Nucleus Accumbens Shell Neurons Encode the Kinematics of Reward Approach Locomotion

Overview

Journal Neuroscience

Specialty Neurology

Date 2023 Jun 17

PMID 37330195

Authors

David Levcik

Adam H Sugi

Marcelo Aguilar-Rivera

Jose A Pochapski

Gabriel Baltazar

Laura N Pulido

Cyrus A Villas-Boas

Romulo Fuentes-Flores

Saleem M Nicola

Claudio da Cunha

Affiliations

Soon will be listed here.

Abstract

The nucleus accumbens (NAc) is considered an interface between motivation and action, with NAc neurons playing an important role in promoting reward approach. However, the encoding by NAc neurons that contributes to this role remains unknown. We recorded 62 NAc neurons in male Wistar rats (n = 5) running towards rewarded locations in an 8-arm radial maze. Variables related to locomotor approach kinematics were the best predictors of the firing rate for most NAc neurons. Nearly 18% of the recorded neurons were inhibited during the entire approach run (locomotion-off cells), suggesting that reduction in firing of these neurons promotes initiation of locomotor approach. 27% of the neurons presented a peak of activity during acceleration followed by a valley during deceleration (acceleration-on cells). Together, these neurons accounted for most of the speed and acceleration encoding identified in our analysis. In contrast, a further 16% of neurons presented a valley during acceleration followed by a peak just prior to or after reaching reward (deceleration-on cells). These findings suggest that these three classes of NAc neurons influence the time course of speed changes during locomotor approach to reward.

Citing Articles

Chronic in vivo sequelae of repetitive acute mfb-DBS on accumbal dopamine and midbrain neuronal activity.

Miguel Telega L, Ashouri Vajari D, Ramanathan C, Coenen V, Dobrossy M J Neurochem. 2024; 169(1):e16223.

PMID: 39308085 PMC: 11658194. DOI: 10.1111/jnc.16223.

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