Altitude and beta-blockade augment glucose utilization during submaximal exercise
To test the hypothesis that altitude exposure increases glucose utilization and that this increment is mediated by a beta-adrenergic mechanism, the effects of hypobaric hypoxia and beta-blockade on glucose rates of appearance (Ra), disappearance (Rd), oxidation (Rox), and leg uptake [G = 2(arteriovenous glucose difference)(1 - leg blood flow)] were measured during rest and a given submaximal exercise task. We studied six healthy beta-blocked (beta) men [26.7 +/- 1.2 (SE) yr, 74.0 +/- 6.6 kg] and five matched controls (C; 26 +/- 1.2 yr, 69.3 +/- 2.6 kg) in energy and nitrogen balance during rest and leg cycle-ergometer exercise at sea level, on acute altitude exposure to 4,300 m (barometric pressure = 463 Torr), and after 3 wk of habituation. Subjects received a primed continuous infusion of [6,6-2H]- and [1-13C]glucose, rested for > or = 90 min, and then immediately exercised for 45 min at 89 W, which elicited 49% of sea-level peak O2 consumption (VO2peak; 65% of altitude VO2peak). At sea level, resting Ra was 1.47 +/- 0.19 and 1.66 +/- 0.16 mg x kg-1 x min-1 for C and beta, respectively, and increased to 3.04 +/- 0.25 and 3.56 +/- 0.27 mg x kg-1 x min-1, respectively, during exercise. Thus glucose Ra was significantly increased by beta-blockade during rest and exercise at sea level. At sea level, beta-blockade increased leg G, which accounted for 49 and 69% of glucose disposal during exercise in C and beta, respectively. On acute altitude exposure, glucose Ra rose significantly during rest and exercise relative to sea level, whereas blockade continued to augment this increment. During exercise on acute exposure, G increased more than at sea level and accounted for a greater percentage (80 and 97%, respectively) of Rd in C and beta during exercise. Similarly, Rox values, particularly during exercise, were increased significantly at altitude relative to sea level, and beta-blockade potentiated this effect. During a given submaximal exercise task after acclimatization, glucose Ra, Rox, and G were increased relative to sea level, but these increments were less than those in response to exercise measured on acute exposure. We conclude that altitude exposure increases glucose use during rest and a given submaximal exercise bout and beta-blockade exaggerates the response.
Systemic hypertension at 4,300 m is related to sympathoadrenal activity
Residence at high altitude has been associated with elevation in systemic arterial blood pressure, but the time course has been little studied and the mechanism is unknown. Because plasma epinephrine (E) and norepinephrine (NE) also increase at altitude, we hypothesized that heightened sympathoadrenal activity may cause increased arterial pressure. We measured ambulatory blood pressure by cuff monitor in relation to 24-h urinary excretion of E and NE at sea level and during 3 wk of residence at 4,300 m (Pikes Peak, CO) in 11 healthy men. In five subjects taking placebo, arterial pressure progressively increased at 4,300 m from 82 +/- 1 (SE) mmHg at sea level to 88 +/- 3 on day 2, 91 +/- 3 on day 8, and 97 +/- 6 on day 17. In six subjects, propranolol (240 mg/day) decreased pressure from 85 +/- 4 to 77 +/- 1 mmHg at sea level but did not prevent sustained increase in pressure at 4,300 m (84 +/- 1, 81 +/- 1, and 85 +/- 3 mmHg on days 2, 8, and 17, respectively). Compared with the placebo group, blood pressure did not increase further over the initial elevation observed on day 2 in the propranolol group. There was interindividual variability in the blood pressure responses in both groups, with some subjects demonstrating a more marked increase in blood pressure. Urinary excretion of NE increased concomitantly with pressure at altitude in both groups, with a greater rise in the placebo group.(ABSTRACT TRUNCATED AT 250 WORDS)
Some human newborns have a syndrome characterized by irreversible pulmonary hypertension and severe hypoxemia and by medial hypertrophy and adventitial thickening of pulmonary arteries. We considered that newborn calves made severely hypoxic might reproduce features of the human disease. When 2-day-old calves were placed at 4,300 m simulated altitude, pulmonary arterial pressure was increased and could be reversed by 100% O2. However, after 2 wk at 4,300 m, pulmonary arterial pressures were suprasystemic and there was right-to-left shunting probably through the foramen ovale and a patent but restrictive ductus arteriosus. Suprasystemic pulmonary pressure and hypoxemia persisted with 100% O2 breathing. Morphometrical examination of the lung arteries showed a markedly thickened adventitia with cellular proliferation and collagen and elastin deposition. There was increased medial thickness and distal muscularization of the pulmonary arteries associated with decreased luminal diameter. The rapid development of severe pulmonary hypertension and poor responsiveness to O2 was associated with increased arterial wall thickness, particularly involving the adventitia. Thus the pulmonary arterial circulation in these calves, which were placed at high altitude for 2 wk, exhibited features resembling persistent pulmonary hypertension in newborn infants.
Hypoxic ventilatory responsiveness in Tibetan compared with Han residents of 3,658 m
Lifelong high-altitude residents of North and South America acquire blunted hypoxic ventilatory responses and exhibit decreased ventilation compared with acclimatized newcomers. The ventilatory characteristics of Himalayan high-altitude residents are of interest in the light of their reportedly lower hemoglobin levels and legendary exercise performance. Until recently, Sherpas have been the only Himalayan population available for study. To determine whether Tibetans exhibited levels of ventilation and hypoxic ventilatory drives that were as great as acclimatized newcomers, we compared 27 lifelong Tibetan residents of Lhasa, Tibet, China (3,658 m) with 30 acclimatized Han ("Chinese") newcomers matched for age, body size, and extent of exercise training. During room air breathing, minute ventilation was greater in the Tibetan than in the Han young men because of an increased respiratory frequency, but arterial O2 saturation and end-tidal PCO2 did not differ, indicating similar levels of effective alveolar ventilation. The Tibetan subjects had higher hypoxic ventilatory response shape parameter A values and hypercapnic ventilatory responsiveness than the Han subjects. Among the Han subjects, duration of high-altitude residence correlated with the degree of blunting of the hypoxic ventilatory drive. Paradoxically, hyperoxia (inspired O2 fraction 0.70) increased minute ventilation and decreased end-tidal PCO2 in the Tibetan but not in the Han men. We concluded that lifelong Tibetan residents of high altitude neither hypoventilated nor exhibited blunted hypoxic ventilatory responses compared with acclimatized Han newcomers, suggesting that the effects of lifelong high-altitude residence on ventilation and ventilatory response to hypoxia differ in Tibetan compared with other high-altitude populations.
Sympathetic and parasympathetic indicators of heart rate control at altitude studied by spectral analysis
The adaptive responses of the cardiovascular system to altitude appear to be dominated by increased sympathetic neural activity. We investigated the combined roles of the sympathetic and parasympathetic nervous systems (SNS and PNS, respectively) in the early (days 4-5) and subsequent (days 11-12) phases of acclimatization on Pike's Peak, CO (4,300 m), by spectral analysis of heart rate variability. Male subjects were randomly assigned to groups receiving oral propranolol (240 mg/day; n = 6) or a matched placebo (n = 3). On ascent to altitude, the high-frequency, fractal, and total spectral powers were reduced in the placebo group during days 4-5 and 11-12. At altitude during days 4-5, all three placebo group subjects increased SNS and decreased PNS activities compared with at sea level, and during days 11-12 SNS decreased and PNS increased compared with days 4-5. Relative to the placebo group, propranolol caused lengthening of the R-R interval; increases in high-frequency power, total spectral power, and the PNS indicator; and a decrease in the SNS indicator. Total spectral power tended to decrease at altitude, but there were no effects of altitude on PNS and SNS indicators in the propranolol group. The data from the placebo and propranolol groups suggest that both the PNS and SNS are involved in the elevated heart rate during the early phase of altitude acclimatization. Changes in heart rate variability during days 11-12 at altitude must be considered in light of the possible reductions in sympathetic receptor number noted in previous studies.
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