Parasympathetic reactivation after repeated sprint exercise

The purpose of this study was to examine the effects of muscular power engagement, anaerobic participation, aerobic power level, and energy expenditure on postexercise parasympathetic reactivation. We compared the response of heart rate (HR) after repeated sprinting with that of exercise sessions of comparable net energy expenditure and anaerobic energy contribution. Fifteen moderately trained athletes performed 1) 18 maximal all-out 15-m sprints interspersed with 17 s of passive recovery (RS), 2) a moderate isocaloric continuous exercise session (MC) at a level of mean oxygen uptake similar to that of the RS trial, and 3) a high-intensity intermittent exercise session (HI) conducted at a level of anaerobic energy expenditure similar to that of the RS trial. Subjects were immediately seated after the exercise trials, and beat-to-beat HR was recorded for 10 min. Parasympathetic reactivation was evaluated through 1) immediate postexercise HR recovery, 2) the time course of the root mean square for the successive R-R interval difference between successive 30-s segments (RMSSD(30s)) and 3) HR variability vagal-related indexes calculated for the last 5-min stationary period of recovery. RMSSD(30s) increased during the 10-min period after the MC trial, whereas RMSSD(30s) remained depressed after both the RS and HI trials. Parasympathetic reactivation indexes were similar for the RS and HI trials but lower than for the MC trial (P < 0.001). When data of the three exercise trials were considered together, only anaerobic contribution was related to HR trial-derived indexes. Parasympathetic reactivation is highly impaired after RS exercise and appears to be mainly related to anaerobic process participation.     

Oxidative metabolism and anaerobic glycolysis during repeated exercise

The purpose of the present study was to examine aerobic and muscle anaerobic energy production during supramaximal repeated exercise. Eight subjects performed three 2-min bouts of cycling (EX1-EX3) at an intensity corresponding to about 125 % of VO2 max separated by 15 min of rest. Ventilatory variables were measured breath by breath during the exercise and a muscle biopsy was taken before and after each exercise bout. Blood samples were collected before and after each cycling period and during the recovery periods. Total work in the first 2 min bout of cycling, EX1, [46.3 +/- 2.1 KJ] was greater than in the second, EX2, (p < 0.01) and in the third, EX3, (p < 0.05). The ATP utilization [4.0 +/- 1.4 mmol x (kg dry weight)(-1), EX1] during the three exercise bouts was the same. The decrement in muscle phosphocreatine (PCr) [46.8 +/- 8.5 mmol x (kg dry weight)(-1), EX1] was also similar for the three exercise bouts. Muscle lactate accumulation was greater (p < 0.05) during EX1 compared to EX2 and EX3. The total oxygen consumption was the same for the three exercise bouts, but when it is corrected for the total work performed, oxygen uptake during EX2 (153 +/- 9 ml x KJ(-1)) and EX3 (150 +/- 9 ml x KJ(-1)) was higher (p < 0.01 and p < 0.05, respectively) than during EX1 (139 +/- 8 ml x KJ(-1)). The present data suggest that oxidative metabolism does not compensate for the reduction of anaerobic glycolysis during repeated fatiguing exercise.     

Effects of prior exercise on muscle metabolism during sprint exercise in horses.

The effect of warm-up exercise on energy metabolism and muscle glycogenolysis during sprint exercise (Spr) was examined in six fit Standardbred horses exercised at 115% of maximal O(2) consumption (VO(2 max)) until fatigued, 5 min after each of three protocols: 1) no warm-up (NWU); 2) 10 min at 50% of VO(2 max) [low-intensity warm-up (LWU)]; and 3) 7 min at 50% VO(2 max) followed by 45-s intervals at 80, 90, and 100% VO(2 max) [high-intensity warm-up (HWU)]. Warm-up increased (P < 0.0001) muscle temperature (T(m)) at the onset of Spr in LWU (38.3 +/- 0.2 degrees C) and HWU (40.0 +/- 0. 3 degrees C) compared with NWU (36.6 +/- 0.2 degrees C), and the rate of rise in T(m) during Spr was greater in NWU than in LWU and HWU (P < 0.01). Peak VO(2) was higher and O(2) deficit lower (P < 0. 05) when Spr was preceded by warm-up. Rates of muscle glycogenolysis were lower (P < 0.05) in LWU, and rates of blood and muscle lactate accumulation and anaerobic ATP provision during Spr were lower in LWU and HWU compared with NWU. Mean runtime (s) in LWU (173 +/- 10 s) was greater than HWU (142 +/- 11 s) and NWU (124 +/- 4 s) (P < 0. 01). Warm-up was associated with augmentation of aerobic energy contribution to total energy expenditure, decreased glycogenolysis, and longer run time to fatigue during subsequent sprint exercise, with no additional benefit from HWU vs. LWU.     

Heritability of aerobic power and anaerobic energy generation during exercise

Twenty-nine pairs of monozygotic twins and 19 pairs of dizygotic twins, all male, ages 18-31 yr, performed a graded uninterrupted exercise test on the bicycle ergometer to exhaustion. By use of path analysis, the genetic variance of measured peak O2 uptake was estimated at 77% (P less than 0.001), at 71% (P less than 0.001) after adjustment for weight and skinfold thickness, and at 66% (P less than 0.001) after additional adjustment for weekly hours of sports participation. O2 uptake at a heart rate of 150 beats/min, a submaximal estimate of exercise capacity, showed less genetic variance, i.e., 61% (P less than 0.001) before and 50% (P less than 0.001) after weight adjustment and only 16% (NS) after correction for life-style factors. Similarly, the heritability of peak O2 uptake, when estimated from submaximal data, was 68% (P less than 0.001), 40% (P = 0.05), and 26% (NS), respectively. Mechanical efficiency had no significant genetic component. O2 uptake at the respiratory exchange ratio of 0.95 and the slope of the curvilinear relationship between CO2 output and O2 uptake, used to assess the anaerobic energy generation during progressive exercise, showed significant (P less than 0.001) genetic variance before (72 and 74%) and after adjustment for weight (67 and 69%) and sports participation (63 and 57%). The heritability of peak aerobic power remained significant (58%; P less than 0.001) after adjustment for these expressions of anaerobic energy generation. In conclusion, the genetic variance of measured peak O2 uptake is significant and persists after adjustment for anthropometric characteristics, life-style factors, anaerobic energy generation, and mechanical efficiency.(ABSTRACT TRUNCATED AT 250 WORDS)     

Human power output during repeated sprint cycle exercise: the influence of thermal stress

Thermal stress is known to impair endurance capacity during moderate prolonged exercise. However, there is relatively little available information concerning the effects of thermal stress on the performance of high-intensity short-duration exercise. The present experiment examined human power output during repeated bouts of short-term maximal exercise. On two separate occasions, seven healthy males performed two 30-s bouts of sprint exercise (sprints I and II), with 4 min of passive recovery in between, on a cycle ergometer. The sprints were performed in both a normal environment [18.7 (1.5) degrees C, 40 (7)% relative humidity (RH; mean SD)] and a hot environment [30.1 (0.5) degrees C, 55 (9)% RH]. The order of exercise trials was randomised and separated by a minimum of 4 days. Mean power, peak power and decline in power output were calculated from the flywheel velocity after correction for flywheel acceleration. Peak power output was higher when exercise was performed in the heat compared to the normal environment in both sprint I [910 (172) W vs 656 (58) W; P < 0.01] and sprint II [907 (150) vs 646 (37) W; P < 0.05]. Mean power output was higher in the heat compared to the normal environment in both sprint I [634 (91) W vs 510 (59) W; P < 0.05] and sprint II [589 (70) W vs 482 (47) W; P < 0.05]. There was a faster rate of fatigue (P < 0.05) when exercise was performed in the heat compared to the normal environment. Arterialised-venous blood samples were taken for the determination of acid-base status and blood lactate and blood glucose before exercise, 2 min after sprint I, and at several time points after sprint II. Before exercise there was no difference in resting acid-base status or blood metabolites between environmental conditions. There was a decrease in blood pH, plasma bicarbonate and base excess after sprint I and after sprint II. The degree of post-exercise acidosis was similar when exercise was performed in either of the environmental conditions. The metabolic response to exercise was similar between environmental conditions; the concentration of blood lactate increased (P < 0.01) after sprint I and sprint II but there were no differences in lactate concentration when comparing the exercise bouts performed in a normal and a hot environment. These data demonstrate that when brief intense exercise is performed in the heat, peak power output increases by about 25% and mean power output increases by 15%; this was due to achieving a higher pedal cadence in the heat.     

Human growth hormone response to repeated bouts of aerobic exercise

Kanaley, J. A., J. Y. Weltman, J. D. Veldhuis, A. D. Rogol,M. L. Hartman, and A. Weltman. Human growth hormone response torepeated bouts of aerobic exercise. J. Appl.Physiol. 83(5): 1756-1761, 1997.We examinedwhether repeated bouts of exercise could override growth hormone (GH)auto-negative feedback. Seven moderately trained men were studied onthree occasions: a control day (C), a sequential exercise day (SEB; at1000, 1130, and 1300), and a delayed exercise day (DEB; at 1000, 1400, and 1800). The duration of each exercise bout was 30 min at 70%maximal O₂ consumption (O_{2 max}) on a cycleergometer. Standard meals were provided at 0600 and 2200. GH wasmeasured every 5-10 min for 24 h (0800-0800). Daytime(0800-2200) integrated GH concentrations were ~150-160% greater during SEB and DEB than during C: 1,282 ± 345, 3,192 ± 669, and 3,389 ± 991 min · µg · l¹for C, SEB, and DEB, respectively [SEB > C(P < 0.06), DEB > C(P < 0.03)]. There were nodifferences in GH release during sleep (2300-0700). Deconvolutionanalysis revealed that the increase in 14-h integrated GH concentrationon DEB was accounted for by an increase in the mass of GH secreted perpulse (per liter of distribution volume,l_v): 7.0 ± 2.9 and 15.9 ± 2.6 µg/l_v for C and DEB,respectively (P < 0.01). Comparisonof 1.5-h integrated GH concentrations on the SEB and DEB days (30 minexercise + 60 min recovery) revealed that, with each subsequentexercise bout, GH release apparently increased progressively, with aslightly greater increase on the DEB day [SEB vs. DEB: 497 ± 162 vs. 407 ± 166 (bout 1), 566 ± 152 vs. 854 ± 184 (bout2), and 633 ± 149 vs. 1,030 ± 352 min · µg · l¹(bout 3),P < 0.05]. We conclude thatthe GH response to acute aerobic exercise is augmented with repeatedbouts of exercise.

     

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.

     

Effects of gradient and age on energy expenditure and fat metabolism during aerobic exercise at equal intensity in women

[Purpose]This study aimed to investigate the effects of gradient and age on energy expenditure and fat metabolism during aerobic exercise at equal intensity in women.[Methods] Thirty women in their twenties (n=15) and fifties (n=15) were enrolled. All subjects performed aerobic exercise on a treadmill for 10 min at 0% and 6% gradient repeatedly to elicit 50%, 60%, and 70% VO₂max.[Results]Energy expenditure and fat oxidation were higher during aerobic exercise at 6% of the gradient than at 0%, and there was no significant difference in carbohydrate oxidation in any age group.[Conclusion]Aerobic exercise at a 6% gradient was more favorable for fat oxidation than a 0% gradient in all age groups. In particular, in the case of women in their fifties, walking on a gradient of 6%, which is favorable for increasing fat oxidation, was more effective than walking on flat ground for preventing and reducing obesity. However, to examine the difference in fat oxidation among exercise intensities more accurately, exercise performed for longer than 30 min is required. Follow-up studies are required to investigate the effect of various gradients on physiological and metabolic characteristics when carrying out aerobic exercises for more than 30 min.     

Adipose tissue lipolysis is increased during a repeated bout of aerobic exercise.

The goal of the study was to examine whether lipid mobilization from adipose tissue undergoes changes during repeated bouts of prolonged aerobic exercise. Microdialysis of the subcutaneous adipose tissue was used for the assessment of lipolysis; glycerol concentration was measured in the dialysate leaving the adipose tissue. Seven male subjects performed two repeated bouts of 60-min exercise at 50% of their maximal aerobic power, separated by a 60-min recovery period. The exercise-induced increases in extracellular glycerol concentrations in adipose tissue and in plasma glycerol concentrations were significantly higher during the second exercise bout compared with the first (P < 0.05). The responses of plasma nonesterified fatty acids and plasma epinephrine were higher during the second exercise bout, whereas the response of norepinephrine was unchanged and that of growth hormone lower. Plasma insulin levels were lower during the second exercise bout. The results suggest that adipose tissue lipolysis during aerobic exercise of moderate intensity is enhanced when an exercise bout is preceded by exercise of the same intensity and duration performed 1 h before. This response pattern is associated with an increase in the exercise-induced rise of epinephrine and with lower plasma insulin values during the repeated exercise bout.     

Contribution of NADH oxidase to aerobic metabolism of Streptococcus pyogenes

An understanding of how the heme-deficient gram-positive bacterium Streptococcus pyogenes establishes infections in O(2)-rich environments requires careful analysis of the gene products important in aerobic metabolism. NADH oxidase (NOXase) is a unique flavoprotein of S. pyogenes and other lactic acid bacteria which directly catalyzes the four-electron reduction of O(2) to H(2)O. To elucidate a putative role for this enzyme in aerobic metabolism, NOXase-deficient mutants were constructed by insertional inactivation of the gene that encodes NOXase. Characterization of the resulting mutants revealed that growth in rich medium under low-O(2) conditions was indistinguishable from that of the wild type. However, the mutants were unable to grow under high-O(2) conditions and demonstrated enhanced sensitivity to the superoxide-generating agent paraquat. Mutants cultured in liquid medium under conditions of carbohydrate limitation and high O(2) tension were characterized by an extended lag phase, a reduction in growth, and a greater accumulation of H(2)O(2) in the growth medium compared to the wild-type strain. All of these mutant phenotypes could be overcome by the addition of glucose. Either the addition of catalase to the culture medium of the mutants or the introduction of a heterologous NADH peroxidase into the mutants eliminated the accumulation of H(2)O(2) and rescued the growth defect of the mutants under high-O(2) conditions in carbohydrate-limited liquid medium. Taken together, these data show that NOXase is important for aerobic metabolism and essential in environments high in O(2) with carbohydrate limitation.     

Energy metabolism during repeated sets of leg press exercise leading to failure or not

This investigation examined the influence of the number of repetitions per set on power output and muscle metabolism during leg press exercise. Six trained men (age 34 ± 6 yr) randomly performed either 5 sets of 10 repetitions (10REP), or 10 sets of 5 repetitions (5REP) of bilateral leg press exercise, with the same initial load and rest intervals between sets. Muscle biopsies (vastus lateralis) were taken before the first set, and after the first and the final sets. Compared with 5REP, 10REP resulted in a markedly greater decrease (P<0.05) of the power output, muscle PCr and ATP content, and markedly higher (P<0.05) levels of muscle lactate and IMP. Significant correlations (P<0.01) were observed between changes in muscle PCr and muscle lactate (R(2) = 0.46), between changes in muscle PCr and IMP (R(2) = 0.44) as well as between changes in power output and changes in muscle ATP (R(2) = 0.59) and lactate (R(2) = 0.64) levels. Reducing the number of repetitions per set by 50% causes a lower disruption to the energy balance in the muscle. The correlations suggest that the changes in PCr and muscle lactate mainly occur simultaneously during exercise, whereas IMP only accumulates when PCr levels are low. The decrease in ATP stores may contribute to fatigue.     

Human muscle metabolism during sprint running

Biopsy samples were obtained from vastus lateralis of eight female subjects before and after a maximal 30-s sprint on a nonmotorized treadmill and were analyzed for glycogen, phosphagens, and glycolytic intermediates. Peak power output averaged 534.4 +/- 85.0 W and was decreased by 50 +/- 10% at the end of the sprint. Glycogen, phosphocreatine, and ATP were decreased by 25, 64, and 37%, respectively. The glycolytic intermediates above phosphofructokinase increased approximately 13-fold, whereas fructose 1,6-diphosphate and triose phosphates only increased 4- and 2-fold. Muscle pyruvate and lactate were increased 19 and 29 times. After 3 min recovery, blood pH was decreased by 0.24 units and plasma epinephrine and norepinephrine increased from 0.3 +/- 0.2 nmol/l and 2.7 +/- 0.8 nmol/l at rest to 1.3 +/- 0.8 nmol/l and 11.7 +/- 6.6 nmol/l. A significant correlation was found between the changes in plasma catecholamines and estimated ATP production from glycolysis (norepinephrine, glycolysis r = 0.78, P less than 0.05; epinephrine, glycolysis r = 0.75, P less than 0.05) and between postexercise capillary lactate and muscle lactate concentrations (r = 0.82, P less than 0.05). The study demonstrated that a significant reduction in ATP occurs during maximal dynamic exercise in humans. The marked metabolic changes caused by the treadmill sprint and its close simulation of free running makes it a valuable test for examining the factors that limit performance and the etiology of fatigue during brief maximal exercise.     

Effect of creatine supplementation on sprint exercise performance and muscle metabolism

The aim of thepresent study was to examine the effect of creatine supplementation(CrS) on sprint exercise performance and skeletal muscle anaerobicmetabolism during and after sprint exercise. Eight active, untrainedmen performed a 20-s maximal sprint on an air-braked cycle ergometerafter 5 days of CrS [30 g creatine (Cr) + 30 g dextrose perday] or placebo (30 g dextrose per day). The trials wereseparated by 4 wk, and a double-blind crossover design was used. Muscleand blood samples were obtained at rest, immediately after exercise,and after 2 min of passive recovery. CrS increased the muscle total Crcontent (9.5 ± 2.0%, P < 0.05, mean ± SE); however, 20-s sprint performance was not improved byCrS. Similarly, the magnitude of the degradation or accumulation ofmuscle (e.g., adenine nucleotides, phosphocreatine, inosine 5'-monophosphate, lactate, and glycogen) and plasma metabolites (e.g., lactate, hypoxanthine, and ammonia/ammonium) were also unaffected by CrS during exercise or recovery. These data demonstrated that CrS increased muscle total Cr content, but the increase did notinduce an improved sprint exercise performance or alterations inanaerobic muscle metabolism.

     

Relative importance of aerobic and anaerobic energy release during short-lasting exhausting bicycle exercise

Anaerobic energy release is of great importance for shortlasting exercise but has been difficult to quantify. In order to determine the amount of anaerobic energy release during shortlasting exercise we let 17 healthy young males exercise on the ergometer bike to exhaustion. The power during exercise was kept constant and selected to cause exhaustion in approximately 30 s, 1 min, or 2-3 min. The O2 uptake was measured continuously during the exercise, and the anaerobic energy release was quantified by the accumulated O2 deficit. The work done as well as the total energy release rose linearly with the exercise duration and was therefore a sum of a component proportional to time plus a constant addition. The accumulated O2 deficit increased from 1.86 +/- 0.07 (SE) mmol/kg for 30 s exercise to 2.25 +/- 0.06 mmol/kg for 1 min exercise and further to 2.42 +/- 0.08 mmol/kg for exercise lasting 2 min or more (P less than 0.01). The accumulated O2 uptake increased linearly with the duration, and as a consequence of this the relative importance of aerobic processes increased from 40% at 30 s duration to 50% at 1 min duration and further to 65% for exercise lasting 2 min. These results show that both aerobic and anaerobic processes contribute significantly during intense exercise lasting from 30 s to 3 min.     

有氧运动对衰老大鼠骨骼肌线粒体能量代谢的影响

目的：探讨有氧运动对衰老大鼠骨骼肌线粒体能量代谢的影响。方法：将20只12月龄的雌性Wistar大鼠随机分为老年安静组（AC,n=10）及老年运动组（AE,n=10）,另取10只2月龄的雌性Wistar大鼠为青年安静组（YC,n=10）;安静组大鼠进行正常饲养,运动组大鼠进行坡度为5°,速度为15.2 m/min,第1天运动15 min、第2天运动30 min、从第3天开始每天运动45 min,每周6 d,共12周。12周后所有大鼠断头处死,取腓肠肌样本,差速离心法提取线粒体,测定SOD和GSH-Px活性、MDA含量、三羧酸循环限速酶（CS、ICD和α-KGDHC）活性及呼吸链酶复合体（RCCⅠ~Ⅳ）活性。结果：①与YC组相比,AC组骨骼肌线粒体SOD活性和MDA含量显著增加（P<0.05）,CS和α-KGDHC活性均显著降低（P<0.05）,RCCⅠ、RCCⅡ和RCCⅣ活性均显著下降（P<0.05）,RCCⅢ活性显著升高（P<0.05）;AE组骨骼肌线粒体SOD、GSH-Px活性和MDA含量均显著增加（P<0.01）,CS、ICD和α-KGDHC活性均显著升高（P<0.01）,RCCⅠ~Ⅳ活性均显著升高（P<0.01）。②与AC组相比,AE组骨骼肌线粒体SOD、GSH-Px活性均显著升高（P<0.05）,MDA含量显著下降（P<0.05）,CS、ICD、α-KGDHC和RCCⅠ~Ⅳ活性均显著升高（P<0.01）。结论：有氧运动可以提高老年大鼠骨骼肌线粒体抗氧化能力,降低脂质过氧化水平,提高三羧酸循环及呼吸链功能,促进线粒体能量代谢,延缓衰老过程中线粒体的退行性变化。     

Effects of sprint duration and exercise: rest ratio on repeated sprint performance and physiological responses in professional soccer players

The purpose of this study was to examine the physiological effects of different sprint repetition protocols on professional footballers. Of particular interest were the abilities of repeated sprint protocols to induce fatigue to an extent observed during competitive soccer. Six professional soccer players were assessed for fatigue rate and physiological responses of heart rate (HR), blood lactate (BLa), and rating of perceived exertion (RPE) during the performance of 4 repeated sprint drills, each totaling a sprint distance of 600 m. The 4 drills used 15- or 40-m sprints with 1:4 or 1:6 exercise: rest ratios. The 15-m sprint drill with 1:4 exercise:rest ratio induced the greatest fatigue (final sprint time 15% greater than initial sprint time) and greatest physiological responses. The 40-m sprint drill using a 1:4 exercise:rest ratio produced similar BLa and HR responses to the 15-m drill (13-14 mmol.L(-1) and 89% HRmax, respectively) but significantly lower RPE (mean +/- SD: 17.1 +/- 0.4 vs. 18.8 +/- 0.4, p < 0.05) and fatigue rates (11.1 vs. 15.0%, p < 0.01). Both sprint distance and exercise:rest ratio independently influenced fatigue rate, with the 15-m sprint distance and the 1:4 exercise:rest ratio inducing significantly (p < 0.01) greater fatigue than the 40-m sprint distance and the 1:6 exercise:rest ratio. The magnitude of fatigue during the 40- x 15-m sprint drill using a 1:6 exercise:rest ratio was 7.5%, which is close to the fatigue rate previously reported during actual soccer play. The present study is the first to examine both variations in sprint distances and rest ratios simultaneously, and the findings may aid the design of repeated sprint training for soccer.     

Skeletal muscle metabolism during high-intensity sprint exercise is unaffected by dichloroacetate or acetate infusion.

This study investigated whether increased provision of oxidative substrate would reduce the reliance on nonoxidative ATP production and/or increase power output during maximal sprint exercise. The provision of oxidative substrate was increased at the onset of exercise by the infusion of acetate (AC; increased resting acetylcarnitine) or dichloroacetate [DCA; increased acetylcarnitine and greater activation of pyruvate dehydrogeanse (PDH-a)]. Subjects performed 10 s of maximal cycling on an isokinetic ergometer on three occasions after either DCA, AC, or saline (Con) infusion. Resting PDH-a with DCA was increased significantly over AC and Con trials (3.58 +/- 0.4 vs. 0.52 +/- 0.1 and 0.74 +/- 0.1 mmol. kg wet muscle(-1). min(-1)). DCA and AC significantly increased resting acetyl-CoA (35.2 +/- 4.4 and 22.7 +/- 2.9 vs. 10.2 +/- 1.3 micromol/kg dry muscle) and acetylcarnitine (12.9 +/- 1.4 and 11.0 +/- 1.0 vs. 3.3 +/- 0.6 mmol/kg dry muscle) over Con. Resting contents of phosphocreatine, lactate, ATP, and glycolytic intermediates were not different among trials. Average power output and total work done were not different among the three 10-s sprint trials. Postexercise, PDH-a in AC and Con trials had increased significantly but was still significantly lower than in DCA trial. Acetyl-CoA did not increase in any trial, whereas acetylcarnitine increased significantly only in DCA. Exercise caused identical decreases in ATP and phosphocreatine and identical increases in lactate, pyruvate, and glycolytic intermediates in all trials. These data suggest that there is an inability to utilize extra oxidative substrate (from either stored acetylcarnitine or increased PDH-a) during exercise at this intensity, possibly because of O(2) and/or metabolic limitations.     

IMP production and energy metabolism during exercise in rats in relation to age.

IMP production in and force exerted by rat quadriceps muscle in situ during various types of exercise were examined in relation to age. During continuous isometric exercise with constant stimulation time, the amount of IMP was linearly and inversely related to the age of the animals; a higher IMP concentration was found in intermittent isometric and dynamic exercise. No relationship was found between the total AMP deaminase activity and age. Exercise influenced neither the total activity nor the activity in the soluble fraction. From the results it is concluded that: the IMP concentration is linearly related to the free intracellular ATP4-/ADP3- ratio and the free AMP2- concentration; older animals are better able to maintain a high intramuscular ATP4-/ADP3- ratio and a low AMP2- concentration; IMP is produced in particular under conditions when the muscle has to work under extreme stress. IMP possibly exerts a feed-back control on the contraction system.