[HTML][HTML] Inactivation of the putamen selectively impairs reward history-based action selection

M Muranishi, H Inokawa, H Yamada, Y Ueda… - Experimental brain …, 2011 - Springer
M Muranishi, H Inokawa, H Yamada, Y Ueda, N Matsumoto, M Nakagawa, M Kimura
Experimental brain research, 2011Springer
Behavioral decisions and actions are directed to achieve specific goals and to obtain
rewards and escape punishments. Previous studies involving the recording of neuronal
activity suggest the involvement of the cerebral cortex, basal ganglia, and midbrain
dopamine system in these processes. The value signal of the action options is represented
in the striatum, updated by reward prediction errors, and used for selecting higher-value
actions. However, it remains unclear whether dysfunction of the striatum leads to impairment …
Abstract
Behavioral decisions and actions are directed to achieve specific goals and to obtain rewards and escape punishments. Previous studies involving the recording of neuronal activity suggest the involvement of the cerebral cortex, basal ganglia, and midbrain dopamine system in these processes. The value signal of the action options is represented in the striatum, updated by reward prediction errors, and used for selecting higher-value actions. However, it remains unclear whether dysfunction of the striatum leads to impairment of value-based action selection. The present study examined the effect of inactivation of the putamen via local injection of the GABAA receptor agonist muscimol in monkeys engaged in a manual reward-based multi-step choice task. The monkeys first searched a reward target from three alternatives, based on the previous one or two choices and their outcomes, and obtained a large reward; they then earned an additional reward by choosing the last rewarded target. Inactivation of the putamen impaired the ability of monkeys to make optimal choices during third trial in which they were required to choose a target different from those selected in the two previous trials by updating the values of the three options. The monkeys normally changed options if the last choice resulted in small reward (lose-shift) and stayed with the last choice if it resulted in large reward (win-stay). Task start time and movement time during individual trials became longer after putamen inactivation. But monkeys could control the motivation level depending on the reward value of individual trial types before and after putamen inactivation. These results support a view that the putamen is involved selectively and critically in neuronal circuits for reward history-based action selection.
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