Determinants of maximal oxygen uptake in severe acute hypoxia

doi:10.1152/ajpregu.00155.2002

Determinants of maximal oxygen uptake in severe acute hypoxia

J. A. L. Calbet¹^,², R. Boushel²^,³, G. Rådegran², H. Søndergaard², P. D. Wagner⁴, and B. Saltin²

¹ Department of Physical Education, University of Las Palmas de Gran Canaria, 35017 Las Palmas de Gran Canaria, Spain; ² The Copenhagen Muscle Research Centre, Rigshospitalet, 2200 Copenhagen N, Denmark; ³ Department of Exercise Science, Concordia University, Montreal, Quebec, Canada H4B 1R6; and ⁴ Department of Medicine, Section of Physiology, University of California San Diego, La Jolla, California 92093

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

To unravel the mechanisms by which maximal oxygen uptake ( $V$ O_2 max) is reduced with severe acute hypoxia in humans,nine Danish lowlanders performed incremental cycle ergometer exerciseto exhaustion, while breathing room air (normoxia) or 10.5% O₂in N₂ (hypoxia, ~5,300 m above sea level). With hypoxia, exercisePa_O₂ dropped to 31-34 mmHg and arterial O₂ content (Ca_O₂) wasreduced by 35% (P < 0.001). Forty-one percent of the reductionin Ca_O₂ was explained by the lower inspired O₂ pressure (PI_O₂)in hypoxia, whereas the rest was due to the impairment of thepulmonary gas exchange, as reflected by the higher alveolar-arterialO₂ difference in hypoxia (P < 0.05). Hypoxia caused a 47% decreasein $V$ O_2 max (a greater fall than accountable by reducedCa_O₂). Peak cardiac output decreased by 17% (P < 0.01), due toequal reductions in both peak heart rate and stroke volume (P< 0.05). Peak leg blood flow was also lower (by 22%, P < 0.01).Consequently, systemic and leg O₂ delivery were reduced by 43and 47%, respectively, with hypoxia (P < 0.001) correlating closelywith $V$ O_2 max (r = 0.98, P < 0.001). Therefore, three mainmechanisms account for the reduction of $V$ O_2 max in severeacute hypoxia: 1) reduction of PI_O₂, 2) impairment of pulmonarygas exchange, and 3) reduction of maximal cardiac output and peakleg blood flow, each explaining about one-third of the loss in $V$ O_2 max.

cardiac output; fatigue; performance; cardiovascular physiology

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

IN ACUTE HYPOXIA, maximal exercise capacity is reduced progressively as inspired O₂ tension falls (1, 19). It is generallyaccepted that this is due to a reduction in arterial oxygen content(Ca_O₂), caused by desaturation (24, 29, 44). At altitudesabove ~4,000 m, however, the reduction in the maximal oxygen uptake( $V$ O_2 max) and exercise capacity is substantially largerthan that expected only from the reduction in Ca_O₂ (1, 19),which implies that other mechanisms in addition to the loweredCa_O₂ contribute to the reduction in $V$ O_2 max. For example,alterations in the cardiovascular response to maximal exercisesuch as a reduced maximal cardiac output (CO) and/or changes inthe distribution of blood flow among the organs could also contributeto limit exercise capacity, especially in very severe acutehypoxia.

During submaximal exercise, even a substantial decrease in Ca_O₂ can be compensated for by counterbalancing increases of COand skeletal muscle blood flow such that O₂ delivery is maintained(17, 30, 31, 39, 49). At maximal exercise, however,systemic and muscular blood flow may be reduced depending on theexercise model and the degree of hypoxia (11). During wholebody exercise with moderate hypoxia (FI_O₂ ~0.12), maximal CO issimilar to that attained during normoxic exercise (21, 23,44). By comparison, a slightly greater level of hypoxia (FI_O₂= 0.11) results in a small decrease in maximal CO (30), seenwith two leg-knee-extension exercise, which recruits only themuscle mass of both quadriceps muscles. In contrast, peak CO isunaffected during normoxic two-legged knee-extension exercisewhen Ca_O₂ is reduced by other means (31) implying that Pa_O₂may influence the maximal pumping capacity of the heart separatelyfrom convective O₂ availability in severe acutehypoxia.

Similarly, during upright cycle ergometer exercise, maximal leg blood flow (LBF) is reported to be similar during normoxiaand moderate acute hypoxia (FI_O₂ = 0.12) (9, 29). Yet, recentstudies showed that a slightly greater level of hypoxia (FI_O₂= 0.11) reduced maximal LBF during exercise with the two leg-knee-extensionergometer (30). Thus, it is unknown whether severe acute hypoxiacauses a substantial reduction in maximal CO and LBF during wholebody exercise. Also of interest in this regard is whether thepartitioning of CO between locomotor muscles and other body tissuesis altered with severe acute hypoxia. One possibility is thatat maximal exercise in severe hypoxia, the fraction of the COdirected to the exercising muscles is enhanced to preserve O₂delivery to those tissues. In this case, leg vascular conductanceand/or perfusion pressure should increase. Alternatively, prioritycould be given to other tissues, which may require a higher bloodflow to maintain normal function when Ca_O₂ is dramatically reduced.If the latter occurs, leg vascular conductance should be decreased.Resolving these issues is critical to unraveling the mechanismsby which $V$ O_2 max is so dramatically affected by severeacutehypoxia.

Therefore, the purpose of this study was to examine oxygen transport and hemodynamic responses in humans during submaximaland maximal exercise under severe acute hypoxia. Special emphasiswas focused on the perfusion of locomotor muscles and, hence,muscular O₂ delivery at maximal exercise. Upright cycling exercisewas used to create a condition in which peripheral O₂ demand taxesthe maximal pumping capacity of the heart. To challenge O₂ deliveryto the central nervous system (CNS), we chose an FI_O₂ low enoughto reduce Pa_O₂ to 30-35 mmHg. This level of hypoxia is very closeto the limit that can be tolerated for a short time by an unacclimatizedhuman and is similar to that reported in resting altitude-acclimatizedsubjects at the summit of Mt. Everest (37). We hypothesizedthat during whole body exercise in severe acute hypoxia, maximaloxygen uptake is reduced by more than lowered Ca_O₂ (caused bydesaturation). It is further impaired by reduced peak CO and muscleblood flow. A reduction in maximal blood flow might be expectedif severe hypoxaemia impairs myocardial contractile function orinhibits the cardiovascular output drive from medullary vasomotornuclei.

	METHODS

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Subjects

Nine healthy, physically active, Danish lowlanders (5 males and 4 females) volunteered to participate in these studies. Theirmean (±SE) age, height, and weight were 24.3 ± 0.5 yr, 176 ± 3cm, and 74 ± 4 kg, respectively. Each subject's health statuswas assessed by a complete medical history and physical examination.All were normal in respect to resting ECG, liver, kidney, andthyroid functions, and fasting plasma glucose and electrolyteconcentrations. The iron status of both males and females wasalso normal, as reflected by blood hemoglobin concentrations (145± 4 and 124 ± 3 g/l) and plasma concentrations of ferritin (69± 19 and 22 ± 8 µg/l) and transferrin (31.3 ± 0.6 and 33.0 ± 1.4µmol/l, respectively). As a part of preliminary examinations,subjects performed a normoxic incremental exercise test to exhaustionon a cycle ergometer (120-W initial work rate increased by 40W every 1 min) and their $V$ O_2 max averaged 59 ± 2 ml ·kg¹ · min¹ (range: 49-62 ml · kg¹ · min¹) and 53 ± 4 ml · kg¹ · min¹ (range: 47-63 ml · kg¹ · min¹) in the males and females, respectively. These $V$ O_2 maxvalues are ~20% higher than those reported for the general Danishpopulation of similar age (3) but 20-30% lower than elite enduranceathletes. Experimental interventions were conducted in a hospitalunder medical supervision. All subjects were informed about theprocedures and risks of the study before giving written informedconsent to participate as approved by the Copenhagen and FredriksbergEthical Committee. The "Guiding Principles For Research InvolvingAnimals and Human Beings" of the American Physiological Societywere strictly followed (2).

Experimental Preparation

Two catheters (femoral artery and femoral vein) and a thermistor (femoral vein) were placed using sterile technique. Briefly,an 18-gauge, 20-cm-long catheter (Hydrocath, Ohmeda, Swindon,UK) was inserted percutaneously under local anesthesia (2% lidocaine)in the femoral vein of either the right or left leg using theSeldinger technique. This catheter was introduced 2 cm below theinguinal ligament and advanced 7 cm distally. The femoral veincatheter was used for venous sampling and downstream cold salineinjection. Subsequently, a thin polyethylene-coated thermistor(model 94-030-2.5F T. D. Probe, Edwards Edslab, Baxter, Irvine,CA) was inserted 3 cm below the inguinal ligament and advancedproximally 10 cm into the same femoral vein. A second 18-gaugecatheter was placed into the femoral artery 2 cm below the inguinalligament and advanced 14 cm proximally. The catheters and thermistorwere sutured to the skin to minimize the risk of movement. Bothcatheters were then connected to a three-way stopcock and fixedto facilitate easy access during the exercise. An additional catheterwas placed in a vein in the left upper arm for the injection ofthe Cardio-green dye for measurement of CO. After the catheterswere placed, the subjects rested in the supine position for 30min.

Experimental Design

All subjects participated previously in similar experiments during normoxia and hypoxia and were familiar with exercise onthe cycle ergometer. Subjects performed upright cycling exerciseat sea level (barometric pressure = 750-760 mmHg) breathing eitherroom air (normoxia) or air from a tank consisting of 10.5% O₂in nitrogen (hypoxia). Two different kinds of exercise were tested:submaximal constant intensity and incremental exercise on thecycle ergometer (Monark 824 E, Vadberg, Sweden) until exhaustion.Thirty minutes after catheterization, subjects sat on the cycleergometer and breathed through a two-way valve inspiring roomair or the hypoxic gas mixture, starting 5 min before restingmeasurements (Fig. 1). Subjects then performed the submaximalexercise bout, cycling at 102-141 W (at 80 revolution/min). Thisintensity corresponded to the highest intensity they could toleratefor 10 min when exercising in acute hypoxia (10). Measurementswere made at 6 and 10 min. Subsequently, after resting for 20-30min, incremental exercise was started with an initial intensityidentical to that used in the submaximal test, which was maintainedfor 2 min. Then the exercise intensity was increased by ~20-40W every min until reaching the maximal workload as determinedin the pretest. Load increments were adjusted such that the exerciseduration of the incremental exercise tests was ~6-7 min in allconditions. Normoxic and hypoxic submaximal exercise bouts wereadministered in random order. When submaximal hypoxic exercisewas performed first, the recovery periods were extended when needed,to allow venous blood lactate to reach similar values to thoseobserved at rest. After the submaxial exercise, the normoxic maximaltests were carried out and, then, after at least 1 h of rest inthe semirecumbent position breathing room air, the acute hypoxiatests were performed. Just at the end of the exercise with hypoxia,subjects were vigorously encouraged to keep pedalling while theywere switched to breathing room air. After 2 min at the peak workrate (Wmax) attained in the hypoxic trial, the workload was increasedagain in steps of 20-40 W until exhaustion.

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Fig. 1. Experimental protocol. Vertical arrows indicate the time points at which measurements were performed.

Although hypoxia was well tolerated by all subjects during exercise, this was not the case at rest. Some subjects experiencedexaggerated hyperventilation and paresthesias after 3 min of hypoxicbreathing, which were alleviated by the beginning of exercise.To minimize the risk of hypotension and loss of consciousness,ECG and intra-arterial blood pressure were monitored continuously.To avoid any interruption of blood pressure recordings, no bloodgas samples were taken at rest during hypoxia. However, in follow-upstudies, with more experience it was possible to obtain restingblood gas samples in the same conditions in six subjects of similarage and physical characteristics and results are reported in Table1. Hypoxia elicited a marked respiratory alkalosis at rest dueto exaggerated hyperventilation. Notably, just after 5 min ofhypoxic breathing, one subject reached an arterial pH of 7.65,with a Pa_CO₂ of 18 mmHg and a Pa_O₂ of 64 mmHg. As a consequence,he suffered paresthesias, carpal spasms, and dizziness that disappearedcompletely after interrupting the experiment and allowing himto return to normoxic breathing. It should be emphasized thenthat this level of hypoxia is very close to the limit that a humancan tolerate acutely at rest.

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Table 1. Femoral arterial and venous blood gases and acid-base balance at rest and during submaximal and maximal exercise during normoxia and severe acute hypoxia

Measurements

Respiratory variables. Pulmonary $V$ O₂, CO₂ production ( $V$ CO₂), and expired minute ventilation ( $V$ E) were measured with an on-line system (MedicalGraphics CPX, Saint Paul, Minneapolis, MN) while the subjectsbreathed through a low-resistance breathing valve and averagedevery 15 s. Gases with known $V$ O₂ and $V$ CO₂ concentration (micro-Scholander)were used for gas analyzercalibration.

Blood flow. Femoral venous blood flow (i.e., LBF) was measured in the femoral vein by constant-infusion thermodilution as described indetail elsewhere (4). Briefly, iced saline was infused throughthe femoral vein catheter at flow rates sufficient to decreaseblood temperature at the thermistor by 0.5-1°C. Infusate and bloodtemperature were measured continuously during saline infusion(Harvard pump, Harvard Apparatus, Millis, MA) via thermistorsconnected to the data-acquisition system (MacLab 16/s ADInstruments,Sydney, Australia). Infusate temperature was measured with a flow-throughhousing (model 93-505, Edslab) hooked to the venous catheter luer-lockport. At rest, saline infusions were continued for at least 60s, while during exercise, 15- to 20-s infusions were used untilfemoral vein temperature had stabilized at its new lower value.Blood flow was calculated on thermal balance principles, as detailedby Andersen and Saltin (4). Resting blood flow was measuredin triplicate and averaged. During submaximal exercise, bloodflow measurements were performed in duplicate at 6 and 9 min.The reported values represent the average of the four measurements.At peak effort, the measurements were made within 1 min of exhaustion.When possible, duplicate measurements of LBF and femoral arteriovenousO₂ differences were made during the brief period of peak exercise.Heart rate (HR), arterial blood pressure, pulmonary $V$ O₂, $V$ CO₂,and $V$ E were measured at the same time as LBF andCO.

Blood pressure and HR. Arterial blood pressure was monitored continuously by a disposable transducer (T100209A, Baxter, Unterschleissheim, Germany)placed at the level of the inguinal ligament. A three-lead ECGwas measured and displayed on a monitor during the experimentaland recovery phases. HR was obtained either from the pressurecurve or from the continuously recorded ECG. The blood pressuretransducer and the ECG electrodes were interfaced with a monitor(Dialogue 2000, Danica, Copenhagen, Denmark), which was, in turn,connected to the data-acquisition system. Systolic and diastolicarterial pressures were computed from the recorded pressure wave,as the maximum and minimum values registered in each cardiac cycle.Mean arterial blood pressure (MAP) was calculated as the integralof the pressure-wave curve over time. Average values correspondingto the blood flow measurement period were recorded for furthercalculations.

CO. CO was measured by indocyanine green (ICG; Akorn, IL) dye-dilution (15). Five to eight milligrams of dye were injected rapidlyinto the forearm vein followed by a 10-ml flush of isotonic saline.Blood from the femoral artery was withdrawn by a pump (Harvard,2202A) at 20 ml/min through a linear photodensitometer (WatersCO-10, Waters Instruments, Rochester, MN) for measurement of thearterial dye concentration. The withdrawn blood (~20 ml) was reinfusedafter each determination. The dye curves were displayed on a chartrecorder (Gould 8000) and extrapolated with a logarithmic scalebased on the exponential decay (downslope) observed from 75 to50% of the peak dye concentration to correct for recirculation.CO was then computed as the ratio of dye injected to the averagearterial ICG concentration over the time interval of the curveand expressed per minute. After each experiment, an ICG calibrationcurve was derived from measuring the deflection from three separate25-ml blood samples with varying concentrations ofICG.

Blood analysis. Blood hemoglobin concentration ([Hb]) and O₂ saturation (SO₂) were measured with a cooximeter (OSM 3 Hemoximeter, Radiometer,Copenhagen, Denmark). PO₂, PCO₂, and pH were determined with ablood gas analyzer (ABL 5, Radiometer, Copenhagen, Denmark) andcorrected for measured femoral vein blood temperature. From thesevalues, plasma HCO and actual baseexcess (BE) were determined as described by Siggaard-Andersen(43). As reduced hemoglobin has a higher buffer capacity thanfully oxygenated, BE was adjusted in each blood sample to fullyoxygenated Hb (BE_adj) (43). Hematocrit was determined by microcentrifugationon triplicate samples. Arterial and venous O₂ content (Ca_O₂ andCv_O₂) were computed from the saturation and [Hb] {i.e., (1.34[Hb]× SO₂) + (0.003 × PO₂)}. Plasma K⁺ and blood lactate and glucose were measured with an electrolytemetabolite analyzer (EML 105, Radiometer, Copenhagen, Denmark).Plasma norepinephrine and epinephrine concentrations were measuredby HPLC with electrochemical detection (20).

Calculations

Arteriovenous [O₂] difference (a- $V$ O₂diff) was calculated from the difference in femoral arterial and femoral venous [O₂].This difference was then divided by arterial concentration togive O₂ extraction. Oxygen delivery was computed as the productof blood flow and Ca_O₂. Leg $V$ O₂ was calculated as the productof LBF, and the a- $V$ O₂diff. Non-leg $V$ O₂ was computed as the differencebetween pulmonary $V$ O₂ and 2 × leg $V$ O₂. Leg plasma flow (LPF)was calculated as the product of LBF and (1 $-$ hematocrit). Leglactate and proton release were calculated as the product of LBFand the venous-arterial difference of lactate and BE_adj,respectively.

Statistical Analysis

Differences in the measured variables among conditions and exercise levels were analyzed with two-way ANOVA for repeated measures,with condition and exercise intensity as within-subjects factors.When F was significant in the ANOVA, planned pair-wise-specificcomparisons were carried out using Student's paired t-test adjustedfor multiple comparisons with the Bonferroni procedure. Simplelinear regression analysis was performed to determine linear relationsbetween variables. Significance was accepted at P < 0.05. Dataare reported as means ±SE.

	RESULTS

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Blood Gases and Acid-Base Status

Severe acute hypoxia markedly reduced femoral arterial and venous PO₂, O₂ saturations, and contents at rest and during submaximaland maximal exercise (Table 1). Acid-base balance was also affectedby hypoxia. Pa_O₂ and Pv_CO₂ were consistently lower during hypoxiathan normoxia (Table 1). In contrast, hypoxia attenuated theexercise-induced drop in arterial and venous pH, such that pHwas higher during hypoxia at submaximal and maximal exercise thanit was during normoxia. In addition, hypoxia elicited predictableincreases in arterial and venous pH at rest. Hypoxia also loweredplasma HCO₃ and base excess in the femoral artery and vein during submaximalexercise. At maximal exercise, however, base excess was less reducedwith hypoxia, whereas plasma HCO valueswere equal for two conditions (Table 1).

Hemodynamics and $V$ O₂

Submaximal exercise (~120 W). Pulmonary ventilation was 72% higher in hypoxia than in normoxia (Fig. 2A), resulting in higher $V$ CO₂ (2.2 ± 0.1 vs. 1.8 ±0.1 l/min, P < 0.001) and arterial pH (Table 1), as well as lowerarterial PCO₂ in hypoxia than in normoxia (Table 1). The alveolar-arterialPO₂ difference (A-aDO₂) was also increased from 7.1 ± 1.6 mmHgin normoxia to 22.2 ± 1.1 mmHg in hypoxia (Fig. 2C). Despite hyperventilation,Ca_O₂ was reduced by 35% during submaximal exercise with acutehypoxia (Table 1). Whole body (pulmonary) $V$ O₂ during both conditionswas similar (Fig. 2D) owing to the increases in CO (21%) and LBF(25%) in hypoxia (Fig. 3, A and B). The elevation in CO was broughtabout by an increase in HR from 132 ± 6 to 158 ± 4 beats/min (P< 0.001), whereas stroke volume (SV) was similar in normoxia andhypoxia (Fig. 3, C and E). Inasmuch as MAP was similar in bothconditions, the additional increase in systemic and LBF observedduring hypoxia was achieved entirely through 18 and 20% enhancementsof systemic and leg vascular conductances, respectively (Fig.3, D, F, and G). The increase in blood flow, however, was insufficientto offset the reduction in Ca_O₂, and, as a consequence, both systemicand leg O₂ delivery fell with hypoxia by 22 and 25%, respectively(Fig. 4, A and B). As expected, leg lactate and proton releasewere dramatically increased with hypoxia (from 0.05 ± 0.25 to3.01 ± 0.83 mmol/min and from 3.44 ± 1.53 to 5.97 ± 0.89 mmol/min,respectively) inducing a marked lactic acidosis (Table 1) thatlikely contributed to the observed 15% increase in O₂ extractionand the reduced amount of O₂ left in femoral venous blood duringhypoxia (Fig. 4, D and E). In fact, a significant inverse relationshipwas found between arterial pH and leg O₂ extraction during hypoxia(r = $-$ 0.70, P < 0.05).

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Fig. 2. Pulmonary ventilation ( $V$ E) and gas exchange. $V$ E, alveolar PO₂ (Pa_O₂), alveolar-arterial O₂ difference (A-aDO₂), and whole body oxygen uptake ( $V$ O₂) during submaximal and maximal exercise with normoxia ( $down-triangle$ ) and hypoxia ( $black-down-triangle$ ). * Significant differences between normoxia and hypoxia at the same absolute exercise intensity (P < 0.05). When maximal exercise values are compared, ¶ indicates significant differences between normoxia and hypoxia (P < 0.05).

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Fig. 3. Cardiovascular variables. Cardiac output ( $Q$ ), stroke volume (SV), heart rate (HR), 2-leg blood flow (2-LBF), mean arterial pressure (MAP), systemic vascular conductance (VC), and 2-leg VC during submaximal and maximal exercise with normoxia ( $down-triangle$ ) and hypoxia ( $black-down-triangle$ ). * Significant differences between normoxia and hypoxia at the same absolute exercise intensity (P < 0.05). When maximal exercise values are compared, ¶ indicates significant differences between normoxia and hypoxia (P < 0.05).

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Fig. 4. Oxygen transport and O₂ consumption. Systemic O₂ delivery, 2-leg O₂ delivery, femoral O₂ content arteriovenous difference (a-vO₂diff), whole body O₂ uptake (pulmonary $V$ O₂), 2-leg O₂ uptake (2-Leg $V$ O₂), leg O₂ extraction and O₂ content of the femoral venous blood (C_fvO₂) during submaximal and maximal exercise with normoxia ( $down-triangle$ ) and hypoxia ( $black-down-triangle$ ). * Significant differences between normoxia and hypoxia at the same absolute exercise intensity (P < 0.05). When maximal exercise values are compared, ¶ indicates significant differences between normoxia and hypoxia (P < 0.05).

Arterial and venous plasma norepinephrine concentrations were markedly elevated in acute hypoxia compared with normoxia. However,arterial and venous plasma epinephrine concentrations were similarin the two conditions (Fig. 5).

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Fig. 5. Plasma catecholamines. Arterial plasma norepinephrine (top) and epinephrine (bottom) concentrations during submaximal and maximal exercise with normoxia ( $down-triangle$ ) and hypoxia ( $black-down-triangle$ ). * Significant differences between normoxia and hypoxia at the same absolute exercise intensity (P < 0.05).

Maximal exercise. Maximal exercise capacity was substantially reduced with acute hypoxia. $V$ O_2 max decreased by 47% (from 4.10 ± 0.25to 2.18 ± 0.10 l/min) (Fig. 2D) and Wmax by 31% (from 298 ± 15to 206 ± 7 W). Peak exercise $V$ E was lower in hypoxia than innormoxia (122 ± 4 vs. 157 ± 8 l/min) (Fig. 2A) and the correspondingarterial plasma K⁺ as well (5.6 ± 0.1 and 6.0 ± 0.1 meq/l). However, the arterialpH was higher and the arterial PCO₂ was lower in hypoxia thanin normoxia (Table 1). The latter combined with the higher $V$ E/ $V$ O₂(57 ± 2 vs. 39 ± 1) and $V$ E/ $V$ CO₂ (40 ± 1 vs. 33 ± 1) in ratioin hypoxia indicates a relatively greater hyperventilatory responseto maximal exercise in hypoxia. However, as illustrated in Fig.2C, maximal exercise A-aDO₂ was higher in hypoxia than in normoxia(23.2 ± 0.7 vs. 16.6 ± 1.6 mmHg, P < 0.001) and was related tothe Pa_O₂ in normoxia (r = $-$ 0.95, P < 0.001) and hypoxia (r = $-$ 0.80,P < 0.01).

Peak CO and LBF were reduced by 17 and 22%, respectively, during acute hypoxia. The diminution in peak CO with hypoxia wasdue to the combined reductions in peak HR (8%) and SV (9%) (Fig.3, A, C, and D). CO, LBF, HR, and SV attained at exhaustion duringhypoxia were all similar to those observed at the same absoluteexercise intensity during normoxia (Fig. 3, A-C, and E). In hypoxia,MAP was lower than duringnormoxia both at exhaustion and at thesame absolute work intensity at which exhaustion occurred duringthe hypoxic trial (Fig. 3D).

At maximal exercise, systemic and two-leg vascular conductance was reduced. However, at the absolute load equal to the maximalload reached in hypoxia, vascular conductances were similar inhypoxia and normoxia (Fig. 3, F and G).

The combined decreases in peak blood flow and Ca_O₂ during hypoxia significantly reduced systemic and two-leg O₂ delivery (Fig.4, A and B). This reduction in O₂ delivery was only partiallyoffset by a 4% increase in O₂ extraction (Fig. 4D). Accordingly,peak whole body (pulmonary) and leg $V$ O₂ were reduced by 47 and45%, respectively (Fig. 2D and 4C). No significant differenceswere observed between hypoxia and normoxia for non-leg $V$ O₂.

Similar two-leg lactate and proton release were observed in both conditions. Arterial and venous plasma norepinephrine concentrationswere elevated similarly in acute hypoxia and normoxia at Wmax,as were those for epinephrine (Fig. 5). By contrast, at a similarabsolute load in normoxia at which the maximal effort was reachedin hypoxia, arterial and venous plasma catecholamine concentrationswere three to six times lower (Fig. 5).

Distribution of CO During Submaximal and Maximal Exercise

A similar proportion of CO was directed to the exercising legs during submaximal (70 ± 5 and 68 ± 5%) and maximal exercise(71 ± 4 and 76 ± 2%) in hypoxia and normoxia. Accordingly, themagnitude of the blood flow distributed to other vascular beds(non-LBF) was comparable during submaximal (5.0 ± 0.8 and 4.4± 0.6 l/min) and maximal exercise (5.7 ± 0.9 and 5.7 ± 0.6 l/min)in hypoxia and normoxia. The lumped vascular conductance throughtissues other than the legs (non-leg vascular conductance) wasalso similar during submaximal (46 ± 6 and 40 ± 7 ml/mmHg, n =7) and maximal exercise (49 ± 8 and 45 ± 5 ml/mmHg, n = 7) inhypoxia andnormoxia.

In normoxia, CO was closely related to exercise intensity (r = 0.84, P < 0.001), as was LBF (r = 0.77, P < 0.01), whereasno relationship was observed between either CO or LBF and exerciseintensity in hypoxia. As depicted in Fig. 6, there were closelinear relationships between mean leg $V$ O₂ and the mean leg O₂delivery during submaximal (r = 0.98, r = 0.95, P < 0.001) andmaximal exercise (r = 0.94, r = 0.97, P < 0.001) in normoxia andhypoxia, respectively.

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Fig. 6. Relationship between O₂ uptake and delivery. Relationship between 2-leg $V$ O₂ and 2-leg O₂ delivery during submaximal (top) and maximal (bottom) exercise with normoxia ( $down-triangle$ ; continuous line) and hypoxia ( $black-down-triangle$ ; dashed line). Note that the regression lines obtained in normoxia and hypoxia were similar suggesting that $V$ O₂ depends on O₂ delivery.

Hypoxia to Normoxia Transition at Wmax

Immediately before exhaustion at the hypoxic Wmax, seven subjects were asked to keep pedaling while they were switched tobreathing room air (normoxia). During the first 10-20 s, exerciseintensity declined slightly. However, after this transient phase,they could reach the target pedaling rate and the test was continuedby increasing the load by 20-40 W/min until exhaustion as performedduring the control incremental exercise in normoxia. At exhaustion,the intensity was 9% lower (P < 0.05) than that attained in thecontrol incremental exercise with normoxia. Despite this decreasein intensity, the values for CO, LBF, HR, SV, leg and systemicvascular conductance, leg O₂ delivery, leg fractional extractionof O₂, and leg $V$ O₂ were identical to those obtained at exhaustionduring the control incremental exercise withnormoxia.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The novel finding of this study was that a substantial proportion of the ~50% reduction of $V$ O_2 max in acute severehypoxia is attributed to a lower maximal CO and muscle blood flow.Previously, it has been shown that with more moderate acute hypoxiaequivalent to an altitude of ~4,000 m, CO at maximal exerciseis essentially similar to that at sea level (Table 2) (44).Thus, this study identifies a mechanism whereby $V$ O_2 maxin severe hypoxia is attenuated in excess of what previously wasexplained by the fall in arterial O₂ saturation and content (19).Our results show that although two-thirds of the reduction of $V$ O_2 max in acute severe hypoxia are accounted for by thefall in O₂ content, one-third of the reduction is due to a decreasein peak CO and muscle blood flow. It should be emphasized thatwe observed a close relationship between leg maximal O₂ deliveryand leg $V$ O_2 max, regardless of FI_O₂, which supports theconcept that during exercise with a large muscle mass, $V$ O_2 maxis limited largely by O₂ supply (7, 44). Furthermore, thelack of a significant alteration in the fractional distributionof blood flow between the locomotor skeletal muscles and the upperbody tissues suggests that CO is the primary determinant of LBFduring maximal exercise in normoxia, as well as in acute severehypoxia.

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Table 2. Systemic O₂ transport and gas exchange at maximal exercise measured during upright cycling with acute hypoxia equivalent to an altitude of 4,000 m (Stenberg et al., Ref. 44) and at 5,300 m (present study)

Attainment of Maximal Effort

In acute hypoxia, as well as in normoxia, the data suggest that subjects exercised to their limit since 1) similar high levelsof arterial and femoral venous lactate were reached at exhaustionin normoxia and hypoxia, 2) femoral venous O₂ tensions at maximalexercise with hypoxia were among the lowest reported for uprightcycling exercise (6-14 mmHg) (7, 44), 3) the rating of perceivedexertion was maximal in hypoxia and normoxia, 4) all tests wereperformed to exhaustion through vigorous verbal encouragement,and 5) all subjects had previously participated in high-altitudestudies and were very familiar with all theprocedures.

Effect of Severe Acute Hypoxia on Maximal CO

The mechanism responsible for the reduction in peak CO in severe acute hypoxia appears to be linked to low Pa_O₂. The reductionin CO experienced with severe acute hypoxia could be envisagedas a regulatory mechanism aimed at protecting either the heartitself or, more importantly, the CNS from hypoxic damage (38)due to the risk of increased desaturation at very high CO. Alternatively,hypoxia could limit the intrinsic pumping capacity of the heartand/or alter neuroendocrine regulation of vascular tone affectingpreload or afterload (i.e., a change in conductance in differentareas throughout the vascular system). A downregulation of maximalCO in acute hypoxia is supported by the fact that, at fatigue,Pa_O₂ and arterial hemoglobin saturation were very similar in allsubjects.

Desaturation in well-trained athletes during maximal exercise at sea level has been associated with, among other factors,a very high CO (13). Due to the sigmoid shape of the O₂ dissociationcurve of hemoglobin, a minimal reduction of lung mean transittime during hypoxia when arterial O₂ saturation lies on the steepposition of the O₂ dissociation curve, as occurred during maximalexercise in hypoxia (66% Sa_O₂), could cause a substantial decreaseof Pa_O₂ and Sa_O₂ (26). It has been shown that lung mean transittime is reduced as CO increases (22, 26). Under these circumstances,a further elevation in CO might result in no increase or, evenworse, a deterioration of systemic O₂ supply. If this hypothesisis true, maximal O₂ delivery in acute hypoxia will be attainedat a lower maximal CO than in normoxia. The downregulation ofmaximal CO was likely mediated by Pa_O₂ and presumably Ca_O₂- andSa_O₂-sensing mechanisms that adjust the output drive from cardiovascularnuclei in the CNS. At peak exercise with hypoxia, Pa_O₂ reached34mmHg.

Hypoxia can be sensed directly by sympathoexcitatory reticulospinal vasomotor neurons of the rostral ventrolateral reticularnucleus of the medulla (45), which initiate the integrated responseto hypoxia by activating neurons distributed elsewhere in theCNS. Consequently, sympathetic nerve activity and arterial bloodpressure are elevated and HR depressed by CNS hypoxia (12).The cardioinhibitory effect of hypoxia could have been also mediatedby activation of the peripheral chemoreceptors, which, throughthe release of nitric oxide, may attenuate the activation of presympatheticvasomotor neurons at the rostral ventrolateral medulla duringhypoxia (50).

This study shows a lower maximal HR during exercise in hypoxia, which could have been mediated by stimulation of medullarycardiovagal neurons by the low PO₂ values attained at exhaustion(40). In fact, in chronic hypoxia, maximal HR is substantiallydecreased but it can be restored to normoxic values by vagal blockadewith glycopyrrolate (10). In addition, this study shows thatduring maximal upright exercise in acute severe hypoxia, maximalSV is also reduced. The reason why SV was diminished at maximalexercise in acute hypoxia despite a small reduction in afterloadis not clear. Two mechanisms, however, could explain this phenomenon:an impairment of myocardial contractile function and/or lowerpreload caused by a reduction in venousreturn.

There were no indications in the present study to suggest an intrinsic impairment of the pumping capacity of the heart ora failure in neuroendocrine regulation of regional compliancesat maximal exercise in hypoxia. All subjects tolerated well theexercise tests and showed no unusual patterns in ECG or bloodpressure responses. The adrenergic response to maximal exercisein the present study was similar in hypoxia and normoxia as previouslyreported (28, 39), indicating a similar positive inotropicstimulation and presumably a similar sympathetic vasoconstrictordrive at maximal exercise in acute hypoxia and normoxia. Eventhough a reduced myocardial contractility in hypoxia cannot beruled out completely, impairment of left ventricular functionhas not been reported during maximal exercise at even higher levelsof hypoxia than in the present study (28, 37). Parallel studiesin which the same subjects exercised in acute hypoxia showed thatthe myocardium is capable of maintaining aerobic metabolism ateven greater simulated altitude (27). Moreover, at the end ofthe exercise with hypoxia when seven subjects were switched tobreathing room air, all of them were able to reach their maximalCO. The fact that maximal CO in hypoxia was rapidly enhanced bysimply increasing the FI_O₂ to 0.21 suggests that reoxygenationeither of the heart itself or of the CNS influences peak CO. Incontrast, the fact that it was possible to continue the incrementalexercise test with reoxygenation argues against a peripheral (muscularor metabolic) mechanism as the main cause of fatigue in severeacute hypoxia (25).

An alternative explanation for the decrease of maximal CO with acute hypoxia is an impairment of venous return and, hence,ventricular filling pressure. Several factors may influence venousreturn during exercise, such as central blood volume, body posture,cardiac aspirating effects, venous vascular tone (venous capacitance),MAP, the muscle pump, the respiratory pump, and CO itself (25).At maximal exercise during hypoxia in the present study, the actionof the respiratory and muscle pumps likely attenuated. In normoxia,a close relationship was observed between maximal CO and maximalexercise intensity. The action of the muscle pump increases withexercise intensity and exerts an important influence on venousreturn and CO (8, 14, 25, 42). One possibility is thatmuscular fatigue during exercise with hypoxia curtails increasesin power output, which, in turn, would limit the action of themuscle pump and ventricular filling. However, it is more likelythat hypoxia first attenuates increases in CO that limits muscleoxygen delivery and power output and, in turn, the muscle pumpand ventricular filling. In hypoxia, the mean values for CO andLBF at exhaustion were identical to those obtained at the sameabsolute intensity duringnormoxia.

Effect of Severe Acute Hypoxia on Maximal LBF

Despite a considerable body of research, the mechanisms that regulate maximal skeletal muscle blood flow during exercise remainelusive. Pioneer investigators showed that alterations in Ca_O₂induced by breathing hypoxic-hyperoxic gases or carbon monoxide,or by blood withdrawal or transfusion, are counterbalanced bychanges in CO, so that systemic O₂ delivery is maintained duringsubmaximal exercise (6, 16, 21). Likewise, LBF can be increasedto compensate for a reduction in Ca_O₂ elicited by acute hypoxia(29, 30, 41). Our results showing an increase in CO andLBF during submaximal exercise with acute hypoxia are in fullagreement with these earlier studies. On the other hand, in contrastto Knight et al. (29), who reported similar LBFs during maximalupright cycling exercise in normoxia and hypoxia, we observeda significant reduction in maximal LBF in acute hypoxia that closelyfollowed the decrease in maximal CO. This apparent discrepancyis likely due to the more severe hypoxia induced in the presentstudy. Although Knight et al. (29) used a FI_O₂ of 0.12, whichelicited a Pa_O₂ of 42 mmHg at exhaustion, we used a FI_O₂ of 0.105,which elicited a lower Pa_O₂ (34 mmHg) atexhaustion.

Although the mechanisms that regulate peak LBF during maximal exercise remain unclear, some experimental evidence points tothe existence of a tight coupling between maximal CO and peakmuscle blood flow during exhaustive exercise (5, 32, 35).For example, Pawelczyk et al. (35) reported a reduction of bothCO and LBF during maximal cycling exercise with $beta$ -blockade. Likewise,in patients with chronic heart failure, Magnusson et al. (32)observed a decrease in peak muscle blood flow during two-leg extensionexercise but not during one-leg extension exercise, suggestingthat when maximal pumping capacity of the heart was diminished,peak muscle blood flow was reduced. The present study adds furtherevidence along this line and demonstrates for the first time thatin severe acute hypoxia with a large muscle mass, peak LBF isreduced by an amount equal to the drop in maximal CO. The latterimplies that the amount of blood flow to upper body tissues wassimilar in normoxia and hypoxia, indicating that a lowered maximalCO cannot be compensated for by redistributing a greater proportionof blood to the active muscles at the expense of reducing bloodflow to noncontracting tissues in severe acutehypoxia.

Effect of Severe Acute Hypoxia on Pulmonary Gas Exchange

Pulmonary gas exchange was dramatically impaired during exercise in hypoxia lowering the Pa_O₂ from 47 at rest to 34 mmHg atmaximal exercise and the corresponding Sa_O₂ from 82 to 66%. AlveolarPO₂ during maximal exercise in normoxia was 120 mmHg, which, incase of a perfect pulmonary gas exchange (A-aDO₂ = 0), would haveelicited a Sa_O₂ of 98%. In the same conditions, an alveolar PO₂of 56 mmHg, as that observed at exhaustion in acute hypoxia, wouldhave corresponded to a Sa_O₂ of 86%. Therefore, 41% of the reductionin Ca_O₂ during maximal exercise in acute hypoxia could be explainedby the lower PI_O₂ and 59% by the impairment of pulmonary gas exchange.The drop in Sa_O₂ with hypoxia occurred despite substantial hyperventilation,which allowed for an elevation of Pa_O₂ (by 8 mmHg) from rest tomaximal exercise. This level of hyperventilation had a dramaticeffect on blood pH, which was 0.1 units higher at exhaustion inhypoxia than in normoxia. The impact of hyperventilation on Sa_O₂at maximal exercise in hypoxia is well illustrated in Fig. 7.With a higher pH, the hemoglobin O₂ dissociation curve was shiftedto the left in hypoxia, improving the level of Sa_O₂ for a givenPa_O₂ (Fig. 7). Applying the Hill's equation for O₂ saturationof hemoglobin, we calculated that had the arterial pH during maximalexercise in hypoxia been similar to that attained in normoxiathe Sa_O₂ would have only been 58%, i.e., 8% less than actuallyobserved (Fig. 7). However, maximal ventilation was 22% lowerduring maximal exercise in hypoxia, perhaps owing to excessiveelimination of CO₂, as corroborated by the low Pa_CO₂ and highpH observed at exhaustion, despite similar arterial blood lactateconcentrations in normoxia and hypoxia (33). The lower arterialplasma K⁺ concentration reached in hypoxia could have also attenuated theventilatory drive in this condition (34). Given the sigmoidshape of the hemoglobin O₂ dissociation curve, had the ventilatoryresponse in hypoxia been similar to that in normoxia, then a smalladditional enhancement of Pa_O₂ would have been possible and likely,a greater Sa_O₂ would have been reached in hypoxia.

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Fig. 7. Hemoglobin dissociation curve. Effect of acute hypoxia on the O₂ dissociation curve of the hemoglobin during exercise in normoxia ( $down-triangle$ ; fine line) and hypoxia ( $black-down-triangle$ ; thick line). Note the left shift caused by hyperventilation and its impact on Sa_O₂ at maximal exercise in hypoxia. Points in the graph represent the mean arterial or femoral venous values for each condition. (PO₂ values corrected for blood temperature.)

The widening of the A-aDO₂ reflects a lower efficiency of the gas exchange process in hypoxia than in normoxia, as supportedby the close relationship observed between A-aDO₂ and Pa_O₂ inboth conditions. According to the model of Piiper and Scheid (36),the process of gas exchange by diffusion in a homogeneous lungcan be described by the equation (Pa $-$ Pv)/(PA $-$ Pv) = 1 $-$ exp( $-$ D/ $beta$ $Q$ ),where Pa is arterial PO₂, Pv is mixed venous PO₂, PA is alveolarPO₂, D is O₂ pulmonary diffusing capacity, $beta$ is effective solubilitycoefficient of O₂ in blood (essentially the average slope of theO₂ hemoglobin dissociation curve), and $Q$ is CO. A high CO decreasesthe mean transit time across the alveolar capillaries (22) andcould be one of the factors explaining the increase of A-aOD₂with exercise intensity in both conditions, due to the reductionof the time available for diffusive equilibration. At maximalexercise, CO was lower in hypoxia and, thus per se, could notcontribute to reducing the ratio of D/( $beta$ $Q$ ) compared with normoxia.Because $beta$ was increased with hypoxia due to the lower Pa_O₂, whichconfined gas exchange to the steep region of the O₂ hemoglobindissociation curve, the impact of diffusion limitation on pulmonarygas exchange was probably considerable at the level of hypoxiaused in the present study, where Pa_O₂ fell below 50 mmHg (48).This is consistent with other results (18, 46-48). Ventilationmismatch, on the other hand, does not play a major role in severehypoxia (48).

In summary, during maximal exercise with a large muscle mass in severe acute hypoxia simulating an altitude ~5,300 m, $V$ O_2 maxis reduced by ~50%. Although at moderate altitudes the drop in $V$ O_2 max can be explained entirely by the reduction ofarterial O₂ content, this factor only accounts for about two-thirdsof the loss in $V$ O_2 max during maximal exercise with severeacute hypoxia. In addition, this study shows that three main mechanismsaccount for the reduction of $V$ O_2 max in severe acute hypoxia:1) the reduction of PI_O₂, 2) the impairment of pulmonary gas exchange,each explaining about one-half of the drop in arterial O₂ content,and 3) the reduction of maximal CO, with a corresponding decreasein peak LBF, explaining the remaining one-third of the loss in $V$ O_2 max. The reduction of maximal CO with severe acutehypoxia appears to be dependent on the level of hypoxemia, regardlessof arterial O₂ content. Taken together, these results highlightthe importance of O₂ delivery as a limiting factor for $V$ O_2 maxboth in normoxia andhypoxia.

	ACKNOWLEDGEMENTS

Special thanks are given to C. Nielsen, K. Hansen, and B. Jessen for excellent technical assistance and G. Ordway for insightfulcomments.

	FOOTNOTES

This study was supported by a grant from The Danish National Research Foundation (504-14). J. A. L. Calbet was on leave fromthe Department of Physical Education at the University of LasPalmas de GranCanaria.

Address for reprint requests and other correspondence: J. A. L. Calbet, Departamento de Educación Física, Campus Universitariode Tafira, 35017 Las Palmas de Gran Canaria, Canary Islands, Spain(E-mail: lopezcalbet{at}terra.es).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

First published October 3, 2002;10.1152/ajpregu.00155.2002

Received 11 March 2002; accepted in final form 27 September 2002.

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