R. F. Grover scite author profile

The pulmonary hypertensive response to chronic hypoxia varies markedly among mammalian species. An explanation for this variability was sought by exposing seven species to hypobaric hypoxia (PB equal to 435 mmHg) for 19-48 days. Control animals were studied at 1,600 m (PB equal to 630 mmHg). The pulmonary hypertension that developed varied in the following order of decreasing severity: calf and pig (severe); rat and rabbit (moderate); sheep, guinea pig, and dog (mild). Right ventricular hypertrophy developed in proportion to the elevation in right ventricular systolic pressure. These interspecies variations in response were not correlated with the degree of arterial hypoxemia, degree of polycythemia, elevation in heart rate, or postnatal age. However, the medial thickness of the small pulmonary arteries in control animals was highly correlated with the development of pulmonary hypertension and right ventricular hypertrophy in hypoxic animals. Thus, the amount of lung vascular smooth muscle inherent within each species is a major determinant of the pulmonary hypertensive response to high altitude and contributes to the interspecies variability in this response.

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Control of breathing in Sherpas at low and high altitude

Hackett¹,

Reeves²,

Reeves³

et al. 1980

Journal of Applied Physiology

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Sherpas are well known for their physical performance at extreme altitudes, yet they are reported to have blunted ventilatory responses to acute hypoxia and relative hypoventilation in chronic hypoxia. To examine this paradox, we studied ventilatory control in Sherpas in comparison to that in Westerners at both low and high altitude. At low altitude, 25 Sherpas had higher minute ventilation, higher respiratory frequency, and lower end-tidal carbon dioxide tension than 25 Westerners. The hypoxic ventilatory response of Sherpas was found to be similar to that in Westerners, even though long altitude exposure had blunted the responses of some Sherpas. At high altitude, Sherpas again had higher minute ventilation and a tendency toward higher arterial oxygen saturation than Westerners. Oxygen administration increased ventilation further in Sherpas but decreased ventilation in Westerners. We conclude that Sherpas differ from other high-altitude natives; their hypoxic ventilatory response is not blunted, and they exhibit relative hyperventilation.

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Diffusing capacity of the lung in Caucasians native to 3,100 m

DeGraff¹,

Grover²,

Johnson³

et al. 1970

Journal of Applied Physiology

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Exercise ventilation correlates positively with ventilatory chemoresponsiveness

Martin¹,

Weil²,

Sparks³

et al. 1978

Journal of Applied Physiology

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To determine the relationship of ventilatory responsiveness to hypoxia and hypercapnia to exercise hyperpnea, these responses and steady-state exercise ventilation (VE) were measured in 16 athletes during light (1/3 VO2 max) and heavy (2/3 VO2 max) exercise. Both the hypoxic and hypercapnic ventilatory responses correlated positively with VE per unit metabolic rate (VE/VCO2) at both exercise levels (P less than 0.05). The contribution of the hypoxic response to normoxic exercise VE was quantified by comparing VE in normoxia to VE during a brief (1 min) exposure to high O2 (PAO2 = 200 Torr). High O2 reduced normoxic exercise VE by a mean of 20% at either exercise intensity. Among individuals this reduction was directly dependent upon the intensity of the hypoxic response, and ranged from 7 to 42% of normoxic VE. After the variable reduction of normoxic VE by hyperoxia, all correlations of ventilatory response with exercise VE were lost except for the correlation of hypercapnic response with heavy exercise VE/VCO2. These findings indicate that the extent of VE in light or heavy exercise is modified by the strength of the hypoxic ventilatory response, and that the hypercapnic response independently correlates with VE during heavy exercise.

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Infant birth weight is related to maternal arterial oxygenation at high altitude

Moore¹,

Rounds²,

Jahnigen³

et al. 1982

Journal of Applied Physiology

105

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Infant birth weight is reported to decrease at high altitude as a reulst of fetal growth retardation (McCullough, Reeves, and Liljegren. Arch. Environ, Health. 32: 36--39, 1977) but not all babies born at high altitude are small. We hypothesized that maternal characteristics acting to lower arterial O2 content would contribute to smaller infant birth weight. To test this hypothesis, we measured arterial oxygenation serially during pregnancy and again postpartum in 44 residents of Leadville, CO (elevation 3,100 m). We identified three maternal characteristics--ventilation, hemoglobin concentration, and smoking habits--that were related to the birth weight of the offspring. Mothers of smaller babies (less than 2,900 g) compared to mothers of larger babies (greater than 3,500 g) were characterized by hypoventilation, no change or a decrease in ventilation and arterial O2 saturation from early to late gestation, and a falling hemoglobin concentration that combined to lower arterial O2 content in the 3rd trimester. Maternal smoking at 3,100 m was associated with a two to threefold greater reduction in infant birth weight (-546 g) than reported from sea level. Thus, maternal arterial oxygenation during pregnancy may be important for predicting fetal growth retardation and the process of adaptation to high altitude.

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R. F. Grover

Lung vascular smooth muscle as a determinant of pulmonary hypertension at high altitude

Control of breathing in Sherpas at low and high altitude

Diffusing capacity of the lung in Caucasians native to 3,100 m

Exercise ventilation correlates positively with ventilatory chemoresponsiveness

Infant birth weight is related to maternal arterial oxygenation at high altitude

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