Affiliation:
1. German Air Force Centre of Aerospace Medicine
2. University Hospital, LMU Munich
3. 74 th Tactical Air Wing of the German Air Force
4. Medical Support Center Munich Occupational Medicine Department
Abstract
Abstract
Background: Fighter aircraft pilots are regularly exposed to physiological challenges from high acceleration (Gz) forces, as well as increased breathing pressure and oxygen supply in the support systems. We studied, whether effects on the lung and systemic oxidative stress were detectable after real training flights comprising a wide variety of exposure conditions and their combinations.
Methods: Thirty-five pilots of the German Air Force performed 145 flights with the Eurofighter Typhoon. Before and after flights, lung diffusing capacity for carbon monoxide (DLCO) and nitric oxide (DLNO), alveolar volume (VA), and diffusing capacities per volume (KCO, KNO) were assessed. Additionally, the fractional concentration of exhaled nitric oxide (FeNO) was determined, and urine samples for the analysis of molecular species related to 8-hydroxy-2’-deoxyguanosine (8-OHdG) were taken. For statistical analysis, mixed ANOVA models were used.
Results: DLNO, DLCO, KNO, KCO and VA were reduced (p<0.001) after flights, mean±SD changes being 2.9±5.0, 3.2±5.2, 1.5±3.7, 1.9±3.7 and 1.4±3.1%, respectively, while FeNO decreased by 11.1% and the ratio of 8-OHdG to creatinine increased by 15.7±37.8%. The reductions of DLNO (DLCO) were smaller (p<0.001) than those of KNO (KCO). In repeated flights on different days, baseline values were restored. Among various flight parameters comprising Gz-forces and/or being indicative of positive pressure breathing and oxygenation support, the combination of long flight duration and high altitude appeared to be linked to greater changes in DLNO and DLCO.
Conclusions: The pattern of reductions in diffusing capacities suggests effects arising from atelectasis and increased diffusion barrier, without changes in capillary blood volume. The decrease in exhaled endogenous NO suggests bronchial mucosal irritation and/or local oxidative stress, and the increase in urinary oxidized guanosine species suggests systemic oxidative stress. Although changes were small and not clinically relevant, their presence demonstrated physiological effects of real training flights in a modern 4th generation fighter jet.
Publisher
Research Square Platform LLC
Reference40 articles.
1. Davis JR, Johnson R, Stepanek J, et al. Fundamentals of aerospace medicine: Wolters Kluwer Health Adis (ESP); 2011. p. 91.
2. G-induced loss of consciousness: retrospective survey results from 2259 military aircrew;Green NDC;Aviat Space Environ Med,2006
3. Oberstarzt Dr. med. Dipl.-Ing. H. Welsch (2005): Höhenphysiologische Aspekte bei der Einführung EF 2000 Eurofighter. 2. Internationales Höhensymposium. Flugmedizinisches Institut der Luftwaffe. Watzmann/Reiteralpe/Oberjettenberg, 8/11/2005. Available online at https://web.archive.org/web/20131224105335/http://www.uni-graz.at/alpinmedizin//Watzmann/Watzmann_14_VortrWELSCH.pdf, checked on 4/28/2023.
4. Short-term exposure to high-pressure ventilation leads to pulmonary biotrauma and systemic inflammation in the rat;Hoegl S;Int J Mol Med,2008
5. Prediction of high airway pressure using a non-linear autoregressive model of pulmonary mechanics;Langdon R;Biomed Eng Online,2017