Neural Coding of Distinct Statistical Properties of Reward Information in Humans

doi:10.1093/cercor/bhj004

Cerebral Cortex Advance Access published online on July 20, 2005
Cerebral Cortex, doi:10.1093/cercor/bhj004

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Published by Oxford University Press 2005.

Article

Neural Coding of Distinct Statistical Properties of Reward Information in Humans

Jean-Claude Dreher ¹^*, Philip Kohn ², and Karen Faith Berman ²

¹ Unit on Integrative Neuroimaging, Clinical Brain Disorders Branch, NIMH, NIH, IRP, Bethesda, MD 892-365, USA; Current address: Institute of Cognitive Science, CNRS-Université de Lyon 1, 67 Bd Pinel, 69675 Bron, France
² Unit on Integrative Neuroimaging, Clinical Brain Disorders Branch, NIMH, NIH, IRP, Bethesda, MD 892-365, USA

^* To whom correspondence should be addressed.
Jean-Claude Dreher, E-mail: dreher{at}isc.cnrs.fr

Abstract

Brain processing of reward information is essential for complexfunctions such as learning and motivation. Recent primate electrophysiologicalstudies using concepts from information, economic and learningtheories indicate that the midbrain may code two statisticalparameters of reward information: a transient reward error predictionsignal that varies linearly with reward probability and a sustainedsignal that varies highly non-linearly with reward probabilityand that is highest with maximal reward uncertainty (rewardprobability = 0.5). Here, using event-related functional magneticresonance imaging, we disentangled these two signals in humansusing a novel paradigm that systematically varied monetary rewardprobability, magnitude and expected reward value. The midbrainwas activated both transiently with the error prediction signaland in a sustained fashion with reward uncertainty. Moreover,distinct activity dynamics were observed in post-synaptic midbrainprojection sites: the prefrontal cortex responded to the transienterror prediction signal while the ventral striatum covariedwith the sustained reward uncertainty signal. These data suggestthat the prefrontal cortex may generate the reward predictionwhile the ventral striatum may be involved in motivational processesthat are useful when an organism needs to obtain more informationabout its environment. Our results indicate that distinct functionalbrain networks code different aspects of the statistical propertiesof reward information in humans.

Keywords: dopamine; error prediction; fMRI; gambling; information theory; uncertainty.

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