High-intensity flywheel exercise and recovery of atrophy after 90 days bed--rest.

AIMS: To investigate differential muscle atrophy during bed-rest, the impact of a high-intensity concentric-eccentric (flywheel) resistance exercise countermeasure and muscle recovery after bed-rest.
METHODS: Twenty-five healthy male subjects underwent 90 dayshead-down tilt bed-rest. Volume of individual lower-limb muscles was measured via MRI before, twice during and four times up to 1 year after bed-rest. Subjects were either inactive (n=16) or performed flywheel exercise every third day of bed-rest (n=9). Functional performance was assessed via countermovement jump.
RESULTS: On 'intent-to-treat' analysis, flywheel prevented atrophy in the vasti (p<0.001) and reduced atrophy in the hip adductor/extensor adductor magnus (p=0.001) and ankle dorsiflexors/toe flexors (soleus (p<0.001), gastrocnemius medialis (p<0.001), gastrocnemius lateralis (p=0.02), and tibialis posterior with flexor digitorum longus (p=0.04)). Flywheel exercise was not effective for the hamstrings, gracilis, sartorius, peroneals and anterior tibial muscles. Muscle atrophy in vasti, soleus, gastrocnemius medialis, gastrocnemius lateralis and adductor magnus correlated with losses in countermovement jump performance. Muscle volume recovered within 90 days after bed-rest, however long-term after bed-rest, the inactive subjects only showed significantly increased muscle volume versus prebed-rest in a number of muscles including soleus (+4.3%), gastrocnemius medialis (+3.9%) and semimembranosus (+4.3%). This was not associated with greater countermovement jump performance.
CONCLUSION: The exercise countermeasure was effective in preventing or reducing atrophy in the vasti, adductor magnus and ankle dorsiflexors/toe flexors but not the hamstrings, medial thigh muscles or peroneals and dorsiflexor muscles. TRIAL REGISTRATION NUMBER: NCT00311571; results.

In disuse, muscle atrophy occurs the fastest in the muscles of the lower-leg (especially soleus and gastrocnemius medialis) followed by those of the thigh (vasti, biceps femoris long head) and hip (quadratus femoris).

In ninety days of strict disuse, a fly-wheel exercise countermeasure reduced atrophy in the monoarticular knee, hip and ankle extensors, but did not impact the hamstrings or medial thigh muscles.

In the months after bed-rest, an overshoot of muscle volume recovery was observed in some muscles in the inactive control subjects with greater muscle size than before bed-rest.

Introduction

Optimising countermeasures against musculoskeletal deterioration is a priority for space agencies around the world. With a long-term view to missions to Mars or a moon base, it is important to maintain the musculoskeletal system to enable completion of mission tasks in the hypogravitational fields on Mars or moon, and also to safeguard the return to the Earth’s 1 g environment. Prolonged bed-rest is a methodology used to model the effects of spaceflight on the human body.1 Most of the musculoskeletal deterioration occurs in the lower quadrant of the body.

The literature to date2 points to the idea that muscle-specific higher-load resistance exercise appears to be more effective in maintaining muscle mass during prolonged bed-rest, with aerobic and/or low load type exercise being less effective. In microgravity, typical Earth-based implementations of resistance exercise are difficult. One approach to exercising in a gravity-independent manner is with the flywheel exercise device.3 During exercise with the flywheel device, resistance is determined by the effort applied to the device by the person during the concentric phase of movement. This energy is stored within the flywheels of the device and then returned as resistance during the eccentric phase. In this way, exercise is not dependent on force generation by, for example, a weight and pulley system. Flywheel exercise has been shown to be capable of generating greater eccentric muscle activation than with a standard gym weight system4 and feasible for implementation in a space station simulation.5 In another model of unloading, unilateral lower-limb suspension, flywheel exercise of the knee extensors was shown to prevent knee extensor, but not plantarflexor, muscle atrophy6 and in an 84 days bed-rest study, it countered some of the metabolic changes in the vastus lateralis muscle.7 With the implementation of leg press and calf press type exercises on the flywheel device, our primary hypothesis was that flywheel exercise will reduce atrophy in hip, knee and calf extensor muscles in microgravity simulation (prolonged bed-rest).

Prolonged bed-rest is also a model of clinical disuse8 and can be informative clinically on which musculature is most affected and hence how to target rehabilitation programmes. While a series of works have examined muscle atrophy in the lower limb in disuse,9–17 yet less is known about atrophy of the deep muscles of the hip and the lower leg. A secondary aim of the current study was to examine which muscles of the lower limb atrophy the most. Furthermore, the recovery of the human body after strict disuse has not been well studied. This is important for estimating time windows of increased injury risk and designing rehabilitation programs. Our tertiary aim was to examine the time course of muscle atrophy after bed-rest and our tertiary hypothesis was that muscle atrophy during disuse will return to prebed-rest levels in the months after bed-rest.

Methods

Study design, participants and study conduct

Twenty-five healthy male subjects underwent 90 days of 6° head-down tilt bed-rest (HDT) as part of the ‘Long Term Bed Rest’ (LTBR) Study at MEDES in Toulouse, France. The LTBR Study was supported by the European, French and Japanese space agencies (ESA, CNES and NASDA). The LTBR Study was approved by the Toulouse I ethics committee (CCPPRB Toulouse I) of the Rangueil University Hospital as well as the ethical committee of the Free University of Berlin. All subjects gave their informed written consent. Subjects were randomised to either a group performing high-intensity eccentric-concentric resistance exercise on the ‘fly-wheel’ exercise device (flywheel group; n=9; mean(SD) age, height and weight: 31.0 (5.5) years, 1.75 (0.05) m and 70.9 (5.4) kg) or a group that performed no exercise (inactive group; n=16; 32.5 (3.4) years, 1.74 (0.04) m, 70.3 (6.1) kg). Diet was strictly monitored and controlled during the in-house periods. Meals were prepared by the hospital kitchen to achieve energy intake with 30% fat, 15% protein and 55% carbohydrate and this was supervised by a dietician. Data on subjects’ physical activity levels showed that 90 days after bed-rest, subjects’ total physical activity scores were significantly less than before bed-rest.18

Countermeasure exercise

The flywheel exercise programme was designed to target muscle and bone in the lower limbs. The exercise device was designed to be gravity-independent. During the concentric contraction phase, the energy applied to the foot plate by the subject was transferred to the flywheels via a strap which was wound around the flywheels. Then, during the eccentric phase, the rotating flywheels provided resistance. Repetitions were performed as one continuous movement cycle, that is, movement was not ceased between each repetition. Prior to bed-rest all subjects performed two familiarisation sessions with the training apparatus on 2 days separated by 4–6 days. In the first session, subjects practised the manoeuvres on the flywheel device at low to moderate effort intensities and in the second session, subjects were progressed to putting in maximum effort. During bed-rest, the flywheel group performed supine leg press exercises (4 sets of 7 repetitions, 2 min between sets; targeting the hip and knee extensor groups) with then 5 min rest and then calf-raise exercises (4 sets of 14 repetitions, 2 min between sets; targeting plantar flexors) every third day from the fifth day of bed-rest onwards. At the start of each set of exercises, two submaximal manoeuvres of the action (ie, leg press or calf-raise) were performed and these were immediately followed by the prescribed number of eccentric-concentric repetitions at maximum contraction. The subject was encouraged to put maximum effort into each concentric-eccentric loading cycle. After maximal concentric contraction at the initiation of the movement, the subject was instructed to start eccentric contraction (deceleration) once half of the range of motion was passed with then maximal effort into an eccentric contraction towards the end of the range of motion. Electrogoniometers positioned at the knee and ankle provided instantaneous feedback on joint position via a screen positioned in the subject's field of view.

Magnetic resonance imaging

A 1.0T Siemens Somatom Impact (Erlangen, Germany) scanner was used to conduct MRI before bed-rest (Baseline), on day 27 (HDT27) and day 89 (HDT89) of bed-rest, and then 13 days (R+13), 90 days (R+90), 180 days (R+180) and 360 days (R+360) after bed-rest during the recovery phase. Both lower limbs, starting at the hip joint and extending to the feet, were scanned (see online supplementary figure 1). Images were then stored for offline analysis. To blind the operator (DLB) to group and study date, each data set was coded with a random number (obtained from www.random.org). The operator used ImageJ (http://rsb.info.nih.gov/ij/) to measure the area of muscles of the lower limb in every image on the right side of the body (see online supplementary figure 1). For the quadratus femoris and obturator internus muscles, based on our prior data19 it was deemed necessary to measure both left and right sides with the results averaged prior to further analysis.

Countermovement jump

For the comparison of changes in countermovement jump performance to muscle atrophy we used data from previously published work20 where detailed methodology of the countermovement jump test was reported. For the purpose of the correlation analyses, only data on percentage change between baseline and first testing session after bed-rest (day 3 after bed-rest; n=25) and the last testing session in the recovery phase (180 days postbed-rest; n=24) were used. We examined peak jump power; similar results are seen when assessing peak jump height or acceleration. The reproducibility of countermovement jump power in adult and elderly subjects is excellent21 22 with data from our own laboratory23 on 24 men aged 20–45 years tested 4 days apart showing a between-day correlation of 0.93 for countermovement jump power. Percentage change in peak jump power versus before bed-rest was used in correlation analyses.

Statistical analyses

Analysis was done on an ‘intent-to-treat’ (ITT) approach. For the primary analysis, data were converted to fractional change in muscle volume and compared with the prebed-rest value. To examine whether the rates of atrophy differed between groups, non-linear mixed-effects modelling was used to calculate exponential decay rates per week of bed-rest (ek*weeks; where k is the decay rate coefficient and weeks is the week of bed-rest). A factor of ‘group’, with subsequent analysis of variance (ANOVA), was examined to determine whether rate of muscle atrophy differed significantly between groups. To examine the recovery of the musculature after bed-rest, the data on whole muscle volume were used. A ‘study-date’ effect with a priori contrasts comparing each time point to baseline was evaluated. Linear mixed-effects models were implemented. For correlation analyses, Pearson’s correlation coefficient was calculated between percentage change in muscle volume and percentage change in countermovement jump power. An α level of 0.05 was taken for statistical significance. To guard against false positives, all p values were adjusted by the false discovery rate method. The ‘R’ statistical environment (V.3.0.2, www.r-project.org) was used for all analyses.

Results

One flywheel subject ceased the training protocol after 7 weeks bed-rest due to a previously unreported knee injury, but he completed the bed-rest study phase. This subject was treated as a flywheel subject in the ITT analysis. Data from one inactive subject were lost on HDT29. Two inactive subjects did not attend on R+90 and one of these also did not attend scanning on R+180. One flywheel subject did not return for the final scanning session on R+360.

Effects in the inactive group

In the inactive subjects, the soleus and gastrocnemius medialis showed the fastest rates of muscle atrophy (figure 1) both losing 28% of their volume by end of bed-rest (table 1). This was followed by the remaining muscles of the lower leg (with the exception of the anterior tibial muscles), vasti, biceps femoris long head and semimembranosus (figure 1). The other members of the hamstrings, semitendinosus and biceps femoris short head, while atrophying, did not show as rapid atrophy of other members of the hamstrings. Of the muscles localised at the hip joint, quadratus femoris atrophied the fastest and of the medial thigh muscles, the greatest atrophy was seen in adductor magnus.

Figure 1

Atrophy and impact of exercise on muscle atrophy values are mean (SD) time constants (‘k’) of exponential decay of muscle volume per week of bed-rest. *: p<0.05; †:p<0.01; ‡: p<0.001 and indicate significance of difference of time constant to zero (ie, whether atrophy occurred). p Values above the columns show where the difference between groups was significant. All p values are adjusted for false positives via the ‘false discovery rate’ method. 

Table 1

Muscle volume changes in the lower leg, anterior thigh

Group	Baseline	Bed-rest		Recovery
		28 days (%)	89 days (%)	13 days (%)	90 days (%)	180 days (%)	360d (%)
Anterior tibial muscles
Inactive	252.1 (24.9)	−7.0 (4.0)‡	−13.6 (4.9)‡	−5.1 (3.9)‡	−0.3 (3.9)	0.1 (3.9)	0.4 (4.7)
Flywheel	246.9 (11.8)	−5.1 (4.0)‡	−11.2 (4.0)‡	−3.0 (4.6)	0.5 (4.5)	1.2 (4.2)	0.4 (4.5)
Flexor digitorum with tibialis posterior
Inactive	136.6 (25.3)	−11.4 (7.4)‡	−19.0 (10.4)‡	−7.3 (6.7)‡	1.8 (5.4)	0.5 (4.2)	0.9 (4.0)
Flywheel	133.5 (28.5)	−7.1 (6.4)†	−13.0 (7.9)‡	−6.0 (7.2)*	−1.2 (5.0)	−0.5 (4.6)	1.0 (5.1)
Flexor hallucis longus
Inactive	80.2 (13.4)	−9.5 (7.0)‡	−19.6 (8.9)‡	−14.7 (9.8)‡	0.0 (6.5)	1.8 (7.5)	2.1 (9.0)
Flywheel	78.3 (8.7)	−8.8 (9.8)*	−15.5 (8.4)‡	−10.1 (8.4)‡	−4.8 (7.1)	−2.9 (8.6)	−2.2 (9.3)
Lateral gastrocnemius
Inactive	132.6 (20.7)	−10.7 (10.3)‡	−23.3 (13.0)‡	−11.8 (11.6)‡	2.6 (9.6)	1.1 (10.1)	3.0 (10.5)
Flywheel	140.2 (15.2)	−4.0 (8.4))	−12.8 (10.7)‡	−7.5 (9.8)*	2.3 (8.4)	−0.8 (7.0)	−1.4 (8.2)
Medial gastrocnemius
Inactive	222.1 (40.6)	−15.6 (7.6)‡	−28.0 (12.3)‡	−7.6 (8.4)‡	2.7 (6.4)	2.5 (4.8)	3.9 (6.0)*
Flywheel	235.2 (30.6)	−5.6 (5.2)†	−13.3 (7.3)‡	−5.1 (6.6)*	1.7 (4.0)	0.9 (3.2)	0.0 (3.0)
Peroneals
Inactive	136.9 (29.0)	−12.1 (6.4)‡	−22.5 (11.8)‡	−12.8 (7.7)‡	−0.1 (4.6)	0.7 (4.2)	1.6 (4.9)
Flywheel	140.9 (29.2)	−10.3 (4.7)‡	−18.4 (6.3)‡	−9.0 (6.0)‡	0.1 (6.7)	−2.0 (8.1)	−0.5 (7.9)
Soleus
Inactive	449.4 (61.0)	−15.6 (6.1)‡	−28.6 (8.5)‡	−5.5 (6.1)‡	2.4 (4.6)	3.9 (3.2)‡	4.3 (5.0)†
Fly-wheel	496.4 (64.5)	−10.6 (3.0)‡	−19.9 (4.5)‡	−5.5 (4.7)†	1.3 (3.8)	0.7 (4.5)	1.2 (3.5)
Vasti
Inactive	1688.8 (203.7)	−12.1 (6.0)‡	−20.3 (7.3)‡	−10.1 (6.7)‡	0.9 (7.5)	1.5 (6.8)	3.1 (8.5)
Flywheel	1670.2 (115.0)	−1.5 (4.3)	−3.8 (5.8)	−0.5 (6.1)	1.6 (2.1)	1.0 (3.2)	−0.5 (2.4)
Rectus femoris
Inactive	259.3 (33.0)	−3.6 (5.3)*	−7.9 (6.2)‡	−4.2 (6.2)*	−0.8 (6.0)	−0.1 (5.4)	1.0 (6.9)
Flywheel	285.2 (37.3)	−0.2 (3.5)	−2.7 (3.7)	0.0 (3.9)	0.0 (3.8)	2.8 (10.4)	0.7 (5.4)

At baseline, values are mean (SD) muscle volume in cm³. During and after bed-rest, values are mean (SD) percentage change in muscle volume compared with baseline. *: p<0.05; †:p<0.01; ‡: p<0.001 and indicate significance of difference to baseline. All p values are adjusted for false positives via the ‘false discovery rate’ method.

Impact of flywheel exercise

ANOVA showed that flywheel exercise significantly reduced the rate of atrophy of the posterior calf muscles soleus (p<0.001; figure 1), gastrocnemius medialis (p<0.001), gastrocnemius lateralis (p=0.02) and tibialis posterior with flexor digitorum longus (p=0.04). At the thigh, flywheel exercise reduced atrophy of the vasti (p<0.001) and adductor magnus muscles (p<0.001). Lower gluteus maximus and rectus femoris atrophied significantly in the inactive group and not in the flywheel group, but the differences between the groups were not statistically significant on ANOVA (p>0.07). Similarly, gracilis atrophied significantly in the flywheel group but not in the inactive group, however the difference between groups in the rates of atrophy was not significant (p=0.28). The flywheel exercise had no impact on atrophy of the hamstrings or other muscles of the thigh and hip.

Long-term recovery of muscle volume after 90 days bed-rest study

Of the muscles that atrophied during bed-rest, significant atrophy was still present 13 days after bed-rest (tables 1 and 2). By 90 days after 90 days bed-rest, all muscles returned to their prebed-rest volumes. In the inactive subjects only, some muscles showed hypertrophy in the months after bed-rest. Specifically, at the hip, adductor brevis was increased in volume on 180 days (+6.0%, p=0.008) and 360 days (+4.9%, p=0.040) of recovery and obturator externus also showed greater volume in recovery (90 days: +8.6%, p=0.004; 180 days: +7.6%, p=0.007; 360 days: +6.4%, p=0.009). In the thigh, semimembranosus (180 days: +2.7%, p=0.019; 360 days: +4.3%, p=0.020) and sartorius (180 days: 3.8%, p=0.023; 360 days: +5.0%, p=0.010) were hypertrophied in the long term after bed-rest. In the calf, soleus (180 days: +3.9%, p<0.001; 360 days: +4.3%, p=0.004) and medial gastrocnemius (360 days: +3.9%, p=0.040) also showed increased volume late in recovery. This effect was not seen in the flywheel group (table 1,2; figure 2).

Figure 2

Increases muscle volume 1 year after bed-rest in inactive subjects only: muscle volume change at end bed-rest versus muscle volume 1 year after bed-rest. Values are mean percentage difference to baseline at end of bed-rest (x-axis) versus 360 days after bed-rest (y-axis). For the inactive group only, the error bars indicate the unadjusted 95% CI of the mean percentage change 360 days after bed-rest. The muscles where the unadjusted 95% CI 360 days after bed-rest does not cross zero are labelled. Note that the effect (A) was isolated to the inactive group and (B) did not appear to be related to the extent of muscle loss during bed-rest. 

Relationship of muscle atrophy to peak lower limb performance

At the end of bed-rest significant associations were seen between loss of muscle volume in the vasti, soleus, gastrocnemius medialis, gastrocnemius lateralis and adductor magnus and losses of countermovement jump performance (table 3). There were no positive correlations between muscle volume differences versus baseline and countermovement jump performance 180 days after bed-rest.

Table 3

Relationship between muscle atrophy and countermovement jump performance at the end of bed-rest and after 180 days of recovery

Muscle	End of bed-rest	180 days after bed-rest
Anterior tibial muscles	0.47a	−0.08
Flexor digitorum with tibialis posterior	0.53a	−0.38
Flexor hallucis longus	0.50a	−0.54b,*
Lateral gastrocnemius	0.64b,*	−0.01
Medial gastrocnemius	0.72c,**	−0.03
Peroneals	0.22	−0.16
Soleus	0.71c,**	0.15
Vasti	0.77c,***	−0.09
Rectus femoris	0.33	−0.42a
Adductor brevis	−0.04	−0.17
Adductor longus	0.28	−0.38
Adductor magnus	0.57b,*	0.14
Gracilis	−0.04	0.23
Sartorius	0.00	−0.38
Lower glut max	−0.05	0.23
Biceps femoris long head	0.03	−0.13
Biceps femoris short head	−0.22	−0.39
Semimembranosus	−0.10	−0.10
Semitendinosus	0.32	−0.27
Popliteus	0.29	0.17
Obturator externus	−0.06	−0.35
Obturator internus	−0.07	−0.02
Quadratus femoris	0.26	−0.27
Iliopsoas	0.02	−0.23

Values are Pearson’s correlation coefficient. *: p<0.05; **:p<0.01; ***: p<0.001 and indicate significance of correlation with p value adjusted for false positives via the ‘false discovery rate’ method. a: p<0.05; b: p<0.01; c: p<0.001 indicate significance of correlation with raw p values. Percentage change in muscle volume versus baseline was correlated with percentage change in countermovement jump power versus baseline. A positive (or negative) correlation implies greater (or less) muscle atrophy is associated with greater (or less) loss of countermovement jump power. Strong positive correlations between calf and thigh muscle atrophy were seen at the end of bed-rest, implying a dependence of jump performance loss on atrophy in these muscles. Since no positive correlations were seen 180 days after bed-rest, this implies that increased muscle volume seen in the inactive control group long-term after bed-rest (figure 2; tables 1 and 2) was not associated with functional benefits.

Discussion

The current study permits some important insights into countermeasure exercise prescription. The flywheel exercise countermeasure was effective, compared with control, in preventing or reducing atrophy in the monoarticular knee extensors (vasti), mono articular hip extensors (adductor magnus) and ankle dorsiflexors/toe flexors. The actual exercise time was 7–9 min ‘time under tension’ with 20 min total training time including rest breaks. Importantly, these findings underscore19 that a short duration, high load, resistance exercise programme can be very effective in reducing muscle atrophy in bed-rest. Previous studies that have implemented low load, non-specific muscle exercises, were unsuccessful at reducing muscle atrophy: whole body vibration in standing in a squat position without exercise did not impact lower limb muscle atrophy,17 nor did whole body vibration implemented in supine position prevent spinal muscle atrophy.24 Furthermore, exercise protocols involving aerobic-based cycling25 and lower body negative pressure26 were largely ineffective at reducing lower limb muscle atrophy. An ergometer-based cycling exercise27 can be effective in reducing lower limb suspension induced muscle atrophy when higher intensities, and hence need for higher force muscle contraction, are implemented.

The countermeasure programme did not have an impact on atrophy in the hamstrings, which are important for ambulation. Of the hamstrings, semimembranosus and biceps femoris long head are primarily hip extensors28 with semitendinosus playing more of a role in control of knee flexion.29 30 In contrast, another research group11 reported complete prevention of hamstring muscle atrophy due to their resistance exercise protocol in 20 days bed-rest when the leg press exercise was performed up to 110° of hip flexion. This underscores the need for greater specificity of exercise prescription for the hamstrings.

Maintenance of the calf musculature in disuse bed-rest via exercise has, in a number of studies, proven difficult. In the current study the atrophy of the calf muscles was significantly reduced, but muscle atrophy still occurred: 20% of soleus muscle volume was lost in the flywheel group compared with 29% loss in the inactive group at the end of bed-rest. Prior work does suggest that higher volumes of calf muscle exercise do appear to have a greater protective effect: when resistive vibration exercise including calf press exercises was performed three times a week,19 15% loss in soleus muscle volume after 56 days of bed-rest was observed, compared with 7% loss in soleus muscle volume after 56 days of bed-rest in another study2 where resistive vibration exercise was performed 11 times a week. However, for the calf muscles, there is evidence in the literature31 that attaining hypertrophy in ambulant exercise studies is more difficult with standard hypertrophy protocols than it is for the knee extensors. This is in line with the notion that muscles that are typically load-bearing in daily life are more difficult to hypertrophy than non-load-bearing muscles.32 Investigation of other exercise modes, such as treadmill running or jumping exercises, is needed to improve exercise prescription for preventing disuse atrophy of the calf musculature.

Recovery of muscle volume occurred in all muscles by 90 days after prolonged bed-rest. We observed, however, increase of muscle volume over and beyond the prebed-rest baseline volume in the inactive subjects in the long term after bed-rest. Importantly, this effect was observed in major muscle groups and not just in minor and/or small muscle groups. The time subjects spent lying supine prior to MR-scanning was strictly controlled in this study. Also, this effect was seen only in the inactive subjects, not in the flywheel exercise subjects (figure 2). We can therefore rule out a systematic, confounding, effect particular to the current study. In further support of our interpretation, peripheral quantitative CT examinations were performed in the same collective33 and these investigations also showed significant increases in lower leg muscle area 90 days and beyond after bed-rest. After another 56 days bed-rest study performed at a different facility,34 the authors observed a statistical trend towards an overshoot of calf musculature area recovery after bed-rest, again specific to the inactive group, but not the exercise group, of that study. While we cannot be certain that this muscle hypertrophy involved true muscle fibre hypertrophy, we did not see any association between these muscle volume increases in the long term after bed-rest with improvements in countermovement jump performance.

Finally, of the muscles active in the hip joint, the quadratus femoris showed the fastest rate and extent, of atrophy. When we observed this in a prior bed-rest study,35 we were not sure if this was a chance finding. In a recent cadaver study, one group concluded that quadratus femoris is a primary extensor of the hip when it is in a flexed position.36 In line with this, recent fine-wire electromyography findings37 found that quadratus femoris shows a peak of activity in walking and running during the first part of stance (ie, when the flexed hip begins to bear load) and also in late swing phase in running, presumably to decelerate the flexing hip during late swing. Overall, the recent finding shows that quadratus femoris is important for load-bearing and control of extension force at the hip joint, particularly in a flexed position. This helps to understand why quadratus femoris in particular is affected in disuse.

It is important to mention limitations of the current work. As is typical of bed-rest studies in Europe, only one gender was included in the study in an effort to reduce intersubject variability. As such, we cannot be certain that our results are applicable to female bed-rest participants. The number of subjects was limited due to logistical and financial restraints. Due to the limited number of subjects, some non-significant results for the effect of the exercise protocol may represent false negatives. For some smaller muscles, such as adductor brevis and obturator externus, reproducibility of the measurements is not as high as for larger muscle groups and non-significant findings for these muscles might be false negatives. Even though the current study provides important evidence for exercise prescription in astronauts, application of the current protocols to spaceflight could not occur on a 1:1 basis.

In conclusion, the current study investigated the impact of 90 days bed-rest on atrophy of the muscles of the lower limb, the impact of a flywheel exercise countermeasure, and the recovery of the musculature after bed-rest. The greatest rates and extent of atrophy was seen in the soleus and gastrocnemius medialis, followed by the gastrocnemius lateralis, peroneals, vasti, biceps femoris long head, other posterior calf musculature, semimembranosus, anterior tibial muscles, adductor magnus and quadratus femoris. The flywheel exercise countermeasure was effective, compared with control, in preventing or reducing atrophy in the vasti, adductor magnus and ankle dorsiflexors/toe flexors. Thus, a short-duration high-intensity resistance exercise programme performed every third day can be effective in preventing muscle atrophy in disuse. The countermeasure was, however, not effective in preventing atrophy of the hamstrings, medial thigh muscles, ankle evertors and dorsiflexors. Finally, in the long term after bed-rest we saw that inactive subjects exhibited an overshoot of muscle volume recovery in some muscle groups compared with before bed-rest.

Table 2

Muscle volume changes in the medial thigh, posterior thigh and hip

Group	Baseline	Bed-rest		Recovery
		28d (%)	89d (%)	13d (%)	90d (%)	180d (%)	360d (%)
Adductor brevis
Inactive	164.1 (24.1)	−1.0 (6.0)	−2.5 (7.3)	−0.8 (8.5)	5.6 (8.9)	6.0 (7.1)†	4.9 (7.5)*
Flywheel	186.7 (20.2)	−8.2 (7.6)†	−4.8 (6.8)	−0.4 (6.0)	−0.6 (5.2)	0.5 (6.5)	−2.4 (7.1)
Adductor longus
Inactive	159.0 (32.5)	−0.7 (11.3)	−7.1 (12.6)*	−0.9 (14.0)	2.9 (9.3)	4.5 (10.7)	5.8 (12.7)
Flywheel	175.8 (20.7)	−1.4 (7.8)	−2.9 (9.1)	−0.9 (9.7)	3.2 (11.1)	−0.6 (11.5)	−1.3 (9.9)
Adductor magnus
Inactive	585.8 (78.2)	−7.8 (5.4)‡	−13.0 (6.2)‡	−4.7 (4.9)‡	1.6 (5.6)	1.4 (5.2)	3.0 (5.6)
Flywheel	586.6 (62.5)	−3.0 (4.1)	−6.1 (3.8)‡	−1.2 (3.9)	2.2 (2.3)*	1.3 (4.3)	−0.2 (3.8)
Gracilis
Inactive	101.6 (20.3)	0.2 (5.4)	−2.6 (5.8)	1.0 (7.0)	3.5 (6.4)	3.3 (5.9)	6.2 (9.9)
Flywheel	115.2 (27.1)	−2.5 (5.0)	−6.8 (8.5)*	1.6 (7.4)	3.9 (6.8)	2.5 (6.1)	0.2 (5.5)
Sartorius
Inactive	162.3 (24.2)	−5.9 (4.9)‡	−9.4 (5.9)‡	−3.8 (5.8)*	2.3 (6.5)	3.8 (5.3)*	5.0 (6.3)*
Flywheel	172.8 (11.4)	−4.3 (3.3)‡	−9.1 (4.9)‡	−1.7 (5.4)	0.8 (4.0)	4.9 (7.0)	0.5 (6.7)
Biceps femoris long head
Inactive	190.2 (24.0)	−10.5 (6.4)‡	−20.0 (7.8)‡	−10.5 (7.0)‡	2.7 (6.9)	1.7 (4.9)	2.2 (6.0)
Flywheel	234.1 (31.3)	−11.8 (3.8)‡	−21.1 (5.2)‡	−11.7 (5.9)‡	0.9 (6.6)	0.9 (7.2)	0.5 (7.3)
Biceps femoris short head
Inactive	97.4 (25.0)	−2.8 (7.5)	−6.3 (8.6)†	−0.2 (7.1)	4.5 (8.5)	3.0 (7.8)	3.1 (8.4)
Flywheel	104.7 (14.9)	−4.4 (3.1)‡	−6.8 (7.6)*	−0.1 (5.9)	−1.1 (5.8)	−0.7 (3.9)	−1.5 (5.1)
Semimembranosus
Inactive	252.6 (43.9)	−10.4 (4.1)‡	−18.0 (6.3)‡	−8.4 (6.5)‡	2.4 (4.5)	2.7 (3.7)*	4.3 (6.0)*
Flywheel	300.5 (50.0)	−10.7 (6.8)‡	−18.0 (9.0)‡	−9.3 (7.5)‡	1.2 (6.2)	−0.6 (6.5)	1.4 (4.7)
Semitendinosus
Inactive	182.3 (19.3)	−4.1 (5.6)*	−7.3 (6.9)‡	−3.6 (6.0)*	2.2 (5.8)	2.2 (6.4)	2.0 (7.6)
Flywheel	189.5 (11.6)	−6.5 (4.5)‡	−10.6 (3.2)‡	−7.1 (4.0)‡	0.7 (6.3)	−1.1 (5.4)	−2.7 (6.5)
Popliteus
Inactive	21.0 (4.3)	−1.6 (6.3)	−5.1 (10.2)	−0.4 (8.2)	2.4 (7.4)	−0.7 (6.2)	1.8 (8.3)
Flywheel	22.1 (3.7)	−2.6 (7.5)	−4.0 (7.8)	2.6 (6.0)	−3.4 (8.5)	0.3 (7.5)	−3.6 (5.9)
Lower gluteus maximus
Inactive	535.6 (96.6)	−4.1 (7.4)	−6.9 (8.5)†	−4.5 (6.4)*	1.6 (7.2)	0.8 (8.1)	5.5 (10.9)
Flywheel	590.4 (80.7)	−0.4 (6.1)	−0.5 (6.6)	−0.3 (7.1)	−2.4 (6.6)	−0.8 (5.5)	−3.5 (7.4)
Obturator externus
Inactive	72.6 (10.2)	3.5 (6.6)	1.9 (7.8)	3.5 (8.3)	8.6 (8.9)†	7.6 (8.7)†	6.4 (7.8)†
Flywheel	73.8 (8.2)	−2.8 (7.2)	−0.7 (9.6)	3.9 (5.7)	2.4 (8.4)	0.2 (3.9)	3.6 (8.0)
Obturator internus
Inactive	57.8 (8.5)	5.6 (7.8)*	3.6 (9.4)	3.3 (9.2)	3.1 (9.0)	2.2 (8.9)	−1.0 (9.4)
Flywheel	60.4 (7.1)	6.1 (6.6)*	9.4 (5.0)‡	9.2 (6.8)†	3.0 (6.2)	0.2 (8.6)	0.3 (7.8)
Quadratus femoris
Inactive	36.1 (9.5)	−8.8 (13.3)*	−13.5 (12.2)‡	−7.8 (11.5)*	−4.5 (8.2)	3.9 (9.5)	4.7 (10.5)
Flywheel	40.0 (6.7)	−7.7 (10.0)*	−9.8 (11.0)*	−1.0 (10.3)	2.0 (6.4)	3.7 (8.0)	−2.8 (9.4)
Iliopsoas
Inactive	71.8 (13.1)	−1.0 (11.3)	−5.9 (11.0)	0.5 (9.5)	−1.3 (9.0)	0.4 (10.0)	1.7 (9.7)
Flywheel	74.0 (16.8)	−5.0 (9.3)	−4.3 (9.8)	−2.1 (12.1)	0.8 (11.8)	4.6 (11.1)	−1.7 (10.2)

At baseline, values are mean (SD) muscle volume in cm³. During and after bed-rest, values are mean (SD) percentage change in muscle volume compared with baseline. *: p<0.05; †:p<0.01; ‡: p<0.001 and indicate significance of difference to baseline. All p values are adjusted for false positives via the ‘false discovery rate’ method.