Influence of Hypobaric Hypoxic Conditions on Ocular Structure and Biological Function at High Attitudes: a Narrative Review

Overview

Journal Front Neurosci

Date 2023 May 25

PMID 37229428

Authors

Yuchen Wang

Xinli Yu

Ziyuan Liu

Zhongsheng Lv

Huaqin Xia

Yiren Wang

Jiaxi Li

Xuemin Li

Affiliations

Soon will be listed here.

Abstract

Background: With the development of science and technology, high-altitude environments, involving aviation, aerospace, and mountainous regions, have become the main areas for human exploration, while such complex environments can lead to rapid decreases in air and oxygen pressure. Although modern aircrafts have pressurized cabins and support equipment that allow passengers and crew to breathe normally, flight crew still face repeated exposure to hypobaric and hypoxic conditions. The eye is a sensory organ of the visual system that responds to light and oxygen plays a key role in the maintenance of normal visual function. Acute hypoxia changes ocular structure and function, such as the blood flow rate, and can cause retinal ischemia.

Methods: We reviewed researches, and summarized them briefly in a review.

Results: The acute hypobaric hypoxia affects corneal, anterior chamber angle and depth, pupils, crystal lens, vitreous body, and retina in structure; moreover, the acute hypoxia does obvious effect on visual function; for example, vision, intraocular pressure, oculometric features and dynamic visual performance, visual field, contrast sensitivity, and color perception.

Conclusion: We summarized the changes in the physiological structure and function of the eye in hypoxic conditions and to provide a biological basis for the response of the human eye at high-altitude.

Citing Articles

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Impact of flight and equivalent short-term high-altitude exposure on ocular structures and function.

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