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01-12-2007 | Research Article

Coordination and concurrency in bimanual rotation tasks when moving away from and toward the body

Authors: A. H. Mason, P. J. Bryden

Published in: Experimental Brain Research | Issue 4/2007

Abstract

In the present series of experiments we investigated how object transport and rotate movements are performed when they are directed away from (Experiment 1) and toward (Experiment 2) the body under both unimanual and bimanual conditions. Our results indicated that unimanual conditions are faster and more efficiently produced than bimanual movements in far peripersonal space, suggesting that there is a cost to performing bimanual movements. However, in near peripersonal space, bimanual same movements were performed in a manner similar to unimanual movements, indicating that there is no significant cost associated with similar bimanual movements that are performed using the lower visual field and in near peripersonal space. Both experiments also indicate that the two hands are tightly synchronized when the two movements being performed require the same rotation. However, when performing bimanual movements where the rotation being performed by the two hands is different, this synchronization is weaker. Finally, the combined results from the two experiments indicated that movements made toward the body are not performed in a similar manner to movements that are made away from the body. Specifically, it is clear from the current studies that movements toward the body are performed faster and possibly that the hands are less synchronized for bimanual movements requiring different rotations by the two hands.

We used velocity in the forward (x) direction to determine end of transport because the resultant velocity remained elevated after transport ended as subjects placed the object in the target well. This was due to motion in the side-to-side (y) and vertical (z) directions. Note however, that all measures of peak velocity and the timing of that peak reported in the results refer to the resultant velocities achieved by the wrist.

A significant interaction was found between condition and hand/rotation for the dependent variable object transport time (F(6,66) = 3.38, P < 0.001). Each condition was examined separately, and planned comparisons were performed comparing the right and left hand at each rotation; however, the planned comparisons revealed no differences between the conditions of interest and thus the results are not presented here.

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Title: Coordination and concurrency in bimanual rotation tasks when moving away from and toward the body
Authors: A. H. Mason
P. J. Bryden
Publication date: 01-12-2007
Publisher: Springer-Verlag
Published in: Experimental Brain Research / Issue 4/2007
Print ISSN: 0014-4819
Electronic ISSN: 1432-1106
DOI: https://doi.org/10.1007/s00221-007-1068-z

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Coordination and concurrency in bimanual rotation tasks when moving away from and toward the body

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