Bojahr Janina, Jörres Rudolf A, Kronseder Angelika, Weber Frank, Ledderhos Carla, Roiu Immanuel, Karrasch Stefan, Nowak Dennis, Teupser Daniel, Königer Christian
Institute and Outpatient Clinic for Occupational, Social and Environmental Medicine, Comprehensive Pneumology Center Munich (CPC-M), Member of the German Center for Lung Research (DZL), University Hospital, LMU Munich, Munich, Germany.
Federal Armed Forces Hospital, Lesserstr. 180, 22049, Hamburg, Germany.
Eur J Med Res. 2024 Feb 5;29(1):100. doi: 10.1186/s40001-024-01668-z.
Fighter aircraft pilots are regularly exposed to physiological challenges from high acceleration (G) 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 of a wide variety of exposure conditions, and their combinations.
Thirty-five pilots of the German Air Force performed 145 flights with the Eurofighter Typhoon. Prior to and after flight lung diffusing capacity for carbon monoxide (DL) and nitric oxide (DL), alveolar volume (V), and diffusing capacities per volume (K, K) were assessed. In addition, 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.
DL, DL, K, K and V 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 DL (DL) were smaller (p < 0.001) than those of K (K). In repeated flights on different days, baseline values were restored. Amongst various flight parameters comprising G-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 DL and DL.
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.
战斗机飞行员经常面临高加速度(G)力带来的生理挑战,以及支持系统中呼吸压力增加和氧气供应变化。我们研究了在包含各种暴露条件及其组合的实际训练飞行后,是否能检测到对肺部和全身氧化应激的影响。
35名德国空军飞行员驾驶欧洲台风战斗机进行了145次飞行。在飞行前后评估一氧化碳(DL)和一氧化氮(DL)的肺弥散能力、肺泡容积(V)以及每容积的弥散能力(K、K)。此外,测定呼出一氧化氮(FeNO)的分数浓度,并采集尿液样本分析与8-羟基-2'-脱氧鸟苷(8-OHdG)相关的分子种类。进行统计分析时使用混合方差分析模型。
飞行后DL、DL、K、K和V均降低(p < 0.001),平均±标准差变化分别为2.9±5.0%、3.2±5.2%、1.5±3.7%、1.9±3.7%和1.4±3.1%,而FeNO降低了11.1%,8-OHdG与肌酐的比值增加了15.7±37.8%。DL(DL)的降低幅度(p < 0.001)小于K(K)。在不同日期的重复飞行中,基线值得以恢复。在包括G力和/或表明正压呼吸及氧合支持的各种飞行参数中,长时间飞行和高海拔的组合似乎与DL和DL的更大变化有关。
弥散能力降低的模式表明肺不张和弥散屏障增加导致了这些影响,而毛细血管血容量未发生变化。呼出内源性NO的减少表明支气管黏膜受到刺激和/或局部氧化应激,尿中氧化鸟苷种类的增加表明全身氧化应激。尽管变化较小且与临床无关,但它们的存在证明了现代第四代战斗机实际训练飞行的生理影响。
