ACCLIMATIZATION AND TOLERANCE TO EXTREME ALTITUDE

被引:23
作者
WEST, JB
机构
[1] Department of Medicine, University of California, La Jolla, California, 92093-0623, San Diego
来源
JOURNAL OF WILDERNESS MEDICINE | 1993年 / 4卷 / 01期
关键词
HYPOXIA; HYPERVENTILATION; MAXIMAL OXYGEN UPTAKE; RESPIRATORY ALKALOSIS; EXERCISE TOLERANCE; BAROMETRIC PRESSURE; SUPPLEMENTARY OXYGEN;
D O I
10.1580/0953-9859-4.1.17
中图分类号
R5 [内科学];
学科分类号
1002 ; 100201 ;
摘要
During the last ten years, two major experiments have elucidated the factors determining acclimatization and tolerance to extreme altitude (over 7000 m). These were the American Medical Research Expedition to Everest, and the low pressure chamber simulation, Operation Everest II. Extreme hyperventilation is one of the most important responses to extreme altitude. Its chief value is that it allows the climber to maintain an alveolar PO2 which keeps the arterial PO2 above dangerously low levels. Even so, there is evidence of residual impairment of central nervous system function after ascents to extreme altitude, and maximal oxygen consumption falls precipitously above 7000 m. The term 'acclimatization' is probably not appropriate for altitudes above 8000 m, because the body steadily deteriorates at these altitudes. Tolerance to extreme altitude is critically dependent on barometric pressure, and even seasonal changes in pressure probably affect climbing performance near the summit of Mt Everest. Supplementary oxygen always improves exercise tolerance at extreme altitudes, and rescue oxygen should be available on climbing expeditions to 8000 m peaks.
引用
收藏
页码:17 / 26
页数:10
相关论文
共 18 条
  • [1] West J.B., Human physiology at extreme altitudes on Mount Everest, Science, 223, pp. 784-788, (1984)
  • [2] Houston C.S., Sutton J.R., Cymerman A., Reeves J.T., Operation Everest II: man at extreme altitude, J Appl Physiol, 63, pp. 877-882, (1987)
  • [3] West J.B., Hackett P.H., Maret K.H., Milledge J.S., Peters R.M., Pizzo C.J., Winslow R.M., Pulmonary gas exchange on the summit of Mt Everest, J Appl Physiol: Respirat Environ Exercise Physiol, 55, pp. 678-687, (1983)
  • [4] Riley R.L., Houston C.S., Composition of alveolar air and volume of pulmonary ventilation during long exposure to high altitude, J Appl Physiol, 3, pp. 526-534, (1951)
  • [5] Rahn H., Otis A.B., Man's respiratory response during and after acclimatization to high altitude, Am J Physiol, 157, pp. 445-449, (1949)
  • [6] Schoene R.B., Lahiri S., Hackett P.H., Peters R.M., Milledge J.S., Pizzo C.J., Sarnquist F.H., Boyer S.J., Graber D.J., Maret K.H., West J.B., Relationship of hypoxic ventilatory response to exercise performance on Mt Everest, J Appl Physiol, 56, pp. 1478-1483, (1984)
  • [7] West J.B., High living: lessons from extreme altitude, Am Rev Respir Dis, 130, pp. 917-923, (1984)
  • [8] Reeves J.T., Groves B.M., Sutton J.R., Wagner P.D., Cymerman A., Malconian M.K., Rock P.B., Young P.M., Houston C.S., Operation Everest II: preservation of cardiac function at extreme altitude, J Appl Physiol, 63, pp. 531-539, (1987)
  • [9] Karliner J.S., Sarnquist F.H., Graber D.H., Peters R.M., West J.B., The electrocardiogram at extreme altitude: experience on Mt Everest, Amer Heart J, 109, pp. 505-513, (1985)
  • [10] Townes B.D., Hornbein T.F., Schoene R.B., Sarnquist F.H., Grant I., Human cerebral function at extreme altitude, High Altitude and Man, pp. 31-36, (1984)
12