Abstract
The neurotransmitter dopamine is important in reward processing, however its precise modulatory role is still being investigated. Carbon-fiber microelectrodes can be used to monitor dopamine on a subsecond time scale in the striatum and nucleus accumbens of rats during behavior, and this approach is providing new insights into the mechanisms that control its extracellular concentration as well as the conditions under which it is released. Three main processes govern the amount of dopamine measured extrasynaptically: exocytotic release, neuronal uptake, and diffusion away from the release site. By monitoring local extracellular dopamine concentrations in the striatum following electrical stimulation of dopamine-containing neurons, release, uptake and diffusion can be individually examined and quantified. Dopaminergic neurons have been shown to fire in two firing modes, tonic and bursts at higher frequency. Electrical stimulation can be designed to mimic either mode to examine their effects on dopamine release. Burst firing causes a transient increase in extracellular dopamine while tonic firing causes a new steady-state level. In behaving primates, dopaminergic neurons display short-latency, phasic firing to primary reward and conditioned cues associated with reward. These bursts code differences between actual and predicted rewards. In rats, transient dopamine release in terminal regions that mimics that seen during burst firing has been demonstrated during reward-related cues. Taken together, these studies indicate that phasic dopamine release is a critical mediator of reward-related processes.
Keywords: reward, diffusion, uptake, release, extrasynaptic, tonic, phasic, Dopamine
CNS & Neurological Disorders - Drug Targets
Title: Phasic Dopamine Signaling During Behavior, Reward, and Disease States
Volume: 5 Issue: 1
Author(s): R. M. Wightman and M. L.A.V. Heien
Affiliation:
Keywords: reward, diffusion, uptake, release, extrasynaptic, tonic, phasic, Dopamine
Abstract: The neurotransmitter dopamine is important in reward processing, however its precise modulatory role is still being investigated. Carbon-fiber microelectrodes can be used to monitor dopamine on a subsecond time scale in the striatum and nucleus accumbens of rats during behavior, and this approach is providing new insights into the mechanisms that control its extracellular concentration as well as the conditions under which it is released. Three main processes govern the amount of dopamine measured extrasynaptically: exocytotic release, neuronal uptake, and diffusion away from the release site. By monitoring local extracellular dopamine concentrations in the striatum following electrical stimulation of dopamine-containing neurons, release, uptake and diffusion can be individually examined and quantified. Dopaminergic neurons have been shown to fire in two firing modes, tonic and bursts at higher frequency. Electrical stimulation can be designed to mimic either mode to examine their effects on dopamine release. Burst firing causes a transient increase in extracellular dopamine while tonic firing causes a new steady-state level. In behaving primates, dopaminergic neurons display short-latency, phasic firing to primary reward and conditioned cues associated with reward. These bursts code differences between actual and predicted rewards. In rats, transient dopamine release in terminal regions that mimics that seen during burst firing has been demonstrated during reward-related cues. Taken together, these studies indicate that phasic dopamine release is a critical mediator of reward-related processes.
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Cite this article as:
Wightman M. R. and Heien L.A.V. M., Phasic Dopamine Signaling During Behavior, Reward, and Disease States, CNS & Neurological Disorders - Drug Targets 2006; 5 (1) . https://dx.doi.org/10.2174/187152706784111605
DOI https://dx.doi.org/10.2174/187152706784111605 |
Print ISSN 1871-5273 |
Publisher Name Bentham Science Publisher |
Online ISSN 1996-3181 |
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