Intra-somatosensory Cortical Circuits Mediating Pain-induced Analgesia

Overview

Journal Nat Commun

Specialty Biology

Date 2025 Feb 21

PMID 39984470

Authors

Ji-Ye Huang

Yu-Xin Jin

Wan-Ying Dong

Wan Zhao

Ping-Kai Cheng

Jun-Hao Miao

An Liu

Di Wang

Juan Li

Zhi Zhang

Wenjuan Tao

Xia Zhu

Affiliations

Soon will be listed here.

Abstract

Pain in one part of the body profoundly diminishes the sensation of pain in other parts of the body in humans. Here, we found that pain-related behaviors in hindpaw are inhibited by noxious stimuli from diverse body regions in mice. Using activity-dependent cell labeling in male Fos mice, we captured a neuronal ensemble in the layers 2-4 of secondary somatosensory cortex (S2) that was activated during pain at diverse body regions induced analgesia. Single-cell projection analysis showed that these S2 neurons receive projections from the contralateral S2 and specifically innervate the layer 4 of primary somatosensory cortex (S1). Microendoscopic calcium imaging and chemogenetic manipulation in freely moving mice showed that this S2 → S1 feedforward inhibitory circuit mediates ipsilateral pain-induced analgesia, whereas contralateral S2 innervation of the S2 → S1 circuit mediates contralateral pain-induced analgesia. Our study defines the intra-somatosensory cortical circuits underlying "pain inhibiting pain", expanding the scope of known circuit mechanisms involved in pain relief.

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