Effect of increased blood glucose availability on glucose kinetics during exercise

This studyexamined the effect of increased blood glucose availability on glucosekinetics during exercise. Five trained men cycled for 40 min at 77 ± 1% peak oxygen uptake on two occasions. During the second trial(Glu), glucose was infused at a rate equal to the average hepaticglucose production (HGP) measured during exercise in the control trial(Con). Glucose kinetics were measured by a primed continuous infusionofD-[3-³H]glucose.Plasma glucose increased during exercise in both trials and wassignificantly higher in Glu. HGP was similar at rest (Con, 11.4 ± 1.2; Glu, 10.6 ± 0.6µmol · kg¹ · min¹).After 40 min of exercise, HGP reached a peak of 40.2 ± 5.5 µmol · kg¹ · min¹in Con; however, in Glu, there was complete inhibition of the increasein HGP during exercise that never rose above the preexercise level. Therate of glucose disappearance was greater(P < 0.05) during the last 15 min ofexercise in Glu. These results indicate that an increase in glucoseavailability inhibits the rise in HGP during exercise, suggesting thatmetabolic feedback signals can override feed-forward activation of HGPduring strenuous exercise.

     

Metabolic effects of low cortisol during exercise in humans

This studyexamined the physiological effect of reduced plasma cortisol (C) duringprolonged exercise in humans. The effects of normal C (NC) werecompared with metyrapone-induced low C (LC) on plasma substrateavailability and the respiratory exchange ratio during 2 h of exerciseat ~60% peak O₂ consumption innine subjects. The C responses were compared with preexercise (Pre) levels and with a rest day (Con). At rest, C was attenuated by ~70%for LC compared with NC. At rest, plasma glucose, lactate, glycerol,-hydroxybutyrate, alanine, branched-chain amino acids, insulin,glucagon, growth hormone, epinephrine, and norepinephrine were similarunder LC and NC (P > 0.05). Duringexercise under NC, plasma C increased compared with Pre, whereas itremained unchanged during LC. During NC, plasma C was elevated at 90 min (compared with Con) and at 120 min (compared with Con and Pre). During exercise, plasma glucose decreased to the same extent and lactate was similar under both conditions, whereas plasma glycerol, -hydroxybutyrate, alanine, and branched-chain amino acids were higher (P < 0.01) under NC. Plasmainsulin declined (P = 0.01) to agreater extent under LC, whereas growth hormone, epinephrine, andnorepinephrine tended to be higher (0.05  P  0.10). Plasma glucagon increasedunder both conditions (P < 0.01).The respiratory exchange ratio did not differ between conditions. Weconclude that, during exercise, 1) Caccelerates lipolysis, ketogenesis, and proteolysis;2) under LC, glucoregulatory hormoneadjustments maintain glucose homeostasis; and3) LC does not alter whole body substrate utilization or the ability to complete 2 h of moderate exercise.

     

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.

     

Exogenous glucose oxidation during exercise in endurance-trained and untrained subjects

Jeukendrup, A. E., M. Mensink, W. H. M. Saris, and A. J. M. Wagenmakers. Exogenous glucose oxidation during exercise in endurance-trained and untrained subjects. J. Appl.Physiol. 82(3): 835-840, 1997.To investigate theeffect of training status on the fuel mixture used during exercise withglucose ingestion, seven endurance-trained cyclists (Tr; maximumO₂ uptake 67 ± 2.3 ml ^· kg^{1 ·} min¹)and eight untrained subjects (UTr; 48 ± 2 ml ^· kg^{1 ·} min¹)were studied during 120 min of exercise at ~60% maximumO₂ uptake. At the onset of exercise, 8 ml ^· kg^{1 ·} min¹of an 8% naturally enriched[¹³C]glucose solutionwas ingested and 2 ml/kg every 15 min thereafter. Energy expenditurewas higher in Tr subjects compared with UTr subjects (3,404 vs. 2,630 kJ; P < 0.01). During the secondhour, fat oxidation was higher in Tr subjects (37 ± 2 g) comparedwith UTr subjects (23 ± 1 g), whereas carbohydrateoxidation was similar (116 ± 8 g in Tr subjects vs. 114 ± 4 g in UTr subjects). No differences were observed in exogenousglucose oxidation (50 ± 2 g in Tr subjects and 45 ± 3 g in UTr subjects, respectively). Peak exogenous glucose oxidationrates were similar in the two groups (0.95 ± 0.07 g/min in Trsubjects and 0.96 ± 0.03 g/min in UTr subjects). It is concluded that the higher energy expenditure in Tr subjects during exercise atthe same relative exercise intensity is entirely met by a higher rateof fat oxidation without changes in the rates of exogenous andendogenous carbohydrates.

     

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.

     

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.     

Effects of respiratory muscle work on cardiac output and its distribution during maximal exercise

We have recently demonstrated that changes inthe work of breathing during maximal exercise affect leg blood flow andleg vascular conductance (C. A. Harms, M. A. Babcock, S. R. McClaran, D. F. Pegelow, G. A. Nickele, W. B. Nelson, and J. A. Dempsey. J. Appl. Physiol. 82: 1573-1583,1997). Our present study examined the effects of changesin the work of breathing on cardiac output (CO) during maximalexercise. Eight male cyclists [maximalO₂ consumption(O_{2 max}):62 ± 5 ml · kg¹ · min¹]performed repeated 2.5-min bouts of cycle exercise atO_{2 max}. Inspiratorymuscle work was either 1) at controllevels [inspiratory esophageal pressure (Pes): 27.8 ± 0.6 cmH₂O],2) reduced via a proportional-assistventilator (Pes: 16.3 ± 0.5 cmH₂O), or 3) increased via resistive loads(Pes: 35.6 ± 0.8 cmH₂O).O₂ contents measured in arterialand mixed venous blood were used to calculate CO via the direct Fickmethod. Stroke volume, CO, and pulmonaryO₂ consumption(O₂) were not different(P > 0.05) between control andloaded trials atO_{2 max} but were lower(8, 9, and 7%, respectively) than control withinspiratory muscle unloading atO_{2 max}. Thearterial-mixed venous O₂difference was unchanged with unloading or loading. We combined thesefindings with our recent study to show that the respiratory muscle work normally expended during maximal exercise has two significant effectson the cardiovascular system: 1) upto 14-16% of the CO is directed to the respiratory muscles; and2) local reflex vasoconstriction significantly compromises blood flow to leg locomotor muscles.

     

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.     

Catecholamine responses to {alpha}-adrenergic blockade during exercise in women acutely exposed to altitude

We have previouslydocumented the importance of the sympathetic nervous system inacclimatizing to high altitude in men. The purpose ofthis investigation was to determine the extent to which -adrenergicblockade affects the sympathoadrenal responses to exercise during acutehigh-altitude exposure in women. Twelve eumenorrheic women (24.7 ± 1.3 yr, 70.6 ± 2.6 kg) were studied at sea level and onday 2 of high-altitude exposure (4,300-m hypobaric chamber)in either their follicular or luteal phase. Subjects performed twograded-exercise tests at sea level (on separate days) on a bicycleergometer after 3 days of taking either a placebo or an -blocker (3 mg/day prazosin). Subjects also performed two similar exercise testswhile at altitude. Effectiveness of blockade was determined byphenylephrine challenge. At sea level, plasma norepinephrine levelsduring exercise were 48% greater when subjects were -blockedcompared with their placebo trial. This difference was only 25% whensubjects were studied at altitude. Plasma norepinephrine values weresignificantly elevated at altitude compared with sea level but to agreater extent for the placebo (59%) vs. blocked (35%) trial. Amore dramatic effect of both altitude (104% placebo vs. 95%blocked) and blockade (50% sea level vs. 44% altitude) wasobserved for plasma epinephrine levels during exercise. No phasedifferences were observed across any condition studied. It wasconcluded that -adrenergic blockade 1) resulted in acompensatory sympathoadrenal response during exercise at sea level andaltitude, and 2) this effect was more pronounced for plasma epinephrine.

     

Failure of prostaglandins to modulate the time course of blood flow during dynamic forearm exercise in humans

Shoemaker, J. K., H. L. Naylor, Z. I. Pozeg, and R. L. Hughson. Failure of prostaglandins to modulate the time course ofblood flow during dynamic forearm exercise in humans.J. Appl. Physiol. 81(4):1516-1521, 1996.The time course and magnitude of increases inbrachial artery mean blood velocity (MBV; pulsed Doppler), diameter(D; echo Doppler), mean perfusionpressure (MPP; Finapres), shear rate ( = 8 ^· MBV/D), andforearm blood flow (FBF = MBV ^· r²)were assessed to investigate the effect that prostaglandins (PGs) haveon the hyperemic response on going from rest to rhythmic exercise inhumans. While supine, eight healthy men performed 5 min of dynamichandgrip exercise by alternately raising and lowering a 4.4-kg weight(~10% maximal voluntary contraction) with a work-to-rest cycle of1:1 (s/s). When the exercise was performed with the arm positionedbelow the heart, the rate of increase in MBV and wasfaster compared with the same exercise performed above the heart.Ibuprofen (Ibu; 1,200 mg/day, to reduce PG-induced vasodilation) andplacebo were administered orally for 2 days before two separate testingsessions in a double-blind manner. Resting heart rate was reduced inIbu (52 ± 3 beats/min) compared with placebo (57 ± 3 beats/min)(P < 0.05) without change to MPP.With placebo, D increased in both armpositions from ~4.3 mm at rest to ~4.5 mm at 5 min of exercise(P < 0.05). This response was notaltered with Ibu (P > 0.05). Ibudid not alter the time course of MBV or forearm blood flow(P > 0.05) in either arm position. The was significantly greater in Ibu vs. placebo at 30 and 40 s of above the heart exercise and for all time points after 25 sof below the heart exercise (P < 0.05). Because PG inhibition altered the time course of at the brachial artery, but not FBF, it was concludedthat PGs are not essential in regulating the blood flow responses todynamic exercise in humans.

     

Effect of exercise intensity on skeletal muscle malonyl-CoA and acetyl-CoA carboxylase

Rasmussen, B. B., and W. W. Winder. Effectof exercise intensity on skeletal muscle malonyl-CoA and acetyl-CoAcarboxylase. J. Appl. Physiol. 83(4):1104-1109, 1997.Malonyl-CoA is synthesized by acetyl-CoAcarboxylase (ACC) and is an inhibitor of fatty acid oxidation. Exerciseinduces a decline in skeletal muscle malonyl-CoA, which is accompaniedby inactivation of ACC and increased activity of AMP-activated proteinkinase (AMPK). This study was designed to determine the effect ofexercise intensity on the enzyme kinetics of ACC, malonyl-CoA levels,and AMPK activity in skeletal muscle. Male Sprague-Dawley rats werekilled (pentobarbital sodium anesthesia) at rest or after 5 min ofexercise (10, 20, 30, or 40 m/min at 5% grade). The fast-twitch redand white regions of the quadriceps muscle were excised and frozen inliquid nitrogen. A progressive decrease in red quadriceps ACC maximalvelocity (from 28.6 ± 1.5 to 14.3 ± 0.7 nmol · g¹ · min¹,P < 0.05), an increase in activationconstant for citrate, and a decrease in malonyl-CoA (from 1.9 ± 0.2 to 0.9 ± 0.1 nmol/g, P < 0.05) were seen with theincrease in exercise intensity from rest to 40 m/min. AMPK activityincreased more than twofold. White quadriceps ACC activity decreasedonly during intense exercise. We conclude that the extent of ACCinactivation during short-term exercise is dependent on exerciseintensity.

     

Training-induced alterations of glucose flux in men

Friedlander, Anne L., Gretchen A. Casazza, Michael A. Horning, Melvin J. Huie, and George A. Brooks. Training-induced alterations of glucose flux in men. J. Appl.Physiol. 82(4): 1360-1369, 1997.We examined thehypothesis that glucose flux was directly related to relative exerciseintensity both before and after a 10-wk cycle ergometer trainingprogram in 19 healthy male subjects. Two pretraining trials [45and 65% of peak O₂ consumption(O_{2 peak})] andtwo posttraining trials (same absolute and relative intensities as 65%pretraining) were performed for 90 min of rest and 1 h of cyclingexercise. After training, subjects increasedO_{2 peak} by9.4 ± 1.4%. Pretraining, the intensity effect on glucose kinetics was evident with rates of appearance(R_a; 5.84 ± 0.23 vs. 4.73 ± 0.19 mg · kg¹ · min¹),disappearance (R_d; 5.78 ± 0.19 vs. 4.73 ± 0.19 mg · kg¹ · min¹),oxidation (R_ox; 5.36 ± 0.15 vs. 3.41 ± 0.23 mg · kg¹ · min¹),and metabolic clearance (7.03 ± 0.56 vs. 5.20 ± 0.28 ml · kg¹ · min¹)of glucose being significantly greater(P  0.05) in the 65% than the 45%O_{2 peak} trial. WhenR_d was expressed as a percentage of total energy expended per minute(R_{d E}), there was nodifference between the 45 and 65% intensities. Training did reduceR_a (4.63 ± 0.25),R_d (4.65 ± 0.24),R_ox (3.77 ± 0.43), andR_{d E} (15.30 ± 0.40 to12.85 ± 0.81) when subjects were tested at the same absolute workload (P  0.05). However, whenthey were tested at the same relative workload,R_a,R_d, andR_{d E} were not different,although R_ox was lowerposttraining (5.36 ± 0.15 vs. 4.41 ± 0.42, P  0.05). These results show1) glucose use is directly relatedto exercise intensity; 2) trainingdecreases glucose flux for a given power output;3) when expressed as relativeexercise intensity, training does not affect the magnitude of bloodglucose use during exercise; 4)training alters the pathways of glucose disposal.

     

Impaired calcium pump function does not slow relaxation in human skeletal muscle after prolonged exercise

Booth, John, Michael J. McKenna, Patricia A. Ruell, Tom H. Gwinn, Glen M. Davis, Martin W. Thompson, Alison R. Harmer, Sandra K. Hunter, and John R. Sutton. Impaired calcium pump function doesnot slow relaxation in human skeletal muscle after prolonged exercise.J. Appl. Physiol. 83(2): 511-521, 1997.This study examined the effects of prolonged exercise on humanquadriceps muscle contractile function and homogenate sarcoplasmicreticulum Ca²⁺ uptake andCa²⁺-adenosinetriphosphataseactivity. Ten untrained men cycled at 75 ± 2% (SE) peak oxygenconsumption until exhaustion. Biopsies were taken from theright vastus lateralis muscle at rest, exhaustion, and 20 and 60 minpostexercise. Peak tension and half relaxation time of the leftquadriceps muscle were measured during electrically evoked twitch andtetanic contractions and a maximal voluntary isometric contraction atrest, exhaustion, and 10, 20, and 60 min postexercise. At exhaustion,homogenate Ca²⁺ uptake andCa²⁺ adenosinetriphosphataseactivity were reduced by 17 ± 4 and 21 ± 5%, respectively, andremained depressed after 60 min recovery (P  0.01). Muscle ATP, creatinephosphate, and glycogen were all depressed at exhaustion(P  0.01). Peak tension during a maximal voluntary contraction, a twitch, and a 10-Hz stimulation werereduced after exercise by 28 ± 3, 45 ± 6, 65 ± 5%,respectively (P  0.01), but noslowing of half relaxation times were found. Thus fatigue induced byprolonged exercise reduced muscleCa²⁺ uptake, but this did notcause a slower relaxation of evoked contractions.

     

Oral glucose ingestion increases endurance capacity in normal and diabetic (type I) humans

Ramires, P. R., C. L. M. Forjaz, C. M. C. Strunz, M. E. R. Silva, J. Diament, W. Nicolau, B. Liberman, and C. E. Negrão. Oral glucose ingestion increases endurance capacity in normal anddiabetic (type I) humans. J. Appl.Physiol. 83(2): 608-614, 1997.The effects of anoral glucose administration (1 g/kg) 30 min before exercise onendurance capacity and metabolic responses were studied in 21 type Idiabetic patients [insulin-dependent diabetes mellitus(IDDM)] and 23 normal controls (Con). Cycle ergometer exercise (55-60% of maximalO₂ uptake) was performed untilexhaustion. Glucose administration significantly increased endurancecapacity in Con (112 ± 7 vs. 125 ± 6 min,P < 0.05) but only in IDDM patientswhose blood glucose decreased during exercise (70.8 ± 8.2 vs. 82.8 ± 9.4 min, P < 0.05).Hyperglycemia was normalized at 15 min of exercise in Con (7.4 ± 0.2 vs. 4.8 ± 0.2 mM) but not in IDDM patients (12.4 ± 0.7 vs.15.6 ± 0.9 mM). In Con, insulin and C-peptide levels werenormalized during exercise. Glucose administration decreased growthhormone levels in both groups. In conclusion, oral glucose ingestion 30 min before exercise increases endurance capacity in Con and in someIDDM patients. In IDDM patients, in contrast with Con, exercise to exhaustion attenuates hyperglycemia but does not bring blood glucose levels to preglucose levels.

     

Testosterone and cortisol in relationship to dietary nutrients and resistance exercise

Volek, Jeff S., William J. Kraemer, Jill A. Bush, ThomasIncledon, and Mark Boetes. Testosterone and cortisol inrelationship to dietary nutrients and resistance exercise.J. Appl. Physiol. 82(1): 49-54, 1997.Manipulation of resistance exercise variables (i.e., intensity,volume, and rest periods) affects the endocrine response to exercise;however, the influence of dietary nutrients on basal andexercise-induced concentrations of hormones is less understood. Thepresent study examined the relationship between dietary nutrients andresting and exercise-induced blood concentrations of testosterone (T)and cortisol (C). Twelve men performed a bench press exercise protocol(5 sets to failure using a 10-repetitions maximum load) and a jumpsquat protocol (5 sets of 10 repetitions using 30% of each subject's1-repetition maximum squat) with 2 min of rest between all sets. Ablood sample was obtained at preexercise and 5 min postexercise fordetermination of serum T and C. Subjects also completed detaileddietary food records for a total of 17 days. There was a significant(P  0.05) increase in postexercise Tcompared with preexercise values for both the bench press (7.4%) andjump squat (15.1%) protocols; however, C was not significantly different from preexercise concentrations. Significantcorrelations were observed between preexercise T and percent energyprotein (r = 0.71), percentenergy fat (r = 0.72), saturated fattyacids (g ^· 1,000 kcal^{1 ·} day¹;r = 0.77), monounsaturated fatty acids(g ^· 1,000 kcal^{1 ·} day¹;r = 0.79), the polyunsaturatedfat-to-saturated fat ratio (r = 0.63), and the protein-to-carbohydrate ratio (r = 0.59). There were nosignificant correlations observed between any nutritional variables andpreexercise C or the absolute increase in T and C after exercise. Thesedata confirm that high-intensity resistance exercise results inelevated postexercise T concentrations. A more impressive finding wasthat dietary nutrients may be capable of modulating restingconcentrations of T.

     

Pulmonary fluid extraction and osmotic conductance, sigma K, measured in vivo

The change in aortic blood density in an in vivo rabbitpreparation was measured to assess fluid movement at the pulmonary capillaries caused by infusion of hypertonic solution (NaCl, urea, glucose, sucrose, or raffinose in isotonic saline) into the vena cavaover 20 s. The hypertonic disturbance increased the plasma osmoticpressure by 30 mosmol/l. The density change indicates that the fluidextraction from the lung tissue was completed within 10 s. It wasfollowed by a fluid filtration into the lung tissue and then anextraction and filtration from peripheral organs. An exchange modelwith flow dispersion yields two equations to estimate the osmoticconductance (K; where is the reflection coefficient of the test solute andK is the filtration coefficient including the total capillary surface area), and the tissue fluid volume from the area and first moment of the measured density changeover the extraction phase. The values ofK are 1.40 ± 0.11, 1.00 ± 0.10, 1.71 ± 0.10, 2.60 ± 0.23, and 3.73 ± 0.34 (SE) ml · h¹ · mosmol¹ · l · g¹for NaCl, urea, glucose, sucrose, and raffinose, respectively. Consistent with the model prediction, the tissue fluid volume (0.28 ± 0.04 ml/g wet lung tissue) was independent of the solute used.This value suggests that all fluid spaces in the alveolar septaparticipate in the process of fluid extraction due to an increase inplasma osmotic pressure.

     

Enhanced ventilatory and exercise performance in athletes with slight expiratory resistive loading

Fee, Lawrence L., Richard M. Smith, and Michael B. English.Enhanced ventilatory and exercise performance in athletes withslight expiratory resistive loading. J. Appl.Physiol. 83(2): 503-510, 1997.We determined thecardiorespiratory and performance effects of slight (1.5-3.0cmH₂O) expiratory resistiveloading (ERL). Twenty-eight highly fit [peakO₂ uptake(O_{2 peak}) = 63.6 ± 1.3 ml · kg¹ · min¹]athletes (age = 33.5 ± 1.3 yr) performed pairedO_{2 peak} cycle ergometer tests (control vs. ERL). End-expiratory lung volume wasseparately determined in a subset of subjects(n = 12) at steady-state 75% maximumpower output (PO_max) and wasfound to increase (0.67 ± 0.29 liter) with ERL. In theO_{2 peak}tests, peak expiratory pressure at the mouth, mean inspiratory flow, minute ventilation, and O₂ pulsewere greater with ERL at every intensity level (i.e., 75, 80, 85, and90% PO_max). Increased minute ventilation was largely due to a trend toward increased tidal volume(P < 0.05 at 80%PO_max).O₂ uptake was greater at 90%PO_max with ERL. IncreasedO₂ pulse with ERL at comparativeworkloads suggests that stroke volume was augmented with ERL. Also,with ERL, athletes attained higherO_{2 peak} (63.0 ± 1.4 vs. 60.1 ± 1.3 ml · kg¹ · min¹)and greater PO_max (352.0 ± 9.9 vs. 345.7 ± 9.5 W). We conclude that elevated end-expiratory lungvolume in response to slight ERL during strenuous exercise served toattenuate both airflow and blood flow limitations, which enhancedexercise capacity.

     

Low energy availability, not stress of exercise, alters LH pulsatility in exercising women

Loucks, A. B., M. Verdun, and E. M. Heath. Low energyavailability, not stress of exercise, alters LH pulsatility in exercising women. J. Appl. Physiol.84(1): 37-46, 1998.We tested two hypotheses about the disruptionof luteinizing hormone (LH) pulsatility in exercising women by assayingLH in blood samples drawn at 10-min intervals over 24 h from nineyoung, habitually sedentary, regularly menstruating women ondays 8,9, or10 of two menstrual cycles after 4 days of intense exercise [E = 30 kcal · kg leanbody mass(LBM)¹ · day¹at 70% of aerobic capacity]. To test the hypothesis that LHpulsatility is disrupted by low energy availability, we controlled thesubjects' dietary energy intakes (I) to set theirenergy availabilities (A = I  E) at 45 and 10 kcal · kgLBM¹ · day¹during the two trials. To test the hypothesis that LH pulsatility isdisrupted by the stress of exercise, we compared the resulting LHpulsatilities to those previously reported in women with similar controlled energy availability who had not exercised. In the exercising women, low energy availability reduced LH pulse frequency by 10% (P < 0.01) during thewaking hours and increased LH pulse amplitude by 36%(P = 0.05) during waking and sleepinghours, but this reduction in LH pulse frequency was blunted by 60%(P = 0.03) compared with that in thepreviously studied nonexercising women whose low energy availabilitywas caused by dietary restriction. The stress of exercise neitherreduced LH pulse frequency nor increased LH pulse amplitude (allP > 0.4). During exercise, theproportion of energy derived from carbohydrate oxidation was reducedfrom 73% while A = 45 kcal · kgLBM¹ · day¹to 49% while A = 10 kcal · kgLBM¹ ·day¹(P < 0.0001). These resultscontradict the hypothesis that LH pulsatility is disrupted by exercisestress and suggest that LH pulsatility in women depends on energyavailability.

     

Venous and arterial reflex responses to positive-pressure breathing and lower body negative pressure

Peters, Jochen K., George Lister, Ethan R. Nadel, and GaryW. Mack. Venous and arterial reflex responses to positive-pressure breathing and lower body negative pressure. J. Appl.Physiol. 82(6): 1889-1896, 1997.We examined therelative importance of arteriolar and venous reflex responses duringreductions in cardiac output provoked by conditions that increase[positive end-expiratory pressure (PEEP)] or decrease[lower body negative pressure (LBNP)] peripheral venous filling.Five healthy subjects were exposed to PEEP (10, 15, 20, and 25 cmH₂O) and LBNP (10,15, 20, and 25 mmHg) to induce progressive butcomparable reductions in right atrial transmural pressure (control tominimum): from 5.9 ± 0.4 to 1.8 ± 0.7 and from 6.5 ± 0.6 to2.0 ± 0.2 mmHg with PEEP and LBNP, respectively. Cardiac output(impedance cardiography) fell less during PEEP than during LBNP (from3.64 ± 0.21 to 2.81 ± 0.21 and from 3.39 ± 0.21 to 2.14 ± 0.24 l · min¹ · m²with PEEP and LBNP, respectively), and mean arterial pressure increased. We observed sustained increases in forearm vascular resistance (i.e., forearm blood flow by venous occlusionplethysmography) and systemic vascular resistance that were greaterduring LBNP: from 19.7 ± 2.91 to 27.97 ± 5.46 and from 20.56 ± 2.48 to 50.25 ± 5.86 mmHg · ml¹ · 100 mltissue¹ · min(P < 0.05) during PEEP and LBNP,respectively. Venomotor responses (venous pressure in thehemodynamically isolated limb) were always transient, significant onlywith the greatest reduction in right atrial transmural pressure, andwere similar for LBNP and PEEP. Thus arteriolar rather than venousresponses are predominant in blood volume mobilization from skin andmuscle, and venoconstriction is not intensified with venous engorgementduring PEEP.

     

Differences between estimates and measured PaCO2 during rest and exercise in older subjects

Williams, J. S., and T. G. Babb. Differences betweenestimates and measured Pa_CO2 during restand exercise in older subjects. J. Appl.Physiol. 83(1): 312-316, 1997.ArterialPCO₂ (Pa_CO2) has been estimated duringexercise with good accuracy in younger individuals by using the Jonesequation(P_JCO₂)(J. Appl. Physiol. 47: 954-960,1979). The purpose of this project was to determine the utility ofestimating Pa_CO2 from end-tidal PCO₂(PET_CO2) orP_JCO₂at rest, ventilatory threshold (Th), and maximalexercise (Max) in older subjects. PET_CO2 was determined fromrespired gases simultaneously (MGA 1100) with arterial blood gases(radial arterial catheter) in 12 older and 11 younger subjects at restand during exercise. Mean differences were analyzed with pairedt-tests, and relationships between theestimated Pa_CO2 values and the actualvalues of Pa_CO2 were determined withcorrelation coefficients. In the older subjects, PET_CO2 was not significantlydifferent from Pa_CO2 at rest (1.2 ± 4.3 Torr), Th (0.4 ± 2.5), or Max(0.8 ± 2.7), and the two were significantly(P < 0.05) correlated atth (r = 0.84) andMax (r = 0.87) but not atrest (r = 0.47).P_JCO₂was similar to Pa_CO2 at rest (1.0 ± 3.9) and th (1.3 ± 2.3) but significantly lower at Max (3.0 ± 2.6), and the two weresignificantly correlated at th(r = 0.86) and Max(r = 0.80) but not at rest (r = 0.54).PET_CO2 was significantlyhigher than Pa_CO2 during exercise in theyounger subjects but similar to Pa_CO2 at rest.P_JCO₂was similar to Pa_CO2 at rest andth but significantly lower at Max in youngersubjects. In conclusion, our data demonstrate thatPa_CO2 during exercise is betterestimated by PET_CO2 than byP_JCO₂in older subjects, contrary to what is observed in younger subjects.This appears to be related to the finding thatPET_CO2 does not exceedPa_CO2 during exercise in older subjects,as occurs in the younger subjects. However,Pa_CO2 at rest is best estimated byP_JCO₂in both younger and older subjects.