Mechanical and cold polymodality coexist in tactile peripheral afferents, and it’s not mediated by TRPM8

In the mammalian somatosensory system, polymodality is defined as the competence of some neurons to respond to multiple forms of energy (e.g., mechanical and thermal). This ability is thought to be an exclusive property of nociceptive neurons (polymodal C-fiber nociceptors) and one of the pillars of...

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Bibliographic Details
Published inMolecular pain Vol. 20; p. 17448069241276378
Main Authors Boada, M Danilo, Gutierrez, Silvia
Format Journal Article
LanguageEnglish
Published Los Angeles, CA SAGE Publications 01.01.2024
Sage Publications Ltd
Subjects
Anesthesiology
Calcitonin gene-related peptide
Electrical properties
Experiments
Immunohistochemistry
Laboratories
Neuromodulation
Neurons
Nociceptors
Pain perception
Physiology
Population studies
Receptor mechanisms
Short Report
Somatosensory system
Spinal cord
Transient receptor potential proteins
Velocity
pain
somatosensory system
cold
mechano-receptors
Polymodality
Pain
Cold
Somatosensory system
Mechano-Cold neurons
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Summary:In the mammalian somatosensory system, polymodality is defined as the competence of some neurons to respond to multiple forms of energy (e.g., mechanical and thermal). This ability is thought to be an exclusive property of nociceptive neurons (polymodal C-fiber nociceptors) and one of the pillars of nociceptive peripheral plasticity. The current study uncovered a completely different neuronal sub-population with polymodal capabilities on the opposite mechanical modality spectrum (tactile). We have observed that several tactile afferents (1/5) can respond to cold in non-nociceptive ranges. These cells’ mechanical thresholds and electrical properties are similar to any low-threshold mechano-receptors (LT), conducting in a broad range of velocities (Aδ to Aβ), lacking CGRP and TRPM8 receptors. Due to its density, cold-response range, speed, and response to injury (or lack thereof), we speculate on its role in controlling reflexive behaviors (wound liking and rubbing) and modulation of nociceptive spinal cord integration. Further studies are required to understand the mechanisms behind this neuron’s polymodality, central architecture, and impact on pain perception.
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ISSN:1744-8069
1744-8069
DOI:10.1177/17448069241276378