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Abstract

The neural mechanisms of limb coordination were investigated by testing callosotomy patients and normal control subjects on bimanual movements Normal subjects produced deviations in the trajectories when spatial demands for the two hands were different, despite temporal synchrony in the onset of bimanual movements Callosotomy patients did not produce spatial deviations, although their hands moved with normal temporal synchrony Normal subjects but not callosotomy patients exhibited large increases in planning and execution time for movements with different spatial demands for the two hands relative to movements with identical spatial demands for the two hands This neural dissociation indicates that spatial interference in movements results from callosal connections, whereas temporal synchrony in movement onset does not rely on the corpus callosum

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References

Bullock

Grossberg

(1988). Neural dynamics of planned arm movements. Emergent invariants and speed-accuracy properties during trajectory formation. Psychological Review, 95, 49–90.

Cook

N.D.

(1986). The brain code Mechanisms of information transfer and the role of the corpus callosum. New York Methuen.

Franz

E.A.

Zelaznik

H.N.

McCabe

(1991). Spatial topological constraints in a bimanual task. Acta Psychologica, 77, 137–151.

Gazzaniga

M.S.

(1989). Organization of the human brain. Science, 245, 447–952.

Gcorgopoulos

A.P.

Taira

M.A.

Lukashin

(1993). Cognitive neurophyaiology of the motor cortex. Science, 260, 47–52.

Heilman

K.M.

(1979). Apraxia. In Heilman

K.M.

Valenstem

T.E.U.

, (Eds.), Clinical neuropsychology, (2nd edpp. 159–185). New York Oxford University Press.

Kelso

J.A.S.

Southard

Goodman

(1979). On the coordination of two-handed movements. Journal of Experimental Psychology Human Perception and Performance, 5, 229–238.

Kim

Ashe

Hendrich

Eillermann

Merkle

Ugarbil

K.A.

Georgopoulos

(1993). Functional magnetic resonance imaging of motor cortex. Hemispheric asymmetry and handedness. Science, 261, 615–617.

Klapp

(1979). Doing two things at once. The role of temporal compatibility. Memory and Cognition, 7, 375–381.

10.

Osman

Kornblum

Meyer

D.E.

(1986). The point of no return in choice reaction time. Controlled and ballistic stages of response preparation. Journal of Experimental Psychology Human Perception and Performance, 12, 243–258.

11.

Preilowski

B.F.B.

(1972). Possible contributions of the anterior forebrain commissures to bilateral motor coordination. Neuropsychologia, 10, 267–277.

12.

Roland

P.E.

Meyer

Shibasaki

Yamanoto

Y.L.

Thompson

C.J.

(1982). Regional cerebral Mood flow changes in cones and basal ganglia during voluntary movements in normal human volunteers. Journal of Neurophysiology, 48, 467–480.

13.

Schoner

Kelso

J.A.S.

(1988). Dynamic pattern generation in behavioral and neural systems. Science, 239, 1513–1520.

14.

Sietz

R.J.

Roland

P.E.

Bohm

Greitz

Stone-Blander

(1990). Motor learning in man. A positron emission tomography study. Neuroreport, 1, 57–66.

15.

Sidtis

J.J.

Volpe

B.T.

Wilson

D.H.

Rayport

Gazzaniga

M.S.

(1981). Variability in right hemisphere language function after callosal section Evidence for a continuum of generative capacity. Journal of Neuroscience, 1, 323–331.

16.

Stucchi

Viviant

(1993). Cerebral dominance and asynchrony between bimanual two-dimensional movements. Journal of Experimental Psychology Human Perception and Performance, 19, 1200–1220.

17.

Yamanishi

Kawato

Suzuki

(1980). Two coupled oscillators as a model for the coordinated finger tapping by both hands. Biological Cybernetics, 37, 219–225.

18.

Zaidel

D.A.

Sperry

R.W.

(1977). Some long-term motor effects of cerebral commissurotomy in man. Neuropsychologia, 15, 193–204.

Dissociation of Spatial and Temporal Coupling in the Bimanual Movements of Callosotomy Patients

Abstract

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