Striatal firing rate reflects head movement velocity

Although the basal ganglia have long been implicated in the initiation of actions, their contribution to movement remains a matter of dispute. Using wireless multi‐electrode recording and motion tracking, we examined the relationship between single‐unit activity in the sensorimotor striatum and move...

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Bibliographic Details
Published in:The European journal of neuroscience 2014-11, Vol.40 (10), p.3481-3490
Main Authors: Kim, Namsoo, Barter, Joseph W., Sukharnikova, Tatyana, Yin, Henry H.
Format: Article
Language:English
Subjects:
Action Potentials - physiology
Air
Animals
Anticipation, Psychological - physiology
basal ganglia
Biological and medical sciences
Corpus Striatum - physiology
Cues
Degenerative and inherited degenerative diseases of the nervous system. Leukodystrophies. Prion diseases
Dietary Sucrose - administration & dosage
Electrodes, Implanted
Female
Head Movements - physiology
Male
Medical sciences
medium spiny neuron
Mice, Inbred C57BL
mouse
Nervous system (semeiology, syndromes)
Nervous system as a whole
Neurology
Neurons - physiology
Parkinson's disease
Physical Stimulation
Punishment
Reward
Signal Processing, Computer-Assisted
striatal interneuron
Tourette syndrome
Water Deprivation
Wireless Technology
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Summary:Although the basal ganglia have long been implicated in the initiation of actions, their contribution to movement remains a matter of dispute. Using wireless multi‐electrode recording and motion tracking, we examined the relationship between single‐unit activity in the sensorimotor striatum and movement kinematics. We recorded single‐unit activity from medium spiny projection neurons and fast‐spiking interneurons while monitoring the movements of mice using motion tracking. In Experiment 1, we trained mice to generate movements reliably by water‐depriving them and giving them periodic cued sucrose rewards. We found high correlations between single‐unit activity and movement velocity in particular directions. This correlation was found in both putative medium spiny projection neurons and fast‐spiking interneurons. In Experiment 2, to rule out the possibility that the observed correlations were due to reward expectancy, we repeated the same procedure but added trials in which sucrose delivery was replaced by an aversive air puff stimulus. The air puff generated avoidance movements that were clearly different from movements on rewarded trials, but the same neurons that showed velocity correlation on reward trials exhibited a similar correlation on air puff trials. These experiments show for the first time that the firing rate of striatal neurons reflects movement velocity for different types of movements, whether to seek rewards or to avoid harm. Using wireless multi‐electrode recording and motion tracking, we examined the relationship between single unit activity in the sensorimotor striatum and movement kinematics. We found that the firing rate of medium spiny projection neurons and fast‐spiking interneurons reflects movement velocity for different types of movements, whether to seek rewards or to avoid harm. These results suggest that the striatum is a component of a velocity control circuit.
ISSN:0953-816X
1460-9568
DOI:10.1111/ejn.12722