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Hypoxic ventilatory response during rest and exercise after a Himalayan expedition (1996)

Steinacker, J. M. ; Halder, A. ; Liu, Y. ; [et al.]

Springer

European journal of applied physiology 73 (1996), S. 202-209

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ISSN: 1439-6327

Keywords: Peripheral chemoreceptors ; Hypoxic ventilatory response ; Altitude acclimatization ; High altitude

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Hypoxic ventilatory response (HVR) was examined before and after acclimatization to high altitude. Transient hyperoxic switches according to Dejours's technique were used to examine the contribution of HVR to the hyperpnoea of increasing exercise intensities. Ten mountaineers were exposed to hypoxia (oxygen fraction in inspired gas,F 1O2 = 0.11, 79 mmHg) before the expedition and after return from altitude (56 days, 30 days at 4900 m or higher). After 25-min breathing hypoxic gas, the subjects performed a maximal cycle ergometer test (increments 50 W per 5 min). Respired gases and ventilation $$(\dot V_E )$$ were analysed breath-by-breath, partial pressure of oxygen (PO2) and oxygen saturation (SO2) were measured in capillary blood. The HVR was tested by switching two breaths to anF 1O2 of 1.0. The nadir of $$\dot V_E $$ after the switch was measured (decrease in ventilation, D $$\dot V_E $$ ). The HVR was expressed as the D $$\dot V_E $$ at a PO2 of 40 mmHg (D $$\dot V_{E40} $$ ) and the D $$\dot V_E $$ versus decrease ofSO2 (D $$\dot V_E $$ /[100 −SO2]). The HVR estimated by D $$\dot V_{E40} $$ increased from 19.9 to 28.01 · min−1 (median,P = 0.013). The HVR expressed as D $$\dot V_E $$ /(100 −SO2) at rest was no different before and after acclimatization (0.89 and 0.86 l · min−1 · %−1, respectively) and during exercise it did not change before the expedition (0.831 · min−1 %−1). However, D $$\dot V_E $$ /(100 −SO2) increased significantly with exercise intensity after the expedition (1.61 l · min−1 · %−1 at 200 W). The changes of D $$\dot V_E $$ versusSO2 as well as of D $$\dot V_E $$ versus $$\dot V_E $$ were steeper after the expedition than before. In summary, after return from 30 day at high altitude, an increased HVR was observed. The augmentation of HVR was evident at higher exercise intensities and we suggest that this reflects a change in sensitivity of the peripheral chemoreflex loop.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF02425477

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Lung diffusion capacity, oxygen uptake, cardiac output and oxygen transport during exercise before and after an Himalayan expedition (1996)

Steinacker, J. M. ; Liu, Y. ; Halder, A. ; [et al.]

Springer

European journal of applied physiology 74 (1996), S. 187-193

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ISSN: 1439-6327

Keywords: Hypoxia ; Exercise ; Rebreathing Alveolar-arterial difference ; Altitude acclimatization

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Studies were made of pulmonary diffusion capacity and oxygen transport before and after an expedition to altitudes at and above 4900 m. Maximum power (P max) and maximal oxygen uptake (VO 2max) were measured in 11 mountaineers in an incremental cycle ergometer test (25W · min−1) before and after return from basecamp (30 days at 4900 m or higher). In a second test, cardiac output (Q c) and lung diffusion capacity of carbon monoxide (D L,CO) were measured by acetylene and CO rebreathing at rest and during exercise at low, medium and submaximal intensities. After acclimatization, VO2max and P max decreased by 5.1% [from 61.0 (SD 6.2) to 57.9 (SD 10.2) ml·kg−1, n.s.] and 9.9% [from 5.13 (SD 0.66) to 4.62 (SD 0.42) W·kg−1, n.s.], respectively. The maximal cardiac index and DL,co decreased significantly by 15.6% [14.1 (SD 1.41) 1·min−1 · m−2 to 11.9 (SD 1.44)1·min−1 m−2, P〈0.05] and 14.3% [85.9 (SD 4.36)ml·mmHg−1 min−t to 73.6 (SD 15.2) ml · mmHg−1 -min−1, P〈0.05], respectively. The expedition to high altitude led to a decrease in maximal Q c, oxygen uptake and DL,CO. A decrease in muscle mass and capillarity may have been responsible for the decrease in maximal Qc which may have resulted in a decrease of D L,CO and an increase in alveolar-arterial oxygen difference. The decrease in D L,CO especially at lower exercise intensities after the expedition may have been due to a ventilation-perfusion mismatch and changes in blood capacitance. At higher exercise intensities diffusion limitation due to reduced pulmonary capillary contact time may also have occurred.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00376512

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