Neural Substrates of Cough Control During Coughing

Overview

Journal Sci Rep

Specialty Science

Date 2024 Jan 8

PMID 38191647

Authors

Takafumi Sugi

Tomoo Inubushi

Tomohisa Ohno

Yuya Onishi

Takashi Isobe

Takashi Shigematsu

Satoshi Hanai

Yoshiro Okada

Ryosuke Takahashi

Yuichi Tawara

Chie Suzuki

Toshihiko Kanno

Yasuhiro Magata

Ichiro Fujishima

Etsuji Yoshikawa

Yasuomi Ouchi

Affiliations

Soon will be listed here.

Abstract

Cough is known as a protective reflex to keep the airway free from harmful substances. Although brain activity during cough was previously examined mainly by functional magnetic resonance imaging (fMRI) with model analysis, this method does not capture real brain activity during cough. To obtain accurate measurements of brain activity during cough, we conducted whole-brain scans during different coughing tasks while correcting for head motion using a restraint-free positron emission tomography (PET) system. Twenty-four healthy right-handed males underwent multiple PET scans with [O]HO. Four tasks were performed during scans: "resting"; "voluntary cough (VC)", which simply repeated spontaneous coughing; "induced cough (IC)", where participants coughed in response to an acid stimulus in the cough-inducing method with tartaric acid (CiTA); and "suppressed cough (SC)", where coughing was suppressed against CiTA. The whole brain analyses of motion-corrected data revealed that VC chiefly activated the cerebellum extending to pons. In contrast, CiTA-related tasks (IC and SC) activated the higher sensory regions of the cerebral cortex and associated brain regions. The present results suggest that brain activity during simple cough is controlled chiefly by infratentorial areas, whereas manipulating cough predominantly requires the higher sensory brain regions to allow top-down control of information from the periphery.

Citing Articles

Decoding the impact of the placebo response in clinical trials for chronic cough.

Zhang M, Zhang B, Morice A ERJ Open Res. 2024; 10(5).

PMID: 39469270 PMC: 11514000. DOI: 10.1183/23120541.00335-2024.

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