Is there a competition for oxygen availability between respiratory and limb muscles?

If a competition between the oxygen demands of limb and respiratory muscles happens, hypoxia may favor redistribution of blood flow from peripheral to respiratory muscles during heavy exercise. This hypothesis was tested in eighteen lowlanders and 27 highlanders at 4350m altitude. During an incremental exercise, the regional tissue oxygen saturation (rSO2) and tissue hemoglobin concentration ([Hbt]) of the intercostal muscles and vastus medialis were monitored simultaneously by NIRS. The intercostal and vastus medialis rSO2 values were lower at altitude than at sea level (-10%, p<0.001) and decreased similarly during incremental exercise (p<0.001) while [Hbt] values increased. At maximal exercise, the intercostal rSO2 was lower than the vastus medialis rSO2 in lowlanders (-7%, p<0.001). In highlanders the time patterns were similar but intercostal rSO2 was less decreased at exercise (p<0.05). Maximal exercise performed in hypoxia did not alter the kinetics of rSO2 and [Hbt] in peripheral muscles. These findings do not favor the hypothesis of blood flow redistribution.

Effects of ß2-adrenergic stimulation on exercise capacity in normal subjects.

ß2-Adrenergic receptor agonists are believed to present with ergogenic properties. However, how combined respiratory, cardiovascular and muscular effects of these drugs might affect exercise capacity remain incompletely understood. The effects of salbutamol were investigated in 23 healthy subjects. The study was randomised, placebo-controlled in double-blind and followed a cross-over design. Salbutamol was given at the dose of 10 µg/min in 11 subjects and 20 µg/min iv in the other 12 subjects. Measurements included muscle sympathetic nerve activity (MSNA), ventilatory responses to hyperoxic hypercapnia (7% CO(2) in O(2,) central chemoreflex), isocapnic hypoxia (10% O(2) in N(2), peripheral chemoreflex) and isometric muscle contraction followed by a local circulatory arrest (metaboreflex), cardiopulmonary exercise test (CPET) variables and isokinetic muscle strength. Salbutamol 10 µg/min increased heart rate and blood pressure, while MSNA burst frequency remained unchanged. Peripheral chemosensitivity increased, as evidenced by an increased ventilatory response to hypoxia, but ventilatory responses to hypercapnia or muscle ischaemia remained unchanged. The effects of salbutamol 20 µg/min were similar. Both doses of salbutamol did not affect CPET. Only the higher dose of salbutamol decreased the anaerobic threshold, but this was not associated with a change in VO(2) max. Salbutamol increased the slopes of ventilation as a function of VO(2) (P < 0.05) and VCO(2) (P < 0.001) during CPET. Maximal isokinetic muscle strength was not affected by salbutamol. In conclusion, the acute administration of either low or high dose salbutamol does not affect exercise capacity in normal subjects, in spite of an earlier anaerobic threshold and increased chemosensitivity.

Digoxin increases peripheral chemosensitivity and the ventilatory response to exercise in normal subjects.

1. The contribution of peripheral chemoreceptors to the regulation of ventilation during exercise remains incompletely understood. Digoxin has been reported to increase chemoreflex sensitivity in humans. In the present randomized, cross-over, double-blind study, we tested the hypothesis that this increases the ventilatory response to exercise in normal subjects, as assessed by changes in minute ventilation (V(E)) in response to the rate of CO(2) production (VCO(2)). 2. Minute ventilation, end-tidal PCO(2), pulse oximetric O(2) saturation (S(p)O(2)), heart rate and blood pressure (BP) were measured in 11 healthy young male untrained subjects after intravenous infusion of digoxin (0.01 mg/kg) or placebo during normoxia, isocapnic hypoxia and hyperoxic hypercapnoea. All participants underwent a maximum cardiopulmonary exercise test. 3. During normoxia, digoxin increased systolic BP only. During hypoxia, digoxin increased V(E) compared with placebo (P = 0.009) for the same fall in S(p)O(2) (P = NS). Moreover, no significant effects on ventilation and haemodynamic responses were recorded during hypercapnoea. Digoxin increased the V(E) /VCO(2) slope above the anaerobic threshold from 30.4 +/- 2.9 to 32.8 +/- 3.7 (P < 0.05), but did not affect VO(2max). 4. In conclusion, enhanced peripheral chemosensitivity with digoxin increases the ventilatory response to CO(2) production above the anaerobic threshold, but does not affect exercise capacity in healthy humans.

Differential effects of oral beta blockade on cardiovascular and sympathetic regulation.

In patients with hypertension, beta blockade decreases muscle sympathetic nerve activity (MSNA; micrographic technique) expressed in burst frequency (burst/min) but does not affect MSNA expressed in burst incidence (burst/100 heart beats), because reductions in blood pressure (BP) upon each diastole continue to deactivate the arterial baroreceptors, but at a slower heart rate (HR). We studied the effects of oral beta blockade on MSNA and baroreflex sensitivity (BRS) in normal participants. Bisoprolol (5 mg, 1 week) was administered in 10 healthy young adults, using a double-blind, placebo-controlled, randomized cross-over study design. The beat-to-beat mean RR interval (RR) and systolic blood pressure (SBP) series were analyzed by power spectral analysis and power computation over the very low frequency (VLF), low frequency, and high frequency (HF) bands. Baroreflex sensitivity was computed from SBP and RR cross-analysis, using time and frequency domain methods. Bisoprolol increased RR (P < .0005), decreased mean SBP and diastolic blood pressure values (P < .01), did not change the SBP and RR powers, except for RR power in VLF (P < .02) and SBP power in HF (P < .03). The MSNA variability (P > .13) and respiratory pattern (P = .84) did not change from placebo to bisoprolol condition. The bisoprolol-induced bradycardia was associated with higher burst/100 heart beats (P < .05) and bisoprolol did not affect burst/min (P = .80). Time domain BRS estimates were increased after bisoprolol (P < .05), while frequency domain ones did not change (P > .1). Oral bisoprolol induces differential effects on sympathetic burst frequency and incidence in normal participants. Peripheral sympathetic outflow over time is preserved as a result of an increased burst incidence, in the presence of a slower HR. Unchanged BP and HR and MSNA variability suggests that the larger burst incidence is not due to sympathetic activation.

Decreased ventilatory response to exercise by dopamine-induced inhibition of peripheral chemosensitivity.

The contribution of the peripheral chemoreflex to the ventilatory response to exercise and aerobic exercise capacity remains incompletely understood. Low-dose dopamine has been reported to specifically inhibit the peripheral chemoreceptors. We therefore investigated the effects of intravenous dopamine (3 microg kg(-1)min(-1)) on cardiopulmonary exercise test (CPET) variables in 13 healthy young male subjects. The study was prospective, placebo-controlled, and randomized with more than 24h between placebo and dopamine administrations. During the CPET, dopamine decreased the .V(E)/.V(CO2) output slope (24.61+/-1.84 vs. 23.09+/-1.81, placebo vs. Dopamine respectively, p=0.025), without affecting maximum workload, .V(E) and O(2) uptake. In conclusion, our study reveals that inhibition of peripheral chemoreflex function with dopamine decreases the .V(E)/.V(CO2) slope during dynamic exercise, with no change in aerobic exercise capacity.