F. Cibella et al., RESPIRATORY MECHANICS DURING EXHAUSTIVE SUBMAXIMAL EXERCISE AT HIGH-ALTITUDE IN HEALTHY HUMANS, Journal of physiology, 494(3), 1996, pp. 881-890
1. The present investigation was conducted to test the hypothesis that
the respiratory system is stressed more during exhaustive exercise in
chronic hypoxia than in normoxia. 2. Four healthy male subjects (aged
33-35 years) exercised on a cycle ergometer at 75% of the local maxim
um oxygen consumption (V-O2,V-max) until exhaustion, at sea level (SL)
and after a 1 month stay at 5050 m (HA). 3. Airflow at the mouth (V),
oesophageal (P-o) and gastric (P-g) pressures were measured at rest,
during exercise and recovery. Minute ventilation (V-E), respiratory po
wer (W-resp), respiratory frequency (f) and transdiaphragmatic pressur
e (P-di) were calculated from the measured variables. 4. The subjects'
mechanical power output of cycling at HE was 23.7% lower than at SL.
In spite of this reduction, time to exhaustion at HA was 55.3% less th
an at SL. V-E increased slightly during: exercise at SL, but showed a
marked increase at HA, and at the end of exercise at HE was 47.3% high
er than at SL. 5. Respiratory power increased more at HA than at XL (7
7.3% higher at the end of exercise) due to the increase in f needed to
sustain the high V-E. 6. Gastric pressure swings were negative at the
end of HA exercise but always positive at SL. The <(P)over bar (di)>
: <(P)over bar (o)> ratio reached values below 1 at HA but never at SL
. 7. These data seem to indicate that the respiratory system is stress
ed more during submaximal exercise at HA than at SL. We suggest that t
he exceedingly high V-E demand, requiring an excessive W-resp, may lea
d to fatigue of the diaphragm.