Neural interactions in the human frontal cortex dissociate reward and punishment learning

How human prefrontal and insular regions interact while maximizing rewards and minimizing punishments is unknown. Capitalizing on human intracranial recordings, we demonstrate that the functional specificity toward reward or punishment learning is better disentangled by interactions compared to loca...

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Bibliographic Details
Published in:eLife 2024-06, Vol.12
Main Authors: Combrisson, Etienne, Basanisi, Ruggero, Gueguen, Maelle C M, Rheims, Sylvain, Kahane, Philippe, Bastin, Julien, Brovelli, Andrea
Format: Article
Language:English
Subjects:
Adult
Brain
Cognition & reasoning
Cognitive science
Cortex (frontal)
cortical interactions
Decomposition
Epilepsy
Female
Frontal Lobe - physiology
functional connectivity
Humans
Hypotheses
information decomposition
Insular Cortex - physiology
Learning
Learning - physiology
Male
Neuroscience
Prefrontal cortex
Prefrontal Cortex - physiology
Punishment
redundancy
Reinforcement
reinforcement learning
Reward
synergy
Variables
Young Adult
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Summary:How human prefrontal and insular regions interact while maximizing rewards and minimizing punishments is unknown. Capitalizing on human intracranial recordings, we demonstrate that the functional specificity toward reward or punishment learning is better disentangled by interactions compared to local representations. Prefrontal and insular cortices display non-selective neural populations to rewards and punishments. Non-selective responses, however, give rise to context-specific interareal interactions. We identify a reward subsystem with redundant interactions between the orbitofrontal and ventromedial prefrontal cortices, with a driving role of the latter. In addition, we find a punishment subsystem with redundant interactions between the insular and dorsolateral cortices, with a driving role of the insula. Finally, switching between reward and punishment learning is mediated by synergistic interactions between the two subsystems. These results provide a unifying explanation of distributed cortical representations and interactions supporting reward and punishment learning.
ISSN:2050-084X
2050-084X
DOI:10.7554/eLife.92938