EXERCISE-INDUCED HYPOXEMIA IN ELITE ENDURANCE ATHLETES - INCIDENCE, CAUSES AND IMPACT ON VO2(MAX)

被引：49

作者：

POWERS, SK

MARTIN, D

DODD, S

机构：

[1] Center for Exercise Science, Departments of Exercise and Sport Sciences, Physical Therapy and Physiology, University of Florida, Gainesville, Florida, 32611

来源：

SPORTS MEDICINE | 1993年 / 16卷 / 01期

关键词：

D O I：

10.2165/00007256-199316010-00003

中图分类号：

G8 [体育];

学科分类号：

04 ; 0403 ;

摘要：

Arterial oxygenation is well maintained in healthy untrained or moderately trained individuals during exercise. In contrast, approximately 40 to 50% of healthy elite endurance athletes (cyclists and runners) demonstrate a significant reduction in arterial oxygenation during exercise at work rates approaching VO2max. The mechanism(s) to explain this exercise-induced hypoxaemia (EIH) remain controversial. However, hypoventilation and venoarterial shunt do not appear to be involved. By elimination, this suggests that ventilation-perfusion inequality and/or pulmonary diffusion limitations must contribute to EIH in this population. Theoretical and direct experimental evidence exists to support the notion that both ventilation-perfusion inequality and diffusion disequilibrium contribute to EIH; however, the relative contribution of each factor remains to be determined. In athletes who exhibit a profound EIH, the exercise-induced decline in arterial oxygenation results in a limitation of VO2max. Further, athletes who exhibit EIH at sea level suffer more severe gas exchange impairments during short term exposure to altitude than athletes or nonathletes who do not exhibit EIH at sea level. This finding explains much of the observed variance in the decline in VO2max among individuals during short term altitude or hypoxia exposure.

引用

页码：14 / 22

页数：9

共 47 条

[11]

Gale G., Torre-Bueno J., Moon R., Saltzman H., Wagner P., Ventilation-perfusion inequality in normal humans during exercise at sea level and simulated altitude, Journal of Applied Physiology, 58, pp. 978-988, (1985)

[12]

Gledhill N., Froese A., Buick F., Bryan A., Va/Q inhomogeneity in man during exercise: the effects of SF6 breathing, Journal of Applied Physiology, 45, pp. 512-515, (1978)

[13]

Gledhill N., Froese A., Dempsey J., Ventilation to perfusion distribution during exercise in health, Muscular exercise and the lung, pp. 325-343, (1977)

[14]

Gledhill N., Spriet L., Froese A., Wilkes D., Meyers E., Acid-base status with induced erythrocemia and its influence on arterial oxygenation during heavy exercise, Medicine and Science in Sports and Exercise, 12, (1980)

[15]

Hansen J., Casaburi R., Validity of ear oximetry in clinical exercise testing, Chest, 91, pp. 333-337, (1987)

[16]

Holmgren A., Linderholm H., Oxygen and carbon dioxide tensions of arterial blood during heavy and exhaustive exercise, Acta Physiologica Scandinavica, 44, pp. 203-215, (1958)

[17]

Lawler J., Powers S., Thompson Q., Linear relationship between maximal oxygen uptake and V̇O2max decrement during exposure to acute hypoxia, Journal of Applied Physiology, 64, pp. 1486-1492, (1988)

[18]

Martin D., Cicale M., Huang D., Mengelkoch L., Powers S., Incidence of exercise-induced hypoxemia in male endurance athletes, Abstract. Medicine and Science in Sports and Exercise, 24, (1992)

[19]

Martin D., O'Kroy J., Effects of acute hypoxia on V̇O2max of trained and untrained subjects, Journal of Sports Sciences, 11, pp. 37-42, (1992)

[20]

Martin D., Powers S., Cicale M., Collop N., Huang D., Et al., Validity of pulse oximetry during exercise in elite endurance athletes, Journal of Applied Physiology, 72, pp. 544-558, (1992)

← 1 2 3 4 5 →