RT Journal Article
SR Electronic
T1 Modular Control of Limb Movements during Human Locomotion
JF The Journal of Neuroscience
JO J. Neurosci.
FD Society for Neuroscience
SP 11149
OP 11161
DO 10.1523/JNEUROSCI.2644-07.2007
VO 27
IS 41
A1 Yuri P. Ivanenko
A1 Germana Cappellini
A1 Nadia Dominici
A1 Richard E. Poppele
A1 Francesco Lacquaniti
YR 2007
UL http://www.jneurosci.org/content/27/41/11149.abstract
AB The idea that the CNS may control complex interactions by modular decomposition has received considerable attention. We explored this idea for human locomotion by examining limb kinematics. The coordination of limb segments during human locomotion has been shown to follow a planar law for walking at different speeds, directions, and levels of body unloading. We compared the coordination for different gaits. Eight subjects were asked to walk and run on a treadmill at different speeds or to walk, run, and hop over ground at a preferred speed. To explore various constraints on limb movements, we also recorded stepping over an obstacle, walking with the knees flexed, and air-stepping with body weight support. We found little difference among covariance planes that depended on speed, but there were differences that depended on gait. In each case, we could fit the planar trajectories with a weighted sum of the limb length and orientation trajectories. This suggested that limb length and orientation might provide independent predictors of limb coordination. We tested this further by having the subjects step, run, and hop in place, thereby varying only limb length and maintaining limb orientation fixed, and also by marching with knees locked to maintain limb length constant while varying orientation. The results were consistent with a modular control of limb kinematics where limb movements result from a superposition of separate length- and orientation-related angular covariance. The hypothesis finds support in the animal findings that limb proprioception may also be encoded in terms of these global limb parameters.