The general goals are to study, using single unit recording and focal ablation methods in chronic trained rhesus monkeys, what the cerebellu, basal ganglia, and cerebral cortex contribute to the control of bodily movement. There are four projects, four experimental set-ups, and four investigators. A new aspect is the parallel study (noninvasive) of human (normal and cerebellar-damaged) performance of the same tasks that our monkeys perform. The first project examines cerebellar control of smooth pursuit wrist tracking of a visual target and the question of whether stretch reflexes contribute to the damping of oscillation (tremor). Damping and stiffness are measured from the oscillation that occurs after torque pulse perturbation. Tracking is against different torque motor loads which selectively increase (positive velocity feedback) and decrease (negative velocity feedback) oscillation. We will look for differences in stretch reflex EMG, spindle afferent, motor cortex and cerebellar neuronal activities as the subjects adapt to control - and not control - tremor. The second project will further examine the cerebellar role in the adaptation of the wrist to step displacements from a central held position. We will measure (1) the EMG, spindle afferent and cerebellar nuclear activity as well as that of the previously studied Purkinje cells (simple and complex spike) during 2-way adaptations (increase and decrease in displacing torque step), and (2) the performance and its adaptive capacity afterfocal cerebellar ablation. A third project, the study of pallidal neuron (1) timing (with respect to onset of movement, EMG, and cerebellar neurons) (2) coding (different relation to fast, slow, visual paced, self-paced, force vs. velocity vs. amplitude of movement, clock-like oscillatory property), and (3) ability/inability to control these parameters after pallidal lesion, will be almost or completely finished by the time this grant period would begin. The fourth project will study motor, supplementary motor, premotor, and prefrontal cortex in relation to directional signals and """"""""set"""""""" for intended movement, individual finger movement, and combinations and sequences of movements with unit recording and focal ablation in monkeys. These experiments are designed to reveal mechanisms of (1) the contributions of these motor regions to normal movement and (2) the neurological deficits that result from the absence of these specific contributions.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS012777-16
Application #
3394979
Study Section
Neurology B Subcommittee 2 (NEUB)
Project Start
1977-09-01
Project End
1992-11-30
Budget Start
1991-04-01
Budget End
1992-11-30
Support Year
16
Fiscal Year
1991
Total Cost
Indirect Cost
Name
Washington University
Department
Type
Schools of Medicine
DUNS #
062761671
City
Saint Louis
State
MO
Country
United States
Zip Code
63130
Norris, Scott A; Hathaway, Emily N; Taylor, Jordan A et al. (2011) Cerebellar inactivation impairs memory of learned prism gaze-reach calibrations. J Neurophysiol 105:2248-59
Reid, E K; Norris, S A; Taylor, J A et al. (2009) Is the parvocellular red nucleus involved in cerebellar motor learning? Curr Trends Neurol 3:15-22
Hakimian, Shahin; Norris, Scott A; Greger, Bradley et al. (2008) Time and frequency characteristics of Purkinje cell complex spikes in the awake monkey performing a nonperiodic task. J Neurophysiol 100:1032-40
Perlmutter, Joel S; Thach, W Thomas (2007) Writer's cramp: questions of causation. Neurology 69:331-2
Thach, W Thomas; Bastian, Amy J (2004) Role of the cerebellum in the control and adaptation of gait in health and disease. Prog Brain Res 143:353-66
Norris, Scott A; Greger, Bradley; Hathaway, Emily N et al. (2004) Purkinje cell spike firing in the posterolateral cerebellum: correlation with visual stimulus, oculomotor response, and error feedback. J Neurophysiol 92:1867-79
Greger, Bradley; Norris, Scott A; Thach, W Thomas (2004) Spike firing in the lateral cerebellar cortex correlated with movement and motor parameters irrespective of the effector limb. J Neurophysiol 91:576-82
Goodkin, H P; Thach, W T (2003) Cerebellar control of constrained and unconstrained movements. I. Nuclear inactivation. J Neurophysiol 89:884-95
Goodkin, H P; Thach, W T (2003) Cerebellar control of constrained and unconstrained movements. II. EMG and nuclear activity. J Neurophysiol 89:896-908
Martin, Tod A; Norris, Scott A; Greger, Bradley E et al. (2002) Dynamic coordination of body parts during prism adaptation. J Neurophysiol 88:1685-94

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