Influence of simulated bed rest and intermittent weight bearing on single skeletal muscle fiber function in aged rats

The Effects of Non-Weight Bearing on Skeletal Muscle in Older Rats: an Interrupted Bout versus an Uninterrupted Bout

Age-related changes in skeletal muscle, in combination with bed rest, may result in a poorer rehabilitation potential for an elderly patient. The purpose of this study was to determine the effects of non-weight bearing (hind limb unweighting [HU]) on the soleus and extensor digitorum longus (EDL) in older rats. Two non-weight bearing conditions were used: an uninterrupted bout of HU and an interrupted bout of HU. Twenty-one rats were randomly placed into 1 of 3 groups: control, interrupted HU (2 phases of 7 days of HU, separated by a 4-day weight-bearing phase) and an uninterrupted HU (18 uninterrupted days of HU). Following non-weight bearing, the soleus and EDL muscles were removed. Fiber type identification was performed by myofibrillar ATPase and cross-sectional area was determined. The findings suggest that any period of non-weight bearing leads to a decrease in muscle wet weight (19%-45%). Both type I and type II fibers of the soleus showed atrophy (decrease in cross-sectional area, 35%-44%) with an uninterrupted bout of non-weight bearing. Only the type II fibers of the soleus showed recovery with an interrupted bout of weight bearing. In the EDL, type II fibers were more affected by an uninterrupted bout of non-weight bearing (15% decrease in fiber size) compared to the type I fibers. EDL type II fibers showed more atrophy with interrupted bouts of non-weight bearing than with a single bout (a 40% compared to a 15% decrease). This study shows that initial weight bearing after an episode of non-weight bearing may be damaging to type II fibers of the EDL.

Effects of weight bearing intervals on disuse atrophy of rat soleus muscle

The purpose of this study was to investigate the effects of weight bearing at varying intervals in suppressing the progression of disuse muscle atrophy, while setting the total daily weight bearing time constant. Disuse muscle atrophy was induced by 2-week hindlimb suspension. Thirty male Wistar rats ( weight : 215 ± 8 g ) were divided into 6 groups ( 5 rats/group ) : control (CON), suspension alone (SUS), two sessions of 30-minute weight bearing at intervals of 4, 8, and 12 hours during suspension, and one session of 60-minute weight bearing at intervals of 24 hours during suspension. Weight bearing was done each day during the daytime. Histochemical staining, followed by morphometrical analysis using NIH Image, demonstrated that the cross-sectional area of type I fiber in SUS was 44% of that in CON, while in the weight bearing groups ranged from 62 to 70%. The proportion of type I fibers was lower in SUS and tended to increase as the interval of weight bearing become longer, indicating the effects of weight bearing at intervals of 12 and 24 hours. For both types I and II, the distribution of muscle fiber size indicated that weight bearing at longer intervals was more effective in keeping the cross-sectional areas of muscle fibers closed to that in CON. In conclusion, when suppressing the progression of disuse atrophy of rat soleus muscle by weight bearing of one hour per day, the results suggest that the weight bearing intervals is important factor.

Influence of the time when weight bearing is started on disuse atrophy in rat soleus muscle

Prevention of disuse muscle atrophy is an important problem in physical therapy. Although several reports have been published concerning the effect of weight bearing on the prevention of disuse atrophy of lower extremity muscles, few basic clinical data are available. The present study was undertaken to examine differences in the progression of disuse muscle atrophy in terms of the time when weight bearing is started. The experimental materials consisted of the soleus muscles of 30 male Wistar rats (weight: 220 ± 6 g). The rats were divided into the control group (CON) and the experimental group, and disuse muscle atrophy caused by non-weight bearing was induced by hindlimb suspension for two weeks in the latter group. The experimental group was subdivided into four groups: no weight bearing permitted (SUS), and daily weight bearing permitted from 1, 4 and 7 days after the start of suspension (1-D, 4-D and 7-D). The relative weight of the soleus muscles did not differ for CON and 1-D or for 7-D and SUS. The mean cross-sectional area of type I fibers was 68% of that of CON for 1-D, 61% for 4-D, 52% for 7-D and 52% for SUS. This parameter showed significant differences any two groups, except for between 7-D and SUS. The results were regarded as normal in view of differences in the total time of weight bearing. The data also suggested that disuse muscle atrophy can be prevented quantitatively if weight bearing is initiated from the day following the start of suspension, and that early start of weight bearing is more effective for controlling atrophy progression.

Inactivity, age, and exercise: single-muscle fiber power generation

We examined the effects of mild therapeutic exercise during a period of inactivity on size and contractile functions of myosin heavy chain (MHC) type I (n = 204) and type II (n = 419) single fibers from the medial gastrocnemius in three age groups. Young adult (5-12 mo), middle-aged (24-31 mo), and old (32-37 mo) F344BNF1 rats were assigned to one of three groups: weight-bearing control, non-weight bearing (NWB), and NWB plus exercise (NWBX). Fourteen days of hindlimb suspension were applied in NWB rats. The NWBX rats exercised on the treadmill for 15 min, four times a day, during the period of NWB. The NWBX did not improve peak power, but increased normalized power of MHC type I fibers in young adult rats. In MHC type II fibers, NWBX did not change peak power, isometric maximal force, V(max), and fiber size from young adult and middle-aged rats. NWBX did not improve peak power and isometric maximal force and showed a dramatic decline in V(max) and normalized power in the old rats. Collectively, mild treadmill exercise during a period of inactivity does not improve peak power of MHC type I or type II fiber from the gastrocnemius in young, middle-aged, and old rats. However, NWBX is beneficial in enhancing normalized power of MHC type I fibers in young adult rats, most likely due to the stimulus intensity and the ability of the individual fibers to adapt to the stimulus. In contrast, several factors, such as impaired adaptation potential, inappropriate exercise intensity, or increased susceptibility to muscle damage, may contribute to the lack of improvement in the older rats.

Differential effects of mild therapeutic exercise during a period of inactivity on power generation in soleus type I single fibers with age

The purpose of this study was to investigate the effects of mild therapeutic exercise (treadmill) in preventing the inactivity-induced alterations in contractile properties (e.g., power, force, and velocity) of type I soleus single fibers in three different age groups. Young adult (5- to 12-mo-old), middle-aged (24- to 31-mo-old), and old (32- to 40-mo-old) F344BNF1 rats were randomly assigned to three experimental groups: weight-bearing control (CON), non-weight bearing (NWB), and NWB with exercise (NWBX). NWB rats were hindlimb suspended for 2 wk, representing inactivity. The NWBX rats were hindlimb suspended for 2 wk and received therapeutic exercise on a treadmill four times a day for 15 min each. Peak power and isometric maximal force were reduced following hindlimb suspension (HS) in all three age groups. HS decreased fiber diameter in young adult and old rats (-21 and -12%, respectively). Specific tension (isometric maximal force/cross-sectional area) was significantly reduced in both the middle-aged (-36%) and old (-23%) rats. The effects of the mild therapeutic exercise program on fiber diameter and contractile properties were age specific. Mild treadmill therapeutic exercise attenuated the HS-induced reduction in fiber diameter (+17%, 93% level of CON group) and peak power (μN·fiber length·s(-1)) (+46%, 63% level of CON group) in young adult rats. In the middle-aged animals, this exercise protocol improved peak power (+60%, 100% level of CON group) and normalized power (kN·m(-2)·fiber length·s(-1)) (+45%, 108% level of CON group). Interestingly, treadmill exercise resulted in a further reduction in shortening velocity (-42%, 67% level of CON group) and specific tension (-29%, 55% level of CON group) in the old animals. These results suggest that mild treadmill exercise is beneficial in attenuating and preventing inactivity-induced decline in peak power of type I soleus single fibers in young adult and middle-aged animals, respectively. However, this exercise program does not prevent the HS-induced decline in muscle function in the old animals.

Age-dependent effects of treadmill exercise during a period of inactivity

The objective of this study was to investigate the effect of a treadmill exercise protocol to prevent muscle weakness, atrophy and alterations in calcium regulation in adult, old and very old rats. Adult (7-12 months), old (29-30 months) and very old (34-36 months) F344BNF(1) rats were randomly assigned to weight bearing (WB), weight bearing exercise (WBX), non-weight bearing (NWB) and non-weight bearing exercise (NWBX) groups. The WB group was considered the sedentary-control animals. NWB rats were hindlimb unweighted for 14 days. WBX and NWBX groups were exercised on a treadmill for approximately 15 min four times daily. The contractile properties [diameter, peak active force (P(0)), specific tension (P(0)/CSA)] of single myosin heavy chain type II fibers and Ca regulation [Ca(2+) dependent ATPase activity] were determined. Fiber diameter reduced by 24% in the very old rats with NWB. P(0) and P(0)/CSA declined in the young adult and very old rats with NWB. NWBX attenuated these changes in the young and very old rats. Ca(2+) dependent ATPase activity increased with treadmill exercise during non-weight bearing in the young animals. In conclusion, the treadmill exercise is beneficial in attenuating the non-weight bearing-induced changes in the individual MHC type II muscle fibers of the gastrocnemius muscle.

The roles of myosin ATPase activity and myosin light chain relative content in the slowing of type IIB fibers with hindlimb unweighting in rats

We tested the hypothesis that slowing of shortening velocity generated by type IIB fibers from hindlimb-unweighted (HU) rats resulted from a reduced ATPase activity and/or a reduction in the relative content of myosin light chain 3f isoform content (MLC(3f)). After 2, 3, and 4 wk of HU, maximal unloaded shortening velocity (V(o)) of single permeabilized semimembranosus muscle fibers was determined by the slack test. Subsequently, the myosin heavy chain and the relative content of MLC were determined by SDS-PAGE. The ratio of MLC(3f) to MLC(2f) was determined by densitometric analysis. In addition, myofibrils were prepared from permeabilized fibers (soleus and semimembranosus muscles) and assayed for resting myosin ATPase and Ca(2+)-activated myosin ATPase. After HU, V(o) declined by 28-40% and the MLC(3f)/MLC(2f) ratio decreased by 32 to 48%. A significant correlation between the relative amount of MLC(3f) and V(o) was found (r = 0.48, P < 0.05). Resting myosin ATPase rates were not different between myofibrils prepared from corresponding muscles of control and HU rats (P = 0.86). Ca(2+)-activated myosin ATPase activities also were not different between myofibrils prepared from corresponding muscles of control and HU rats (P = 0.13). These data suggest that the slowing of maximal unloaded shortening velocity in type IIB fibers with HU is, at least in part, due to a relative change in the essential light chain composition, a decrease in the relative amount of MLC(3f) and most likely a concomitant increase in MLC(1f). However, this reduction in V(o) is independent of myosin ATPase activity.

Effects of hindlimb unweighting and aging on rat semimembranosus muscle and myosin

We tested the hypothesis that lower specific force (force/cross-sectional area) generated by type II fibers from hindlimb-unweighted rats resulted from structural changes in myosin (i.e., a change in the ratio of myosin cross bridges in the weak- and strong-binding state during contraction). In addition, we determined whether those changes were age dependent. Permeabilized semimembranosus muscle fibers from young adult and aged rats, some of which were hindlimb unweighted for 3 wk, were studied for Ca(2+)-activated force generation and maximal unloaded shortening velocity. Fibers were also spin labeled specifically at myosin Cys707 to assess the structural distribution of myosin during maximal isometric contraction using electron paramagnetic resonance spectroscopy. Myosin heavy chain isoform (MHC) expression and the ratio of MHC to actin were evaluated in each fiber. Fibers from the unweighted rats generated 34% less specific force than fibers from weight-bearing rats (P < 0.001), independent of age. Electron paramagnetic resonance analyses showed that the fraction of myosin heads in the strong-binding structural state during contraction was 11% lower in fibers from the unweighted rats (P = 0.019), independent of age. More fibers from unweighted rats coexpressed MHC IIB-IIX compared with fibers from weight-bearing rats (P = 0.049). Unweighting induced a slowing of maximal unloaded shortening velocity and an increase in the ratio of MHC to actin in fibers from young rats only. These data indicate that altered myosin structural distribution during contraction and a preferential loss of actin contribute to unweighting-induced muscle weakness. Furthermore, the age of the rat has an influence on some parameters of changes in muscle contractility that are induced by unweighting.

Molecular regulation of apoptosis in fast plantaris muscles of aged rats

This study tested the hypothesis that aging exacerbates apoptotic signaling in rat fast plantaris muscle during muscle unloading. Plantaris muscle mass was 22% lower in aged animals and the apoptotic index was 600% higher, when compared to those in young adult animals. Following 14 days of hind-limb unloading, absolute plantaris muscle mass was 20% lower in young adult animals with a corresponding 200% higher elevation of the apoptotic index. Unloading had no affect on muscle weight or apoptotic index of aged plantaris muscles. The changes in pro-apoptotic messenger RNA (mRNA) for apoptotic protease activating factor-1 (Apaf-1), Bax, and inhibitor of differentiation protein-2 (Id2) were exacerbated with aging. Bax and Bcl-2 protein levels were also altered differently in aged muscle, compared to young. Significant positive correlations were observed between the changes in Id2 and Bax mRNA, and Id2 and caspase-9 mRNA. These data suggest that a pro-apoptotic environment may contribute to aging-associated atrophy in fast skeletal muscle, but apoptotic signaling differs by age.

Prehabilitation and rehabilitation for attenuating hindlimb unweighting effects on skeletal muscle and gait in adult and old rats

OBJECTIVE

To compare the effectiveness of no exercise with prehabilitation (exercise before hindlimb unweighting [HLU]) versus rehabilitation (exercise given after HLU) on gait function and skeletal muscle mass and force.

DESIGN

Randomized controlled trial.

SETTING

Animal laboratory.

ANIMALS

Male-specific, pathogen-free Fisher344/Brown Norway rats (N=149). Groups consisted of adult and old controls, HLU, prehabilitation, rehabilitation, natural cage recovery (reloading), and exercise without HLU.

INTERVENTIONS

Ten days of general conditioning exercise were given to 6-month-old adult and 30-month-old old rats before or after a week of HLU.

MAIN OUTCOME MEASURES

Gait stride length and width; soleus, plantaris, extensor digitorum longus, and peroneus longus mass and peak contractile force; whole gastrocnemius mass; and total protein concentration for the soleus and gastrocnemius.

RESULTS

Muscle mass (approximately 30%) and force (24%-36%) declined with age in all muscles studied. In adult rats declines in muscle mass occurred with HLU in the soleus, plantaris, and gastrocnemius. Prehabilitation did not prevent the loss of muscle mass in adult rats. Rehabilitation and natural recovery effectively restored soleus and gastrocnemius muscle mass in adult rats but not soleus peak force. Old rats had a significant 23% HLU effect only on gastrocnemius mass (control, 1670+/-129 mg; HLU, 1274+/-184 mg). Prehabilitation did not prevent the decline in gastrocnemius mass. Rehabilitation in old rats restored gastrocnemius mass to within 13% of control levels. Prehabilitation was effective for preventing and rehabilitation was effective for restoring soleus contractile force in old rats (control, 114+/-9 mg; HLU, 67+/-22 mg; prehabilitation, 106+/-31 mg; rehabilitation, 120+/-26 mg) compared with recovery without exercise (86+/-29 g). A significant reduction in stride length was observed with aging (136+/-18 mm vs 98+/-10 mm), which decreased further with HLU (78+/-14 mm). Prehabilitation attenuated HLU-related reductions in stride length, and rehabilitation was effective for stride length restoration in old rats.

CONCLUSIONS

Exercise, particularly rehabilitation, was more effective for old than young rats. Prehabilitation and rehabilitation diminished some of the detrimental effects of HLU on skeletal muscle mass and force and gait function in old rats.

Effects of endurance exercise-training on single-fiber contractile properties of insulin-treated streptozotocin-induced diabetic rats

The purpose of this study was to characterize the contractile properties of individual skinned muscle fibers from insulin-treated streptozotocin-induced diabetic rats after an endurance exercise training program. We hypothesized that single-fiber contractile function would decrease in the diabetic sedentary rats and that endurance exercise would preserve the function. In the study, 28 rats were assigned to either a nondiabetic sedentary, a nondiabetic exercise, a diabetic sedentary, or a diabetic exercise group. Rats in the diabetic groups received subcutaneous intermediate-lasting insulin daily. The exercise-trained rats ran on a treadmill at a moderate intensity for 60 min, five times per week. After 12 wk, the extensor digitorum longus and soleus muscles were dissected. Single-fiber diameter, Ca2+-activated peak force, specific tension, activation threshold, and pCa50as well as the myosin heavy chain isoform expression (MHC) were determined. We found that in MHC type II fibers from extensor digitorum longus muscle, diameters were significantly smaller from diabetic sedentary rats compared with nondiabetic sedentary rats ( P < 0.001). Among the nondiabetic rats, fiber diameters were smaller with exercise ( P = 0.038). The absolute force-generating capacity of single fibers was lower in muscles from diabetic rats. There was greater specific tension (force normalized to cross-sectional area) by fibers from the rats that followed an endurance exercise program compared with sedentary. From the results, we conclude that alterations in the properties of contractile proteins are not implicated in the decrease in strength associated with diabetes and that endurance-exercise training does not prevent or increase muscle weakness in diabetic rats.

Effect of inactivity and undernutrition after acute ischemic stroke in a rat hindlimb muscle model

BACKGROUND

Stroke patients experience functional changes resulting from muscle atrophy related to disuse, lack or limited neuronal stimulation, and undernutrition. Acute ischemic stroke is assumed to induce muscle atrophy. However, there is little information regarding muscle changes after acute stroke.

OBJECTIVE

The purpose of this study was to examine the effect of inactivity and undernutrition after acute stroke on mass, myofibrillar protein content, and Types I and II fiber cross-sectional areas of rat hindlimb muscles.

METHODS

Adult male Sprague-Dawley rats (body weight, 240-270 g) were randomly assigned to one of three groups: a stroke group (n = 7) that had occlusion of the right middle cerebral artery, a control group (n = 7) that underwent a sham right middle cerebral artery procedure, and an undernourished group (n = 9) that was pair-fed to match the intake of stroke rats. Food and water intake as well as body weight were measured daily. The rats were anesthetized 7 days after occlusion or sham occlusion, after which the soleus (Type I), plantaris (Type II), and gastrocnemius (Type II) muscles were dissected from both the affected and unaffected sides. The brain was sectioned to identify cerebral infarction in the stroke group. Body weight, food intake, muscle weight, fiber type distribution, cross-sectional area, and myofibrillar protein content of the dissected muscles were determined.

RESULTS

The stroke group at 7 days after ischemic stroke showed significant decreases (p <.05), as compared with the control rats, in diet intake and body weight, muscle weight of affected gastrocnemius, Type I fiber cross-sectional area of the affected soleus muscle, Types I and II fiber cross-sectional areas and Type II fiber distribution of the unaffected soleus muscle, and myofibrillar protein content of both the affected and unaffected soleus muscles. As compared with the control group, the undernourished group showed significant decreases (p <.05) in diet intake and body weight, Type I fiber cross-sectional area of the affected soleus muscle, Types I and II fiber cross-sectional areas and Type II fiber distribution of the unaffected soleus muscle, Type I fiber distribution of the affected gastrocnemius muscle, and myofibrillar protein content of both the affected and unaffected soleus muscles. As compared with the undernourished group, the stroke group showed significant decreases (p <.05) in muscle weight and Type II fiber distribution of the affected gastrocnemius muscle. There were no differences in muscle characteristics between the affected and unaffected hindlimb muscles at 7 days after ischemic stroke.

CONCLUSIONS

Hindlimb muscle atrophy occurs in both affected and unaffected sides after acute stroke, with Type I muscle changes more apparent than Type II changes.

Histochemical study on the changes in muscle fibers in relation to the effects of aging on recovery from muscular atrophy caused by disuse in rats

To investigate the effects of aging on the degree of muscular atrophy caused by disuse and its recovery, we evaluated the recovery from muscular atrophy induced in both young and old rats under the same conditions. The soleus was atrophied by immobilization of the foot joint in a hindlimb and unweighting of the bilateral hindlimbs for 2 weeks, and measurement of the wet weight of muscles and biochemical examination were performed 2, 4, and 6 weeks after the removal of unweighting and fixation during the recovery period of 6 weeks. There was no difference in the degree of atrophy in the fixed soleus between the young and old rats. The recovery from atrophy was delayed in the older rats compared to the young rats. In the unfixed hindlimb, the degree of atrophy was low in both the old and young rats, and the recovery was rapid. Because the recovery from disuse muscular atrophy is delayed with aging, it is necessary to avoid unweighting and immobilization, or to reduce the period spent under such conditions.

Satellite cell regulation of muscle mass is altered at old age

Muscle mass is decreased with advancing age, likely due to altered regulation of muscle fiber size. This study was designed to investigate cellular mechanisms contributing to this process. Analysis of male Fischer 344 X Brown Norway rats at 6, 20, and 32 mo of age demonstrated that, even though significant atrophy had occurred in soleus muscle by old age, myofiber nuclear number did not change, resulting in a decreased myonuclear domain. Also, the number of centrally located nuclei was significantly elevated in soleus muscle of 32-mo-old rats, correlating with an increase in gene expression of MyoD and myogenin. Whereas total 5'-bromo-2'deoxyuridine (BrdU)-positive nuclei were decreased at older ages, BrdU-positive myofiber nuclei were increased. These results suggest that, with age, loss of muscle mass is accompanied by increased myofiber nuclear density that involves fusion of proliferative satellite cells, resembling ongoing regeneration. Interestingly, centrally located myofiber nuclei were not BrdU labeled. Rats were subjected to hindlimb suspension (HS) for 7 or 14 days and intermittent reloading during HS for 1 h each day (IR) to investigate how aging affects the response of soleus muscle to disuse and an atrophy-reducing intervention. After 14 days of HS, soleus muscle size was decreased to a similar extent at all three ages. However, myofiber nuclear number and the total number of BrdU-positive nuclei decreased with HS only in the young rats. IR was associated with an attenuation of atrophy in soleus muscles of 6- and 20- but not 32-mo-old rats. Furthermore, IR was associated with an increase in BrdU-positive myofiber nuclei only in young rats. These data indicate that altered satellite cell function with age contributes to the impaired response of soleus muscle to an intervention that attenuates muscle atrophy in young animals during imposed disuse.

Morphological characteristics of skeletal muscles in relation to gender

BACKGROUND AND AIMS

The aim of this study was to ascertain whether there are gender-related differences in the morphological characteristics of the soleus and tibialis anterior muscles in young adult and old Fischer 344/Brown Norway F1 rats.

METHODS

We tested 1) whether there was a gender-related difference between the fiber type composition of these muscles, and 2) whether the cross-sectional area of individual muscle fibers demonstrated gender-associated differences, fibers from males being larger than fibers from females.

RESULTS

Gender differences were not found in the fiber type composition of the soleus and tibialis anterior muscles, but were present in the single skeletal fiber cross-sectional area of the tibialis anterior muscle. The cross-sectional area of type I fibers in females was greater than that in males at both 12 (16%) and 30 (5%) months of age. In contrast, the cross-sectional area of type Ila fibers of 12-month-old males was larger than that of 12-month-old females. No significant differences between genders were found for the cross-sectional area of type Ilb fibers in either age group. In the soleus muscle, 30-month-old males had larger single fiber cross-sectional areas of both fiber types I and lIa. At 12 months of age, type I fibers from females were larger than those from males.

CONCLUSIONS

Our findings indicate that gender-related differences exist in the size of individual skeletal fibers from the soleus and tibialis anterior muscles and that they may influence metabolism and the adaptive response to rehabilitation programs.

Influence of hindlimb unweighting and intermittent weight bearing on dynamics of nuclei in rat soleus muscle

The purpose of this study was to examine differences in the inhibitory effect of disuse atrophy as a result of intermittent weight bearing in terms of the dynamics of nuclei in rat soleus muscle. Disuse muscle atrophy was induced by hindlimb suspension for two weeks. Forty-nine male Wistar rats (body weight: 190-228 g) were divided into the control group (CON) and the experimental group. The experimental group was subdivided into four groups: hindlimb suspension alone (HS), weight bearing for 10 minutes × 4 times/day (W10), weight bearing for 20 minutes × 2 times/day (W20), and weight bearing for 40 minutes × one time/day (W40). In addition to histochemical examination, this study examined both cell proliferation and apoptosis in terms of the dynamics of myonuclei immuno-histochemically. The mean cross-sectional area of muscle fibers demonstrated the effect of weight bearing. The number of proliferating myonuclei per 100 muscle fibers was decreased in the experimental groups as compared with CON. Proliferating myonuclei in W10 and W40 were more than HS, indicating the effect of weight bearing. Apoptotic myonuclei was increased in the experimental groups as compared with CON. This parameter in W10 and W40 were statistically not significantly different from CON, suggesting that these weight bearing methods can prevent the loss of myonuclei by apoptosis. However, W20 was not significantly different from HS in terms of the dynamics of myonuclei. This suggests that weight bearing for W20 was ineffective. The results in this study indicated the possibility of inducing different effects by the frequency of weight bearing.

Enzymatic alterations in single type IIB skeletal muscle fibers with inactivity and exercise in 12- and 30-month-old rats

The purpose of the present study was to examine the effects of aging, inactivity and weight-bearing exercise on fast-twitch single Type IIB skeletal muscle fibers from the superficial region of the lateral head of the gastrocnemius (Type IIB fibers). Specifically, this study compared the biochemical properties of Type IIB fibers after 7 days of hindlimb unweighting (HU), 7 days of HU with intermittent weight-bearing (HU-Ex), and cage control (C) from adult and aged Fischer 344 Brown Norway F1 Hybrid rats (12- and 30-month old). Biochemical measurements included total lactate dehydrogenase (LDH) and beta-hydroxy-acyl-coenzyme A dehydrogenase activities (BHAD), expressed in nmoles/microg/hr dry weight. Fiber-typing for myosin heavy chain isoform was determined by SDS-PAGE. With age, LDH activity in Type IIB fibers decreased from 52.0 +/- 3.4 nmoles/microg/hr (12-month old) to 39.5 +/- 2.9 nmoles/microg/hr (30-month old). Following HU, LDH activity of single Type IIB fibers increased by 22% (52.0 +/- 3.4 to 66.4 +/- 3.2 nmoles/microg/hr) in the 12-month-old animals, whereas no difference was observed with HU in the Type IIB fibers of the 30-month-old animals. Following HU-Ex, LDH activity of Type IIB fibers in the 12-month-old animals was not significantly different from that of Type IIB fibers from HU animals, whereas a significant increase was observed (38.1 +/- 2.9 to 51.8 +/- 3.1 nmoles/microg/hr) in Type IIB fibers of 30-month-old animals, for HU and HU-Ex, respectively. Analysis of variance revealed an interaction between age and condition, indicating that Type IIB fibers from adult and aged animals have a different biochemical response to inactivity. The enzyme activities for BHAD were not different between the experimental conditions. The results demonstrate that the total LDH enzyme activities of the Type IIB fibers decrease with age, suggesting an age-related shift in the biochemical profile. Further, single skeletal muscle fiber adaptation is age-dependent.

Skeletal muscle adaptations with age, inactivity, and therapeutic exercise

One of the remarkable features of skeletal muscle is its adaptability. Skeletal muscle adaptations are characterized by modifications of morphological, biochemical, and molecular variables that alter the functional attributes of specific skeletal muscle fiber types. Skeletal muscle adaptation is diverse and the magnitude of change is dependent on many factors, such as activity pattern, age, and muscle fiber type composition. The adaptation of skeletal muscle in the adult population is well described. In contrast, the adaptation of skeletal muscle in the older population is less documented, especially in the area of inactivity-induced alterations. Age-related changes in skeletal muscle may play a significant role in the magnitude of change with inactivity and influence the rehabilitation process for the older adult. A consistent feature of age and inactivity is limb muscle atrophy and the loss of peak force and power. Differences exist in the rate and mechanisms of muscle wasting and in the susceptibility of a given fiber type to atrophy. Most likely, the rapid muscle wasting might be in part due to a decrease in protein synthesis coupled with an increased degradation. Besides the quantitative change in muscle mass, age and inactivity induce important qualitative changes in the structure of key skeletal muscle proteins that are manifested in alterations in contractile properties. Therefore, the purpose of this clinical commentary is to identify the major effects of age and inactivity on skeletal muscle structure and function, and discuss potential therapeutic interventions. Special emphasis will be placed on how alterations in muscle structure affect function and on the cellular and molecular mechanisms of the age-related and inactivity-induced muscle changes.

Effects of inactivity on glycolytic capacity of single skeletal muscle fibers in adult and aged rats

The purpose of this study was to determine the effects of inactivity on lactate dehydrogenase (LDH) enzyme activity (expressed in nmol/g dry weight x hour) in single skeletal musclefibers from the soleus muscle in adult and aged rats. Fourteen 12-month-old andfifteen 30-month-old Fisher 344 Brown Norway F1 Hybrid rats were randomly assigned to control, 1 week of hindlimb unweighting (HU1), or 2 weeks of hindlimb unweighting (HU2). With age, a significant decrease in LDH enzyme activity occurred in type I skeletal muscle fibers (29.5%, P < 0.05). Following HU2, individual type I skeletal muscle fibers from the 12-month-old animals showed a 33.3% increase in LDH activity. In contrast, individual type I fibers from the aged animals showed a 50.0% increase after HU1. In conclusion, the baseline levels of LDH activity were significantly less in aged versus adult rats. The timing of the skeletal muscle adaptation to inactivity was different between young and old animals, such that the older animals responded to inactivity before the younger animals. These biochemical changes may have an impact on the fatigability of the muscle following inactivity. Thefindings indicate that treatment during bed rest for the older adult may be different than that for the younger adult.

Calcium sensitivity of force production and myofibrillar ATPase activity in muscles from Thoroughbreds with recurrent exertional rhabdomyolysis

OBJECTIVE

To determine whether the basis for recurrent exertional rhabdomyolysis (RER) in Thoroughbreds lies in an alteration in the activation and regulation of the myofibrillar contractile apparatus by ionized calcium.

ANIMALS

4 Thoroughbred mares with RER and 4 clinically normal (control) Thoroughbreds.

PROCEDURES

Single chemically-skinned type-I (slow-twitch) and type-II (fast-twitch) muscle fibers were obtained from punch biopsy specimens, mounted to a force transducer, and the tensions that developed in response to a series of calcium concentrations were measured. In addition, myofibril preparations were isolated from muscle biopsy specimens and the maximal myofibrillar ATPase activity, as well as its sensitivity to ionized calcium, were measured.

RESULTS

Equine type-I muscle fibers were more readily activated by calcium than were type-II muscle fibers. However, there was no difference between the type-II fibers of RER-affected and control horses in terms of calcium sensitivity of force production. There was also no difference between muscle myofibril preparations from RER-affected and control horses in calcium sensitivity of myofibrillar ATPase activity.

CONCLUSIONS AND CLINICAL RELEVANCE

An alteration in myofibrillar calcium sensitivity is not a basis for pathologic contracture development in muscles from RER-affected horses. Recurrent exertional rhabdomyolysis in Thoroughbreds may represent a novel heritable defect in the regulation of muscle excitation-contraction coupling or myoplasmic calcium concentration.

Maximal and submaximal forces of slow fibers in human soleus after bed rest

The effects of 2 and 4 mo of bed rest, with or without exercise countermeasures, on the contractile properties of slow fibers in the human soleus muscle were examined. Mean fiber diameters were 8 and 36% smaller after 2 and 4 mo of bed rest, respectively, than the pre-bed rest level. Maximum tetanic force (P(o)), maximum activated force (F(max)) per cross-sectional area (CSA), and the common-logarithm value of free Ca(2+) concentration required for half-maximal activation (pCa(50)) also decreased after 2 and 4 mo of bed rest. In contrast, maximum unloaded shortening velocity (V(o)) was increased after 2 and 4 mo of bed rest. After 1 mo of recovery, fiber diameters, P(o), F(max) per CSA (P > 0.05), and pCa(50) were increased and V(o) decreased toward pre-bed rest levels. Effects of knee extension/flexion exercise by wearing an anti-G Penguin suit for 10 h daily, and the effects of loading or unloading of the plantar flexors with (Penguin-1) or without (Penguin-2) placing the elastic loading elements of the suit, respectively, were investigated during ~2 mo of bed rest. In the Penguin-1 group, mean fiber diameter, P(o), F(max) per CSA, V(o), and pCa(50) were similar before and after bed rest. However, the responses of fiber size and contractile properties to bed rest were not prevented in the Penguin-2 group, although the degree of the changes was less than those induced by bed rest without any countermeasure. These results indicate that long-term bed rest results in reductions of fiber size, force-generation capacity, and Ca(2+) sensitivity, and enhancement of shortening velocity in slow fibers of the soleus. The data indicate that continuous mechanical loading on muscle, such as stretching of muscle, is an effective countermeasure for the prevention of muscular adaptations to gravitational unloading.

Clenbuterol in the prevention of muscle atrophy: a study of hindlimb-unweighted rats

OBJECTIVE

To determine whether the administration of clenbuterol, a beta2-adrenergic agonist, prevents loss of muscle mass during a period of imposed inactivity.

DESIGN

Randomized trial.

SETTING

Basic laboratory research.

ANIMALS

Thirty Fischer 344 Brown Norway F1 Hybrid rats, 12 and 30 months of age.

INTERVENTIONS

The rats were randomly assigned to a control group, or to 1 of 2 experimental groups: hindlimb unweighted for 2 weeks (HU-2), or hindlimb unweighted with daily injections of clenbuterol for 2 weeks (HU-2Cl).

MAIN OUTCOME MEASURES

Muscle mass weighed in milligrams and single fiber cross-sectional area histochemically evaluated.

RESULTS

In both age groups, the HU-2 animals had greater muscle atrophy (decrease in muscle mass) in the soleus muscle than the extensor digitorum longus (EDL) muscle. In the HU-2Cl groups, the decline in muscle mass of both the soleus and EDL muscles was attenuated by about 4% to 20%. In the HU-2 group, single fiber cross-sectional area decreased for both fiber types (type I, 20%-40%; type II, 37%-50%) in both age groups. Clenbuterol retarded the inactivity-induced decline in single fiber cross-sectional area by 12% to 50%. In the EDL muscles of the HU-2Cl group, we found hypertrophy in both fiber types in the 30-month-old animals and in type I fibers in the 12-month-old animals.

CONCLUSIONS

Clenbuterol attenuated the decrease in muscle mass and single fiber cross-sectional area in both age groups. By preventing the loss of muscle mass, clenbuterol administered early in rehabilitation may benefit severely debilitated patients imposed by inactivity. The attenuated muscle atrophy found with clenbuterol in the present study provides cellular evidence for the reported change in muscle strength after its administration after knee surgery. Thus, the administration of clenbuterol may lead to a more rapid rate of rehabilitation.

Clenbuterol reduces soleus muscle fatigue during disuse in aged rats

High levels of clenbuterol have been shown to preserve muscle mass and function during disuse. In this study we report that a low dose of clenbuterol (10 microg/kg per day) lessened the loss of in situ soleus muscle isometric force normalized to wet muscle weight (P(o)/g wet weight) by 8% and reduced isometric fatigue by approximately 30% in senescent rats after 21 days of hindlimb suspension (HS). Clenbuterol did not reduce the loss of relative force in the soleus of adult rats or the plantaris of old or adult rats. Furthermore, clenbuterol failed to improve muscle force or isometric fatigue in the soleus of adult rats or in the plantaris of either age group after HS. We conclude that low levels of clenbuterol reduce muscle fatigue in slow muscles during disuse and this beta-agonist may also have therapeutic value for reducing fatigue in slow muscles (e.g., postural muscles) in the elderly during disuse.

Relationship of skeletal muscle atrophy to functional status: a systematic research review

In the realm of muscle atrophy research, many studies address minute details of molecular function but few examine the effects of atrophy in terms of mobility, strength, endurance, and performance of activities of daily living. The relationship between impairment and functional limitation is the focus of this research review. A wide array of studies constitute this area of inquiry, including investigations as diverse and widely disparate as molecular chemistry and space travel and populations as different as rats, healthy young men, and elderly women. Thirty-four studies were selected based on their fit with the Enabling-Disabling Model. Three paradigms of atrophy and function emerged. Adaptation reflects the plastic nature of muscle when placed under certain conditions, ranging from disuse to high-resistance exercise. Injury/loss describes damage to muscle tissue from ischemia, medications, or reloading or reperfusion trauma. Also in this category is the loss of muscle that is seen with aging. Integrity relates to the muscle's tendency to protect itself and maintain structural adjacencies and cellular proportions. Based on the 3 muscle research paradigms, the relationship of muscle atrophy to function is portrayed as a bidirectional interaction wherein form and function have an influence on each other by way of physical changes, including those of adaptation, injury/loss, or integrity. A conceptual model is constructed to reflect this relationship.

A physiological level of clenbuterol does not prevent atrophy or loss of force in skeletal muscle of old rats

Supraphysiological levels of clenbuterol (CL) reduce muscle degradation in both young and old animals; however, these pharmacological levels induce side effects that are unacceptable in the elderly. In this study, we tested the hypothesis that a "physiological" dose of CL (10 microg. kg(-1). day(-1)) would attenuate the loss of in situ isometric force and mass in muscles of senescent rats during hindlimb suspension (HS). Adult (3 mo) and senescent (38 mo) Fischer 344 x Brown Norway rats received CL or a placebo during 21 days of normal-weight-bearing or HS conditions (8 rats/age group). HS reduced soleus muscle weight-to-body weight ratio by 31%, muscle cross-sectional area by 37%, and maximal isometric tetanic force (P(o)) by 76% in senescent rats. CL attenuated the loss of P(o) and muscle weight by 17 and 8%, respectively, in the soleus of senescent rats relative to HS+placebo conditions, but it did not improve muscle weight normalized for body weight. CL did not reduce the decrease in soleus P(o) or mass after HS in adult rats. CL failed to reduce the loss of plantaris weight (-20%) and P(o) (-46%) in senescent rats after HS. Our data support the conclusion that physiological levels of CL do not improve fast muscle atrophy and only modestly reduce slow muscle atrophy, and, therefore, it is largely an ineffective countermeasure for preventing muscle wasting from HS in senescent rats.

Age-related changes in contractile properties of single skeletal fibers from the soleus muscle

Peak absolute force, specific tension (peak absolute force per cross-sectional area), cross-sectional area, maximal unloaded shortening velocity (Vo; determined by the slack test), and myosin heavy chain (MHC) isoform compositions were determined in 124 single skeletal fibers from the soleus muscle of 12-, 24-, 30-, 36-, and 37-mo-old Fischer 344 Brown Norway F1 Hybrid rats. All fibers expressed the type I MHC isoform. The mean Vo remained unchanged from 12 to 24 mo but did decrease significantly from the 24- to 30-mo time period (from 1.71 +/- 0.13 to 0.85 +/- 0.09 fiber lengths/s). Fiber cross-sectional area remained constant until 36 mo of age, at which time there was a 20% decrease from the values at 12 mo of age (from 5,558 +/- 232 to 4,339 +/- 280 micrometer2). A significant decrease in peak absolute force of single fibers occurred between 12 and 24 mo of age (from 51 +/- 2 x 10(-5) to 35 +/- 2 x 10(-5) N) and then remained constant until 36 mo, when another 43% decrease occurred. Like peak absolute force, the specific tension decreased significantly between 12 and 24 mo by 20%, and another 32% decline was observed at 37 mo. Thus, by 24 mo, there was a dissociation between the loss of fiber cross-sectional area and force. The results suggest time-specific changes of the contractile properties with aging that are independent of each other. Underlying mechanisms responsible for the time-dependent and contractile property-specific changes are unknown. Age-related changes in the molecular dynamics of myosin may be the underlying mechanism for altered force production. The presence of more than one beta/slow MHC isoform may be the mechanism for the altered Vo with age.

The fiber-type-specific effect of inactivity and intermittent weight-bearing on the gastrocnemius muscle of 30-month-old rats

OBJECTIVE

To characterize single skeletal muscle fiber contractile properties from the gastrocnemius muscle that occur during inactivity and intermittent weight-bearing in 30-month-old animals.

DESIGN

Randomized control trial.

SETTING

A controlled laboratory environment.

SUBJECTS

Eighteen 30-month-old male Fisher 344 Brown Norway F1 Hybrid rats were randomly assigned to control (C), hindlimb unweighted (HU), and hindlimb unweighted with intermittent weight-bearing (HU-X) groups.

INTERVENTIONS

The HU and HU-X rats were suspended for 7 days. The HU-X animals were unsuspended for four 15-minute bouts of weight-bearing.

MAIN OUTCOME MEASURES

Single skeletal muscle fiber contractile properties (diameter, peak active force [P0], peak specific tension [P0/CSA], and maximal shortening velocity [V0] by fiber type) were determined from the deep portion of the lateral head of the gastrocnemius muscle (RG).

RESULTS

In comparison to C animals, the ratio of gastrocnemius weight to body weight decreased by 18% and 14% following HU and HU-X, respectively. Diameter and P0 of type I fibers from the RG were reduced after HU. Attenuation of the decline in diameter and P0 was observed in type I fibers from the RG with HU-X. P0 was reduced in type IIa fibers and type I-IIa fibers with HU. Attenuation of the decline in P0 by intermittent weight-bearing in type IIa fibers and type I-IIa fibers did not occur.

CONCLUSIONS

Inactivity altered the contractile properties of single skeletal muscle fibers from the gastrocnemius muscle of 30-month-old animals. The inactivity-induced alterations were present in the three fiber types. Therapeutic intervention of weight-bearing attenuated the inactivity-induced changes in the type I fibers from the gastrocnemius, but not the other fiber types.

Single soleus muscle fiber function after hindlimb unweighting in adult and aged rats

This investigation compared how hindlimb unweighting (HU) affected the contractile function of single soleus muscle fibers from 12- and 30-mo-old Fischer 344 Brown Norway F1 Hybrid rats. After 1 wk of HU, functional properties of single permeabilized fibers were studied, and, subsequently, the fiber type was established by myosin heavy chain (MHC) analysis. After HU, the relative mass of soleus declined by 12 and 19% and the relative mass of the gastrocnemius declined by 15 and 13% in 12- and 30-mo-old animals, respectively. In 12-mo-old animals, the peak active force (5.0 +/- 0.2 x10(-4) vs. 3.8 +/- 0.2 x10(-4) N) and the peak specific tension (92 +/- 4 vs. 78 +/- 3 kN/m2) were significantly reduced in the MHC type I fibers by 24 and 15%, respectively. In 30-mo-old animals, the peak active force declined by 40% (4.7 +/- 0.2 x10(-4) vs. 2.8 +/- 0. 3 x10(-4) N) and the peak specific tension declined by 30% (79 +/- 5 vs. 55 +/- 4 kN/m2). The maximal unloaded shortening velocity of the MHC type I fibers increased in 12-mo-old animals (from 1.65 +/- 0.12 to 2.59 +/- 0.26 fiber lengths/s) and in 30-mo-old animals (from 0.90 +/- 0. 09 to 1.50 +/- 0.10 fiber lengths/s) after HU. Collectively, these data suggest that the effects of HU on single soleus skeletal muscle fiber function occur in both age groups; however, the single MHC type I fibers from the older animals show greater changes than do single MHC type I fibers from younger animals.

Immobilization effects on contractile properties of aging rat skeletal muscle

The effect of four weeks of ankle immobilization on muscle mass and in situ contractile properties of soleus (SOL), plantaris (PLA), and extensor digitorum longus (EDL) of 31- and 37-month-old (mo) Fisher 344/Brown Norway rats was examined. Following contractile tests, muscles were harvested, weighed, and analyzed for fiber type and fiber cross-sectional area. Body weights (g) were similar in both control (CON) groups (31 mo, 578 +/- 20; 37 mo, 553 +/- 26; mean +/- SE) and both immobilized (IM) groups (31 mo, 496 +/- 6; 37 mo, 461 +/- 15). Immobilization-related differences in peak tetanic tension (g) were less in 37 mo than 31 mo rats (age x treatment, p < 0.05) for SOL (31 mo, CON 156 +/- 11, IM 63 +/- 12; 37 mo, CON 70 +/- 6, IM 46 +/- 8), PLA (31 mo, CON 435 +/- 13, IM 239 +/- 40; 37 mo, CON 155 +/- 14, IM 152 +/- 20) and EDL (31 mo, CON 227 +/- 13, IM 139 +/- 17; 37 mo, CON 117 +/- 16, IM 108 +/- 4). Immobilization-related differences in muscle mass (mg) were smaller in 37 mo rats compared to 31 mo animals for SOL (31 mo, 206 +/- 14 vs 129 +/- 8, 37 mo, 148 +/- 5 vs 114 +/- 2, age x treatment p < 0.06) and PLA (31 mo, 409 +/- 14 vs 257 +/- 22, 37 mo, 234 +/- 17 vs 181 +/- 18, age x treatment p < 0.05), but immobilization-related muscle mass differences were similar in both age groups for EDL (31 mo, 178 +/- 7 vs 134 +/- 9; 37 mo, 157 +/- 10 vs 112 +/- 7). There were no immobilization-related changes in fiber type distribution in any of the three muscles studied in either age group. The results suggest that disuse-related change is diminished when superimposed on muscles that have already undergone marked age-related decline.

Contractile function of single muscle fibers after hindlimb unweighting in aged rats

This investigation determined how muscle atrophy produced by hindlimb unweighting (HU) alters the contractile function of single muscle fibers from older animals (30 mo). After 1 wk of HU, small bundles of fibers were isolated from the soleus muscles and the deep region of the lateral head of the gastrocnemius muscles. Single glycerinated fibers were suspended between a motor lever and force transducer, functional properties were studied, and the myosin heavy chain (MHC) composition was determined electrophoretically. After HU, the diameter of type I MHC fibers of the soleus declined (88 +/- 2 vs. 80 +/- 4 microns) and reductions were observed in peak active force (47 +/- 3 vs. 28 +/- 3 mg) and peak specific tension (Po; 80 +/- 5 vs. 56 +/- 5 kN/m2). The maximal unloaded shortening velocity increased. The type I MHC fibers from the gastrocnemius showed reductions in diameter (14%), peak active force (41%), and Po (24%), whereas the type IIa MHC fibers showed reductions in peak active force and Po. Thus 1 wk of inactivity has a significant effect on the force-generating capacity of single skeletal muscle fibers from older animals in a fiber type-specific manner (type I MHC > type IIa MHC > type I-IIa MHC). The decline in the functional properties of single skeletal muscle fibers in the older animals appears to be more pronounced than what has been reported in younger animal populations.

Aging and protein metabolism

During aging, there are qualitative and quantitative modifications of proteins in various tissues. In muscle, myofibrillar and mitochondrial proteins are affected, resulting in a loss of strength and, to a lesser degree, endurance. Mechanisms of sarcopenia remain not well known and probably involve loss of motoneurons, muscle disuse and hormonal alterations. Partial prevention of muscle loss is possible by resistance training. In all tissues, and particularly in the brain, oxidative changes in proteins are likely to alter various functions of proteins.