysiology.

[18]  Scott T. Grafton,et al.  Motor sequence learning with the nondominant left hand , 2002, Experimental Brain Research.

[19]  M Hallett,et al.  Steady-state movement-related cortical potentials: a new approach to assessing cortical activity associated with fast repetitive finger movements. , 1997, Electroencephalography and clinical neurophysiology.

[20]  Marcel Kinsbourne,et al.  Asymmetrical transfer of training between hands: Implications for interhemispheric communication in normal brain , 1989, Brain and Cognition.

[21]  H. Kornhuber,et al.  Hirnpotentialänderungen bei Willkürbewegungen und passiven Bewegungen des Menschen: Bereitschaftspotential und reafferente Potentiale , 1965, Pflüger's Archiv für die gesamte Physiologie des Menschen und der Tiere.

[22]  R. Sainburg,et al.  Interlimb transfer of visuomotor rotations: independence of direction and final position information , 2002, Experimental Brain Research.

[23]  Christopher A. Buneo,et al.  Direct visuomotor transformations for reaching , 2002, Nature.

[24]  Jinsung Wang,et al.  Interlimb transfer of novel inertial dynamics is asymmetrical. , 2004, Journal of neurophysiology.

[25]  G C Galbraith,et al.  EEG correlates of visual-motor practice in man. , 1975, Electroencephalography and clinical neurophysiology.

[26]  U. Halsband,et al.  LEFT HEMISPHERE PREPONDERANCE IN TRAJECTORIAL LEARNING , 1992, Neuroreport.

[27]  Kenneth M. Heilman,et al.  Left-Hemisphere Motor Dominance in Righthandersi , 1980, Cortex.

[28]  Richard A. Andersen,et al.  Coordinate transformations in the representation of spatial information , 1993, Current Opinion in Neurobiology.

[29]  G. Pfurtscheller,et al.  Simultaneous EEG 10 Hz desynchronization and 40 Hz synchronization during finger movements. , 1992, Neuroreport.

[30]  M. Hallett,et al.  Event-related coherence and event-related desynchronization/synchronization in the 10 Hz and 20 Hz EEG during self-paced movements. , 1997, Electroencephalography and clinical neurophysiology.

[31]  M. Gentilucci,et al.  Mechanisms for distance reproduction in perceptual and motor tasks , 1996, Experimental Brain Research.

[32]  M. Kawato,et al.  Coordinates transformation and learning control for visually-guided voluntary movement with iteration: A Newton-like method in a function space , 1988, Biological Cybernetics.

[33]  C. Atkeson,et al.  Learning arm kinematics and dynamics. , 1989, Annual review of neuroscience.

[34]  Digby Elliott,et al.  Vision and motor control , 1992 .

[35]  J. F. Soechting,et al.  Errors in pointing are due to approximations in sensorimotor transformations. , 1989, Journal of neurophysiology.

[36]  K. Macko,et al.  Near-field acuity after visual system lesions in pigeons. I. Thalamus , 1984, Behavioural Brain Research.

[37]  Robert L Sainburg,et al.  Interlimb differences in control of movement extent. , 2004, Journal of neurophysiology.

[38]  R. C. Oldfield The assessment and analysis of handedness: the Edinburgh inventory. , 1971, Neuropsychologia.

[39]  J F Soechting,et al.  Moving in three-dimensional space: frames of reference, vectors, and coordinate systems. , 1992, Annual review of neuroscience.

[40]  Mu-Jang Yang Mirror writing in right-handers and in left-handers: a study using chinese characters , 1997, Neuropsychologia.

[41]  Richard A. Abrams,et al.  Coordination of eye and hand for aimed limb movements. , 1992 .

[42]  D. Dewey,et al.  The temporal locus of transfer of training between hands: an interference study , 1991, Behavioural Brain Research.

[43]  G. Thut,et al.  Intermanual transfer of training: blood flow correlates in the human brain , 1997, Behavioural Brain Research.

[44]  D. Wolpert,et al.  Evidence for an eye-centered spherical representation of the visuomotor map. , 1999, Journal of neurophysiology.

[45]  J. Vaid,et al.  Asymmetries in intermanual transfer of maze learning in right- and left-handed adults , 1996, Neuropsychologia.

[46]  Robert E Hicks,et al.  The Locus of Bimanual Skill Transfer. , 1982, The Journal of general psychology.

[47]  Peter Brown,et al.  The integration of cortical and behavioural dynamics during initial learning of a motor task , 2003, The European journal of neuroscience.

[48]  A M Amjad,et al.  A framework for the analysis of mixed time series/point process data--theory and application to the study of physiological tremor, single motor unit discharges and electromyograms. , 1995, Progress in biophysics and molecular biology.

[49]  G Pfurtscheller,et al.  Event-related coherence as a tool for studying dynamic interaction of brain regions. , 1996, Electroencephalography and clinical neurophysiology.

[50]  J. Stiles-Davis,et al.  Mirror writing: An advantage for the left-handed? , 1989, Brain and Language.

[51]  H. Jasper,et al.  The ten-twenty electrode system of the International Federation. The International Federation of Clinical Neurophysiology. , 1999, Electroencephalography and clinical neurophysiology. Supplement.

[52]  Reza Shadmehr,et al.  Learned dynamics of reaching movements generalize from dominant to nondominant arm. , 2003, Journal of neurophysiology.

[53]  M. Hallett,et al.  Task-related coherence and task-related spectral power changes during sequential finger movements. , 1998, Electroencephalography and clinical neurophysiology.

[54]  Robert L. Sainburg,et al.  Interlimb transfer of load compensation during rapid elbow joint movements , 2005, Experimental Brain Research.