Split-belt adaptation is a sub-type of motor adaptation in which the limbs on each side of the animal's body are driven at different speeds. This is achieved through the use of a split-belt
treadmill that consists of two independently controlled treadmill belts. Animals undergoing split-belt adaptation adjust their interlimb coordination pattern to regain overall
gait symmetry. Split-belt adaptation has a notable after-effect period (limbs driven at the same speed) in which the interlimb coordination pattern remains altered from that during the pre-adaptation period for some time after the split-belt perturbation period. The after-effect, however, is context-dependent and therefore, will only exist in the same locomotor environment in which the adaptation had occurred. Moreover, split-belt adaptation has spatial (placement of the limb) and temporal (timing of limb movement) components that are dissociable at the behavioral and circuit level. The adaptation rates of the two components are different where the adaptation of the temporal component is faster than that of spatial component. In vertebrates, the cerebellum is suggested to facilitate split-belt adaptation, and in mice, the interposed
cerebellar nucleus is particularly crucial for this form of adaptation. Additionally,
somatomotor regions of cerebral cortex in mice are shown to be not involved in split-belt adaptation. The split-belt adaptation paradigm is clinically important for aiding in the adjustment or recovery of impaired limb coordination patterns resulting from injury or
pathologies, as well as understanding the specific aspects (e.g. temporal or spatial components) of gait that are disrupted in gait pathologies. == After-effects ==