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-Adrenergic or parasympathetic inhibition, heart rate and cardiac output during normoxic and acute hypoxic exercise in humans

Susan R. Hopkins, Harm J. Bogaard, Kyuichi Niizeki, Yoshiki Yamaya, Michael G. Ziegler and Peter D. Wagner

Acute hypoxia increases heart rate (HR) and cardiac output (Q˙_t) at a given oxygen consumption (_O2) during submaximal exercise. It is widely believed that the underlying mechanism involves increased sympathetic activation and circulating catecholamines acting on cardiac receptors. Recent evidence indicating a continued role for parasympathetic modulation of HR during moderate exercise suggests that increased parasympathetic withdrawal plays a part in the increase in HR and Q˙_t during hypoxic exercise. To test this, we separately blocked the -sympathetic and parasympathetic arms of the autonomic nervous system (ANS) in six healthy subjects (five male, one female; mean ± S.E.M. age = 31.7 ± 1.6 years, normoxic maximal _O2 (_O2,max) = 3.1 ± 0.3 l min^-1) during exercise in conditions of normoxia and acute hypoxia (inspired oxygen fraction = 0.125) to _O2,max. Data were collected on different days under the following conditions: (1)control, (2) after 8.0 mg propranolol I.V. and (3) after 0.8 mg glycopyrrolate I.V. Q˙_t was measured using open-circuit acetylene uptake. Hypoxia increased venous [adrenaline] and [noradrenaline] but not [dopamine] at a given _O2 (P < 0.05, P < 0.01 and P = 0.2, respectively). HR/_O2 and Q˙_t/_O2 increased during hypoxia in all three conditions (P < 0.05). Unexpectedly, the effects of hypoxia on HR and Q˙_t were not significantly different from control with either -sympathetic or parasympathetic inhibition. These data suggest that although acute exposure to hypoxia increases circulating [catecholamines], the effects of hypoxia on HR and Q˙_t do not necessarily require intact cardiac muscarinic and receptors. It may be that cardiac receptors play a primary role in elevating HR and Q˙_t during hypoxic exercise, or perhaps offer an alternative mechanism when other ANS pathways are blocked.

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