Prior eccentric contractions impair maximal insulin action on muscle glucose uptake in the conscious rat

Asp, Sven, Allan Watkinson, Nicholas D. Oakes, and Edward W. Kraegen. Prior eccentric contractions impair maximal insulin action on muscle glucose uptake in the conscious rat.J. Appl. Physiol. 82(4):1327-1332, 1997.Our aim was to examine the effect of prioreccentric contractions on insulin action locally in muscle in theintact conscious rat. Anesthetized rats performed one-leg eccentriccontractions through the use of calf muscle electrical stimulationfollowed by stretch of the active muscles. Two days later, basal andeuglycemic clamp studies were conducted with the rats in the awakefasted state. Muscle glucose metabolism was estimated from2-[¹⁴C(U)]deoxy-D-glucoseandD-[3-³H]glucose administration, and comparisons were made between the eccentrically stimulated and nonstimulated (control) calfmuscles. At midphysiological insulin levels, effects ofprior eccentric exercise on muscle glucose uptake were notstatistically significant. Maximal insulin stimulation revealed reducedincremental glucose uptake above basal(P < 0.05 in the red gastrocnemius;P < 0.1 in the white gastrocnemiusand soleus) and impaired net glycogen synthesis in all eccentricallystimulated muscles (P < 0.05). Weconclude that prior eccentric contractions impair maximal insulin action (responsiveness) on local muscle glucose uptake and glycogen synthesis in the conscious rat.

     

Evidence that nitric oxide increases glucose transport in skeletal muscle

Balon, Thomas W., and Jerry L. Nadler. Evidence thatnitric oxide increases glucose transport in skeletal muscle.J. Appl. Physiol. 82(1): 359-363, 1997.Nitric oxide synthase (NOS) is expressed in skeletal muscle.However, the role of nitric oxide (NO) in glucose transport in thistissue remains unclear. To determine the role of NO in modulatingglucose transport, 2-deoxyglucose (2-DG) transport was measured in ratextensor digitorum longus (EDL) muscles that were exposed to either amaximally stimulating concentration of insulin or to an electricalstimulation protocol, in the presence ofN^G-monomethyl-L-arginine,a NOS inhibitor. In addition, EDL preparations were exposed to sodiumnitroprusside (SNP), an NO donor, in the presence of submaximal andmaximally stimulating concentrations of insulin. NOS inhibition reducedboth basal and exercise-enhanced 2-DG transport but had no effect oninsulin-stimulated 2-DG transport. Furthermore, SNP increased 2-DGtransport in a dose-responsive manner. The effects of SNP and insulinon 2-DG transport were additive when insulin was present inphysiological but not in pharmacological concentrations. Chronictreadmill training increased protein expression of both type I and typeIII NOS in soleus muscle homogenates. Our results suggest that NO maybe a potential mediator of exercise-induced glucose transport.

     

More tetanic contractions are required for activating glucose transport maximally in trained muscle

Kawanaka, Kentaro, Izumi Tabata, and MitsuruHiguchi. More tetanic contractions are requiredfor activating glucose transport maximally in trained muscle.J. Appl. Physiol. 83(2): 429-433, 1997.Exercise training increases contraction-stimulated maximalglucose transport and muscle glycogen level in skeletal muscle.However, there is a possibility that more muscle contractions arerequired to maximally activate glucose transport in trained than inuntrained muscle, because increased glycogen level after training mayinhibit glucose transport. Therefore, the purpose of this study was toinvestigate the relationship between the increase in glucose transportand the number of tetanic contractions in trained and untrained muscle.Male rats swam 2 h/day for 15 days. In untrained epitrochlearis muscle,resting glycogen was 26.6 µmol glucose/g muscle. Ten, 10-s-longtetani at a rate of 1 contraction/min decreased glycogen level to 15.4 µmol glucose/g muscle and maximally increased2-deoxy-D-glucose(2-DG) transport. Training increasedcontraction-stimulated maximal 2-DG transport (+71%;P < 0.01), GLUT-4 protein content(+78%; P < 0.01), and restingglycogen level (to 39.3 µmol glucose/g muscle;P < 0.01) on the next day after thetraining ended, although this training effect might be due, at least inpart, to last bout of exercise. In trained muscle, 20 tetani werenecessary to maximally activate glucose transport. Twenty tetanidecreased muscle glycogen to a lower level than 10 tetani (18.9 vs.24.0 µmol glucose/g muscle; P < 0.01). Contraction-stimulated 2-DG transport was negatively correlatedwith postcontraction muscle glycogen level in trained (r = 0.60;P < 0.01) and untrained muscle(r = 0.57;P < 0.01).

     

Wortmannin inhibits both insulin- and contraction-stimulated glucose uptake and transport in rat skeletal muscle

Wojtaszewski, Jørgen F. P., Bo F. Hansen, BirgitteUrsø, and Erik A. Richter. Wortmannin inhibits both insulin-and contraction-stimulated glucose uptake and transport in rat skeletal muscle. J. Appl. Physiol. 81(4):1501-1509, 1996.The role of phosphatidylinositol (PI) 3-kinasefor insulin- and contraction-stimulated muscle glucose transport wasinvestigated in rat skeletal muscle perfused with a cell-freeperfusate. The insulin receptor substrate-1-associated PI 3-kinaseactivity was increased sixfold upon insulin stimulation but wasunaffected by contractions. In addition, the insulin-stimulated PI3-kinase activity and muscle glucose uptake and transport in individualmuscles were dose-dependently inhibited by wortmannin with one-halfmaximal inhibition values of ~10 nM and total inhibition at 1 µM.This concentration of wortmannin also decreased thecontraction-stimulated glucose transport and uptake by ~30-70%without confounding effects on contractility or on muscle ATP andphosphocreatine concentrations. At higher concentrations(3 and 10 µM), wortmannin completely blocked thecontraction-stimulated glucose uptake but also decreased thecontractility. In conclusion, inhibition of PI 3-kinase with wortmanninin skeletal muscle coincides with inhibition of insulin-stimulated glucose uptake and transport. Furthermore, in contrast to recent findings in incubated muscle, wortmannin also inhibitedcontraction-stimulated glucose uptake and transport. The inhibitoryeffect of wortmannin on contraction-stimulated glucose uptake may beindependent of PI 3-kinase activity or due to inhibition of asubfraction of PI 3-kinase with low sensitivity to wortmannin.

     

Voluntary exercise training enhances glucose transport in muscle stimulated by insulin-like growth factor I

Hokama, Jason Y., Ryan S. Streeper, and Erik J. Henriksen.Voluntary exercise training enhances glucose transport in muscle stimulated by insulin-like growth factor I. J. Appl. Physiol. 82(2): 508-512, 1997.Skeletal muscle glucosetransport can be regulated by hormonal factors such as insulin andinsulin-like growth factor I (IGF-I). Although it is well establishedthat exercise training increases insulin action on muscle glucosetransport, it is currently unknown whether exercise training leads toan enhancement of IGF-I-stimulated glucose transport in skeletal muscle. Therefore, we measured glucose transport activity [by using 2-deoxy-D-glucose (2-DG)uptake] in the isolated rat epitrochlearis muscle stimulated bysubmaximally and maximally effective concentrations of insulin (0.2 and13.3 nM) or IGF-I (5 and 50 nM) after 1, 2, and 3 wk of voluntary wheelrunning (WR). After 1 wk of WR, both submaximal andmaximal insulin-stimulated 2-DG uptake rates were significantly(P < 0.05) enhanced (43 and 31%)compared with those of sedentary controls, and these variables werefurther increased after 2 (86 and 57%) and 3 wk (71 and 70%) ofWR. Submaximal and maximal IGF-I-stimulated 2-DG uptakerates were significantly enhanced after 1 wk of WR (82 and 61%), andthese increases did not expand substantially after 2 (71 and 58%) and3 wk (96 and 70%) of WR. This enhancement of hormone-stimulated 2-DGuptake in WR muscles preceded any alteration in glucose transporter(GLUT-4) protein level, which increased only after 2 (24%) and 3 wk(54%) of WR. Increases in GLUT-4 protein were significantly correlated (r = 0.844) with increases in citratesynthase. These results indicate that exercise training can enhanceboth insulin-stimulated and IGF-I-stimulated muscle glucose transportactivity and that these improvements can develop without an increase inGLUT-4 protein.

     

Decreased contraction economy in mouse EDL muscle injured by eccentric contractions

Warren III, Gordon L., Jay H. Williams, Christopher W. Ward,Hideki Matoba, Christopher P. Ingalls, Karl M. Hermann, and R. B. Armstrong. Decreased contraction economy in mouse EDL muscleinjured by eccentric contractions. J. Appl.Physiol. 81(6): 2555-2564, 1996.The objective ofthis study was to find out whether basal and/or active energymetabolism are altered in isolated mouse extensor digitorum longusmuscle injured by eccentric (Ecc) contractions. Measurements of basalO₂ consumption and isometric tetanus O₂ recovery cost were madeat 25°C on muscles that had done either 10 Ecc, 10 isometric (Iso),or no contractions (No). In parallel experiments, rates of lactate andpyruvate production were measured to estimate the anaerobiccontribution. Basal O₂ consumptionwas unaffected by the type of protocol performed(P = 0.07). However, the tetanusO₂ cost per force-time integral was elevated by 30-36% for the Ecc protocol muscles over that forthe Iso and No protocol muscles. When including the increased lactateproduction by the Ecc protocol muscles, the total energetic cost perforce-time integral was 53% higher than that for the Iso protocolmuscles [2.35 ± 0.17 vs. 1.54 ± 0.18 µmolO₂/(N ^· m ^· s)].The decreased economy was attributed to two factors. First, in skinnedfibers isolated from the injured muscles, the ratio of maximalactomyosin adenosinetriphosphatase activity to force production was upby 37.5%, suggesting uncoupling of ATP hydrolysis from forceproduction. Second, increased reliance on anaerobic metabolism alongwith the fluorescent microscopic study of mitochondrial membranepotential and histochemical study of ATP synthase suggested anuncoupling of oxidative phosphorylation in the injured muscles.

     

Greater initial adaptations to submaximal muscle lengthening than maximal shortening

Hortobágyi, Tibor, Jason Barrier, David Beard, JohnBraspennincx, Peter Koens, Paul Devita, Line Dempsey, and Jean Lambert. Greater initial adaptations to submaximal muscle lengthening thanmaximal shortening. J. Appl. Physiol.81(4): 1677-1682, 1996.The purpose of this study was tocompare the short-term strength and neural adaptations to eccentric andconcentric training at equal force levels. Forty-two sedentary women(age = 21.5 yr) were ranked based on the initial quadriceps strengthscore, and trios of subjects were randomly assigned to either aneccentric (n = 14), a concentric (n = 14), or a nonexercising controlgroup (n = 14). Training involved atotal of 824 eccentric or concentric quadriceps actions at 1.05 rad ^· s¹administered in four sets of 6-10 repetitions, four times per weekfor 6 wk. Before and after training, all subjects were tested forunilateral maximal isometric and eccentric and concentric actions at1.05 rad ^· s¹and for a 40-repetition eccentric and concentric fatigue series of theleft and right quadriceps. Surface electromyographic activity of thevastus lateralis and medialis was monitored during testing. Concentrictraining increased concentric (36%, P < 0.05), isometric (18%, P < 0.05), and eccentric strength (13%), and eccentric training increasedeccentric (42%, P < 0.05),isometric (30%, P < 0.05), andconcentric (13%) strength. Eccentric training improved eccentric andisometric strength more (P < 0.05)than did concentric training. The electromyographic adaptations weregreater with eccentric training. Cross-education was 6%, and neithertraining mode modified fatigability. The data suggest that training ofthe quadriceps muscle with submaximal eccentric actions brings aboutgreater strength adaptations faster than does training withmaximal-level concentric actions in women. This greater adaptation islikely to be mediated by both mechanical and neural factors.

     

Neuromuscular factors contributing to in vivo eccentric moment generation

Webber, Sandra, and Dean Kriellaars. Neuromuscularfactors contributing to in vivo eccentric moment generation.J. Appl. Physiol. 83(1): 40-45, 1997.Muscle series elasticity and its contribution to eccentricmoment generation was examined in humans. While subjects [male,n = 30; age 26.3 ± 4.8 (SD) yr; body mass 78.8 ± 13.1 kg] performed an isometric contractionof the knee extensors at 60° of knee flexion, a quick stretch was imposed with a 12°-step displacement at 100°/s. The test wasperformed at 10 isometric activation levels ranging from 1.7 to 95.2%of maximal voluntary contraction (MVC). A strong linear relationship was observed between the peak imposed eccentric moment derived fromquick stretch and the isometric activation level(y = 1.44x + 7.08; r = 0.99). This increase in theeccentric moment is consistent with an actomyosin-dependent elasticitylocated in series with the contractile element of muscle. Byextrapolating the linear relationship to 100% MVC, the predictedmaximum eccentric moment was found to be 151% MVC, consistent with invitro data. A maximal voluntary, knee extensor strength test was alsoperformed (5-95°, 3 repetitions, ±50, 100, 150, 200, and250°/s). The predicted maximum eccentric moment was 206% of theangle- and velocity-matched, maximal voluntary eccentric moments. Thiswas attributed to a potent neural regulatory mechanism that limits therecruitment and/or discharge of motor units during maximalvoluntary eccentric contractions.

     

Modulation of myosin isoform expression by mechanical loading: role of stimulation frequency

Caiozzo, Vincent J., Michael J. Baker, and Kenneth M. Baldwin. Modulation of myosin isoform expression by mechanical loading: role of stimulation frequency. J. Appl.Physiol. 82(1): 211-218, 1997.This study testedthe hypothesis that mechanical loading, not stimulation frequency perse, plays a key role in determining the plasticity of myosin heavychain (MHC) protein isoform expression in muscle undergoing resistancetraining. Female Sprague-Dawley rats were randomly assigned toresistance-training programs that employed active1) shortening(n = 7) or2) lengthening contractions(n = 8). The medial gastrocnemius (MG)muscles in each group trained under loading conditions thatapproximated 90-95% of maximum isometric tetanictension but were stimulated at frequencies of 100 and~25 Hz, respectively. Lengthening and shortening contractions wereproduced by using a Cambridge ergometer system. The MG muscles trainedevery other day, performing a total of 16 training sessions. Bothtraining programs produced significant (P < 0.01) and similar reductions inthe fast type IIB MHC protein isoform in the white MG muscle, reducingits relative content to ~50% of the total MHC protein isoform pool.These changes were accompanied by increases in the relative content ofthe fast type IIX MHC protein isoform that were of similar magnitudefor both groups. The results of this study clearly demonstrate thatstimulation frequency does not play a key role in modulating MHCisoform alterations that result from high-resistance training.

     

Normal forces and myofibrillar disruption after repeated eccentric exercise

Hortobágyi, Tibor, Joseph Houmard, David Fraser,Ronald Dudek, Jean Lambert, and James Tracy. Normalforces and myofibrillar disruption after repeated eccentric exercise.J. Appl. Physiol. 84(2): 492-498, 1998.To investigate the "rapid-adaptation" phenomenon, weexamined force, neural, and morphological adaptations in 12 subjectswho performed 100 eccentric contractions with the quadriceps muscle(bout 1) and repeated the sameexercise after a 2-wk hiatus (bout2). Two days after bout1, quadriceps muscle strength and surfaceelectromyographic (EMG) activity declined ~37 and 28%, respectively,in the control group (n = 6). Atday 2 after bout 1, significant increases occurred in patellar tendonreflex amplitude (~25%), muscle soreness (fivefold), and serumcreatine kinase (220%), and 65 ± 12% of the total number of pixelsin the EMG indicated myofibrillar disruption. At day7 after bout 1, all variables returned to normal. At day 2 after bout 2, no significant changesoccurred in force, EMG, creatine kinase, or soreness, but reflexamplitude increased, and 23 ± 4% of the total number of pixels inthe EMG still indicated myofibrillar disruption. The results suggestthat the rapid force recovery following eccentric exercise is mediatedat least in part by neural factors and that this recovery may occurindependently of cell disruption.

     

Exercise and exhaustion effects on glycogen synthesis pathways

Gunderson, Hans, Nadja Wehmeyer, Diane Burnett, John Nauman,Cynthia Hartzell, and Scott Savage. Exercise and exhaustion effects on glycogen synthesis pathways. J. Appl.Physiol. 81(5): 2020-2026, 1996.FemaleSprague-Dawley rats were infused with [1-¹³C]glucose tomeasure the effect of endurance training and the effect of variousmetabolic conditions on pathways of hepatic glycogen synthesis. Fourmetabolic states [sedentary (S), trained (T), sedentary exhausted(SE), and trained exhausted (TE)] were studied. T and TE ratswere trained on a motor-driven treadmill (30 m/min, 15% grade, 1.0 h/day, 5 days/wk) for 8-10 wk. After a 24-h fast, SE and TE ratswere run to exhaustion (sedentary average = 78 min, trained average = 155 min) at a training pace and immediately infused with labeledglucose for 2 h. S and T rats were infused after a 24-h fast. Afterinfusion, tissues were removed and glycogen was isolated and hydrolyzedto glucose. The glucose was measured for distribution of¹³C by using nuclear magneticresonance. Glycogen was synthesized predominantly by the indirectpathway for all metabolic states, indicating that infused glucose wasfirst metabolized primarily in the peripheral tissue. Thedirect-pathway utilization was greater in rested S than in rested Tanimals (30 vs. 14%); however, for exhausted animals, the trained useof the direct pathway was greater (22 vs. 9%). Both TE and rested Tanimals utilize the indirect pathway a comparable amount. Sedentaryanimals, on the other hand, dramatically decreased utilization of thedirect pathway, with exhaustive exercise changing from 30 to 9%. Theresults indicate that endurance training modifies glucose utilizationduring glycogen synthesis after fasting and exhaustive exercise.

     

Resistance training and human cervical muscle recruitment plasticity

Conley, Michael S., Michael H. Stone, Michael Nimmons, andGary A. Dudley. Resistance training and human cervical muscle recruitment plasticity. J. Appl.Physiol. 83(6): 2105-2111, 1997.This studyexamined cervical neuromuscular adaptations to resistance training. TheResX group performed conventional resistance training plushead-extension exercise. Another group performed only conventional resistance training, and the control group performed no resistance exercise. Muscle use during head extension was determinedby quantifying shifts in T2 in serial-transaxial magnetic resonanceimages of the neck. ResX was the only group that showed a trainingeffect. Training decreased (P < 0.05) the cross-sectional area (CSA) of cervical muscle used to performsubmaximal head extension by 31%. This reflected a decrease(P < 0.05) in relative use of thesplenius capitis, semispinalis capitis, and semispinalis cervicis andmultifidus muscles by about one-third; their percentage of CSA showingcontrast shift was reduced from 60 to 40% on average. This sameexercise evoked no contrast shift in the levator scapulae, longissimus capitis and cervicis, and scalenus medius and anterior muscles posttraining, yet 20% or more of their CSA was engaged pretraining. The relative CSA of cervical musculature that was used to perform maximal head extension was increased(P < 0.05) 16% bytraining. The findings suggest functional redundancy ofneck musculature that can be modified by training; submaximal tasks canbe performed despite cessation of recruitment of individual muscles,yet recruitment can be increased for maximal efforts. These resultsalso suggest that neuromuscular adaptations to training require aspecific cervical exercise

     

Doublet potentiation during eccentric and concentric contractions of cat soleus muscle

Sandercock, Thomas G., and C. J. Heckman. Doubletpotentiation during eccentric and concentric contractions of cat soleusmuscle. J. Appl. Physiol. 82(4):1219-1228, 1997.The addition of an extra stimulus pulse, ordoublet, at the beginning of a low-frequency train has been shown tosubstantially increase isometric force. This study examined the effectsof muscle movement on this doublet potentiation. The soleus muscles ofanesthetized cats were stimulated at 10 Hz for 1 s, with and without anadded doublet (0.01-s interval). Isovelocity releases reduced but didnot eliminate peak and early doublet potentiation (average 0.0-0.5s after the doublet). Large releases, >0.4 s after the doublet,completely abolished sustained doublet potentiation (average0.5-1.0 s after the doublet). In contrast, early isovelocitystretches boosted peak doublet potentiation. Yet, large stretches laterin the stimulus almost completely eliminated sustained doubletpotentiation. This suggests that a different mechanism is responsiblefor early and sustained doublet potentiations. Because peak and averageinitial doublet potentiation were not strongly affected by movement,doublets still offer a viable control strategy to increase force during movement while minimizing the number of stimulus pulses.

     

Coca chewing for exercise: hormonal and metabolic responses of nonhabitual chewers

Favier, Roland, Esperanza Caceres, Laurent Guillon, BrigitteSempore, Michel Sauvain, Harry Koubi, and Hilde Spielvogel. Cocachewing for exercise: hormonal and metabolic responses of nonhabitualchewers. J. Appl. Physiol. 81(5):1901-1907, 1996.To determine the effects of acute coca use onthe hormonal and metabolic responses to exercise, 12 healthynonhabitual coca users were submitted twice to steady-state exercise(~75% maximal O₂ uptake). Onone occasion, they were asked to chew 15 g of coca leaves 1 h beforeexercise, whereas on the other occasion, exercise was performed after 1 h of chewing a sugar-free chewing gum. Plasma epinephrine,norepinephrine, insulin, glucagon, and metabolites (glucose, lactate,glycerol, and free fatty acids) were determined at rest before andafter coca chewing and during the 5th, 15th, 30th, and 60th min ofexercise. Simultaneously to these determinations, cardiorespiratoryvariables (heart rate, mean arterial blood pressure, oxygen uptake, andrespiratory gas exchange ratio) were also measured. At rest, cocachewing had no effect on plasma hormonal and metabolic levels exceptfor a significantly reduced insulin concentration. During exercise, theoxygen uptake, heart rate, and respiratory gas exchange ratio weresignificantly increased in the coca-chewing trial compared with thecontrol (gum-chewing) test. The exercise-induced drop in plasma glucoseand insulin was prevented by prior coca chewing. These results contrastwith previous data obtained in chronic coca users who display duringprolonged submaximal exercise an exaggerated plasma sympatheticresponse, an enhanced availability and utilization of fat (R. Favier,E. Caceres, H. Koubi, B. Sempore, M. Sauvain, and H. Spielvogel.J. Appl. Physiol. 80: 650-655, 1996). We conclude that, whereas coca chewing might affect glucose homeostasis during exercise, none of the physiological data provided bythis study would suggest that acute coca chewing in nonhabitual userscould enhance tolerance to exercise.

     

Reduced oxidation rates of ingested glucose during prolonged exercise with low endogenous CHO availability

Jeukendrup, Asker E., Lars B. Borghouts, Wim H. M. Saris,and Anton J. M. Wagenmakers. Reduced oxidation rates of ingested glucose during prolonged exercise with low endogenous CHO availability. J. Appl. Physiol. 81(5):1952-1957, 1996.This study investigated the effect of endogenouscarbohydrate (CHO) availability on oxidation rates of ingested glucoseduring moderate-intensity exercise. Seven well-trained cyclistsperformed two trials of 120 min of cycling exercise in random order at57% maximal O₂ consumption. Preexercise glycogen concentrations were manipulated byglycogen-lowering exercise in combination with CHO restriction[low-glycogen (LG) trial] or CHO loading[moderate-to-high-glycogen (HG) trial]. In the LG and HGtrials, subjects ingested 4 ml/kg body wt of an 8% corn-derivedglucose solution of high natural¹³C abundance at the start,followed by boluses of 2 ml/kg every 15 min. The third trial, in whichpotato-derived glucose was ingested, served as a control test forbackground correction. Exogenous glucose oxidation rates werecalculated from the ¹³C enrichmentof the ingested glucose and of the breathCO₂. Total CHO oxidation was lowerin the LG trial than in the HG trial during 60-120 min of exercise[84 ± 7 (SE) vs. 116 ± 8 g;P < 0.05]. Exogenous CHOoxidation in this period was 28% lower in the LG trial compared withthe HG trial. Maximal exogenous oxidation rates were also lower(P < 0.05) in the LG trial (0.64 ± 0.05 g/min) than in the HG trial (0.88 ± 0.04 g/min). Thisdecreased utilization of exogenous glucose was accompanied by increased plasma free fatty acid levels (2-3 times higher) and lower insulin concentrations. It is concluded that glycogen-lowering exercise, performed the evening before an exercise bout, in combination with CHOrestriction leads to a reduction of the oxidation rate of ingestedglucose during moderate-intensity exercise.

     

Impaired muscle glycogen resynthesis after a marathon is not caused by decreased muscle GLUT-4 content

Asp, Sven, Thomas Rohde, and Erik A. Richter. Impairedmuscle glycogen resynthesis after a marathon is not caused by decreasedmuscle GLUT-4 content. J. Appl.Physiol. 83(5): 1482-1485, 1997.Our purpose wasto investigate whether the slow rate of muscle glycogen resynthesisafter a competitive marathon is associated with a decrease in the totalmuscle content of the muscle glucose transporter (GLUT-4). Sevenwell-trained marathon runners participated in the study, and musclebiopsies were obtained from the lateral head of the gastrocnemiusmuscle before, immediately after, and 1, 2, and 7 days after themarathon, as were venous blood samples. Muscle GLUT-4 content wasunaltered over the experimental period. Muscle glycogen concentrationwas 758 ± 53 mmol/kg dry weight before the marathon anddecreased to 148 ± 39 mmol/kg dry weight immediately afterward.Despite a carbohydrate-rich diet (containing at least 7 gcarbohydrate · kg bodymass¹ · day¹),the muscle glycogen concentration remained 30% lower than before-race values 2 days after the race, whereas it had returned to before-race levels 7 days after the race. We conclude that the total GLUT-4 proteincontent is unaltered in the lateral gastrocnemius after a competitivemarathon and that the slow recovery of muscle glycogen after the raceapparently involves factors other than changes in the total content ofthis protein.

     

Alignment of microvascular units along skeletal muscle fibers of hamster retractor

Emerson, Geoffrey G., and Steven S. Segal. Alignment ofmicrovascular units along skeletal muscle fibers of hamster retractor.J. Appl. Physiol. 82(1): 42-48, 1997.When muscle fibers contract, blood flow requirements increasealong their entire length. However, the organization of capillaryperfusion along muscle fibers is unclear. The microvascular unit (MVU)is defined as a terminal arteriole and the group of capillaries itsupplies. We investigated whether neighboring MVUs along the fiber axis perfused the same group of muscle fibers by using the parallel-fibered retractor muscle. Hamsters were anesthetized and perfused with Microfilto visualize MVUs relative to muscle fibers. Fields of study, whichencompassed five to seven neighboring MVUs along a muscle fiber, werechosen from the interior of muscles and along muscle edges. On average,MVUs were 1 mm in length, 0.50 mm in width, and 0.1 mm deep; segmentsof ~30 fibers were contained in this tissue volume of 0.05 mm³ (20 MVUs/mg muscle). The totaldistance across muscle fibers encompassed by a pair of MVUs isdesignated "union" (U); the fraction of this distance common toboth MVUs is designated "intersection" (I). The ratio of I to Ufor the widths of neighboring MVUs provides an index of MVU alignmentalong muscle fibers (e.g., I/U = 1.0 indicates complete alignment,where the fibers perfused by one MVU are the same as those perfused bythe neighboring MVU). We found that I/U along muscle edges (0.71 ± 0.02) was greater (P < 0.05) thanthe ratio measured within muscles (0.66 ± 0.02). A model predicteda maximum I/U of 0.58 with random MVU alignment. Thus measured valueswere closer to random than to complete alignment. These findingsindicate that an increase in blood flow along muscle fibers requiresthe perfusion of many MVUs and imply that vasodilation is coordinatedamong the parent arterioles from which corresponding MVUsarise.

     

Effects of muscle kinematics on surface EMG amplitude and frequency during fatiguing dynamic contractions

Potvin, J. R. Effects of muscle kinematics on surfaceEMG amplitude and frequency during fatiguing dynamic contractions. J. Appl. Physiol. 82(1): 144-151, 1997.Fifteen male subjects performed a repetitive elbowflexion/extension task with a 7-kg mass until exhaustion. Average jointangle, angular velocity, and biceps brachii surface electromyographic(EMG) amplitude (aEMG) and mean powerfrequency (MPF) were calculated with each consecutive 250-ms segment ofdata during the entire trial. Data were separated into concentric oreccentric phases and into seven 20°-ranges from 0 to 140° ofelbow flexion. A regression analysis was used to estimate the restedand fatigued aEMG and MPF values. aEMG values were expressed as apercentage of amplitudes from maximum voluntary contractions (MVC).Under rested dynamic conditions, the average concentric aEMG amplitudewas 10% MVC higher than average eccentric values. Rested MPF valueswere similar for concentric and eccentric phases, although valuesincreased ~20 Hz from the most extended to flexed joint angles.Fatigue resulted in an average increase in concentric and eccentricaEMG of 35 and 10% MVC, respectively. The largest concentric aEMGincreases (up to 58% MVC) were observed at higher joint velocities,whereas eccentric increases appeared to be related to decreases invelocity. Fatigue had a similar effect on MPF during both concentricand eccentric phases. Larger MPF decreases were observed at shortermuscle lengths such that values within each angle range were verysimilar by the end of the trial. It was hypothesized that this findingmay reflect a biological minimum in conduction velocity beforepropagation failure occurs.

     

Eccentric contractions require unique activation strategies by the nervous system

Enoka, Roger M. Eccentric contractions require uniqueactivation strategies by the nervous system. J. Appl.Physiol. 81(6): 2339-2346, 1996.Eccentriccontractions occur when activated muscles are forcibly lengthened. Thismode of muscle function occurs frequently in the activities of dailyliving and in athletic competition. This review examines theexperimental evidence that provides the foundation for our currentunderstanding of the benefits, consequences, and control of eccentriccontractions. Over the past several decades, numerous studies haveestablished that eccentric contractions can maximize the force exertedand the work performed by muscle; that they are associated with agreater mechanical efficiency; that they can attenuate the mechanicaleffects of impact forces; and that they enhance the tissue damageassociated with exercise. More recent evidence adds a new feature tothis repertoire by suggesting a new hypothesis: that the neuralcommands controlling eccentric contractions are unique. Examination of this hypothesis is critical because the existence of such a control scheme would increase substantially the complexity of the strategies that the nervous system must use to control movement.

     

Exercise training and the glucose transport system in obese SHHF/Mcc-facp rats

Ferrara, Cynthia M., W. Michael Sherman, Nicole Leenders,Sylvia A. McCune, and Karla Roehrig. Exercise training and theglucose transport system in obeseSHHF/Mcc-fa^cprats. J. Appl. Physiol. 81(4):1670-1676, 1996.The effects of a similar exercise trainingstimulus on maximal insulin-stimulated (MIS) plasma membrane glucosetransporter number and glucose transport were determined in lean andobeseSHHF/Mcc-fa^cprats. Six-week-old lean and obese male rats were randomly divided intofour groups: lean sedentary (LSed), obese sedentary (OSed), leanexercise (LEx), and obese exercise (OEx). An 8- to 12-wk treadmillrunning program equalized daily muscular work for LEx and OEx. Plasmamembranes were isolated from control and MIS muscles of mixed fibertypes. MIS significantly increased glucose transport (3.4- and2.8-fold) in LSed and OSed, respectively. MIS significantly increased glucose transporter number (2.5-fold) in LSed, but there wasno increase in glucose transporter number in OSed. Peak oxygen uptakeand citrate synthase activity were increased a similar amount for LExand OEx groups, demonstrating a similar training stimulus. MISsignificantly and similarly increased glucose transport in LEx and OEx(4.4- and 5.1-fold, respectively). The effects of MIS on plasmamembrane glucose transporter number in the exercise-trained rats weresimilar to the responses observed in the sedentary lean and obesegroups. MIS significantly increased glucose transporter number(2.6-fold) in LEx, whereas there was no increase in glucose transporternumber in OEx. The reduction in MIS glucose transport in OSed appearsto be related to a defect in the processes associated with thetranslocation of glucose transporters to the plasma membrane. Exercisetraining of the obese rats apparently did not alter this defect.Similar increases in peak oxygen uptake, citrate synthase, and MISglucose transport in LEx and OEx groups suggest that insulin resistancedoes not limit the ability of the glucose transport system to adapt toexercise training in the obese maleSHHF/Mcc-fa^cprats.