CO2 Breathing Prior to Simulated Diving Increases Decompression Sickness Risk in a Mouse Model: The Microbiota Trail Is Not Forgotten
-
Published:2024-08-28
Issue:9
Volume:21
Page:1141
-
ISSN:1660-4601
-
Container-title:International Journal of Environmental Research and Public Health
-
language:en
-
Short-container-title:IJERPH
Author:
Daubresse Lucille1, Portas Aurélie2, Bertaud Alexandrine3ORCID, Marlinge Marion3ORCID, Gaillard Sandrine2, Risso Jean-Jacques4, Ramdani Céline4, Rostain Jean-Claude3, Adjiriou Nabil3, Desruelle Anne-Virginie4, Blatteau Jean-Eric1, Guieu Régis3, Vallée Nicolas4
Affiliation:
1. Service de Médecine Hyperbare, Hôpital d’Instruction des Armées, 83000 Toulon, France 2. Université de Toulon, 83130 La Garde, France 3. Aix-Marseille University, 27 Boulevard Jean-Moulin, 13005 Marseille, France 4. Subaquatic Operational Research Team (ERRSO), Military Institute of Biomedical Research (IRBA), 83000 Toulon, France
Abstract
Decompression sickness (DCS) with neurological disorders is the leading cause of major diving accidents treated in hyperbaric chambers. Exposure to high levels of CO2 during diving is a safety concern for occupational groups at risk of DCS. However, the effects of prior exposure to CO2 have never been evaluated. The purpose of this study was to evaluate the effect of CO2 breathing prior to a provocative dive on the occurrence of DCS in mice. Fifty mice were exposed to a maximum CO2 concentration of 70 hPa, i.e., 7% at atmospheric pressure, for one hour at atmospheric pressure. Another 50 mice breathing air under similar conditions served as controls. In the AIR group (control), 22 out of 50 mice showed post-dive symptoms compared to 44 out of 50 in the CO2 group (p < 0.001). We found that CO2 breathing is associated with a decrease in body temperature in mice and that CO2 exposure dramatically increases the incidence of DCS (p < 0.001). More unexpectedly, it appears that the lower temperature of the animals even before exposure to the accident-prone protocol leads to an unfavorable prognosis (p = 0.046). This study also suggests that the composition of the microbiota may influence thermogenesis and thus accidentology. Depending on prior exposure, some of the bacterial genera identified in this work could be perceived as beneficial or pathogenic.
Funder
Direction Générale de l’Armement of the French army, Paris, France
Reference90 articles.
1. Elevated environmental carbon dioxide exposure confounding physiologic events in aviators?;Andicochea;Mil. Med.,2019 2. Hyperbaric conditions;Doolette;Compr. Physiol.,2010 3. Oxygen or carbogen breathing before simulated submarine escape;Gennser;J. Appl. Physiol.,2008 4. Daubresse, L., Amara, J.J., Grau, M.M., De Maistre, S., Guillaume, C.G., Lehot, H.H., Texier, G.G., and Blatteau, J.-E. (September, January 31). Case series of unusual neurologic symptoms after scuba diving training sessions, in the context of SARS COV2 preventive measures and restrictions. Proceedings of the EUBS, Prague, Czech Republic. 5. Relationship between CO2 levels and decompression sickness: Implications for disease prevention;Mano;Aviat. Space Environ. Med.,1978
|
|