Influence of muscle fiber type and pedal frequency on oxygen uptake kinetics of heavy exercise

Barstow, Thomas J., Andrew M. Jones, Paul H. Nguyen, andRichard Casaburi. Influence of muscle fiber type and pedal frequency on oxygen uptake kinetics of heavy exercise.J. Appl. Physiol. 81(4):1642-1650, 1996.We tested the hypothesis that the amplitude ofthe additional slow component ofO₂ uptake(O₂) during heavy exerciseis correlated with the percentage of type II (fast-twitch) fibers inthe contracting muscles. Ten subjects performed transitions to a workrate calculated to require aO₂ equal to 50% betweenthe estimated lactate (Lac) threshold and maximalO₂ (50%).Nine subjects consented to a muscle biopsy of the vastus lateralis. Toenhance the influence of differences in fiber type among subjects,transitions were made while subjects were pedaling at 45, 60, 75, and90 rpm in different trials. Baseline O₂ was designed to besimilar at the different pedal rates by adjusting baseline work ratewhile the absolute increase in work rate above the baseline was thesame. The O₂ response after the onset of exercise was described by a three-exponential model. Therelative magnitude of the slow component at the end of 8-min exercisewas significantly negatively correlated with %type I fibers at everypedal rate (r = 0.64 to 0.83, P < 0.05-0.01). Furthermore,the gain of the fast component forO₂ (asml ^· min^{1 ·} W¹)was positively correlated with the %type I fibers across pedal rates(r = 0.69-0.83). Increase inpedal rate was associated with decreased relative stress of theexercise but did not affect the relationships between%fiber type and O₂parameters. The relative contribution of the slow component was alsosignificantly negatively correlated with maximalO₂(r = 0.65), whereas the gainfor the fast component was positively associated(r = 0.68-0.71 across rpm). Theamplitude of the slow component was significantly correlated with netend-exercise Lac at all four pedal rates(r = 0.64-0.84), but Lac was notcorrelated with %type I (P > 0.05).We conclude that fiber type distribution significantly affects both thefast and slow components ofO₂ during heavy exerciseand that fiber type and fitness may have both codependent andindependent influences on the metabolic and gas-exchange responses toheavy exercise.

     

Combined heart rate and activity improve estimates of oxygen consumption and carbon dioxide production rates

Moon, Jon K., and Nancy F. Butte. Combined heart rateand activity improve estimates of oxygen consumption and carbon dioxideproduction rates. J. Appl. Physiol.81(4): 1754-1761, 1996.Oxygen consumption(O₂) andcarbon dioxide production (CO₂) rates were measuredby electronically recording heart rate (HR) and physical activity (PA).Mean daily O₂ andCO₂ measurements by HR andPA were validated in adults (n = 10 women and 10 men) with room calorimeters. Thirteen linear and nonlinear functions of HR alone and HR combined with PA were tested as models of24-h O₂ andCO₂. Mean sleepO₂ andCO₂ were similar to basalmetabolic rates and were accurately estimated from HR alone[respective mean errors were 0.2 ± 0.8 (SD) and0.4 ± 0.6%]. The range of prediction errorsfor 24-h O₂ andCO₂ was smallestfor a model that used PA to assign HR for each minute to separateactive and inactive curves(O₂, 3.3 ± 3.5%; CO₂, 4.6 ± 3%). There were no significant correlations betweenO₂ orCO₂ errors and subject age,weight, fat mass, ratio of daily to basal energy expenditure rate, orfitness. O₂,CO₂, and energy expenditurerecorded for 3 free-living days were 5.6 ± 0.9 ml ^· min^{1 ·} kg¹,4.7 ± 0.8 ml ^· min^{1 ·} kg¹,and 7.8 ± 1.6 kJ/min, respectively. Combined HR and PA measured 24-h O₂ andCO₂ with a precisionsimilar to alternative methods.

     

Changes in maximum oxygen uptake during prolonged training, overtraining, and detraining in horses

Tyler, Catherine M., Lorraine C. Golland, David L. Evans,David R. Hodgson, and Reuben J. Rose. Changes in maximum oxygenuptake during prolonged training, overtraining, and detraining inhorses. J. Appl. Physiol. 81(5):2244-2249, 1996.Thirteen standardbred horses were trained asfollows: phase 1 (endurance training, 7 wk),phase 2 (high-intensity training, 9 wk),phase 3 (overload training, 18 wk), andphase 4 (detraining, 12 wk). Inphase 3, the horses were divided intotwo groups: overload training (OLT) and control (C). The OLT groupexercised at greater intensities, frequencies, and durations than groupC. Overtraining occurred after 31 wk of training and was defined as asignificant decrease in treadmill run time in response to astandardized exercise test. In the OLT group, there was a significantdecrease in body weight (P < 0.05).From pretraining values of 117 ± 2 (SE)ml ^· kg^{1 ·} min¹,maximal O₂ uptake(O_{2 max}) increased by15% at the end of phase 1, and when signs of overtraining werefirst seen in the OLT group,O_{2 max} was 29%higher (151 ± 2 ml ^· kg^{1 ·} min¹in both C and OLT groups) than pretraining values. There was nosignificant reduction inO_{2 max} until after 6 wk detraining whenO_{2 max} was 137 ± 2 ml ^· kg^{1 ·} min¹.By 12 wk detraining, meanO_{2 max} was134 ± 2 ml ^· kg^{1 ·} min¹,still 15% above pretraining values. When overtraining developed, O_{2 max} was notdifferent between C and OLT groups, but maximal values forCO₂ production (147 vs. 159 ml ^· kg^{1 ·} min¹)and respiratory exchange ratio (1.04 vs. 1.11) were lower in the OLTgroup. Overtraining was not associated with a decrease inO_{2 max} and, afterprolonged training, decreases inO_{2 max} occurredslowly during detraining.

     

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.

     

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.     

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.

     

Smaller lungs in women affect exercise hyperpnea

We subjected 29 healthy young women (age: 27 ± 1 yr) with a wide range of fitness levels [maximal oxygenuptake (O_{2 max}): 57 ± 6 ml · kg¹ · min¹;35-70ml · kg¹ · min¹]to a progressive treadmill running test. Our subjects had significantly smaller lung volumes and lower maximal expiratory flow rates, irrespective of fitness level, compared with predicted values for age-and height-matched men. The higher maximal workload in highly fit(O_{2 max} > 57 ml · kg¹ · min¹,n = 14) vs. less-fit(O_{2 max} < 56 ml · kg¹ · min¹,n = 15) women caused a higher maximalventilation (E) with increased tidal volume (VT)and breathing frequency (f_b) atcomparable maximal VT/vitalcapacity (VC). More expiratory flow limitation (EFL; 22 ± 4% ofVT) was also observed duringheavy exercise in highly fit vs. less-fit women, causing higherend-expiratory and end-inspiratory lung volumes and greater usage oftheir maximum available ventilatory reserves.HeO₂ (79% He-21%O₂) vs. room air exercise trialswere compared (with screens added to equalize external apparatusresistance). HeO₂ increasedmaximal expiratory flow rates (20-38%) throughout the range ofVC, which significantly reduced EFL during heavy exercise. When EFL wasreduced with HeO₂, VT,f_b, andE (+16 ± 2 l/min) weresignificantly increased during maximal exercise. However, in theabsence of EFL (during room air exercise),HeO₂ had no effect onE. We conclude that smaller lungvolumes and maximal flow rates for women in general, and especiallyhighly fit women, caused increased prevalence of EFL during heavyexercise, a relative hyperinflation, an increased reliance onf_b, and a greater encroachment onthe ventilatory "reserve." Consequently,VT andE are mechanically constrained duringmaximal exercise in many fit women because the demand for highexpiratory flow rates encroaches on the airways' maximum flow-volumeenvelope.

     

Respiratory muscle work compromises leg blood flow during maximal exercise

Harms, Craig A., Mark A. Babcock, Steven R. McClaran, DavidF. Pegelow, Glenn A. Nickele, William B. Nelson, and Jerome A. Dempsey.Respiratory muscle work compromises leg blood flow during maximalexercise. J. Appl. Physiol.82(5): 1573-1583, 1997.We hypothesized that duringexercise at maximal O₂ consumption (O_{2 max}),high demand for respiratory muscle blood flow() would elicit locomotor muscle vasoconstrictionand compromise limb . Seven male cyclists(O_{2 max} 64 ± 6 ml · kg¹ · min¹)each completed 14 exercise bouts of 2.5-min duration atO_{2 max} on a cycleergometer during two testing sessions. Inspiratory muscle work waseither 1) reduced via aproportional-assist ventilator, 2)increased via graded resistive loads, or3) was not manipulated (control).Arterial (brachial) and venous (femoral) blood samples, arterial bloodpressure, leg (legs;thermodilution), esophageal pressure, andO₂ consumption(O₂) weremeasured. Within each subject and across all subjects, at constantmaximal work rate, significant correlations existed(r = 0.74-0.90;P < 0.05) between work of breathing(Wb) and legs (inverse), leg vascular resistance (LVR), and leg O₂(O_{2 legs};inverse), and between LVR and norepinephrine spillover. Mean arterialpressure did not change with changes in Wb nor did tidal volume orminute ventilation. For a ±50% change from control in Wb,legs changed 2 l/min or 11% of control, LVRchanged 13% of control, and O₂extraction did not change; thusO_{2 legs}changed 0.4 l/min or 10% of control. TotalO_{2 max} was unchangedwith loading but fell 9.3% with unloading; thusO_{2 legs}as a percentage of totalO_{2 max} was 81% incontrol, increased to 89% with respiratory muscle unloading, anddecreased to 71% with respiratory muscle loading. We conclude that Wbnormally incurred during maximal exercise causes vasoconstriction inlocomotor muscles and compromises locomotor muscle perfusion andO₂.

     

Mechanical and metabolic determination of VO2 and fatigue during repetitive isometric contractions in situ

Repetitiveisometric tetanic contractions (1/s) of the caninegastrocnemius-plantaris muscle were studied either at optimal length(L_o) or shortlength (L_s;~0.9 · L_o),to determine the effects of initial length on mechanical and metabolicperformance in situ. Respective averages of mechanical and metabolicvariables were(L_o vs.L_s, allP < 0.05) passive tension (preload) = 55 vs. 6 g/g, maximal active tetanic tension(P_o) = 544 vs. 174 (0.38 · P_o)g/g, maximal blood flow () = 2.0 vs. 1.4 ml · min¹ · g¹,and maximal oxygen uptake(O₂) = 12 vs. 9 µmol · min¹ · g¹.Tension at L_odecreased to0.64 · P_o over20 min of repetitive contractions, demonstrating fatigue; there were nosignificant changes in tension atL_s. In separatemuscles contracting atL_o, was set to that measured atL_s (1.1 ml · min¹ · g¹),resulting in decreased O₂(7 µmol · min¹ · g¹),and rapid fatigue, to0.44 · P_o. Thesedata demonstrate that 1)muscles at L_ohave higher andO₂ values than those at L_s;2) fatigue occurs atL_o with highO₂, adjusting metabolic demand (tension output) to match supply; and3) the lack of fatigue atL_s with lowertension, , andO₂ suggestsadequate matching of metabolic demand, set low by shortmuscle length, with supply optimized by low preload. Thesedifferences in tension andO₂ betweenL_o andL_s groupsindicate that muscles contracting isometrically at initial lengthsshorter than L_oare working under submaximal conditions.

     

Alveolar oxygen uptake and femoral artery blood flow dynamics in upright and supine leg exercise in humans

We tested the hypothesis that the slowerincrease in alveolar oxygen uptake(O₂) at the onset ofsupine, compared with upright, exercise would be accompanied by aslower rate of increase in leg blood flow (LBF). Seven healthy subjectsperformed transitions from rest to 40-W knee extension exercise in theupright and supine positions. LBF was measured continuously with pulsedand echo Doppler methods, andO₂ was measured breath bybreath at the mouth. At rest, a smaller diameter of thefemoral artery in the supine position(P < 0.05) was compensated by agreater mean blood flow velocity (MBV) (P < 0.05) so that LBF was not different in the two positions. At the end of6 min of exercise, femoral artery diameter was larger in the uprightposition and there were no differences inO₂, MBV, or LBF betweenupright and supine positions. The rates of increase ofO₂ and LBF in thetransition between rest and 40 W exercise, as evaluated by the meanresponse time (time to 63% of the increase), were slower in the supine[O₂ = 39.7 ± 3.8 (SE) s, LBF = 27.6 ± 3.9 s] than in the uprightpositions (O₂ = 29.3 ± 3.0 s, LBF = 17.3 ± 4.0 s;P < 0.05). These data support ourhypothesis that slower increases in alveolarO₂ at the onset of exercisein the supine position are accompanied by a slower increase in LBF.

     

Training-induced alterations of carbohydrate metabolism in women: women respond differently from men

We examined the hypothesis that glucose flux wasdirectly related to relative exercise intensity both beforeand after a 12-wk cycle ergometer training program [5days/wk, 1-h duration, 75% peakO₂ consumption(O_{2 peak})] inhealthy female subjects (n = 17; age23.8 ± 2.0 yr). Two pretraining trials (45 and 65% of O_{2 peak})and two posttraining trials [same absolute workload (65% of oldO_{2 peak})and same relative workload (65% of new O_{2 peak})] wereperformed on nine subjects by using a primed-continuous infusion of[1-¹³C]- and[6,6-²H]glucose.Eight additional subjects were studied by using[6,6-²H]glucose.Subjects were studied postabsorption for 90 min of rest and 1 h ofcycling exercise. After training, subjects increased O_{2 peak} by 25.2 ± 2.4%. Pretraining, the intensity effect on glucose kinetics wasevident between 45 and 65% ofO_{2 peak} with rates ofappearance (R_a: 4.52 ± 0.25 vs. 5.53 ± 0.33 mg · kg¹ · min¹),disappearance (R_d: 4.46 ± 0.25 vs. 5.54 ± 0.33 mg · kg¹ · min¹),and oxidation (R_ox: 2.45 ± 0.16 vs. 4.35 ± 0.26 mg · kg¹ · min¹)of glucose being significantly greater(P  0.05) in the 65% thanin the 45% trial. Training reducedR_a (4.7 ± 0.30 mg · kg¹ · min¹),R_d (4.69 ± 0.20 mg · kg¹ · min¹),and R_ox (3.54 ± 0.50 mg · kg¹ · min¹)at the same absolute workload (P  0.05). When subjects were tested at the same relative workload,R_a,R_d, andR_ox were not significantlydifferent after training. However, at both workloads after training,there was a significant decrease in total carbohydrate oxidation asdetermined by the respiratory exchange ratio. These results show thefollowing in young women: 1)glucose use is directly related to exercise intensity;2) training decreasesglucose flux for a given power output;3) when expressed asrelative exercise intensity, training does not affect the magnitude ofblood glucose flux during exercise; but4) training does reduce totalcarbohydrate oxidation.

     

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.

     

Importance of the lactate anion in control of breathing

Hardarson, Thorir, Jon O. Skarphedinsson, and TorarinnSveinsson. Importance of the lactate anion in control ofbreathing. J. Appl. Physiol. 84(2):411-416, 1998.The purpose of this study was to examine theeffects of raising the arterialLa andK⁺ levels on minute ventilation(E) in rats. EitherLa or KCl solutions wereinfused in anesthetized spontaneously breathing Wistar rats to raisethe respective ion arterial concentration ([La] and[K⁺]) gradually tolevels similar to those observed during strenuous exercise.E, blood pressure, and heart rate wererecorded continuously, and arterial[La],[K⁺], pH, and bloodgases were repeatedly measured from blood samples. To prevent changesin pH during the Lainfusions, a solution of sodium lactate and lactic acid was used. Raising [La] to13.2 ± 0.6 (SE) mM induced a 47.0 ± 4.0% increase inE without any concomitant changes ineither pH or PCO₂. Raising[K⁺] to 7.8 ± 0.11 mM resulted in a 20.3 ± 5.28% increase inE without changes in pH. Thus ourresults show that Laitself, apart from lactic acidosis, may be important in increasing E during strenuous exercise, and weconfirm earlier results regarding the role of arterial[K⁺] in the control ofE during exercise.

     

Age-related declines in maximal aerobic capacity in regularly exercising vs. sedentary women: a meta-analysis

Fitzgerald, Margaret D., Hirofumi Tanaka, Zung V. Tran, andDouglas R. Seals. Age-related declines in maximal aerobic capacityin regularly exercising vs. sedentary women: a meta-analysis. J. Appl. Physiol. 83(1): 160-165, 1997.Our purpose was to determine the relationship between habitualaerobic exercise status and the rate of decline in maximal aerobiccapacity across the adult age range in women. A meta-analytic approachwas used in which mean maximal oxygen consumption(O_{2 max}) values fromfemale subject groups (ages 18-89 yr) were obtained from thepublished literature. A total of 239 subject groups from 109 studiesinvolving 4,884 subjects met the inclusion criteria and werearbitrarily separated into sedentary (groups = 107; subjects = 2,256),active (groups = 69; subjects = 1,717), and endurance-trained (groups = 63; subjects = 911) populations.O_{2 max} averaged 29.7 ± 7.8, 38.7 ± 9.2, and 52.0 ± 10.5 ml · kg¹ · min¹,respectively, and was inversely related to age within each population (r = 0.82 to 0.87, allP < 0.0001). The rate of decline inO_{2 max} withincreasing subject group age was lowest in sedentary women (3.5ml · kg¹ · min¹· decade¹), greater inactive women (4.4ml · kg¹ · min¹· decade¹), andgreatest in endurance-trained women (6.2ml · kg¹ · min¹ · decade¹)(all P < 0.001 vs. each other). Whenexpressed as percent decrease from mean levels at age ~25 yr, therates of decline inO_{2 max} were similarin the three populations (10.0 to 10.9%/decade). Therewas no obvious relationship between aerobic exercise status and therate of decline in maximal heart rate with age. The results of thiscross-sectional study support the hypothesis that, in contrast to theprevailing view, the rate of decline in maximal aerobic capacity withage is greater, not smaller, in endurance-trained vs. sedentary women.The greater rate of decline inO_{2 max} in endurance-trained populations may be related to their higher values asyoung adults (baseline effect) and/or to greater age-related reductions in exercise volume; however, it does not appear to berelated to a greater rate of decline in maximal heart rate with age.

     

Reductions in visceral fat during weight loss and walking are associated with improvements in {V}O2 max

The accumulation ofvisceral fat is independently associated with an increased risk forcardiovascular disease. The aim of this study was to determine whetherthe loss of visceral adipose tissue area (VAT; computed tomography) isrelated to improvements in maximal O₂ uptake(O_2 max) during a weight loss(250-350 kcal/day deficit) and walking (3 days/wk, 30-40 min)intervention. Forty obese [body fat 47 ± 1 (SE) %], sedentary(O_2 max 19 ± 1 ml · kg¹ · min¹)postmenopausal women (age 62 ± 1 yr) participated in the study. The intervention resulted in significant declines in body weight (8%), total fat mass (dual-energy X-ray absorptiometry; 17%), VAT(17%), and subcutaneous adipose tissue area (17%) with no changein lean body mass (all P < 0.001). Women with anaverage 10% increase in O_2 max reducedVAT by an average of 20%, whereas those who did not increaseO_2 max decreased VAT by only 10%,despite comparable reductions in body fat, fat mass, and subcutaneousadipose tissue area. The decrease in VAT was independently related tothe change in O_2 max(r² = 0.22; P < 0.01) andfat mass (r² = 0.08; P = 0.05). These data indicate that greater improvements inO_2 max with weight loss and walking areassociated with greater reductions in visceral adiposity in obesepostmenopausal women.

     

Interaction of cross-sectional area, driving pressure, and airflow of passive velopharynx

Isono, Shiroh, Thom R. Feroah, Eric A. Hajduk, Rollin Brant,William A. Whitelaw, and John E. Remmers. Interaction ofcross-sectional area, driving pressure, and airflow of passive velopharynx. J. Appl. Physiol. 83(3):851-859, 1997.Previous studies have shown that, when thepharyngeal muscles are relaxed, the velopharynx is a highly compliantsegment of the pharynx. Thus, under these circumstances,cross-sectional area of the velopharynx (A_VP), drivingpressure across the velopharynx (P), and inspiratory airflow(I) willbe mutually interdependent variables. The purpose of the presentinvestigation was to describe the interrelation among these threevariables during inspiration. We studied 15 sleeping patients withobstructive sleep apnea/hypopnea when the pharyngeal muscles wererendered hypotonic by applying continuous positive airway pressure tothe nasal airway.A_VP, determined by endoscopic imaging, was significantly greater at onset ofI limitationthan at minimum oropharyngeal pressure(P < 0.01). Snoring was neverobserved duringIlimitation. In a subgroup of six patients, values for P,I, andA_VP were obtainedat 0.1-s intervals at various levels of mask pressure. For these sixpatients, the mathematical expressionI = 0.657(A_VP/A_max) · P^0.332,where A_max ismaximal A_VP,described the relationship among the three variables(R² = 0.962) forflow-limited and non-flow-limited inspirations. The impedance of thepassive velopharynx, defined asP^0.33/,was inversely related toA_VP and increaseddramatically when A_VP was <0.3cm². In summary, we observed aprogressive decrease inA_VP during flow-limited inspiration in patients with obstructive sleep apnea. Thisconstriction of the velopharynx contributes to an increase invelopharyngeal impedance that, in turn, counterbalances the increase inP during flow limitation.

     

Oxygen transport in conscious newborn dogs during hypoxic hypometabolism

We questioned whether the decrease inO₂ consumption(O₂) during hypoxia innewborns is a regulated response or reflects a limitation inO₂ availability. Experiments wereconducted on previously instrumented conscious newborn dogs.O₂ was measured at a warmambient temperature (30°C, n = 7)or in the cold (20°C, n = 6),while the animals breathed air or were sequentially exposed to 15 minof fractional inspired O₂(FI_O2): 21, 18, 15, 12, 10, 8, and 6%. In normoxia,O₂ averaged 15 ± 1 (SE)and 25 ± 1 ml · kg¹ · min¹in warm and cold conditions, respectively. In the warmcondition, hypometabolism (i.e., hypoxicO₂ < normoxicO₂) occurred at FI_O2 10%, whereas in thecold condition, hypometabolism occurred atFI_O2 12%. The sameresults were obtained in a separate group(n = 14) of noninstrumented puppies.For all levels of FI_O2 withhypometabolism, the relationships between measures ofO₂ availability (arterialO₂ saturation or content, venousPO₂ or saturation,x-axis) vs.O₂(y-axis) had lower slopes in warm than in coldconditions. Hence, O₂ during hypometabolism in the warm condition was not the maximal attainable for the level of oxygenation. The results do not support thepossibility that the hypoxic drop inO₂ in the newborn reflects a limitation in O₂availability. The results are compatible with the ideathat the phenomenon is one of "regulated conformism" tohypoxia.

     

Kinetics of oxygen uptake at the onset of exercise in boys and men

The objective of this study was to compare theO₂ uptake(O₂) kinetics at the onsetof heavy exercise in boys and men. Nine boys, aged 9-12 yr, and 8 men, aged 19-27 yr, performed a continuous incremental cyclingtask to determine peak O₂(O_{2 peak}).On 2 other days, subjects performed each day four cycling tasks at 80 rpm, each consisting of 2 min of unloaded cycling followed twice bycycling at 50%O_{2 peak} for 3.5 min,once by cycling at 100%O_{2 peak} for 2 min,and once by cycling at 130%O_{2 peak} for 75 s.O₂ deficit was not significantlydifferent between boys and men (respectively, 50%O_{2 peak} task: 6.6 ± 11.1 vs. 5.5 ± 7.3 ml · min¹ · kg¹;100% O_{2 peak} task:28.5 ± 8.1 vs. 31.8 ± 6.3 ml · min¹ · kg¹;and 130%O_{2 peak}task: 30.1 ± 5.7 vs. 35.8 ± 5.3 ml · min¹ · kg¹).To assess the kinetics, phase I was excluded from analysis. Phase IIO₂ kinetics could bedescribed in all cases by a monoexponential function. ANOVA revealed nodifferences in time constants between boys and men (respectively, 50%O_{2 peak}task: 22.8 ± 5.1 vs. 26.4 ± 4.1 s; 100%O_{2 peak} task: 28.0 ± 6.0 vs. 28.1 ± 4.4 s; and 130%O_{2 peak} task: 19.8 ± 4.1 vs. 20.7 ± 5.7 s). In conclusion, O₂ deficit and fast-componentO₂ on-transientsare similar in boys and men, even at high exercise intensities, whichis in contrast to the findings of other studies employing simplermethods of analysis. The previous interpretation that children relyless on nonoxidative energy pathways at the onset of heavy exercise isnot supported by our findings.

     

Norepinephrine response to exercise at the same relative intensity before and after endurance exercise training

It is welldocumented that endurance exercise training results in a bluntednorepinephrine (NE) response to exercise of a given absolute exerciseintensity. However, it is not clear what effect traininghas on the catecholamine response to exercise of the same relativeintensity because previous studies have provided conflicting results.The purpose of the present study was, therefore, to determine thecatecholamine response to exercise of the same relative exerciseintensity before and after endurance exercise training. Six women andthree men [age 28 ± 8 (SD) yr] performed 10 wk oftraining. Maximal O₂ uptake(O_{2 max}) wasdetermined during treadmill exercise. Fifteen-minute treadmill exercisebouts were performed at 60, 65, 70, 75, 80, and 85% ofO_{2 max} before andafter training.O_{2 max} was increasedby 20% (from 39.2 ± 7.7 to 46.9 ± 8.1 ml · kg¹ · min¹;P < 0.05) in response to training.Plasma NE concentrations were higher(P < 0.05) during exercise at thesame relative intensity after, compared with before, training at65-85% ofO_{2 max.}Differences between heart rates and plasma epinephrine concentrationsafter, compared with before, training were not statisticallysignificant. These results provide evidence that the NE response toexercise is dependent on the absolute as well as the relative intensity of the exercise.     

VO2 kinetics in the horse during moderate and heavy exercise

Langsetmo, I., G. E. Weigle, M. R. Fedde, H. H. Erickson, T. J. Barstow, and D. C. Poole.O₂ kinetics in thehorse during moderate and heavy exercise. J. Appl.Physiol. 83(4): 1235-1241, 1997.The horse is asuperb athlete, achieving a maximalO₂ uptake (~160ml · min¹ · kg¹)approaching twice that of the fittest humans. Although equine O₂ uptake(O₂) kinetics arereportedly fast, they have not been precisely characterized, nor hastheir exercise intensity dependence been elucidated. To addressthese issues, adult male horses underwent incremental treadmill testingto determine their lactate threshold (T_lac) and peakO₂(O_{2 peak}),and kinetic features of their O₂ response to"square-wave" work forcings were resolved using exercisetransitions from 3 m/s to abelow-T_lac speed of 7 m/s or anabove-T_lac speed of 12.3 ± 0.7 m/s (i.e., between T_lac and O_{2 peak}) sustainedfor 6 min. O₂ andCO₂ output were measured using anopen-flow system: pulmonary artery temperature was monitored, and mixedvenous blood was sampled for plasma lactate.O₂ kinetics at work levelsbelow T_lac were well fit by atwo-phase exponential model, with a phase2 time constant(₁ = 10.0 ± 0.9 s) thatfollowed a time delay (TD₁ = 18.9 ± 1.9 s). TD₁ was similar tothat found in humans performing leg cycling exercise, but the timeconstant was substantially faster. For speeds aboveT_lac,TD₁ was unchanged (20.3 ± 1.2 s); however, the phase 2 time constantwas significantly slower (₁ = 20.7 ± 3.4 s, P < 0.05) than for exercise belowT_lac. Furthermore, in four of fivehorses, a secondary, delayed increase inO₂ became evident135.7 ± 28.5 s after the exercise transition. This "slowcomponent" accounted for ~12% (5.8 ± 2.7 l/min) of the netincrease in exercise O₂. Weconclude that, at exercise intensities below and aboveT_lac, qualitative features ofO₂ kinetics in the horseare similar to those in humans. However, at speeds belowT_lac the fast component of theresponse is more rapid than that reported for humans, likely reflectingdifferent energetics of O₂utilization within equine muscle fibers.