Muscle fatigue and exhaustion during dynamic leg exercise in normoxia and hypobaric hypoxia

Fulco, Charles S., Steven F. Lewis, Peter N. Frykman, RobertBoushel, Sinclair Smith, Everett A. Harman, Allen Cymerman, and Kent B. Pandolf. Muscle fatigue and exhaustion during dynamic leg exercisein normoxia and hypobaric hypoxia. J. Appl. Physiol. 81(5): 1891-1900, 1996.Using anexercise device that integrates maximal voluntary static contraction(MVC) of knee extensor muscles with dynamic knee extension, we comparedprogressive muscle fatigue, i.e., rate of decline in force-generatingcapacity, in normoxia (758 Torr) and hypobaric hypoxia (464 Torr).Eight healthy men performed exhaustive constant work rate kneeextension (21 ± 3 W, 79 ± 2 and 87 ± 2% of 1-leg kneeextension O₂ peak uptake fornormoxia and hypobaria, respectively) from knee angles of90-150° at a rate of 1 Hz. MVC (90° knee angle) wasperformed before dynamic exercise and during 5-s pauses every 2 minof dynamic exercise. MVC force was 578 ± 29 N in normoxia and 569 ± 29 N in hypobaria before exercise and fell, at exhaustion, to similar levels (265 ± 10 and 284 ± 20 N for normoxia andhypobaria, respectively; P > 0.05)that were higher (P < 0.01) thanpeak force of constant work rate knee extension (98 ± 10 N, 18 ± 3% of MVC). Time to exhaustion was 56% shorter for hypobariathan for normoxia (19 ± 5 vs. 43 ± 7 min, respectively;P < 0.01), and rate of right leg MVC fall wasnearly twofold greater for hypobaria than for normoxia (mean slope = 22.3 vs. 11.9 N/min, respectively;P < 0.05). With increasing durationof dynamic exercise for normoxia and hypobaria, integratedelectromyographic activity during MVC fell progressively with MVCforce, implying attenuated maximal muscle excitation. Exhaustion, perse, was postulated to relate more closely to impaired shorteningvelocity than to failure of force-generating capacity.

     

Maximal and submaximal isometric torque is elevated immediately following highly controlled active stretches of the hamstrings

Hamstring strain rehabilitation programs with an eccentric bias are effective but have a low adherence rate. Post-stretch isometric (PS-ISO) contractions which incorporate a highly controlled eccentric contraction followed by an isometric contraction resulting in elevated torque during following stretch, compared with isometric contractions at the same joint angle. This study measured torque, activation and musculotendinous unit behaviour of the hamstrings during PS-ISO contractions of maximal and submaximal levels using two stretch amplitudes. Ten male participants (24.6 years ± 2.22 years) completed maximal and submaximal baseline isometric contractions at 90°, 120° and 150° knee flexion and PS-ISO contractions of maximal and submaximal intensity initiated at 90° and 120° incorporating active stretch of 30° and 60° at 60°·s⁻¹. Torque and muscle activation of the knee flexors were simultaneously recorded. Musculotendinous unit behaviour of the biceps femoris long head was recorded via ultrasound during all PS-ISO contractions. Compared with baseline, torque was 8% and 39% greater in the maximal and submaximal PS-ISO conditions respectively with no change in muscle activation. The biceps femoris long head muscle lengthened during all PS-ISO contractions. PS-ISO contractions may be beneficial where the effects of highly controlled eccentric contractions and elevated isometric torque are desired, such as hamstring rehabilitation.     

Multivariate genetic analysis of maximal isometric muscle force at different elbow angles

Thomis, Martine A., Marc Van Leemputte, Hermine H. Maes,Cameron J. R. Blimkie, Albrecht L. Claessens, Guy Marchal, Eustachius Willems, Robert F. Vlietinck, and Gaston P. Beunen. Multivariate genetic analysis of maximal isometric muscle force at different elbowangles. J. Appl. Physiol. 82(3):959-967, 1997.The maximal isometric moment at five differentelbow joint angles was measured in 25 monozygotic and 16 dizygotic maleadult twin pairs (22.4 ± 3.7 yr). Genetic model fittingwas used to quantify the genetic and environmental contributions toindividual differences in isometric strength. Additive genetic factorsexplained 66-78% of the variance in maximal torque at170-140-110 and 80° flexion (extension = 180°). At50° flexion, common and subject-specific environmental factorscontributed equally to the variation. The contribution of uniqueenvironmental factors concurs with the level of variability in muscleactivation and (dis)-comfort of torque production in the specificangle. The relative contribution of lever arm and force-lengthrelationship in torque varies according to the angle. Because thesefactors might be genetic, this variability is reflected in the geneticcontribution at the extreme angles of 170 and 50°. Multivariateanalyses suggested a general set of genes that control muscle area andisometric strength, together with a more specific strength factor.Genetic correlations were high (0.82-0.99). Genes responsible forarm-segment lengths did not contribute to muscle area nor to isometricstrength.

     

Neuromuscular drive and force production are not altered during bilateral contractions

Jakobi, J. M., and E. Cafarelli. Neuromuscular driveand force production are not altered during bilateral contractions. J. Appl. Physiol. 84(1): 200-206, 1998.Several investigators have studied the deficit in maximalvoluntary force that is said to occur when bilateral muscle groupscontract simultaneously. A true bilateral deficit (BLD) would suggest asignificant limitation of neuromuscular control; however, some of thedata from studies in the literature are equivocal. Our purpose was todetermine whether there is a BLD in the knee extensors of untrainedyoung male subjects during isometric contractions and whether thisdeficit is associated with a decreased activation of the quadriceps,increased activation of the antagonist muscle, or an alteration inmotor unit firing rates. Twenty subjects performed unilateral (UL) and bilateral (BL) isometric knee extensions at 25, 50, 75, and 100% maximal voluntary contraction. Total UL and BL force (3%) and maximal rate of force generation (2.5%) were not significantly different. Total UL and BL maximal vastus lateralis electromyographic activity (EMG; 2.7 ± 0.28 vs. 2.6 ± 0.24 mV) andcoactivation (0.17 ± 0.02 vs. 0.20 ± 0.02 mV) were also notdifferent. Similarly, the ratio of force to EMG during submaximal ULand BL contractions was not different. Analysis of force production byeach leg in UL and BL conditions showed no differences in force, rateof force generation, EMG, motor unit firing rates, and coactivation.Finally, assessment of quadriceps activity with the twitchinterpolation technique indicated no differences in the degree ofvoluntary muscle activation (UL: 93.6 ± 2.51 Hz, BL: 90.1 ± 2.43 Hz). These results provide no evidence of a significant limitationin neuromuscular control between BL and UL isometric contractions ofthe knee extensor muscles in young male subjects.

     

Mechanical behavior of skeletal muscle during intermittent voluntary isometric contractions in humans

Vøllestad, N. K., I. Sejersted, and E. Saugen. Mechanical behavior of skeletal muscle duringintermittent voluntary isometric contractions in humans.J. Appl. Physiol. 83(5):1557-1565, 1997.Changes in contractile speed and force-fusionproperties were examined during repetitive isometric contractions withthe knee extensors at three different target force levels. Sevenhealthy subjects were studied at target force levels of 30, 45, and60% of their maximal voluntary contraction (MVC) force. Repeated 6-s contractions followed by 4-s rest were continued until exhaustion. Contractile speed was determined for contractions elicited by electrical stimulation at 1-50 Hz given during exercise and a subsequent 27-min recovery period. Contraction time remained unchanged during exercise and recovery, except for an initial rapid shift in thetwitch properties. Half relaxation time(RT_1/2) decreased gradually by 20-40% during exercise at 30 and 45% of MVC. In the recovery period, RT_1/2 values werenot fully restored to preexercise levels. During exercise at 60% MVC,the RT_1/2 decreased for twitches and increased for the 50-Hz stimulation. In the recovery period after60% MVC, RT_1/2 values declinedtoward those seen after the 30 and 45% MVC exercise. The forceoscillation amplitude in unfused tetani relative to the mean forceincreased during exercise at 30 and 45% MVC but remained unalteredduring the 60% MVC exercise. This altered force-fusion was closelyassociated with the changes inRT_1/2. The faster relaxation mayat least partly explain the increased energy cost of contractionreported previously for the same type of exercise.

     

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.

     

Lower limb skeletal muscle function after 6wk of bed rest

Berg, H. E., L. Larsson, and P. A. Tesch. Lower limbskeletal muscle function after 6 wk of bed rest. J. Appl. Physiol. 82(1): 182-188, 1997.Force,electromyographic (EMG) activity, muscle mass, and fibercharacteristics were studied in seven healthy men before and after 6 wkof bed rest. Maximum voluntary isometric and concentric knee extensortorque decreased (P < 0.05)uniformly across angular velocities by 25-30% after bed rest.Maximum quadricep rectified EMG decreased by 19 ± 23%, whereassubmaximum (100-Nm isometric action) EMG increased by 44 ± 28%.Knee extensor muscle cross-sectional area (CSA), assessed by usingmagnetic resonance imaging, decreased by 14 ± 4%. Maximum torqueper knee extensor CSA decreased by 13 ± 9%. Vastus lateralis fiberCSA decreased 18 ± 14%. Neither type I, IIA, and IIB fiberpercentages nor their relative proportions of myosin heavy chain (MHC)isoforms were altered after bed rest. Because the decline in strengthcould not be entirely accounted for by decreased muscle CSA, it issuggested that the strength loss is also due to factors resulting indecreased neural input to muscle and/or reduced specifictension of muscle, as evidenced by a decreased torque/EMG ratio.Additionally, it is concluded that muscle unloading in humans does notinduce important changes in fiber type or MHC composition or in vivomuscle contractile properties.

     

Older adults can maximally activate the biceps brachii muscle by voluntary command

De Serres, Sophie J., and Roger M. Enoka. Older adultscan maximally activate the biceps brachii muscle by voluntary command.J. Appl. Physiol. 84(1): 284-291, 1998.Because some of the decline in strength with age may beexplained by an impairment of muscle activation, the purpose of thisstudy was to determine the activation level achieved in biceps brachiiby older adults during a maximum voluntary contraction (MVC). Thiscapability was assessed with two superimposition techniques: onecalculated the activation level that was achieved during an MVC, andthe other provided an estimate of the expected MVC force based on extrapolation with submaximal forces. The activation level in bicepsbrachii was incomplete (<100%) for the young(n = 16) and elderly(n = 16) subjects, with the elderlysubjects exhibiting the greater deficit. In contrast, there was nodifference between the measured and expected MVC forces for eithergroup of subjects, whether the extrapolation involved a third-orderpolynomial or linearization of the data. Because of the lowersignal-to-noise ratio associated with the measurement of activationlevel and the greater number of measurements that contributed to theestimate of the expected MVC force, we conclude that the older adultswere able to achieve complete activation of the biceps brachii muscle during an MVC.

     

Activation-induced force enhancement in human adductor pollicis

It has been known for a long time that the steady-state isometric force after muscle stretch is bigger than the corresponding force obtained in a purely isometric contraction for electrically stimulated and maximal voluntary contractions (MVC). Recent studies using sub-maximal voluntary contractions showed that force enhancement only occurred in a sub-group of subjects suggesting that force enhancement for sub-maximal voluntary contractions has properties different from those of electrically-induced and maximal voluntary contractions. Specifically, force enhancement for sub-maximal voluntary contractions may contain an activation-dependent component that is independent of muscle stretching. To address this hypothesis, we tested for force enhancement using (i) sub-maximal electrically-induced contractions and stretch and (ii) using various activation levels preceding an isometric reference contraction at 30% of MVC (no stretch). All tests were performed on human adductor pollicis muscles. Force enhancement following stretching was found for all subjects (n = 10) and all activation levels (10%, 30%, and 60% of MVC) for electrically-induced contractions. In contrast, force enhancement at 30% of MVC, preceded by 6 s of 10%, 60%, and 100% of MVC was only found in a sub-set of the subjects and only for the 60% and 100% conditions. This result suggests that there is an activation-dependent force enhancement for some subjects for sub-maximal voluntary contractions. This activation-dependent force enhancement was always smaller than the stretch-induced force enhancement obtained at the corresponding activation levels. Active muscle stretching increased the force enhancement in all subjects, independent whether they showed activation dependence or not. It appears that post-activation potentiation, and the associated phosphorylation of the myosin light chains, might account for the stretch-independent force enhancement observed here.     

The highest antagonistic coactivation of the vastus intermedius muscle among quadriceps femoris muscles during isometric knee flexion

Although the possibility that the vastus intermedius (VI) muscle contributes to flexion of the knee joint has been suggested previously, the detail of its functional role in knee flexion is not well understood. The purpose of this study was to examine the antagonist coactivation of VI during isometric knee flexion. Thirteen men performed 25–100% of maximal voluntary contraction (MVC) at 90°, 120°, and 150° knee joint angles. Surface electromyography (EMG) of the four individual muscles in the quadriceps femoris (QF) was recorded and normalized by the EMG signals during isometric knee extension at MVC. Cross-talk on VI EMG signal was assessed based on the median frequency response to selective cooling of hamstring muscles. Normalized EMG of the VI was significantly higher than that of the other synergistic QF muscles at each knee joint angle (all P < 0.05) with minimum cross-talk from the hamstrings to VI. There were significant correlations between the EMG signal of the hamstrings and VI (r = 0.55–0.85, P < 0.001). These results suggest that VI acts as a primary antagonistic muscle of QF during knee flexion, and that VI is presumably a main contributor to knee joint stabilization.     

Efficiency of human skeletal muscle in vivo: comparison of isometric, concentric, and eccentric muscle action

Ryschon, T. W., Fowler, R. E. Wysong, A.-R. Anthony, and R. S. Balaban. Efficiency of human skeletal muscle in vivo: comparison of isometric, concentric, and eccentric muscle action. J. Appl. Physiol. 83(3): 867-874, 1997.The purpose of this study was to estimate the efficiency of ATPutilization for concentric, eccentric, and isometric muscle action inthe human tibialis anterior and extensor digitorum longus in vivo. Adynamometer was used to quantitate muscle work, or tension, whilesimultaneous ³¹P-nuclear magneticresonance data were collected to monitor ATP, phosphocreatine,inorganic phosphate, and pH. The relative efficiency of the actions wasestimated in two ways: steady-state effects on high-energyphosphates and a direct comparison of ATP synthesis rates with work. Inthe steady state, the cytosolic free energy dropped to the lowest valuewith concentric activity, followed by eccentric and isometric actionfor comparative muscle tensions. Estimates of ATP synthesis ratesrevealed a mechanochemical efficiency [i.e., ATP productionrate/work (both in J/s)] of 15.0 ± 1.3% in concentric and34.7 ± 6.1% in eccentric activity. The estimated maximum ATPproduction rate was highest in concentric action, suggesting anactivation of energy metabolism under these conditions. By using directmeasures of metabolic strain and ATP turnover, these data demonstrate adecreasing metabolic efficiency in human muscle action from isometric,to eccentric, to concentric action.

     

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.

     

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.

     

Optimal whole-body vibration settings for muscle strength and power enhancement in human knee extensors

This study compared the effects of 6-week whole-body vibration (WBV) training programs with different frequency and peak-to-peak displacement settings on knee extensor muscle strength and power. The underlying mechanisms of the expected gains were also investigated. Thirty-two physically active male subjects were randomly assigned to a high-frequency/high peak-to-peak displacement group (HH; n = 12), a low-frequency/low peak-to-peak displacement group (LL; n = 10) or a sham training group (SHAM; n = 10). Maximal voluntary isometric, concentric and eccentric torque of the knee extensors, maximal voluntary isometric torque of the knee flexors, jump performance, voluntary muscle activation, and contractile properties of the knee extensors were assessed before and after the training period. Significant improvement in knee extensor eccentric voluntary torque (P < 0.01), knee flexor isometric voluntary torque (P < 0.05), and jump performance (P < 0.05) was observed only for HH group. Regardless of the group, knee extensor muscle contractile properties (P < 0.05) were enhanced. No modification was observed for voluntary muscle activation or electrical activity of agonist and antagonist muscles. We concluded that high-frequency/high peak-to-peak displacement was the most effective vibration setting to enhance knee extensor muscle strength and jump performance during a 6-week WBV training program and that these improvements were not mediated by central neural adaptations.     

Augmentation of exercise-induced muscle sympathetic nerve activity during muscle heating

Ray, Chester A., and Kathryn H. Gracey. Augmentation ofexercise-induced muscle sympathetic nerve activity during muscle heating. J. Appl. Physiol. 82(6):1719-1725, 1997.The muscle metabo- and mechanoreflexes have beenshown to increase muscle sympathetic nerve activity (MSNA) duringexercise. Group III and IV muscle afferents, which are believed tomediate this response, have been shown to be thermosensitive inanimals. The purpose of the present study was to evaluate the effect ofmuscle temperature on MSNA responses during exercise. Eleven subjectsperformed ischemic isometric handgrip at 30% of maximal voluntarycontraction to fatigue, followed by 2 min of postexercise muscleischemia (PEMI), with and without local heating of the forearm. Localheating of the forearm increased forearm muscle temperature from 34.4 ± 0.2 to 38.9 ± 0.3°C(P = 0.001). Diastolic andmean arterial pressures were augmented during exercise in the heat.MSNA responses were greater during ischemic handgrip with local heatingcompared with control (no heating) after the first 30 s. MSNA responsesat fatigue were greater during local heating. MSNA increased by 16 ± 2 and 20 ± 2 bursts per 30 s for control and heating,respectively (P = 0.03). Whenexpressed as a percent change in total activity (total burstamplitude), MSNA increased 531 ± 159 and 941 ± 237% forcontrol and heating, respectively (P = 0.001). However, MSNA was not different during PEMI between trials.This finding suggests that the augmentation of MSNA during exercisewith heat was due to the stimulation of mechanically sensitive muscleafferents. These results suggest that heat sensitizes skeletal muscleafferents during muscle contraction in humans and may play a role inthe regulation of MSNA during exercise.

     

Effect of hip flexion angle on stiffness of the adductor longus muscle during isometric hip flexion

This study examined the effect of hip flexion angle on the stiffness of the adductor longus (AL) muscle during isometric hip flexion. Seventeen men were recruited. Ten participants performed submaximal voluntary contraction at 0%, 25%, 50%, and 75% of maximal voluntary contraction (MVC) during isometric hip flexion after performing MVC at 0°, 40°, and 80° of hip flexion. Seven participants performed submaximal voluntary tasks during isometric hip extension in addition to hip flexion task. The shear modulus of the AL muscle was used as the index of muscle stiffness, and was measured using ultrasound shear-wave elastography during the tasks at each contraction intensity for each hip flexion angle. During hip flexion, the shear modulus of the AL muscle was higher at 0° than at 40° and 80° of hip flexion at each contraction intensity (p < 0.016). Conversely, a significant effect was not found among hip flexion angle during hip extension at 75% of MVC (p = 0.867). These results suggest that mechanical stress of the AL muscle may be higher at 0° of hip flexion during isometric hip flexion.     

Passive sensitization of human airways induces myogenic contractile responses in vitro

Mitchell, R. W., K. F. Rabe, H. Magnussen, and A. R. Leff.Passive sensitization of human airways induces myogenic contractile responses in vitro. J. Appl.Physiol. 83(4): 1276-1281, 1997.We assessedeffects of passive sensitization on human bronchial smooth muscle (BSM)response to mechanical stretching in vitro. Bronchial rings were sham(control) or passively sensitized overnight by using sera from donorsdemonstrating sensitivity to Dermatophagoides farinae and having immunoglobulin E (IgE)concentrations of 2,600 ± 200 U/ml. Tissues were fixedisometrically to force transducers to measure responses to electricalfield stimulation (EFS) and quick stretch (QS). The myogenic responseto QS was normalized to the maximal response to EFS (%EFS). Themyogenic response of sensitized BSM was 47.9 ± 10.9 %EFS to a QSof ~6.5% optimal length (L_o);sham-sensitized tissues had a myogenic response of 13.5 ± 6.4 %EFS(P = 0.012 vs. passively sensitized).A QS of ~13% L_o in sensitizedBSM caused a response of 82.8 ± 20.9 %EFS; sham-sensitized tissuesdeveloped a response of 38.2 ± 17.3 %EFS(P = 0.004). BSM incubated with serumfrom nonallergic donors did not demonstrate increased QS response (4.6 ± 1.4 %EFS, P = not significantvs. tissue exposed to atopic sera). However, tissues incubated in serafrom nonatopic donors supplemented with hapten-specific chimeric IgE(JW8) demonstrated augmented myogenic response to QS of ~6.5% L_o (21.9 ± 6.2 %EFS, P = 0.027 vs. nonatopicsera alone). We demonstrate that passive sensitization of human BSMpreparations causes induction and augmentation of myogenic contractionsto QS; this hyperresponsiveness corresponds to the IgE concentration insensitizing sera.

     

Muscle inactivation: assessment of interpolated twitch technique

Behm, D. G., D. M. M. St-Pierre, and D. Perez. Muscleinactivation: assessment of interpolated twitch technique.J. Appl. Physiol. 81(5):2267-2273, 1996.The validity, reliability, and protocol for theinterpolated twitch technique (ITT) were investigated with isometricplantar flexor and leg extension contractions. Estimates of muscleinactivation were attempted by comparing a variety of superimposed withpotentiated evoked torques with submaximal and maximal voluntarycontraction (MVC) torques or forces. The use of nerve and surfacestimulation to elicit ITT was reliable, except for problems inmaintaining maximal stimulation with nerve stimulation at 20°plantar flexion and during leg extension. The interpolated twitchratio-force relationship was best described by a shallow hyperboliccurve resulting in insignificant MVC prediction errors withsecond-order polynomials (1.1-6.9%). The prediction error under40% MVC was approximately double that over 60% MVC, contributing topoor estimations of MVC in non-weight-bearing postimmobilized anklefracture patients. There was no significant difference in the ITTsensitivity when twitches, doublets, or quintuplets were used.The ITT was valid and reliable when high-intensity contractions wereanalyzed with a second-order polynomial.

     

Effects of submaximal and maximal long-lasting contractions on the compliance of vastus lateralis tendon and aponeurosis in vivo

The present study investigated the effects of submaximal sustained and maximal repetitive contractions on the compliance of human vastus lateralis (VL) tendon and aponeurosis in vivo using two different fatiguing protocols. Twelve male subjects performed three maximum voluntary isometric contractions (MVC) of the knee extensors before and after two fatiguing protocols on a dynamometer. The first fatiguing protocol consisted of a long-lasting sustained isometric knee extension contraction at 25% MVC until failure (inability to hold the defined load). The second fatiguing protocol included long-lasting isokinetic (90°/s) knee extension contractions, where maximum moment was exerted and failure was proclaimed when this value fell below 70% of unfatigued maximum isokinetic moment. Ultrasonography was used to determine the elongation and strain of the VL tendon and aponeurosis. Muscle fatigue was indicated by a significant decrease in maximum resultant knee extension moment (p < 0.05) observed during the MVCs after both long-lasting contractions. No significant (p > 0.05) differences in elongation and strain of the VL tendon and aponeurosis were found, when compared every 300 N (tendon force) before and after the fatiguing protocols. The present data indicate, that the VL tendon and aponeurosis in vivo do not suffer from changes in the compliance neither after long-lasting static mechanical loading (strain ～3.2%) nor after long-lasting cyclic mechanical loading (strain 6.2–5.5%).     

Multi-channel electromyography during maximal isometric and dynamic contractions

Motor unit behavior differs between contraction types at submaximal contraction levels, however is challenging to study during maximal voluntary contractions (MVCs). With multi-channel surface electromyography (sEMG), mean physiological characteristics of the active motor units can be extracted. Two 8-electrode sEMG arrays were attached on biceps brachii muscle (one on each head) to examine behavior of sEMG variables during isometric, eccentric and concentric MVCs of elbow flexors in 36 volunteers.On average, isometric (364 ± 88 N) and eccentric (353 ± 74 N) MVCs were higher than concentric (290 ± 73 N) MVC (p < 0.001). Mean muscle fiber conduction velocity (CV) was highest during eccentric MVC (4.42 ± 0.49 m/s) than concentric (4.25 ± 0.49 m/s, p < 0.01) and isometric (4.14 ± 0.45 m/s, p < 0.001) MVCs. Furthermore, eccentric MVC showed lower sEMG amplitude at the largest elbow joint angles (120–170°) and higher CV at the smallest (70–150°) elbow joint angles (p < 0.05–0.001) than concentric MVC.The differences in CV and sEMG amplitude between the MVCs suggest that the control strategy of motor units differs between the contraction types during MVCs, and is dependent on the muscle length between the dynamic MVCs.