PT - JOURNAL ARTICLE AU - Taig, Efrat AU - Küper, Michael AU - Theysohn, Nina AU - Timmann, Dagmar AU - Donchin, Opher TI - Deficient Use of Visual Information in Estimating Hand Position in Cerebellar Patients AID - 10.1523/JNEUROSCI.1153-12.2012 DP - 2012 Nov 14 TA - The Journal of Neuroscience PG - 16274--16284 VI - 32 IP - 46 4099 - http://www.jneurosci.org/content/32/46/16274.short 4100 - http://www.jneurosci.org/content/32/46/16274.full SO - J. Neurosci.2012 Nov 14; 32 AB - We tested cerebellar degeneration in human patients in a task designed to isolate different aspects of motor planning and found a specific relationship between their ability to do inverse kinematic transformation and sparing of Crus I. Our approach was based on an experimental design introduced by Sober and Sabes (2003, 2005). Their paradigm allows behavioral deficits in planning of movement direction to be dissociated from deficits in generation of motor commands and also allows for the relative role played by visual and proprioceptive information to be quantified. Perturbation of visual information about hand position affected cerebellar degeneration patients (N = 12) and age-matched controls equally in determining movement direction, but had less of an effect in both groups in the transformation of movement direction to motor command. However, when provided with vision of the joints, control participants were more affected in generating the motor command in perturbed trials, and cerebellar degeneration participants were not. Thus, cerebellar patients were less able to use visual information about the joints in generating motor commands. Voxel-based morphometric analysis showed that this inability was primarily correlated with degeneration of Crus I. These results show that the cerebellum plays a role in motor planning, and specifically in the generation of inverse kinematic models for sensorimotor processing. The involvement of Crus I is consistent with an emerging picture in which increasingly posterior lobules of the anterior cerebellar cortex are associated with increasingly complex and abstract aspects of motor behavior.