An Externally Validated Resting-state Brain Connectivity Signature of Pain-related Learning

Overview

Journal Commun Biol

Specialty Biology

Date 2024 Jul 17

PMID 39020002

Authors

Balint Kincses

Katarina Forkmann

Frederik Schlitt

Robert Jan Pawlik

Katharina Schmidt

Dagmar Timmann

Sigrid Elsenbruch

Katja Wiech

Ulrike Bingel

Tamas Spisak

Affiliations

Soon will be listed here.

Abstract

Pain can be conceptualized as a precision signal for reinforcement learning in the brain and alterations in these processes are a hallmark of chronic pain conditions. Investigating individual differences in pain-related learning therefore holds important clinical and translational relevance. Here, we developed and externally validated a novel resting-state brain connectivity-based predictive model of pain-related learning. The pre-registered external validation indicates that the proposed model explains 8-12% of the inter-individual variance in pain-related learning. Model predictions are driven by connections of the amygdala, posterior insula, sensorimotor, frontoparietal, and cerebellar regions, outlining a network commonly described in aversive learning and pain. We propose the resulting model as a robust and highly accessible biomarker candidate for clinical and translational pain research, with promising implications for personalized treatment approaches and with a high potential to advance our understanding of the neural mechanisms of pain-related learning.

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