CONTRAST SENSITIVITY AND EYE MICROTREMOR AS MARKERS OF ADAPTATION AND READAPTATION IN A MODEL EXPERIMENT TO STUDY THE INFLUENCE OF GRAVITY CHANGES-Reference-Cited by-同舟云学术

CONTRAST SENSITIVITY AND EYE MICROTREMOR AS MARKERS OF ADAPTATION AND READAPTATION IN A MODEL EXPERIMENT TO STUDY THE INFLUENCE OF GRAVITY CHANGES

Published:2022-11-24 Issue:4 Volume:7 Page:619-623
ISSN:2499-9962
Container-title:Russian Journal of Biological Physics and Chemisrty
language:en
Short-container-title:

Author:

Shoshina I.¹,Zelenskaya I.²,Bekreneva M.²,Lyapunov S.³,Lyapunov I.³,Kotova D.¹,Tomilovskaya E.²

Affiliation:

1. St. Petersburg State University

2. Institute of Biomedical Problems of the Russian Academy of Sciences

3. Prokhorov General Physics Institute RAS

Abstract

Visual perception plays a crucial role in providing the brain with the information it needs to make decisions, build a picture of the world, and adapt to changing environmental conditions. Under conditions of "dry" immersion, which simulates the effects of weightlessness on the human body, contrast sensitivity and tremor eye movements were studied under changing environmental conditions. The study involved 10 volunteers (mean age 30.8±4.6 years). The contrast sensitivity of the visual system was recorded using the method of visocontrastometry. We presented the Gabor elements with a spatial frequency: 0.4; 0.8; 1.0; 3.0; 6.0 and 10.0 cycle/deg. The parameters of eye micromovements, i.e., the amplitude and frequency of eye tremor oscillations, were recorded using an optical system providing high-frequency video recording. The measurements were carried out the day before immersion in the immersion bath, on days 1, 3, 5, and 7 of “dry” immersion, as well as the next day after its completion. A change in contrast sensitivity in the range of low and high spatial frequencies, as well as in the amplitude of eye micromovements, was established. The data obtained today are a new step in the search for methods for an objective assessment of the functional state under changing environmental conditions.

Publisher

RIOR Publishing Center

Reference23 articles.

1. White O., Clement G., Fortrat J.O. et al. Towards human exploration of space: the THESEUS review series on neurophysiology research priorities. NPJ Microgravity, 2016, vol. 2, p. 16023, doi: 10.1038/npjmgrav.2016.23., White O., Clement G., Fortrat J.O. et al. Towards human exploration of space: the THESEUS review series on neurophysiology research priorities. NPJ Microgravity, 2016, vol. 2, p. 16023, doi: 10.1038/npjmgrav.2016.23.

2. Pechenkova E., Nosikova I., Rumshiskaya A. et al. Alterations of Functional Brain Connectivity After Long-Duration Spaceflight as Revealed by fMRI. Front. Physiol., 2019, vol. 10, p. 761, doi: 10.3389/fphys.2019.00761., Pechenkova E., Nosikova I., Rumshiskaya A. et al. Alterations of Functional Brain Connectivity After Long-Duration Spaceflight as Revealed by fMRI. Front. Physiol., 2019, vol. 10, p. 761, doi: 10.3389/fphys.2019.00761.

3. Marshall-Goebel K., Damani R., Bershad E.M. Brain physiological response and adaptation during spaceflight. Neurosurgery, 2019, vol. 85, pp. E815-E821., Marshall-Goebel K., Damani R., Bershad E.M. Brain physiological response and adaptation during spaceflight. Neurosurgery, 2019, vol. 85, pp. E815-E821.

4. Stahn A.C., Riemer M., Wolbers T. et al. Spatial Updating Depends on Gravity. Front. Neural Circuits, 2020, vol. 14, p. 20., Stahn A.C., Riemer M., Wolbers T. et al. Spatial Updating Depends on Gravity. Front. Neural Circuits, 2020, vol. 14, p. 20.

5. Roberts D.R., Stahn A.C., Seidler R.D., Wuyts F.L. Towards understanding the effects of spaceflight on the brain. Lancet Neurol, 2020, vol. 19, p. 808., Roberts D.R., Stahn A.C., Seidler R.D., Wuyts F.L. Towards understanding the effects of spaceflight on the brain. Lancet Neurol, 2020, vol. 19, p. 808.