Spencer, Rebecca M. C., Richard B. Ivry, Daniel Cattaert, and Andras Semjen. Bimanual coordination during rhythmic movements in the absence of somatosensory feedback. J Neurophysiol 94: [2901][2902][2903][2904][2905][2906][2907][2908][2909][2910] 2005. First published July 13, 2005; doi:10.1152/jn.00363.2005. We investigated the role of somatosensory feedback during bimanual coordination by testing a bilaterally deafferented patient, a unilaterally deafferented patient, and three control participants on a repetitive bimanual circle-drawing task. Circles were drawn symmetrically or asymmetrically at varying speeds with full, partial, or no vision of the hands. Strong temporal coupling was observed between the hands at all movement rates during symmetrical drawing and at the comfortable movement rate during asymmetrical drawing in all participants. When making asymmetric movements at the comfortable and faster rates, the patients and controls exhibited similar evidence of pattern instability, including a reduction in temporal coupling and trajectory deformation. The patients differed from controls on measures of spatial coupling and variability. The amplitudes and shapes of the two circles were less similar across limbs for the patients than the controls and the circles produced by the patients tended to drift in extrinsic space across successive cycles. These results indicate that somatosensory feedback is not critical for achieving temporal coupling between the hands nor does it contribute significantly to the disruption of asymmetrical coordination at faster movement rates. However, spatial consistency and position, both within and between limbs, were disrupted in the absence of somatosensory feedback.
I N T R O D U C T I O NStudies involving bimanual periodic movements have shown that two patterns of coordination, in-phase and antiphase, exhibit spontaneous stability. With respect to the sagittal plane of the body, in-phase movements are symmetric and typically involve the simultaneous activation of homologous muscles. Antiphase movements are asymmetric, with muscle activation patterns typically 180°out of phase. A fundamental observation in the motor control literature is that these two patterns are not equally stable. For in-phase movements, the variability of relative phase remains low and relatively constant across a large range of movement frequencies. In contrast, for antiphase movements, relative phase variability increases as frequency increases and, at a critical frequency, spontaneous transitions from anti-to in-phase movements are observed (reviewed in Schoener and Kelso 1988).Although the dynamics of hand coordination were originally developed for single-joint, oscillatory movements (Kelso 1984), many recent studies have used a two-dimensional bimanual circle-drawing task in which movements are made either symmetrically with one hand circling clockwise and the other, counterclockwise, or asymmetrically, with both hands circling clockwise or counterclockwise (Carson et al. 1997;Semjen et al. 1995)....
