Muscle Atrophy Clinical Trial
Official title:
The Effects of 17β-estradiol on Skeletal Muscle Mass Following Immobilization
The maintenance of skeletal muscle mass and function is critical for healthy aging. Muscle
loss with disuse, termed muscle disuse muscle atrophy, leads to impaired functional capacity,
the onset of insulin resistance, as well as a heightened risk for morbidity and mortality.
With advancing age there is a chronic wasting of muscle. This is especially true in women,
where rapid rates of decline in muscle mass and greater anabolic resistance are experienced
around the time of menopause, despite higher protein synthesis rates. As women have a longer
life expectancy, they are particularly venerable to age-related frailty and morbidity.
Skeletal muscle protein turnover serves to maintain the optimal function of proteins and also
provides plasticity of the tissue during altered demands such as during increased loading or
unloading of the muscle. Reduced periods of physical activity also have a similar, albeit
milder, impact on skeletal muscle and most, people will likely experience multiple bouts of
skeletal muscle disuse during their lifetime from which some, particularly older adult women,
will fail to fully recover. Thus, muscle disuse atrophy is a significant and continuing
problem as reclamation of lost muscle mass, strength/function, and potentially metabolic
health (particularly insulin-induced glucose disposal), following disuse is oftentimes
incomplete and may be further exacerbated after menopause.
Previous evidence has demonstrated that in the loss of muscle mass is less pronounced in
post-menopausal women when receiving hormone replacement therapy. Skeletal muscle has
estrogen-β-receptors on the cell membrane, in the cytoplasm and on the nuclear membrane, and
therefore a direct mechanistic link between low estrogen levels and a decrease MPS.
Interestingly, despite higher rates of protein synthesis, older women still lose muscle mass
with advancing age. It has been suggested that the negative muscle protein balance is due to
an enhanced rate of MPB. Insulin is a potent inhibitor of MPB and estrogen has been shown to
enhance insulin sensitivity in skeletal muscle. However, to our knowledge, no study has
examined the efficacy of estrogen supplementation to attenuate the losses of skeletal muscle
mass and function during a period of disuse. The findings of this investigation may yield
critical data for those who wish to combat skeletal muscle disuse atrophy, particularly after
menopause.
Design and detailed description of methodology This is a parallel-group randomized controlled
trial, blinded to the 17β-estradiol (n=10) or placebo (n=10) supplement administered every
day for 10 days. Twelve healthy young men (age: 18-25yrs; BMI: 22-33 kg/m2) will be recruited
to participate in this study. During phone or e-mail conversations we will explain the
purpose and experimental design of the study and address all questions the participants might
have (see telephone and email scripts). Participants will visit the laboratory for a
screening to assess whether they are eligible to participate in this study. During the
screening we will first explain the experimental design and obtain written informed consent.
A medical questionnaire will be completed by the participants to assess their general health
and use of medication. Body height and mass will be measured as baseline characteristics of
the participants. Participants will be requested to fill out a 3-d dietary record to assess
habitual energy and protein intake. Participants will be randomly assigned to the
17β-estradiol (n=10) or placebo (n=10) supplementation group. Randomization will be performed
using a computerized list randomizer (https://www.random.org/lists/), and participants will
be sequentially allocated to a condition according to the randomized list. The experimental
trial is composed of 10 days of 17β-estradiol (Estrace, Acerus Pharmaceuticals Corporation,
Mississauga, ON, Canada or placebo (400 mg/day Polycose, Abbott Laboratories, St. Laurent,
QC, Canada) supplementation, including 3 days of pre-immobilization, and 7 days of single leg
immobilization. Three days prior to immobilization (t=-3 d) a blood sample will be obtained
and muscle strength will be assessed before daily 17β-estradiol or placebo supplementation
will be initiated. Participants will consume 1mg/day for 3-days and 3mg/day for 7-days of
Estrace or 400 mg/day of Polycose for 7-days. The estrogen and placebo bottles are coded to
ensure complete blinding to both researchers and participants. Additional blood samples will
be obtained to assess the compliance of the participants to the supplementation. In addition,
at t=-3 d a saliva sample will be obtained before ingesting 150 mL of deuterium-labeled water
(D2O). Daily saliva sampling will be continued until the end of the experimental trial to
assess precursor pool enrichments. Dietary intake will be controlled for 10-days (including 3
d prior to immobilization and 7 d of immobilization) providing an energy balanced diet
containing 1 weight per day equally distributed over breakfast, lunch, and dinner (15).
Participants will be instructed to refrain from vigorous-intensity physical activity
(running, fast cycling, competitive sports, carrying heavy loads, etc.) and refrain from
alcohol consumption for 3 d prior to and during the 7-day single leg immobilization. Daily
activity will be monitored with a SenseWear Armband, which subjects will be required to wear
from t=-3 d until the end of the experimental trial.
Participants will have one leg immobilized by means of knee bracing
(http://www.breg.com/products/knee-bracing/post-op) thus the contralateral limb will act as
an internal control. The leg to be immobilized will be chosen in a random counterbalanced
manner to result in equal numbers of participants having their weaker or stronger legs being
immobilized. The brace (http://www.breg.com/products/knee-bracing/post-op) will be worn in a
fixed flexion position at 140° (i.e., 40° from full extension) with a plastic band that is
removed to check for pressure points daily and resealed with a custom-modified plastic strap
that is melted to seal the strap, as we have done previously19,20. The reason for this is
that the brace cannot be removed without breaking the plastic seal, but could be broken in
the case of an emergency and the brace removed entirely, if required. Using this model of
disuse we have found the immobilizing brace to be well tolerated, not restrictive, and
importantly it does not occlude for popliteal and/or femoral artery blood flow, and we have
had no cases of edema or venous thrombosis in previous studies. Participants will also be
provided with elastic support bandages to lessen the risk of deep vein thrombosis.
On t=0 d, a blood sample, saliva sample and muscle biopsy will be collected for the
assessment of muscle protein synthesis rates. Muscle strength and volume will be assessed
using a Biodex and ultrasonography respectively. A knee brace will be placed to start the
7-day single leg immobilization phase. The choice of leg for immobilization will be
randomized and balanced for dominance according to maximal isometric strength. At the end of
the immobilization phase (t=7 d), a blood sample will be obtained, muscle biopsies will be
collected from both the immobilized and non-immobilized leg, and muscle volume and strength
will be assessed. After strength is assessed in both legs, a further muscle biopsy will be
taken to assess the effect of 17β-estradiol on muscle response to a single bout of exercise
(Biodex) in both the non-immobilized and immobilized leg 3-hrs after the exercise bout.
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