and Self-touch Differ in Hemodynamic Response in the Prefrontal Cortex-An FNIRS Study

Overview

Journal Front Neuroergon

Date 2024 Jan 18

PMID 38234502

Authors

Sabrina von Au

Ingo Helmich

Simon Kieffer

Hedda Lausberg

Affiliations

Soon will be listed here.

Abstract

Introduction: Each individual touches the own body several 100 times a day. While some researchers propose a self-regulatory function of self-touch, others report that self-touching increases nervousness. This controversy appears to be caused by the fact that researchers did not define the kind of self-touch they examined and actually, referred to different types of self-touch. Thus, kinematically defining different types of self-touch, such as (discrete), , and , and exploring the neural correlates of the different types will provide insight into the neuropsychological function of self-touching behavior.

Methods: To this aim, we assessed hemodynamic responses in prefrontal brain areas using functional near-infrared spectroscopy (fNIRS) and behavioral responses with NEUROGES®. Fifty-two participants were recorded during three specific kinematically types of self-touch () that were to be performed on command. The recently developed toolbox Satori was used for the visualization of neuronal processes.

Results: Behaviorally, the participants did not perform self-touch reliably. Neurally, the comparison of and self-touch revealed different activation patterns. self-touch is associated with stronger hemodynamic responses in the left Orbitofrontal Cortex and the Dorsolateral Prefrontal Cortex than self-touch.

Discussion: These brain areas have been reported to be associated with self-regulatory processes. Furthermore, self-touch appears to be primarily generated by implicit neural control. Thus, by distinguishing kinematically different types of self-touch, our findings shed light on the controverse discussion on the neuropsychological function of self-touch.

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