Adaptations of diaphragm and medial gastrocnemius muscles to inactivity.

The effects of 2 wk of inactivity on in vitro contractile properties of diaphragm and medial gastrocnemius (MG) muscles were examined in adult hamsters. In addition, inactivity effects on fiber-type proportions and cross-sectional areas were studied. Inactivity of the right hemidiaphragm or MG muscle was induced by either tetrodotoxin (TTX) blockade of nerve impulses or denervation (DNV). Inactivity effects on diaphragm or MG were compared with corresponding sham (saline-treated or untreated control) muscles. After both TTX- and DNV-induced inactivity, isometric twitch contraction and half-relaxation times were prolonged, maximum tetanic force decreased, and fatigue resistance improved. Proportions of type I and II fibers in both diaphragm and MG were unaffected by TTX- and DNV-induced inactivity. However, in both muscles, type I fibers hypertrophied, whereas type II fibers atrophied. In diaphragm, contractile and morphometric adaptations after DNV were generally more pronounced than those induced by TTX. In addition, compared with corresponding untreated or saline-treated control groups, inactivity effects (both TTX and DNV) on MG were generally greater than those induced in diaphragm, with the exception of hypertrophy of type I fibers. We conclude that inactivity exerts differential effects on type I and II fibers in both diaphragm and MG. Yet, these morphometric adaptations cannot completely account for the adaptations in muscle contractile and fatigue properties after inactivity.     

The effect of muscle fatigue on the isometric contractile characteristics of skeletal muscle in the cat

The rise time of an isometric twitch, the tetanic tension, the twitch tetanus ratio, the frequency-tension relationship, and the height of the MUAP (motor unit action potential) were measured in fast twitch (medial gastrocnemius) and slow twitch (soleus) muscles of the cat immediately before, in the middle, and immediately after fatiguing isometric contractions at tensions of 30, 50 and 80% of each muscle's initial strength (tetanic tension recorded from the unfatigued muscle). Although the twitch-tetanus ratio was always less for the soleus than for the medial gastrocnemius muscles, the twitch-tetanus ratio for any one muscle was constant throughout the duration of fatiguing isometric contractions at any of the tensions examined. In contrast, the twitch tension and tetanic tension of the muscles were both less after the contractions, the largest reduction occurring for both muscles during contractions sustained at the lowest isometric tensions. The time to peak tension of an isometric twitch was prolonged for both muscles following the contractions. This was associated with a corresponding shift in the frequency tension relationship such that at the point of muscular fatigue, the muscles tetanized at lower frequencies of stimulation than did the unfatigued muscle. In contrast, the amplitude of the MUAP showed only a modest reduction throughout the duration of the fatiguing contractions.     

Fatigue and contraction of slow and fast muscles in hypokinetic/hypodynamic rats

This investigation examined the effects of hypokinesia/hypodynamia (H/H) on fatigability and contractile properties of rat soleus (S) and gastrocnemius (G) muscles. Whole-body suspension for 1 wk was used to eliminate hindlimb load-bearing functions and simultaneously permit voluntary isotonic contractions. Train stimulations (45/min, 16 min) resulted in significantly (P less than 0.05) faster rates of fatigue to lower asymptotes in G from H/H rats. Fatigue in the S was minimal at this stimulation frequency and differences between H/H and control animals were not significant. Contractile properties (twitch and tetanic) were measured before and after train stimulations. H/H suspension resulted in an increased twitch tension in G. However, H/H did not change train or tetanic tensions per gram or other G contractile properties. Peak twitch, train, and tetanic tensions, time to peak tension, one-half relaxation time, and twitch and tetanic peak rates of tension development and decline were unchanged by H/H in S muscles. These results indicate that 1 wk of H/H-induced muscle atrophy significantly increases fatigability in G but does not effect contractile properties of fast-twitch (G) or slow-twitch (S) muscles.     

Effect of acute nutritional deprivation on diaphragm structure and function

The influence of 90 h of acute nutritional deprivation (ND) on the cross-sectional areas of muscle fibers and the contractile and fatigue properties of the adult rat diaphragm were determined. Isometric contractile properties and fatigue resistance of the diaphragm were measured by means of an in vitro nerve-muscle strip preparation. Contractions were evoked by using phrenic nerve stimulation (left hemidiaphragm) or direct muscle stimulation (right hemidiaphragm) in the presence of curare. Acute ND resulted in a 20% reduction in body weight. No significant decrements in diaphragm or soleus weights were noted in the ND animals compared with controls (CTL), whereas the weight of the medial gastrocnemius was reduced by 20% in the ND animals. Peak twitch and tetanic tensions (normalized for the weight of the diaphragm strip) were not reduced in ND compared with CTL animals after either nerve or muscle stimulation. The fatigue index of the diaphragm was significantly reduced in ND animals only after nerve stimulation. After the fatigue test, there was rapid recovery of the additional fatigue noted with nerve stimulation. The proportions of type I and II muscle fibers of the diaphragm were similar in the CTL and ND animals. No differences in diaphragm cross-sectional areas were noted for either type I or II muscle fibers in the CTL and ND animals. It is concluded that acute ND has no effect on diaphragm contractility or morphometry and only an inconsequential influence on diaphragm fatigue.     

Development of rat muscle during short- and long-term hindlimb suspension

Histochemical and contractile properties of developing rat soleus (Sol) and plantaris (P) muscles were studied after hindlimb suspension to determine the effects of reduced activity levels on muscle development. Suspension (S) began at age 18 days and lasted for 14, 28, and 206 days, and results were compared with age-matched controls. Body weights were normal until 14 days and Sol growth was inhibited more than P, weighing 38 and 47% of controls at 46 and 224 days compared with 68 and 59% in P. The Sol did not develop into a slow-twitch (ST) muscle as evidenced by faster times to peak tension and half-relaxation times, faster times to develop 50% of maximum tetanic tension (Po) and a mean of 33% fewer ST fibers. Twitch tension and Po were lower in S-Sol and S-P, but force/cross-sectional area was unchanged. Fiber areas were smaller, but no structural changes characteristic of disuse atrophy were found. Fiber type populations were unchanged in P, and contractile properties were only minimally affected, demonstrating the greater importance of activity for ST muscles during development.     

Influence of overload on recovery of rat plantaris from partial denervation

A functional index of neural adaptability is the capacity of motoneurons to extend and establish supernumerary connections with neighboring denervated muscle fibers. The purpose of this study was to guage this response in rat plantaris muscles subjected to increased levels of activity resulting from the surgical removal of the synergistic gastrocnemius and soleus muscles. Thirty-seven days of overload increased plantaris absolute (69%) and relative (82%) weight, whole muscle (35%) and individual fiber (37%) mean cross-sectional area, half-relaxation time (1/2RT; 25%), and maximum tetanic tension (P0; 21%). In a separate group of animals that had undergone 30 days of overload, three-quarters of the plantaris muscle fibers were denervated by sectioning radicular nerve L4. At 7 days postlesion, contractile responses were obtained from sprouting motor units remaining in radicular nerve L5, and the results compared to a nonoverloaded group that had undergone this same procedure. Twitch time to peak tension and 1/2RT were prolonged in normal partially denervated (PD) and overloaded partially denervated (OPD) muscles, and this response was significantly greater in the overloaded muscles. Both PD and OPD muscles increased twitch tension (38%) and peak tension developed at 25 Hz (34%) to a similar extent, during recovery from partial denervation. These increases, attributable to sprouting of L5 motor axon collaterals, were matched in PD muscles with a corresponding increase in P0, a response which did not occur in OPD muscles. Additionally, a more extensive decrease in P0 occurred as a result of partial denervation in OPD muscles compared with whole muscle P0 of nondenervated muscle (L4 plus L5 stimulation).(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of low extracellular calcium and ryanodine on muscle contraction of the mouse during postnatal development.

We have examined the effects of low Ca2+ solutions, Co2+, and ryanodine on the isometric tension and contraction speed of isolated, developing mouse EDL muscles. Twitch responses of young muscles (7-14 days postnatal) were more sensitive to lowered [Ca2+]o than those of more fully developed muscles (22-35 days postnatal). Responses of EDL muscles from a middle-aged group (15-21 days postnatal) were intermediate between the two other groups. Overall, the time course of contraction in a single twitch was accelerated by low [Ca2+]o. Ca(2+)-free solution induced a 7.95 and 9.25 mV depolarization in young and "old" muscle fibres, respectively. The presence of cobalt ions (5 mM) in the Krebs solution had a similar effect as Ca(2+)-free Krebs in terms of reduction of the isometric twitch and tetanic tensions of EDL muscles from the various age groups. In contrast, the shortening of the contraction time seen with Ca(2+)-free solution did not take place following exposure to Co(2+)-containing solutions. Finally, young (7-14 days postnatal) muscles were less sensitive to the inhibitory action of ryanodine on the twitch compared with more fully developed muscles (22-35 days postnatal). Taken together, our results indicate that from birth to maturity, there is a gradual change in the spectrum of calcium utilization for the contractile process.     

The peripheral nerve allograft in the primate immunosuppressed with Cyclosporin A: II. Functional evaluation of reinnervated muscle.

Isometric contractile function was evaluated in primates receiving peripheral nerve allografts and autografts. Twelve adult male cynomolgus monkeys received both sural nerve allografts and autografts to the ulnar nerve in opposite forearms. Half the animals received Cyclosporin A (CsA) immunosuppression (25 mg/kg per day); the remaining animals received placebo. One year following nerve engraftment, isometric contractile muscle function was evaluated in reinnervated abductor digiti quinti and intact abductor pollicis brevis muscles. Maximal twitch tension (Pt), tetanic tension (P(o)), time to peak tension (tpt), rate of rise of twitch tension (DP/dt), and muscle fatigue were evaluated at optimal muscle length (L(o)). All reinnervated muscles distal to nerve autografts and allografts in both Cyclosporin A-immunosuppressed and placebo-treated animals generated equivalent maximal twitch tension, tetanic tension, and time to peak tension, with no significant difference between groups (p > 0.05 by ANOVA). There was a tendency toward increased muscle fatiguability in Cyclosporin A-treated animals (p > 0.05). However, the rate of rise of twitch tension was significantly faster in the reinnervated and intact muscles of Cyclosporin A-treated primates (p < 0.05). Evidence of excellent functional reinnervation across nerve allografts and autografts similar to that seen in histologic and electrophysiologic studies was noted. Cyclosporin A immunosuppression did not significantly enhance recovery of muscle function distal to nerve allografts in this model.     

Functional morphology of the M. gastrocnemius medialis of the rat during growth

Length-force relations, both active and passive, and twitch contraction characteristics were quantified for left medial gastrocnemius muscles of four young, four adult, and four old male Wistar rats. Muscle and bundle optimum length and muscle weight were also determined and subsequently used for calculation of a number of morphological characteristics of the muscles. Fiber optimum length was derived from muscle bundle optimum length. Generally, physiological characteristics remained constant during growth. There was no change either in active tension at muscle optimum length or in active working range relative to fiber optimum length, relative passive fiber stiffness, active force relative to passive force at optimum length, twitch contraction time and twitch half relaxation time at optimum length. A number of morphological changes, however, did take place in the medial gastrocnemius muscle during growth. Fiber optimum length increased but only by about 2 mm from youth to old age, whereas muscle optimum length increased by approximately 14 mm, presumably owing to extensive hypertrophy of the muscle fibers during growth. The priority for force of the medial gastrocnemius muscle (defined as the quotient of physiological cross-sectional area of a muscle and the cubed root of its volume, a measure independent of architecture and dimensions of muscles) increased during growth. This increase indicates that during growth the muscle shifts relatively more towards force generation than towards excursion generation. These findings are discussed in view of existing scaling theories.     

Biochemical and physiological changes in overloaded rat fast- and slow-twitch ankle extensors

The rat soleus (SOL) or medial gastrocnemius (MG) were chronically overloaded by removing their major synergists bilaterally. After 12-14 wks the overloaded SOL (OS) and overloaded MG (OMG) muscles had approximately 50% greater cross-sectional areas (CSA) than the controls. Maximum twitch (Pt) and tetanic (Po) tensions were approximately 46% larger in the OS compared with the normal SOL. The OMG produced 10 and 37% higher Pt and Po, respectively. Specific tension (Po/CSA) was not altered in either group (P greater than 0.05). Contraction times and half-relaxation times were unchanged. Myofibrillar and myosin ATPase specific activities indicated a shift toward that resembling a slower muscle in both the OS and the red portion but not the white portion of the OMG. Generally, markers of glycogen metabolism were reduced (P less than 0.05) in the same muscle areas that showed reduced ATPase activity. These biochemical results were consistent with the apparent histochemical conversion of fibers from fast-twitch, glycolytic----fast-twitch, oxidative-glycolytic----slow-twitch, oxidative types in these muscle areas. These results suggest that overloading either a fast- or slow-twitch plantarflexor results in an increase in muscle mass and maximum tension and in metabolic shifts that generally resemble those observed in a slower muscle. Further, the degree of adaptation appears to be related to the initial fiber type composition of the muscle and/or of the muscle region.     

Efficiency of reinnervation of neonatal rat muscle of original and foreign nerves

Formation of neuromuscular connections in mammals may involve a hierarchy of efficiency of synapse formation at a stage when motor nerves have already contacted muscle fibers and during the transitional period of multiple innervation. In an attempt to test for such a hierarchy, we examined, in neonatal rats, the relative efficiency of reinnervation by foreign or original nerves implanted simultaneously in a large muscle so that competition for muscle fibers was minimized. The tibial nerve, containing gastrocnemius nerve fibers, and the “foreign” peroneal nerve were implanted into the denervated lateral gastrocnemius muscle. One to five months later, indirect tetanic tensions obtained upon stimulating the implanted nerves were measured by isometric techniques and were compared to contralateral control muscles. When both nerves were implanted side by side at the end-plate region, approximately equal tetanic tensions were obtained at the time of testing. The same result was also obtained when the tibial and common peroneal nerves were implanted into non-end-plate and end-plate regions, respectively. However, in the reverse experiment, the tibial nerve implanted at the end-plate region produced significantly higher tetanic tension than the peroneal nerve at the non-end-plate site in the same muscle. Thus, the original nerve, compared to a foreign nerve, appeared to reinnervate neonatal muscle more effectively, but this was only revealed under conditions where access to former end-plate regions was unequal.     

Changes in rat muscle with compensatory overload occur in a sequential manner

The present study was initiated to determine the time course of changes in the profile of selected skeletal muscle myofibril proteins during compensatory overload. Whole muscle isometric contractile properties were measured to assess the physiological consequences of the overload stimulus. Compensatory overload of plantaris muscle of rats was induced by surgical ablation of the synergistic soleus and gastrocnemius muscles. Myosin light chain (LC) and tropomyosin (TM) compositions of control (CP) and overloaded plantaris (OP) muscles were determined by electrophoresis and myofibrillar ATPase assays were performed to assess changes in contractile protein interactions. Within one week of overload decreases in the alpha:beta TM ratio and myofibrillar ATPase activity were observed. Following 30 days of overload, a transition in type II to type I fibres was associated with an increase in slow myosin LC1. Interestingly, after 77 days of overload, the TM subunit ratio returned to one resembling a fast twitch muscle. It is proposed that the early and transitory changes in the TM subunits of OP, as well as the rapid initial depression in maximum tetanic isometric force and myofibrillar ATPase activity may be explained as a result of muscle fibre degeneration-regeneration. We propose that alterations in protein expression induced by compensatory overload reflect both degenerative-regenerative change and increased neuromuscular activity.     

Seasonal variations in the contractile behaviour of gastrocnemius muscles of Uromastix hardwickii

Seasonal variations in the isometric activity of the isolated gastrocnemius muscle of Uromastix hardwickii was studied from winter to summer in Karachi, Pakistan. A constant 20 degrees C temperature was maintained during experimentation to avoid influence of this factor on seasonal changes. The twitch and tetanic tensions recorded at resting lengths showed a significant rise from winter to summer (p less than 0.0005) with a greater effect on tetanic tensions. The rate of rise of tensions also showed a significant elevation (p less than 0.0005) from winter to summer, while the duration of active state decreased by 66% during spring and summer. The results are discussed in terms of speed of summation of active state, cross bridge interaction, and characteristic expression of gastrocnemius muscle morphology on its mechanical behaviour from winter to summer.     

Mass and functional capacity of regenerating muscle is enhanced by myoblast transfer

Morphology and functional capacity of homotopically transplanted extensor digitorum longus muscles (EDL) of adult SCID mice that received 1 × 10⁶ myoblasts [stably transfected to express nuclear localizing β-galactosidase under the control of the myosin light-chain 3F promoter/enhancer] 2 days posttransplantation were evaluated 9 weeks after transplantation, to determine whether the injection of exogenous myoblasts had an effect on muscle regeneration. Regenerated muscles that received exogenous myoblasts were compared to similarly transplanted muscles that received (a) no further treatment, or (b) sham injection of the vehicle (without myoblasts) and to unoperated EDL. Nine weeks after myoblast transfer, myofibers containing donor-derived nuclei could be identified after staining with X-gal solution. Judging from its size and poor functional performance compared to muscles subjected to transplantation only, sham injection provided a secondary trauma to the regenerating muscle from which it failed to fully recover. In comparison to the sham-injected muscle, the myoblast-injected muscles weighed 61% more and had 50% more myofibers and 82% more cross-sectional area occupied by myofibers at the muscles' widest girths. Their absolute twitch and tetanic tensions were threefold and twofold greater, respectively, and their specific twitch and tetanic tensions were 71% and 50% greater, respectively, than those of sham-injected muscles. In many parameters, the regenerating muscle subjected to myoblast transfer equaled or exceeded those of muscles that were transplanted only received only one trauma). Absolute twitch and tetanic tensions were 73% and 65% greater, respectively, and specific twitch tensions of the muscles receiving myoblasts were 50% greater than forces generated by muscles subjected to whole-muscle transplantation only. © 1997 John Wiley & Sons, Inc. J Neurobiol 33: 185–198, 1997     

Absence of staircase following disuse in rat gastrocnemius muscle

Repetitive stimulation of mammalian fast-twitch skeletal muscles will normally result in a positive staircase response. This phenomenon was investigated in the rat gastrocnemius muscle following a 2-week period of tetrodotoxin-induced disuse. Muscle inactivity was imposed by superfusing tetrodotoxin in saline over the left sciatic nerve via an implanted osmotic pump. In situ isometric contractile responses to double pulse stimulation and repetitive stimulation at 10 Hz were determined the day after removal of the pump. Two weeks of disuse resulted in 40% muscle weight loss. A twitch contraction gave the same force when expressed per gram of wet muscle weight in control muscles, 317 +/- 24.6 (means +/- SE) g/g, as compared with tetrodotoxin-treated muscles, 328 +/- 24.2 g/g. Both contraction time and half-relaxation time were prolonged following treatment with tetrodotoxin. Repetitive stimulation at 10 Hz resulted in a positive staircase response in the control muscles, but not in muscles of the tetrodotoxin-treated rats. The observed changes in the time course of the twitch contraction with repetitive stimulation following tetrodotoxin-induced disuse are consistent with alterations in sarcoplasmic reticulum handling of calcium. It is not certain if there is a change following disuse in the mechanism normally associated with staircase or if this mechanism is merely opposed by an early fatigue.     

Histochemical and contractile responses of rat medial gastrocnemius to 2 weeks of complete disuse.

We studied the histochemical and in situ contractile changes in a rat ankle extensor, medial gastrocnemius, in which activation of muscle fibres by motoneurones was blocked for 14 days, using the sodium channel blocker tetrodotoxin applied to the sciatic nerve. Muscles were atrophied and showed slower twitch responses, greater fusion at subtetanic frequencies of stimulation, and higher twitch/tetanic ratios. Tetanic force/mm2 of fibre area and fatiguability were unchanged. Type II fibres were more atrophied and showed greater decreases in mitochondrial succinate dehydrogenase activity than type I fibres. The contractile changes resulting from complete disuse do not occur in models in which weight-bearing alone has been removed (space flight, hindlimb suspension), suggesting that the residual motoneurone activity reported in models of weightlessness is sufficient to prevent these responses. Similarly, the finding of a greater type II fibre susceptibility to complete disuse, which differs from the pattern seen in models of weightlessness, suggest that this residual motoneurone activity in the latter influences atrophic responses in a manner that is variable among motor unit types, to produce the reported preferential type I atrophy characteristic of removal of weight-bearing.     

Carbonic anhydrase inhibition affects contraction of directly stimulated rat soleus

We have studied the contractile parameters of directly stimulated isolated rat soleus muscles incubated in media containing the carbonic anhydrase inhibitors chlorzolamide (5.10(-4)M) or cyanate (10(-2)M). Both inhibitors caused a decrease in isometric twitch and tetanic (5s) tensions and an increase in muscle relaxation time. It is speculated that among the three types of skeletal muscle carbonic anhydrase it may be the enzyme associated with the sarcoplasmatic reticulum whose inhibition caused the observed changes in contractile parameters.     

Genetic ablation of acetylcholinesterase alters muscle function in mice

Although acetylcholinesterase (AChE) knockout mice survive, they have abnormal neuromuscular function. We analysed further the effects of the mutation on hind limb muscle contractile properties. Tibialis anterior muscle from AChE KO mice is unable to maintain tension during a short period of repetitive nerve stimulation (tetanic fade) and has an increased twitch tension in response to a single nerve electric stimulation. In response to direct muscle stimulation, we found that maximal velocity of shortening of soleus muscle is increased and maximum tetanic force is decreased in AchE KO mice versus control animals. As the contractile properties of the soleus muscle were altered by AChE ablation, our results suggest cellular and molecular changes in AChE ablated muscle containing both fast and slow muscle fibres.     

Effect of nutritional deprivation on diaphragm contractility and muscle fiber size

The influence of nutritional deprivation on the contractile and fatigue properties of the diaphragm was studied in adult rats. Food access was restricted to one-third of normal daily intake until the body weight of nutritionally deprived (ND) animals was approximately 50% of controls (CTL). Isometric contractile properties were studied in an in vitro nerve muscle strip preparation. Both twitch (Pt) and tetanic (Po) tensions of diaphragms from the ND animals were markedly reduced compared with CTL; however, Pt/Po was higher for the ND group. The shape of the force-frequency curve (normalized to Po) was generally similar between the two groups, except at 5 and 10 pulses/s stimulation, where greater relative tensions were produced in diaphragms from the ND animals. Diaphragm fatigue was induced by repetitive stimulation at either 20 or 100 pulses/s. Endurance time (defined as the time required for tension to fall to 50% of initial) of diaphragms from ND animals was prolonged at both 20 and 100 pulses/s. Immediately after induction of fatigue, force-frequency curves for both ND and CTL diaphragms were shifted to the right. However, this rightward shift was attenuated in the ND group compared with CTL. Nutritional deprivation had no effect on the proportions of different fiber types within the diaphragm but did result in a significant decrease in the cross-sectional area of both fast-and slow-twitch fibers. This decrease in cross-sectional area was significantly greater for fast-twitch fibers. We conclude that these changes in diaphragm contractile and fatigue properties occur as a result of the influence of malnutrition on muscle fiber cross-sectional area.     

Electrically evoked contractions of the triceps surae during and following 21 days of voluntary leg immobilization

The effects of 21 days voluntary leg (plaster) immobilization on the mechanical properties of the triceps surae have been studied in 11 young female subjects, mean age 19.4 years. The results show that during the period of immobilization the mean time to peak tension (TPT) and half relaxation time (1/2RT) and tension (Pt) of the maximal twitch increased significantly (p less than 0.001) but the effects were short lived. Maximal tension and contraction times of the twitch recovered within 2-14 days following the removal of the plaster cast. The electrically evoked tetanic tensions at 10 Hz and 20 Hz did not change significantly (P greater than 0.1) during immobilization, but the 50 Hz tetanic tension (Po50) and maximal voluntary contraction (MVC) were reduced (p less than 0.05). The fall in Po50 and MVC was associated with 10% decrease in the estimated muscle (plus bone) cross-sectional area. The relative (%) change in Po50 and MVC following immobilization was related to the initial physiological status (as indicated by the response of the triceps surae to a standard fatigue test prior to immobilization) of the muscle. The rate of rise and recovery fall of the tetanus were slightly but significantly (p less than 0.01) reduced on day 7 of immobilization, but thereafter remained constant. The isokinetic properties of the triceps surae as reflected in the measured torque/velocity relation of the muscle in 4 subjects did not change significantly if account was taken of the slight degree of atrophy present following immobilization.(ABSTRACT TRUNCATED AT 250 WORDS)