The O-sensitive Brain Stem, Hyperoxic Hyperventilation, and CNS Oxygen Toxicity

Overview

Journal Front Physiol

Date 2022 Aug 12

PMID 35957982

Authors

Jay B Dean

Nicole M Stavitzski

Affiliations

Soon will be listed here.

Abstract

Central nervous system oxygen toxicity (CNS-OT) is a complex disorder that presents, initially, as a sequence of cardio-respiratory abnormalities and nonconvulsive signs and symptoms (S/Sx) of brain stem origin that culminate in generalized seizures, loss of consciousness, and postictal cardiogenic pulmonary edema. The risk of CNS-OT and its antecedent "early toxic indications" are what limits the use of hyperbaric oxygen (HBO) in hyperbaric and undersea medicine. The purpose of this review is to illustrate, based on animal research, how the temporal pattern of abnormal brain stem responses that precedes an "oxtox hit" provides researchers a window into the early neurological events underlying seizure genesis. Specifically, we focus on the phenomenon of hyperoxic hyperventilation, and the medullary neurons presumed to contribute in large part to this paradoxical respiratory response; neurons in the caudal Solitary complex (cSC) of the dorsomedial medulla, including putative CO chemoreceptor neurons. The electrophysiological and redox properties of O-/CO-sensitive cSC neurons identified in rat brain slice experiments are summarized. Additionally, evidence is summarized that supports the working hypothesis that seizure genesis originates in subcortical areas and involves cardio-respiratory centers and cranial nerve nuclei in the hind brain (brainstem and cerebellum) based on, respectively, the complex temporal pattern of abnormal cardio-respiratory responses and various nonconvulsive S/Sx that precede seizures during exposure to HBO.

Citing Articles

Respiratory plasticity induced by chronic hyperoxia in juvenile and adult rats.

Bavis R, Danielson M, Dufour G, Hanus J, Pratt A, Tobin K Respir Physiol Neurobiol. 2024; 333:104386.

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PEG300 Protects Mitochondrial Function By Upregulating PGC-1α to Delay Central Nervous System Oxygen Toxicity in Mice.

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PMID: 38884699 DOI: 10.1007/s12640-024-00708-0.

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