First-time imaging of effects of inspired oxygen concentration on regional lung volumes and breathing pattern during hypergravity

Purpose Aeroatelectasis can develop in aircrew flying the latest generation high-performance aircraft. Causes alleged are relative hyperoxia, increased gravity in the head-to-foot direction (+G z ), and compression of legs and stomach by anti-G trousers (AGT). We aimed to assess, in real time, the e...

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Published in:European journal of applied physiology 2015-02, Vol.115 (2), p.353-363
Main Authors: Borges, João Batista, Hedenstierna, Göran, Bergman, Jakob S., Amato, Marcelo B. P., Avenel, Jacques, Montmerle-Borgdorff, Stéphanie
Format: Article
Language:English
Subjects:
Adult
Altitude
Biomedical and Life Sciences
Biomedicine
Electrical impedance tomography
Gravity Suits
Human Physiology
Humans
Hypergravity
Hypergravity - adverse effects
Hyperoxia
Hyperoxia - physiopathology
Inhalation
Lung - drug effects
Lung - physiology
Male
Military aircraft
Noninvasive monitoring
Occupational Medicine/Industrial Medicine
Original Article
Oxygen - toxicity
Regions
Respiration
Sports Medicine
Tidal Volume
Tomography
Variance analysis
Ventilators
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Summary:Purpose Aeroatelectasis can develop in aircrew flying the latest generation high-performance aircraft. Causes alleged are relative hyperoxia, increased gravity in the head-to-foot direction (+G z ), and compression of legs and stomach by anti-G trousers (AGT). We aimed to assess, in real time, the effects of hyperoxia, +G z accelerations and AGT inflation on changes in regional lung volumes and breathing pattern evaluated in an axial plane by electrical impedance tomography (EIT). Methods The protocol mimicked a routine peacetime flight in combat aircraft. Eight subjects wearing AGT were studied in a human centrifuge during 1 h 15 min exposure of +1 to +3.5G z . They performed this sequence three times, breathing AIR, 44.5 % O 2 or 100 % O 2 . Continuous recording of functional EIT enabled uninterrupted assessment of regional lung volumes at the 5th intercostal level. Breathing pattern was also monitored. Results EIT data showed that +3.5G z , compared with any moment without hypergravity, caused an abrupt decrease in regional tidal volume (V T ) and regional end-expiratory lung volume (EELV) measured in the EIT slice, independently of inspired oxygen concentration. Breathing AIR or 44.5 % O 2 , sub-regional EELV measured in the EIT slice decreased similarly in dorsal and ventral regions, but sub-regional V T measured in the EIT slice decreased significantly more dorsally than ventrally. Breathing 100 % O 2 , EELV and V T decreased similarly in both regions. Inspired tidal volume increased in hyperoxia, whereas breathing frequency increased in hypergravity and hyperoxia. Conclusions Our findings suggest that hypergravity and AGT inflation cause airway closure and air trapping in gravity-dependent lung regions, facilitating absorption atelectasis formation, in particular during hyperoxia.
ISSN:1439-6319
1439-6327
1439-6327
DOI:10.1007/s00421-014-3020-9