Respiratory gas-exchange ratios during graded exercise in fed and fasted trained and untrained men

We evaluated the hypotheses that endurance training increasesrelative lipid oxidation over a wide range of relative exercise intensities in fed and fasted states and that carbohydrate nutrition causes carbohydrate-derived fuels to predominate as energy sources during exercise. Pulmonary respiratory gas-exchange ratios [(RER) = CO₂production/O₂ consumption(O₂)] were determinedduring four relative, graded exercise intensities in both fed andfasted states. Seven untrained (UT) men and seven category 2 and 3 US Cycling Federation cyclists (T) exercised in the morning in random order, with target power outputs of 20 and 40% peakO₂(O_{2 peak}) for 2 h,60% O_{2 peak} for 1.5 h, and 80%O_{2 peak} fora minimum of 30 min after either a 12-h overnight fast or 3 h after astandardized breakfast. Actual metabolic responses were 22 ± 0.33, 40 ± 0.31, 59 ± 0.32, and 75 ± 0.39%O_{2 peak}. T subjectsshowed significantly (P < 0.05)decreased RER compared with UT subjects at absolute workloads when fedand fasted. Fasting significantly decreased RER values compared withthe fed state at 22, 40, and 59%O_{2 peak} inT and at 40 and 59%O_{2 peak} in UTsubjects. Training decreased (P < 0.05) mean RER values compared with UT subjects at 22%O_{2 peak} when theyfasted, and at 40%O_{2 peak} when fed orfasted, but not at higher relative exercise intensities in eithernutritional state. Our results support the hypothesis that endurancetraining enhances lipid oxidation in men after a 12-h overnight fast at low relative exercise intensities (22 and 40%O_{2 peak}). However, atraining effect on RER was not apparent at high relative exercise intensities (59 and 75%O_{2 peak}). Becausemost athletes train and compete at exercise intensities >40% maximalO₂, they will not oxidize agreater proportion of lipids compared with untrained subjects,regardless of nutritional state.     

Thermal drive contributes to hyperventilation during exercise in sheep

The etiology of exercise hypocapnia is unknown.The contributions of exercise intensity (ExInt), lactic acid,environmental temperature, rectal temperature(T_re), and physicalconditioning to the variance in arterialCO₂ tension(Pa_CO2) in the exercising sheep werequantified. We hypothesized that thermal drive contributes tohyperventilation. Four unshorn sheep were exercised at ~30, 50, and70% of maximal O₂ consumption for30 min, or until exhaustion, both before and after 5 wk of physicalconditioning. In addition, two of the sheep were shorn and exercised ateach intensity in a cold (<15°C) environment.T_re andO₂ consumption were measured continuously. Lactic acid and Pa_CO2 weremeasured at 5- to 10-min intervals. Data wereanalyzed by multiple regression onPa_CO2. During exercise,T_re rose andPa_CO2 fell, except at the lowest ExIntin the cold environment. T_reexplained 77% of the variance in Pa_CO2,and ExInt explained 5%. All other variables were insignificant. Weconclude that, in sheep, thermal drive contributes to hyperventilation during exercise.

     

The Effect of Pedal Rate and Time of Day on the Time to Exhaustion from High‐Intensity Exercise

The aim of this study was to examine the supposed influence of pedal rate on the diurnal fluctuation of the time to exhaustion from high‐intensity exercise. Eleven male cyclists performed three tests at 06:00 h and three at 18:00 h at a free pedal rate (FPR) and two imposed pedal rates (80% and 120% of the FPR). They performed the tests until exhaustion using a power output corresponding to 95% maximal power (P_max). Time to exhaustion, rectal temperature, oxygen consumption (V˙O₂), M. quadriceps, vastus medialis, M. biceps femoris electromyographic Root Mean Square activity rise (RMS slope), and blood lactate concentration were measured. The mean time to exhaustion recorded at 18:00 h (270.6±104.8 sec) was greater than at 06:00 h (233.9±84.9 sec). The time to exhaustion was significantly greater when the pedal rate was imposed at 80% versus 120% FPR. The blood lactate concentration and absolute core temperature at the point of exhaustion were significantly higher during tests done at 18:00 h. There was no diurnal variation in core temperature increase, V˙O₂, and RMS slope. The time‐of‐day effect for every variable did not depend on pedal rate. Diurnal variations in maximal aerobic endurance cannot be explained by a change in aerobic metabolism or in muscular fatigue. The origin of the diurnal variation in the time to exhaustion is likely to lie in greater participation in anaerobic metabolism. Also, the influence of temperature on neuromuscular functioning as an explanation for the diurnal variation in performance cannot be excluded in this study. The hypothesis on the basis of which pedal rate would influence diurnal variations in time to exhaustion in cycling was not validated by this research.     

Abnormal oxygen uptake kinetic responses in women with type II diabetes mellitus

Persons with type II diabetes mellitus(DM), even without cardiovascular complications have a decreasedmaximal oxygen consumption (O_{2 max}) andsubmaximal oxygen consumption(O₂) duringgraded exercise compared with healthy controls. Weevaluated the hypothesis that change in the rate ofO₂ in response to the onsetof constant-load exercise (measured byO₂-uptakekinetics) was slowed in persons with type II DM. Ten premenopausalwomen with uncomplicated type II DM, 10 overweight, nondiabeticwomen, and 10 lean, nondiabetic women had aO_{2 max} test. On twoseparate occasions, subjects performed 7-min bouts of constant-loadbicycle exercise at workloads below and above the lactate threshold toenable measurements of O₂kinetics and heart rate kinetics (measuring rate of heart rate rise).O_{2 max}was reduced in subjects with type II DM compared with both lean andoverweight controls (P < 0.05).Subjects with type II DM had slowerO₂ and heart rate kineticsthan did controls at constant workloads below the lactate threshold.The data suggest a notable abnormality in the cardiopulmonary responseat the onset of exercise in people with type II DM. The findings mayreflect impaired cardiac responses to exercise, although an additional defect in skeletal muscle oxygen diffusion or mitochondrial oxygen utilization is also possible.

     

Gas Exchange of the Avian Egg Time, Structure, and Function

Data are presented for oxygen consumption water loss duringincubation water vapor conductance of the shell and pore numberof avian eggs and the way in which these values relate not onlyto egg mass but also to incubation time. It is proposed thatall these functions are proportional to the product of egg massand rate of development where the latter is defined as the inverseof incubation time. These interrelationships account at theend of incubation for similar O₂ and CO₂ tensions in the airspace of eggs utilization of calories (0.5 kcal g^–1) andwater loss (15 g g^–1)     

A moderate glycemic meal before endurance exercise can enhance performance

Kirwan, John P., Donal O'Gorman, and William J. Evans.A moderate glycemic meal before endurance exercise can enhance performance. J. Appl. Physiol. 84(1):53-59, 1998.The purpose of this study was to determine whetherpresweetened breakfast cereals with various fiber contents and amoderate glycemic index optimize glucose availability and improveendurance exercise performance. Six recreationally active women ate 75 g of available carbohydrate in the form of breakfast cereals: sweetenedwhole-grain rolled oats (SRO, 7 g of dietary fiber) or sweetenedwhole-oat flour (SOF, 3 g of dietary fiber) and 300 ml of water orwater alone (Con). The meals were provided 45 min before semirecumbentcycle ergometer exercise to exhaustion at 60% of peakO₂ consumption (O_{2 peak}). Diet andphysical activity were controlled by having the subjects reside in theGeneral Clinical Research Center for 2 days before each trial. Bloodsamples were drawn from an antecubital vein for glucose, free fattyacid (FFA), glycerol, insulin, epinephrine, and norepinephrinedetermination. Breath samples were obtained at 15-min intervals aftermeal ingestion and at 30-min intervals during exercise. Muscle glycogenconcentration was determined from biopsies taken from the vastuslateralis muscle before the meal and immediately after exercise. PlasmaFFA concentrations were lower (P < 0.05) during the SRO and SOF trials for the first 60 and 90 min ofexercise, respectively, than during the Con trial. Respiratory exchangeratios were higher (P < 0.05) at 90 and 120 min of exercise for the SRO and SOF trials, respectively, than for the Con trial. At exhaustion, glucose, insulin, FFA, glycerol, epinephrine, and norepinephrine concentrations, respiratory exchange ratio, and muscle glycogen use in the vastus lateralis muscle weresimilar for all trials. Exercise time to exhaustion was 16% longer(P < 0.05) during the SRO thanduring the Con trial: 266.5 ± 13 and 225.1 ± 8 min,respectively. There was no difference in exercise time for the SOF(250.8 ± 12) and Con trials. We conclude that eating ameal with a high dietary fiber content and moderate glycemic index 45 min before prolonged moderately intense exercise significantly enhancesexercise capacity.

     

The Development of Fast-Start Performance in Fishes: Escape Kinematics of the Chinook Salmon (Oncorhynchus tshawytscha)

C-starts are high acceleration swimming movements critical forpredator avoidance by fishes. Since larval fishes are particularlyvulnerable to predation, C-start behavior is likely to be especiallyimportant during early life history stages. This paper examinesthe developmental changes in C-start performance with kinematicdata on immature chinook salmon (Oncorhynchus tshawytscha) (eleuthroembryostage, sensu Balon, 1975). The scaling of C-start kinematicsof immature fishes differs from that of adults. Adult C-startdurations increase with increasing body length while C-startdurations of immature fishes decrease (e.g., adult stage 1 duration[sec] = 0.0019.length [L] [cm] $ 0.026 [R² = 0.77] [Webb, 1978];eleuthroembryos stage 1 duration [sec] = –0.026L [cm]$ 0.100 [R² = 0.81]). Distance traveled during stage 2 alsodiffers between adult and immature fishes. Adult distance traveledscales directly with length (distance [cm] = 0.38L^1.01 [cm],R² = 0.96 [Webb, 1978]) while chinook eleuthroembryo distancetraveled is positively allometric with length (distance [cm]=0.37L¹³¹ [cm], R² = 0.83). There are similarities in the developmentof C-starts and burst swimming. For example, mean velocity scalessimilarly between the two locomotor modes (For burst swimming:U_mean [cm/sec] = 8.1 ± 1.1L [cm] $ 4.89 [R² = 0.86] [Webband Corolla, 1981]. For C-start stage 2: U_mean [cm/sec] = 10.96L[cm] - 14.09 [R² = 0.70]). This study demonstrates that C-startescape performance improves during early post-hatching development.Comparisons of immature chinook salmon fast-starts with dataon larval burst swimming and on adult C-starts suggest thatchanges specific to developing fish affect the scaling of kinematicparameters.     

Nitric oxide response in exhaled air during an incremental exhaustive exercise

Chirpaz-Oddou, M. F., A. Favre-Juvin, P. Flore, J. Eterradossi, M. Delaire, F. Grimbert, and A. Therminarias. Nitric oxide response in exhaled air during an incremental exhaustive exercise. J. Appl. Physiol. 82(4):1311-1318, 1997.This study examines the response of the exhalednitric oxide (NO) concentration (CNO) and the exhaled NOoutput(NO)during incremental exercise and during recovery in six sedentary women,seven sedentary men, and eight trained men. The protocolconsisted of increasing the exercise intensity by 30 W every 3 minuntil exhaustion, followed by 5 min of recovery. Minute ventilation(E), oxygen consumption (O₂), carbon dioxideproduction, heart rate, CNO, andNOwere measured continuously. TheCNO in exhaled air decreasedsignificantly provided that the exercise intensity exceeded 65% of thepeak O₂. It reached similarvalues, at exhaustion, in all three groups. TheNO increasedproportionally with exercise intensity up to exhaustion and decreasedrapidly during recovery. At exhaustion, the mean values weresignificantly higher for trained men than for sedentary men andsedentary women. During exercise,NOcorrelates well with O₂,carbon dioxide production, E, and heartrate. For the same submaximal intensity, and thus a givenO₂ and probably a similarcardiac output,NO appearedto be similar in all three groups, even if theE was different. These results suggestthat, during exercise,NO is mainlyrelated to the magnitude of aerobic metabolism and that thisrelationship is not affected by gender differences or by noticeabledifferences in the level of physical training.

     

Comparison of femoral blood gases and muscle near-infrared spectroscopy at exercise onset in humans

We hypothesized that near-infrared spectroscopy(NIRS) measures of hemoglobin and/or myoglobinO₂ saturation(IR-SO₂)in the vascular bed of exercising muscle would parallel changes infemoral venous O₂ saturation(Sfv_O2)at the onset of leg-kicking exercise in humans. Six healthy subjectsperformed transitions from rest to 48 ± 3 (SE)-W two-legged kickingexercise while breathing 14, 21, or 70% inspiredO₂.IR-SO₂ wasmeasured over the vastus lateralis muscle continuouslyduring all tests, and femoral venous and radial artery blood sampleswere drawn simultaneously during rest and during 5 min of exercise. Inall gas-breathing conditions, there was a rapid decrease in bothIR-SO₂ andSfv_O2 at the onset of moderate-intensityleg-kicking exercise. Although Sfv_O2 remained atlow levels throughout exercise,IR-SO₂increased significantly after the first minute of exercise in bothnormoxia and hyperoxia. Contrary to the hypothesis, these data showthat NIRS does not provide a reliable estimate of hemoglobinand/or O₂ saturation asreflected by direct femoral vein sampling.     

O2 extraction maintains O2 uptake during submaximal exercise with beta -adrenergic blockade at 4,300m

Wholebody O₂ uptake (O₂)during maximal and submaximal exercise has been shown to be preservedin the setting of -adrenergic blockade at high altitude, despitemarked reductions in heart rate during exercise. An increase in strokevolume at high altitude has been suggested as the mechanism thatpreserves systemic O₂ delivery (blood flow × arterialO₂ content) and thereby maintains O₂ at sea-level values. To test thishypothesis, we studied the effects of nonselective -adrenergicblockade on submaximal exercise performance in 11 normal men(26 ± 1 yr) at sea level and on arrival and after 21 days at 4,300 m. Six subjects received propranolol (240 mg/day), and five subjectsreceived placebo. At sea level, during submaximal exercise, cardiacoutput and O₂ delivery were significantly lower inpropranolol- than in placebo-treated subjects. Increases instroke volume and O₂ extraction were responsible for themaintenance of O₂. At 4,300 m,-adrenergic blockade had no significant effect onO₂, ventilation, alveolarPO₂, and arterial blood gases duringsubmaximal exercise. Despite increases in stroke volume, cardiac outputand thereby O₂ delivery were still reduced inpropranolol-treated subjects compared with subjects treated withplacebo. Further reductions in already low levels of mixed venousO₂ saturation were responsible for the maintenance ofO₂ on arrival and after 21 days at4,300 m in propranolol-treated subjects. Despite similarworkloads and O₂,propranolol-treated subjects exercised at greater perceived intensitythan subjects given placebo at 4,300 m. The values for mixed venousO₂ saturation during submaximal exercise inpropranolol-treated subjects at 4,300 m approached thosereported at simulated altitudes >8,000 m. Thus -adrenergicblockade at 4,300 m results in significant reduction in O₂delivery during submaximal exercise due to incomplete compensation bystroke volume for the reduction in exercise heart rate. Total bodyO₂ is maintained at a constant levelby an interaction between mixed venous O₂ saturation, thearterial O₂-carrying capacity, and hemodynamics duringexercise with acute and chronic hypoxia.

     

Caffeine, performance, and metabolism during repeated Wingate exercise tests

Investigations examining the ergogenicand metabolic influence of caffeine during short-term high-intensityexercise are few in number and have produced inconsistent results. Thisstudy examined the effects of caffeine on repeated bouts ofhigh-intensity exercise in recreationally active men. Subjects(n = 9) completed four 30-s Wingate(WG) sprints with 4 min of rest between each exercise bout on twoseparate occasions. One hour before exercise, either placebo (Pl;dextrose) or caffeine (Caf; 6 mg/kg) capsules were ingested. Caf ingestion did not have any effect on poweroutput (peak or average) in the first two WG tests and had a negative effect in the latter two exercise bouts. Plasmaepinephrine concentration was significantly increased 60 min after Cafingestion compared with Pl; however, this treatment effect disappearedonce exercise began. Caf ingestion had no significant effect on bloodlactate, O₂ consumption, oraerobic contribution at any time during the protocol. After the secondWingate test, plasma NH₃concentration increased significantly from the previous WG test and wassignificantly higher in the Caf trial compared with Pl. These datademonstrate no ergogenic effect of caffeine on power output duringrepeated bouts of short-term, intense exercise. Furthermore, there was no indication of increased anaerobic metabolism after Caf ingestion with the exception of an increase inNH₃ concentration.

     

The VO2 slow component for severe exercise depends on type of exercise and is not correlated with time to fatigue

The purpose ofthis study was to examine the influence of the type of exercise(running vs. cycling) on the O₂uptake (O₂) slow component.Ten triathletes performed exhaustive exercise on a treadmill and on acycloergometer at a work rate corresponding to 90% of maximalO₂ (90% work rate maximalO₂). The duration of thetests before exhaustion was superimposable for both type of exercises(10 min 37 s ± 4 min 11 s vs. 10 min 54 s ± 4 min 47 s forrunning and cycling, respectively). TheO₂ slow component (difference between O₂ atthe last minute and minute 3 ofexercise) was significantly lower during running compared with cycling(20.9 ± 2 vs. 268.8 ± 24 ml/min). Consequently, there was norelationship between the magnitude of theO₂ slow component and thetime to fatigue. Finally, because blood lactate levels at the end of the tests were similar for both running (7.2 ± 1.9 mmol/l) and cycling (7.3 ± 2.4 mmol/l), there was a clear dissociation between blood lactate and the O₂slow component during running. These data demonstrate that1) theO₂ slow component dependson the type of exercise in a group of triathletes and2) the time to fatigue isindependent of the magnitude of theO₂ slow component and bloodlactate concentration. It is speculated that the difference in muscularcontraction regimen between running and cycling could account for thedifference in theO₂ slow component.

     

Effect of prolonged, heavy exercise on pulmonary gas exchange in athletes

During maximalexercise, ventilation-perfusion inequality increases, especially inathletes. The mechanism remains speculative. Wehypothesized that, if interstitial pulmonary edema is involved, prolonged exercise would result in increasing ventilation-perfusion inequality over time by exposing the pulmonary vascular bed to highpressures for a long duration. The response to short-term exercise wasfirst characterized in six male athletes [maximal O₂ uptake(O_{2 max}) = 63 ml · kg¹ · min¹] by using 5 minof cycling exercise at 30, 65, and 90%O_{2 max}. Multiple inert-gas, blood-gas, hemodynamic, metabolic rate, and ventilatory data were obtained. Resting log SD of the perfusion distribution (logSD) was normal [0.50 ± 0.03 (SE)] and increased with exercise (logSD = 0.65 ± 0.04, P < 0.005), alveolar-arterialO₂ difference increased (to 24 ± 3 Torr), and end-capillary pulmonary diffusion limitation occurred at 90%O_{2 max}. The subjectsrecovered for 30 min, then, after resting measurements were taken,exercised for 60 min at ~65%O_{2 max}.O₂ uptake, ventilation, cardiacoutput, and alveolar-arterial O₂difference were unchanged after the first 5 min of this test, but logSD increased from0.59 ± 0.03 at 5 min to 0.66 ± 0.05 at 60 min(P < 0.05), without pulmonary diffusion limitation. LogSD was negativelyrelated to total lung capacity normalized for body surface area(r = 0.97,P < 0.005 at 60 min). These data are compatible with interstitial edema as a mechanism and suggest that lungsize is an important determinant of the efficiency of gas exchangeduring exercise.

     

Phosphocreatine hydrolysis during submaximal exercise: the effect of FIO2

There isevidence that the concentration of the high-energy phosphatemetabolites may be altered during steady-state submaximal exerciseby the breathing of different fractions of inspiredO₂ (FI_O2). Whereasit has been suggested that these changes may be the result ofdifferences in time taken to achieve steady-state O₂ uptake(O₂) at differentFI_O2 values, we postulated that they are due to a direct effect ofO₂ tension. We used³¹P-magnetic resonancespectroscopy during constant-load, steady-state submaximal exercise todetermine 1) whether changes inhigh-energy phosphates do occur at the sameO₂ with variedFI_O2 and2) that these changes are not due todifferences in O₂onset kinetics. Six male subjects performed steady-state submaximal plantar flexion exercise [7.2 ± 0.6 (SE) W] for 10 minwhile lying supine in a 1.5-T clinical scanner. Magnetic resonancespectroscopy data were collected continuously for 2 min beforeexercise, 10 min during exercise, and 6 min during recovery. Subjectsperformed three different exercise bouts at constant load with theFI_O2 switched after 5 min ofthe 10-min exercise bout. The three exercise treatments were1)FI_O2 of 0.1 switched to0.21, 2)FI_O2 of 0.1 switched to1.00, and 3)FI_O2 of 1.00 switched to0.1. For all three treatments, theFI_O2 switch significantly (P  0.05) altered phosphocreatine:1) 55.5 ± 4.8 to 67.8 ± 4.9% (%rest); 2) 59.0 ± 4.3 to72.3 ± 5.1%; and 3) 72.6 ± 3.1 to 64.2 ± 3.4%, respectively. There were no significantdifferences in intracellular pH for the three treatments. The resultsdemonstrate that the differences in phosphocreatine concentration withvaried FI_O2 are not theresult of different O₂onset kinetics, as this was eliminated by the experimental design.These data also demonstrate that changes in intracellular oxygenation,at the same work intensity, result in significant changes in cell homeostasis and thereby suggest a role for metabolic control by O₂ even during submaximalexercise.

     

Letters to the Editor

The following is the abstract of the article discussed in thesubsequent letter:

Koga, Shunsaku, Tomoyuki Shiojiri, Narihiko Kondo,and Thomas J. Barstow. Effect of increased muscle temperature on oxygen uptake kinetics during exercise. J. Appl. Physiol.83(4): 1333-1338, 1997.To test whether increased muscletemperature (T_m) would improve O₂ uptake(O₂) kinetics, seven menperformed transitions from rest to a moderate work rate [below theestimated lactate threshold (LT_est)] and a heavy workrate (O₂ = 50% of thedifference between LT_est and peakO₂) under conditions of normal T_m (N) and increased T_m (H), produced bywearing hot water-perfused pants before exercise. QuadricepsT_m was significantly higher in H, but rectal temperaturewas similar for the two conditions. There were no significantdifferences in the amplitudes of the fast component ofO₂ or in the time constantsof the on and off transients for moderate and heavy exercise betweenthe two conditions. The increment inO₂ between the 3rd and 6thmin of heavy exercise was slightly but significantly smaller for H thanfor N. These data suggest that elevated T_m before exercise onset, which would have been expected to increase O₂delivery and off-loading to the muscle, had no appreciable effect onthe fast exponential component ofO₂ kinetics (invariant timeconstant). These data further suggest that elevated T_m doesnot contribute to the slow component ofO₂ during heavy exercise.

     

Photosynthesis, Respiration, and Carbon Assimilation in Water-Stressed Maize at Two Oxygen Concentrations

Photosynthesis decreased with decreasing leaf water potentialas a consequence of stomatal closure and possibly non-stimataleffects of severe stress. Assimilation ceased at c. 16x 10⁵Pa. Photo-respiration, in 21% O₂, was small in relation to assimilationin unstressed leaves and decreased as leaf water potential fellbut it was much larger in proportion to photosynthesis at severestress. Decreasing the O₂ content to 1.5% increased photosynthesisslightly and decreased photo-respiration but did not changethe stress at which assimilation stoped. Dark respiration wasinsensitive to both O₂ and stress. Less ¹⁴C accumulated in stressedleaves but in 21% O₂ a greater proportion of it was in aminoacids, particularly glycine and serine. 1.5% O₂ decreased the¹⁴C in glycine to 10% and in serine to 50% of their levels in21% O₂. In both O₂ concentrations the proportion of ¹⁴C in serineincreased only at the most severe stress. Gas exchange measurementsand changes in the ¹⁴C flux to glycine are interpreted as theresult of glycolate pathway metabolism increasing as a proportionof assimilation in stressed leaves in high O₂. The small absoluterate of photorespiration in high O₂ and at low leaf water potentialmay be due to slow rates of glycine decarbodylation as wellas efficient fixation of any CO₂ produced. Serine is synthesizedby an O₂-sensitive pathway and an O₂-insensitive pathway, whichis most active at severe stress. Synthesis of alanine competeswith that of glycine and serine for a common precursor suppliedby the photo-synthetic carbon reduction cycle. The relativespecific radioactivities of aspartate and alanine suggest thatthey are derived from a common precursor pool, probably pyruvatefrom 3-PGA. The amounts of 3-PGA, aspartate, malate, alanine,and sucrose decreased with increasing water stress as a consequenceof slower assimilation and pool filling. Other amino acids,glycine, serine, glutamate, and proline, accumulated at lowwater potential possibly due to increased synthesis and slowerrates of consumption. Changes in pool sizes, carbon fludes,and specific activities of metabolites are related to the mechanismof C₄ photosynthesis and current concepts of glycolate pathwaymetabolism.     

Acceleration of VO2 kinetics in heavy submaximal exercise by hyperoxia and prior high-intensity exercise

MacDonald, Maureen, Preben K. Pedersen, and Richard L. Hughson. Acceleration ofO₂ kinetics in heavysubmaximal exercise by hyperoxia and prior high-intensity exercise.J. Appl. Physiol. 83(4):1318-1325, 1997.We examined the hypothesis thatO₂ uptake (O₂) wouldchange more rapidly at the onset of step work rate transitions inexercise with hyperoxic gas breathing and after prior high-intensityexercise. The kinetics ofO₂ were determined from themean response time (MRT; time to 63% of total change inO₂) andcalculations of O₂ deficit andslow component during normoxic and hyperoxic gas breathing in one groupof seven subjects during exercise below and above ventilatory threshold(VT) and in another group of seven subjects during exercise above VTwith and without prior high-intensity exercise. In exercise transitions below VT, hyperoxic gas breathing did not affect the kinetic response of O₂ at theonset or end of exercise. At work rates above VT, hyperoxic gasbreathing accelerated both the on- and off-transient MRT, reduced theO₂ deficit, and decreased theO₂ slow component fromminute 3 to minute6 of exercise, compared with normoxia. Prior exerciseabove VT accelerated the on-transient MRT and reduced theO₂ slow component fromminute 3 to minute6 of exercise in a second bout of exercise with bothnormoxic and hyperoxic gas breathing. However, the summatedO₂ deficit in the second normoxicand hyperoxic steps was not different from that of the first steps inthe same gas condition. Faster on-transient responses in exerciseabove, but not below, VT with hyperoxia and, to a lesser degree, afterprior high-intensity exercise above VT support the theory of anO₂ transport limitation at theonset of exercise for workloads >VT.

     

Does an acute COPD crisis modify the cardiorespiratory and ventilatory adjustments to exercise in horses?

The present study was conducted to understandbetter the mechanisms leading to the decrease in exercise capacityobserved in horses suffering from chronic obstructive pulmonary disease (COPD). Five COPD horses were submitted to a standardized submaximal treadmill exercise test while they were in clinical remission or inacute crisis. Respiratory airflow,O₂ andCO₂ fractions in the respired gas,pleural pressure changes and heart rate were recorded, and arterial andmixed venous blood were analyzed for gas tensions, hemoglobin, andplasma lactate concentrations. O₂ consumption, CO₂ production,expired minute ventilation, tidal volume, alveolar ventilation, cardiacoutput, total pulmonary resistance, and mechanical work of breathingwere calculated. The results showed that, whensubmaximally exercised, COPD horses in crisis were significantly morehypoxemic and hypercapnic and that their total pulmonary resistance andmechanical work of breathing were significantly higher and theirexpired minute ventilation significantly lower than when they were inremission. However, their O₂consumption remained unchanged, which was probably due to theoccurrence of compensatory mechanisms, i.e., higher heart rate, cardiacoutput, and hemoglobin concentration. Last, their net anaerobicmetabolism seemed to be more important.

     

Norepinephrine, but not epinephrine, enhances platelet reactivity and coagulation after exercise in humans

The effects of exercise and catecholamineson platelet reactivity or coagulation and fibrinolysis appear to beinconsistent. This may be partly due to the methods employed inprevious studies. In the present study, we investigated the effects ofacute aerobic exercise and catecholamines on the thrombotic status by anovel in vitro method, shear-induced hemostatic plug formation(hemostatometry), using nonanticoagulated (native) blood. Aerobicexercise (60% maximal O₂consumption) was performed by healthy male volunteers for 20 min, andthe effect on platelet reactivity and coagulation was assessed byperforming hemostatometry before and immediately after exercise.Exercise significantly increased shear-induced platelet reactivity,coagulation, and catecholamine levels. The effect of catecholamines onplatelet reactivity and coagulation was assessed in vitro by addingcatecholamines to blood collected in the resting state. The mainfindings of the present study are that elevation of circulatingnorepinephrine at levels that are attained during exercise causesplatelet hyperreactivity and a platelet-mediated enhanced coagulation.This may be a mechanism of an association of aerobic exercise withthrombotic risk.

     

Effect of increased muscle temperature on oxygen uptake kinetics during exercise

Koga, Shunsaku, Tomoyuki Shiojiri, Narihiko Kondo,and Thomas J. Barstow. Effect of increased muscle temperature on oxygen uptake kinetics during exercise. J. Appl.Physiol. 83(4): 1333-1338, 1997.To test whetherincreased muscle temperature (T_m) would improveO₂ uptake(O₂) kinetics, seven menperformed transitions from rest to a moderate work rate [belowthe estimated lactate threshold(LT_est)] and a heavy workrate (O₂ = 50% of thedifference between LT_est and peakO₂) under conditions of normal T_m (N) and increasedT_m (H), produced by wearing hotwater-perfused pants before exercise. QuadricepsT_m was significantly higher in H,but rectal temperature was similar for the two conditions. There wereno significant differences in the amplitudes of the fast component ofO₂ or in the time constantsof the on and off transients for moderate and heavy exercise betweenthe two conditions. The increment inO₂ between the 3rd and 6thmin of heavy exercise was slightly but significantly smaller for H thanfor N. These data suggest that elevatedT_m before exercise onset, whichwould have been expected to increaseO₂ delivery and off-loading to themuscle, had no appreciable effect on the fast exponential component ofO₂ kinetics (invariant timeconstant). These data further suggest that elevatedT_m does not contribute to the slowcomponent of O₂ duringheavy exercise.