Posted on 19 Feb 2010 21:57
The effects of age on skeletal muscle and the phosphocreatine energy system.
Creatine supplementation has been found to significantly increase muscle strength and hypertrophy in young adults (= 35 yr) particularly when consumed in conjunction with a resistance training regime. Literature examining the efficacy of creatine supplementation in older adults (55-82 yr) suggests creatine to promote muscle strength and hypertrophy to a greater extent than resistance training alone. The following is a review of literature reporting on the effects of creatine supplementation on intramuscular high energy phosphates, skeletal muscle morphology and quality of life in older adults. Results suggest creatine supplementation to be a safe, inexpensive and effective nutritional intervention, particularly when consumed in conjunction with a resistance training regime, for slowing the rate of muscle wasting that is associated with aging. Physicians should strongly consider advising older adults to supplement with creatine and to begin a resistance training regime in an effort to enhance skeletal muscle strength and hypertrophy, resulting in enhanced quality of life.
Sarcopenia is an age-dependent loss of skeletal muscle mass resulting in reduced strength, limited mobility and increased injury risk. Nearly 50% of older adults (= 60 yr) in the United States have been estimated to be sarcopenic, with approximately 20% classified as functionally disabled. In 2000, direct health care costs of sarcopenia were estimated to be $18.5 billion. Interestingly, a 10% reduction in the prevalence of sarcopenia could save the United States $1.1 billion per year in health care costs. The best treatments for reducing the effects of sarcopenia include resistance training[3,4] and testosterone administration; however testosterone is often widely unavailable and may be associated with adverse effects in older adults.
Conversely, creatine supplementation may prove to be a safe and effective over-the-counter means to diminish age-related declines in muscle mass and strength as research has found creatine supplementation to increase strength and type II muscle fiber diameter independent of exercise. Moreover, creatine supplementation has repeatedly been found to increase performance in younger (= 35 yr) [8-15] adults, particularly when consumed in conjunction with a resistance training regimen. However, studies examining the effects of creatine supplementation in older adults (> 55 yr) have yielded apparently equivocal results [16-26]. This review will report on the effects of creatine supplementation on intramuscular high energy phosphates, skeletal muscle morphology and quality and quantity of life in older adults (> 55 yr). Furthermore, this review will attempt to elucidate why creatine supplementation may be effective in delaying sarcopenia, as well as discuss extraneous factors that may influence the efficacy of creatine supplementation in older adults.
Aging and Skeletal Muscle Adaptations
At the cellular level sarcopenia is best described as a gradual loss of type II muscle fibers with a concurrent increase in intramuscular fat storage. In 1983, Lexell et al. used autopsy analyses to demonstrate that aged men (70-73 yr) had approximately 110,000 less muscle fibers in the midsection of the vastus lateralis than younger men (19-37 yr), yielding a 23% decline in muscle fiber content. Furthermore, 80 yr old men possessed 30% less type II muscle fibers compared to younger counterparts. Results from a different cross-sectional investigation found that roughly 20-30% of lean body mass is lost between the third and eighth decade of life.
With age comes a shift in muscle fiber composition, resulting in a greater percentage of type I fibers which may affect energy metabolism. Since type II fibers are predominantly involved in high force/power, short duration patterns of recruitment; potential alterations in energy-rich compounds could affect the phosphocreatine system and fast glycolysis. Moller et al. were among the first to examine the effects of aging on energy rich compounds and the energy charge potential of the adenylate system. Specifically, Moller et al. found intramuscular phosphocreatine levels to be 5% lower in older (52-79 yr) compared to younger (18-36 yr) adults, while intramuscular creatine levels were found to be 5% higher in older adults. However, the authors found ATP concentrations, the ratio of ATP/ADP and the energy charge potential to be unaffected with age.
A later study in 61-80 yr old males found that cycling on a bicycle ergometer for 30 minutes, three times per week at workloads of 100-200 W to match each individuals maximal working capacity of 150-160 beats per minute, was enough to result in a significant decline in intramuscular creatine levels while significantly increasing the phosphocreatine/total creatine ratio. Taken together these findings suggest exercise can increase intramuscular phosphocreatine levels in older adults, albeit no research has examined the effects of age on ATPase and creatine kinase which are likely responsible for the liberation of energy from ATP and the formation of phosphocreatine, respectively. If ATPase or creatine kinase is significantly reduced in aged populations the phosphocreatine energy system may be unable to perform optimally.
Further support for the ability of exercise to enhance the phosphocreatine energy system was demonstrated in humans by Moller et at and in rats by Bastien et al. . In each study intramuscular phosphocreatine was reduced with age in sedentary subjects. However, when a training program was initiated for a period of six or twelve weeks the phosphocreatine energy system was enhanced. Specifically, Moller et al. found that six weeks of bicycle ergometer training in 61-80 yr old men resulted in a significant decrease in intramuscular creatine concentrations and significant increases in phosphocreatine/total creatine and ATP/ADP ratios.
Why Creatine Supplementation Could Be Effective in Older Adults
It has been demonstrated that a reduction in cross sectional area (CSA) of type II fibers is primarily responsible for the decrease in muscle mass with aging and biopsy studies have found type IIA and type IIB muscle fiber CSA to decrease by 15-25% with age. Creatine supplementation may aid in the retention of type II skeletal muscle fibers with age as research suggests creatine supplementation may be able to promote muscle hypertrophy through a variety of mechanisms including: cell swelling, which may act as a signal to reduce whole-body proteolysis and amino acid oxidation, alter the expression of myogenic transcription factors [15,35-37], increase satellite cell mitotic activity[38,39], and allow for increased exercise volume due to enhanced rates of ATP regeneration as a result of extending the duration of the phosphocreatine energy system[40,41].
Specifically, Sipila et al. reported creatine supplementation increased type II skeletal muscle fiber diameter independent of a training stimulus. Furthermore, Willoughby and Rosene found that 6 g/day creatine supplementation, in conjunction with 12 weeks of resistance training, increased myosin heavy chain (MHC) isoform mRNA and protein expression to a greater extent than training alone in college-aged men, although this study design has not been sufficiently applied to older populations.
Currently the most popular mechanism to explain the efficacy of creatine supplementation is the enhancement of the phosphocreatine energy system, allowing users to maintain a greater work intensity for longer durations of time (i.e., increased total training volume). Research conducted by Moller et al. found phosphocreatine and total adenine nucleotides to be significantly reduced in older compared to younger adults (creatine: 49.00 ± 0.85, 53.25 ± 1.98 mmol/kg dry weight; phosphocreatine: 75.50 ± 0.85, 72.73 ± 1.40 mmol/kg dry weight; total creatine: 124.40 ± 1.25, 126.28 ± 2.36 mmol/kg dry weight; data are reported as younger followed by older adults using means ± standard error); a finding supported by the work of Campbell et al. (creatine: 53.52 ± 1.98, 66.3 ± 4.9 mmol/kg dry weight; phosphocreatine: 72.73 ± 1.40, 43.3 ± 2.8 mmol/kg dry weight; total creatine: 126.28 ± 2.36, 109.6 ± 4.8 mmol/kg dry weight; data are reported as younger followed by older adults using means ± standard error). However, the ATP/ADP ratio was not affected by age and the authors concluded ATP regeneration in older adults should be similar to that experienced in younger adults. Since creatine supplementation has repeatedly been found to enhance intramuscular concentrations of phosphocreatine[43,44], enhance skeletal muscle strength[9,13,14,41,45] and hypertrophy[15,45] in college-aged individuals it is conceivable that older adults should experience comparable results.
Tables 1 and 2 were developed using a meta-analytical approach. Table 1 demonstrates the expected percent increase in resting high energy phosphate levels (total creatine, phosphocreatine, creatine and ATP) following creatine supplementation in younger and older adults. Table 2 identifies statistical differences in resting high energy phosphate concentrations between younger and older adults at rest prior to creatine supplementation. Furthermore, table 2 identifies statistical differences that are likely to exist between younger and older adults following a typical creatine supplementation regime. All referenced interventions supplemented subjects either through a loading phase (i.e., 20 g/d for 5 days) or through a 14-to-24 week supplementation protocol using 5 g/d and classified younger adults being between the ages of 18-36 yr and older adults being between the ages of 52-79 yr. Statistical significance was set at p < 0.05 and significance was determined utilizing separate independent samples t-tests.
In 2000, Tarnopolsky hypothesized that creatine supplementation may provide more pronounced effects in older adults compared to the results typically experienced in younger adults. In support, numerous research studies have reported older adults to have lower intramuscular levels of total creatine (total creatine = creatine + phosphocreatine)[30,47] than younger counterparts. Individuals with lower endogenous total creatine levels seem to respond greater to creatine supplementation than individuals with higher endogenous total creatine levels[48,49], albeit these results have been equivocal.
Effects of Creatine Supplementation on the Phosphocreatine Energy System
In regards to active older adults, creatine supplementation may be able to have similar effects to that commonly displayed in younger adults supplementing with creatine. Smith et al. used 31P nuclear magnetic resonance spectroscopy (MRS) to determine relative concentrations of intramuscular phosphocreatine in younger (30 ± 5 yr) and older (58 ± 4 yr; data is presented as means ± standard deviation) men while performing three sets of single-leg knee extensions, with 3 minute rest intervals between sets. Participants performed two sets of knee extensions for two minutes followed by one set of knee extensions until exhaustion.
The exercise session was performed on three occasions: at baseline and following the five day consumption of 0.3 g•kg-1•day-1 of a placebo (trial 1) and creatine (trial 2). Following the placebo, the authors found resting phosphocreatine concentrations (younger: 39.5 ± 5.1; older: 35.0 ± 5.2 mmol/kg) and the phosphocreatine resynthesis rate (younger: 23.2 ± 6.0; older: 18.1 ± 3.5 mmol•kg-1•min-1) to be significantly lower in older men compared to younger men. Following creatine supplementation resting phosphocreatine concentrations significantly increased in the younger (15%) and older men (30%). It is important to note that the phosphocreatine resynthesis rate also significantly increased in the older men to a level equivalent to the younger men (young: 24.3 ± 3.8; old: 24.2 ± 3.2 mmol•kg-1•min-1). This study demonstrates that creatine supplementation has a greater effect on phosphocreatine availability and resynthesis rate in older men than younger men.
In 2002, Rawson et al. examined the effects of 5 days of creatine supplementation at a dose of 20 g/d on muscle phosphocreatine levels in younger (n = 8, 24 ± 1.4 yr) and older (n = 7, 70 ± 2.9 yr; data presented as means ± standard error) men. Baseline and post-supplementation measures of phosphocreatine were obtained using nuclear magnetic resonance spectroscopy. At baseline, phosphocreatine levels were significantly greater in the older (23.9 ± 0.7 mmol/kg wet weight) compared to the younger men (20.5 ± 0.7 mmol/kg wet weight). Following creatine supplementation, both groups experienced a significant increase in phosphocreatine (older: 7%, younger 35%). Since baseline differences were present between groups for intramuscular phosphocreatine levels, using baseline measures of phosphocreatine as the covariate, ANCOVA analyses revealed that younger men experienced a significantly greater increase in intramuscular phosphocreatine following supplementation compared to older men (younger: 27.6 ± 0.5; older: 25.7 ± 0.8 mmol/kg wet weight).
Although creatine supplementation was not found to increase intramuscular phosphocreatine levels to the same extent in older men compared to younger men, creatine supplementation was responsible for physiologically significant increases in each population. Furthermore, it does not appear significant that the effect of creatine supplementation on intramuscular phosphocreatine levels in older adults was less dramatic than younger adults, as older adults had baseline phosphocreatine levels significantly closer to the maximal storage capacity of intramuscular phosphocreatine levels than younger adults. This study provides direct evidence that creatine supplementation can enhance intramuscular phosphocreatine levels in older adults, which may enhance the energy providing capacity of the phosphocreatine energy system in this population.
Creatine Supplementation and the Quality and Quantity of Life
Perhaps the most practical application of creatine supplementation in older adults is the potential to increase the quality and quantity of life[51,52]. Recently, two rodent models were used to examine the effects of long-term creatine supplementation on sarcopenia, overall health markers and survival. In 2005, Derave et al. compared the muscle mass, morphology, contractility and metabolic properties of senescence-accelerated mice (SAMP8) who were creatine supplemented (2% of food intake) from weeks 10 to 60 of life (the equivalent of supplementation in humans from the ages of 6 yr to 30-40 yr of life) against a control group. Creatine supplementation was found to have no significant effect on intramuscular ATP, total creatine, phosphocreatine, or absolute muscle mass of the soleus, extensor digitalis longus and tibialis anterior muscles. Further analyses revealed no significant differences between groups in absolute force or relative tension in the soleus or extensor digitalis longus. Finally, creatine supplementation had no significant effect on maintenance of muscle fiber size or distribution with age, leading the authors to conclude creatine supplementation is not an effective nutritional intervention to prevent sarcopenia in senescence-accelerated mice.
A more recent study examined the effects of long-term creatine supplementation in female wild-type C57BL/6J mice either fed a standard rodent diet or the same diet with 1% creatine, starting at the age of 52 weeks (the equivalent of starting creatine supplementation between the ages of 30-35 yr of life in a human), 365 ± 2 days. The creatine-fed mice were found to have a significantly greater healthy life span (corresponding to a 9% increase), as defined by the age at which mice were classified as suffering from disease (creatine: 613 ± 84 days; control: 563 ± 95 days; results reported as mean ± standard error). Creatine supplementation was also found to enhance the overall lifespan (creatine: 716 ± 14 days; control: 692 ± 7 days) for the top 10% longest lived animals in each condition. Furthermore, creatine supplemented mice were found to have a trend increase in locomotor activity and mental health.
Results from Derave et al. and Bender et al. suggest that although long-term creatine supplementation may not significantly affect muscle morphology and intramuscular high-energy phosphate concentrations, creatine supplementation does appear to promote improved quality and quantity of life in mice, particularly when creatine supplementation began later in life and was continued until death.
Possible explanations to account for the results from Derave et al. may be a down-regulation of creatine transporter protein concentration with prolonged exposure to supra-physiological exogenous creatine concentrations resulting from creatine supplementation. If correct, these results demonstrate the potential importance of cycling between periods of creatine use and disuse when consumed over long durations of time. Another explanation for the aforementioned results may involve the point of time within the lifespan in which the mice were supplemented. The pitfalls from Derave et al. may be due to the fact that creatine administration began early in life and was discontinued around the time of middle-age. Conversely, Bender et al. found creatine supplementation to enhance the quality and quantity of life in mice when creatine administration began at middle-age and was continued until death. Therefore, these results suggest that creatine supplementation may have a greater impact on overall health in mature adults rather than adolescence.
Creatine Supplementation in Older Adults
Research appears to be equivocal regarding the effects of creatine supplementation in older adults. Creatine supplementation has been found to enhance muscle strength, endurance, power as measured by maximal isometric knee extension and flexion, lower body peak and mean power, lower body functional capacity using the sit-to-stand and tandem gait tests, body mass, fat-free mass[22,24], anaerobic power, work capacity and has been shown to reduce muscle fatigue. While other studies have found creatine supplementation to have no significant effect on body composition[16,23], maximal dynamic strength[16,23], dynamic or isometric endurance, time to fatigue and isometric strength. However, variable creatine supplementation protocols and different methodologies may account for the equivocal findings between studies. See Additional Files 1 and 2) for a summary of effective and ineffective studies conducted on creatine supplementation in older adults.
Additional file 1. Table 3. Creatine supplementation enhances performance in older adults. Format: PDF Size: 53KB
Additional file 2. Table 4. Creatine supplementation does not enhance performance in older adults. Format: PDF Size: 51KB
Low Dose Creatine Supplementation and Functional Tasks
A placebo-controlled study conducted by Gotshalk et al. found creatine supplementation at a dose of 0.3 g•kg-1•d-1 to significantly increase body mass, 1 repetition maximum (RM) leg and bench press strength, isometric knee extension and flexion, lower body average peak and mean power, and improve performance in the sit-to-stand and tandem gait tests in older men (57-72 yr). In 2008, Gotshalk et al. examined the effects of creatine supplementation in 30 older women (58-71 yr). Participants were assessed on the sit-to-stand test, 1 RM bench press and leg press, isometric hand-grip test, tandem gait test, and upper and lower body ergometer tests prior to and following supplementation with 0.3 g•kg-1•d-1 of a placebo for seven days followed by supplementation at a dose of 0.3 g•kg-1•d-1 of creatine for seven days. Compared to the placebo condition, consuming creatine resulted in a significant increase in body mass and fat-free mass, along with a significant increase in 1 RM bench press and leg press, and increased performance on the tandem gait test.
The investigations by Gotshalk et al.[17,22] are important for several reasons. First, creatine supplementation was found to improve performance in several practical measures of quality of life including strength and functional capacity tests (sit-stand and tandem gait) in older populations of men and women. Second, participants exposed to a low dose creatine regimen (0.3 g•kg-1•d-1) increased body mass and performance, suggesting low dose creatine supplementation can be effective in older populations. Finally, creatine supplementation improved performance independent of training and since the experimenters had participants perform six familiarization protocols it is not likely that any performance improvements were due to a learning effect.
Another study compared the effects of resistance training and 10 weeks of supplementation of either creatine or a placebo administered at a dose of 0.3 g•kg-1•d-1 for the first five days, then 0.07 g•kg-1•d-1 for 65 days in older adults (71.0 ± 1.5 yr). Training consisted of 36 resistance training sessions in which participants performed three sets of 10 repetitions for the bench press, bicep curl, back extension, hip (extension, flexion, adduction and abduction), leg flexion, knee extension and leg press. When compared to the placebo group, creatine supplementation significantly increased lean body mass, 1 RM leg press and knee extension performance, leg press and knee extension endurance, and average lower body power as assessed by three sets of 10 repetitions of isokinetic knee extension/flexion at 60°•s-1 with one-minute rest periods between sets. There were no differences between groups for fat mass, percent body fat, 1 RM bench press or bench press endurance. Of particular interest was the finding that lower body muscle strength and endurance was significantly enhanced with creatine supplementation while having no significant effect on maximal upper body strength or endurance. These findings suggest that in older adults, creatine supplementation may be most effective at enhancing performance of large muscle groups and may explain the non-significant increases in strength using the elbow flexors in other investigations[16,21].
In contrast, Berman et al. examined the effects of consuming an oral creatine supplement or placebo at a dose of 20 g/day for five days and 3 g/d for an additional 47 days in 32 older (67-80 yr) men and women. Participants were randomly divided into one of four groups: creatine-no training, placebo-no training, creatine-exercise or placebo-exercise. Participants in the training groups performed three sets of eight repetitions for leg press, leg extension and chest press, three days per week for seven weeks. Anthropometric measures included assessment of percent body fat via skin-fold assessment and an estimation of lower limb muscle CSA by correcting for thickness of skin and subcutaneous fat by skin-fold measurements. Following seven weeks of supplementation and training, creatine ingestion was found to have no effect on body mass, body fat, or lower limb muscle volume.
Furthermore, creatine was found to have no effect on muscle strength and muscle endurance as supplementation did not significantly improve 1 or 12 RM performance for the leg press, leg extension or seated chest press. However, a major limitation of this study was allowing all training groups to self-select the progression of their resistance training program, rather than following a standardized rate of progression during the course of the study. One of the primary mechanisms by which creatine supplementation has been proposed to improve performance is through enhancement of the phosphocreatine energy system allowing users to train at higher volumes. It is unlikely older men and women were self-selecting loads that would optimize the effects of creatine supplementation for muscle strength and endurance enhancement. Despite the short-comings of the study design, participants in the creatine-exercise group performed better, albeit it not significantly different than participants in the placebo-exercise group on each of the muscle strength and muscle endurance measures.
In 1999, Rawson and Wehnert examined the effects of consuming creatine or a placebo at a dose of 20 g/day for 10 days followed by 4 g/d for 20 days on body composition and strength independent of training. Creatine supplementation was found to have no effect on body mass, body density, fat-free mass or elbow flexor strength. However, creatine was effective at enhancing lower body muscle endurance as determined by assessing the percent change in total peak torque generated during leg extensions on an isokinetic dynamometer. Participants performed five sets of 30 maximal voluntary contractions at 180°•s-1. The finding that creatine supplementation in the absence of training does not improve strength is not surprising. However, it is plausible that a significant effect may have been observed if strength testing involved exercises requiring large muscle groups, such as using a chest or leg press, particularly since lower body muscle endurance was found to be enhanced.
Creatine Supplementation and Skeletal Muscle Fatigue
Wiroth et al. examined the effects of 15 g/day of creatine or a placebo on maximal pedaling performance in older men. Participants were separated into three groups: older sedentary (n = 14, 70.1 ± 1.2 yr; data represented as means ± SE), older trained cyclists (n = 14, 66.4 ± 1.4 yr) and younger sedentary (n = 14, 26.0 ± 1.2 yr). Prior to and following supplementation all participants performed five maximal exertion 10-second sprints on a cycle ergometer, with 60-second rest intervals of passive recovery between sets. Creatine supplementation was found to significantly enhance maximal power and total work in the younger and older sedentary groups. Results of this study suggest short-term creatine supplementation can enhance anaerobic power and work capacity in younger and older adults and that short-term creatine supplementation is able to significantly improve performance in untrained participants. However, creatine supplementation may have a less pronounced affect on trained individuals or trained individuals may require longer supplementation periods for creatine to significantly improve performance.
In a double-blind, randomized, cross-over design Stout et al. examined the effects of consuming creatine or a placebo at a dose of 20 g/d for seven days followed by a dose of 10 g/d for an additional seven days in older men and women (74.5 ± 6.4 yr; data reported as mean ± standard deviation). The experimenters employed a 4-6 week washout period prior to cross-over to the other condition. Also, testing was conducted prior to and following each supplementation period. There were no differences between groups for body mass or performance on the sit-to-stand test; however, participants performed significantly better on grip strength and physical working capacity fatigue threshold tests when consuming creatine compared to the placebo. Results from this investigation provide further evidence that short-term creatine supplementation may enhance strength and delay neuromuscular fatigue which are important functions for maintaining health and independent living with age.
Jakobi et al. examined the effects of creatine supplementation on neuromuscular properties and fatigue in 12 older (65-82 yr) men. The five-day supplementation protocol consisted of two groups of men receiving either 20 g/day of both creatine and maltodextrin (n = 7; 4 × 5 g creatine + 5 g maltodextrin) or a maltodextrin placebo (n = 5; 4 × 5 g maltodextrin). Maximal isometric voluntary force, muscle activation and surface electromyography were measured in elbow flexor muscles at baseline, during a fatiguing task, and over a 10 minute recovery period. Compared to placebo, creatine supplementation was found to have no effect on body mass, maximal isometric voluntary force or muscle activation.
Creatine supplementation was also found to have no effect on time to fatigue, decline in maximal isometric voluntary force, muscle activation or contractile properties during the fatiguing protocol. Similarly, creatine provided no beneficial effect on rates of recovery, voluntary force or stimulated contractile force during recovery. Results from this investigation, albeit limited in sample size and statistical power, suggests that short-term (5 days) creatine supplementation does not influence isometric performance of the elbow flexors in older men.
In 2000, Rawson and Clarkson examined the effects of creatine and sucrose (20 g/d of creatine and 4 g/d of sucrose) or a placebo (24 g of sucrose) on isometric strength, isokinetic skeletal muscle endurance and body mass in 17 older (60-78 yr) men. Results indicate that creatine supplementation significantly increased body mass while having no significant effect on isometric strength as determined by elbow flexion. There was a significant interaction effect, as creatine supplementation significantly enhanced muscle endurance as determined from an intermittent fatigue test of the knee extensors in which participants performed three sets of 30 repetitions, with 60-second rest periods between sets. However, the authors concluded that the significant effect on knee extensor performance was not meaningful as the creatine group experienced a small non-significant increase and the placebo group experienced a small non-significant decrease in performance. Results from this investigation suggest a loading phase of 20 g/d of creatine and 4 g/d of sucrose is able to significantly increase body mass and possibly muscle endurance.
Effects of Creatine Supplementation on Skeletal Muscle Morphology
Brose et al. examined the effects of 14 weeks of resistance training on male and female participants supplemented with either 5 g/day creatine plus 2 g/day of dextrose or 7 g/day of a dextrose only placebo. The resistance training regime consisted of three exercise sessions per week in which participants performed a circuit of 12 exercises prescribed to train the major muscle groups of the upper and lower body. Training progressed from one set of each exercise at 50% of initial 1 RM, to three sets at 80% 1 RM. The 1 RM was re-evaluated every two weeks and the training loads were adjusted to meet the new load demands. Moreover, muscle biopsies were obtained prior to and following supplementation for assessment of mean fiber area and percentage of fiber distribution of type I, IIA and IIX skeletal muscle fibers.
Additional muscle analyses included assessment of creatine, phosphocreatine, total creatine and ATP concentrations. Training resulted in significant increases in all measures of strength, functional tasks, and muscle fiber area in both the creatine and placebo groups. Compared to the placebo, creatine supplementation was found to significantly increase intramuscular total creatine, total body mass and fat-free mass while increasing isometric knee extension strength in men and women, and dorsiflexion strength in men. Results from this study suggest an adequate resistance exercise program alone can reverse the effects of sarcopenia; however, consuming a low dose of creatine during training may enhance the effects of training. Specifically, training plus creatine may increase both muscle mass and strength in older men and women to a greater extent than resistance training alone.
In 2003, Eijnde et al. examined the effects of six months of training plus 5 g/day creatine supplementation or placebo in 46 older (55-75 yr) men. Pertinent variables assessed included body weight, fat-free mass, percent body fat, maximal isometric strength, and intramuscular concentrations of ATP, creatine, phosphocreatine and total creatine. Creatine supplementation was found to have no significant effect on body mass, percent body fat or fat-free mass compared to the placebo condition. Creatine supplementation did not affect intramuscular stores of ATP, creatine, phosphocreatine and total creatine when compared to the placebo.
Flaws in study design include a resistance training protocol designed to stimulate improved muscular endurance (two sets of 30 repetitions of seven exercises), but baseline and post-test measures assessed maximal strength. Moreover, the fact that creatine supplementation did not improve intramuscular levels of high-energy phosphates to a greater extent than the placebo may suggest there were a large number of non-responders to creatine supplementation in the investigation. The possibility also exists that the training necessary to maximize the effects of creatine supplementation may need to be of a higher intensity than that designed to promote skeletal muscle endurance.
Combined Effects of Creatine and Protein Supplementation
Most recently, Candow et al. conducted a study utilizing 35 older (59-77 yr) men who were resistance trained three days per week for 10 weeks. Participants were randomly assigned in a double-blind fashion to one of three groups: creatine-protein (0.1 g•kg-1 of creatine + 0.3 g•kg-1 of protein), creatine (0.1 g•kg-1 of creatine) or a placebo. Supplements were only consumed on training days. Creatine and creatine-protein supplementation resulted in significantly greater gains in body mass, total muscle thickness and less bone resorption assessed by cross-linked N-telopeptides of type I collagen (NTx) when compared to the placebo group. Further analyses revealed the creatine-protein group increased bench press strength to a significantly greater degree than the creatine and placebo groups. Results from this investigation demonstrate that low-dose creatine consumed only three days per week can help improve health in older populations when used in conjunction with a resistance training program. Furthermore, the benefits of creatine may be enhanced in older adults when consumed with protein.
Rates of Muscle Loss Following Cessation of Creatine Supplementation
Results from numerous studies have found creatine supplementation to be effective at enhancing muscle function in older adults[17,22,24-26,55] but the only study to examine the effects of ceasing creatine supplementation while maintaining resistance training in older adults was conducted by Candow et al.. Participants supplemented with 0.3 g•kg-1•d-1 for a period of five days and 0.07 g•kg-1•d-1 for 11 weeks with either creatine or a placebo. Participants in the creatine group experienced significantly greater gains in body mass, total muscle thickness and less bone resorption than participants consuming the placebo. A sub-group of participants supplementing with creatine or the placebo then trained for an additional 12 weeks at a reduced training volume (33% lower). Cessation of creatine supplementation was found to have no effect on strength or lean tissue mass. Muscle endurance was significantly decreased following the cessation of creatine, but the rate of loss was similar between participants in the creatine and placebo groups.
Since participants supplementing with creatine experienced a greater increase muscle thickness than participants supplementing with a placebo while resistance training at a volume/intensity designed to stimulate skeletal muscle hypertrophy and upon the cessation of creatine supplementation and beginning a training regime at a lower intensity there were no differences between groups for loss of muscle function or size these results suggest that older adults who supplement with creatine should experience greater improvements in strength and hypertrophy over time than older adults who only resistance train.
Collectively, creatine supplementation studies in older men and women[17,21,22,24-26,55] suggest that doses as low as 0.3 g•kg-1•d-1, for a period of as little as seven days[17,22], can significantly enhance muscle strength and functional capacity, independent of training. Furthermore, numerous studies have found that short-term creatine supplementation ranging from five days to fourteen weeks can result in significant increases in body mass[17,21,22,25], fat-free mass[17,22,24,25] and strength[17,21,22,24,25,55]. For example, Brose et al. reported that 5 g/day of creatine plus 2 g/day dextrose, for 14 weeks, significantly increased intramuscular total creatine levels. As a result, creatine supplementation appears to be an effective intervention for maintaining strength, body mass, lean mass and functional capacity with age.
Potential Problems with Creatine Supplementation in Older Adults
The use of questionable methodologies may account for the lack of significant performance improvements following creatine supplementation in older adults, but physiological variables may also account for the non-significant findings. For example there are three proposed inter-individual responses to creatine supplementation: 1) responders, individuals who experience a > 20 mmol·kg-1 dw increase in total creatine[57,58], 2) quasi responders, individuals who experience a 10-20 mmol·kg-1 dw increase in total creatine and 3) non-responders, individuals who experience < 10 mmol·kg-1 dw increase in total creatine.
Syrotuik and Bell conducted a study to determine the physiological profile of responders and non-responders to creatine supplementation. Participants consisted of younger males (22.7 yr) who supplemented with creatine for 5 days at a dosage of 0.3 g•kg-1•d-1. Of the 11 participants 3 were responders, 5 were quasi responders and 3 were non-responders. There was a descending trend regarding muscle fiber composition, body mass and fat free mass between the three groups. Responders had the highest percentage of type II fibers (63.1%), followed by quasi responders (45.5%) and non-responders (39.5%).
Responders and quasi responders had a greater muscle cross-sectional area than non-responders pre and post creatine supplementation. Responders, quasi responders and non-responders had mean cross-sectional areas for type I (1,509; 1,270; 900 µm2), type IIA (1,807; 2,238; 1,377 µm2) and type IIB (1,695; 1,740; 1,213 µm2) fibers, respectively. Responders had greater mean muscle fiber increases than non-responders, type I (320 verse 60 µm2), type IIA (971 verse 46 µm2), and type IIB (840 verse 78 µm2). The authors concluded the primary determining factors influencing the effectiveness of creatine supplementation were muscle fiber distribution and muscle CSA. In terms of effects on body composition and strength responders had the greatest increase in total body mass (2.4 kg) and fat free mass (2.0 kg), followed by quasi responders (2.1 kg and 1.9 kg) and non-responders (1.9 kg and 1.7 kg). Responders improved maximal leg press performance by 25.8 kg followed by quasi responders (2.5 kg) and non-responders (2.0 kg).
Results from the Syrotuik and Bell investigation do not bode well for the practicality of creatine supplementation in older adults, a population known to have a greater percentage of type I muscle fibers[59,60] and reduced muscle CSA[33,61,62]. As a result older adults may be less likely to respond to creatine supplementation compared to younger adults. Additionally, creatine uptake is enhanced when consumed in conjunction with carbohydrates. This is problematic as aging is associated with glucose intolerance and a decline in insulin-stimulated transport. Moreover, the saturable component of creatine transport is related to cell age and is greater in young cells. Taken together older adults may not be as responsive to the traditional creatine dosing regimen typically employed in younger adults (loading phase: 20 g/d, maintenance phase: 5 g/d) and may require longer supplementation periods or may need to consume higher doses of creatine to reach saturation levels in muscles. However, this hypothesis has not been supported by the majority of research conducted in older adults as dosing interventions as low as 0.1 g•kg-1 three days per week for 10 weeks combined with resistance exercise have been found to significantly increase body mass and total muscle thickness. While a dose of 5 g/d of creatine with 2 g/d of dextrose for 14 weeks has been found to increase intramuscular total creatine concentrations in older (> 65 yr) men and women.
Finally, the theoretical increase in total creatine following a standard dosing protocol of creatine is 19.3 mmol/kg in older and 27.0 mmol/kg in younger adults (Table 2). These differences suggest a greater responder rate in younger compared to older adults and/or an increased non-responder rate in older adults. This theory is supported by Greenhaff et al. who suggest it may be necessary to increase intramuscular total creatine by approximately 20 mmol·kg-1 dry weight (dw) to obtain significant performance improvements from creatine supplementation. Following this theory Greenhaff et al. suggest that 20%-30% of younger adults fall into the category of non-responders following five days of creatine supplementation at a dose of 20 grams per week. Thus, it is possible that the greater non-responder rate in older adults may account for the lack of significant performance improvements observed in some studies; particularly those with small sample sizes and statistical power.
Despite physiological adaptations that occur with aging that may reduce the effectiveness of creatine supplementation, well designed studies have found creatine supplementation to safely enhance muscle strength[17,22,24-26,56], hypertrophy[17,22,24-26,56], endurance[22,24,55] and performance in functional tasks[17,22] in older adults. Of equal interest, such results have been observed in response to relatively short interventions (5-7 days of creatine supplementation). Therefore, creatine supplementation should be strongly considered as a safe, inexpensive and effective nutritional intervention to help slow the rate of muscle wasting with age, particularly when consumed in conjunction with a resistance training regimen. Future research should examine factors that can affect creatine transport into muscle, such as creatine transporter protein concentrations and uptake from oral ingestion. Researchers also need to examine the effects of age on ATPase and creatine kinase levels, which are integral enzymes needed for phosphocreatine energy system functionality. Finally, research in older populations should focus on the ideal dosing and timing of creatine supplementation, along with the practicality of combining creatine consumption with protein, beta-alanine and/or beta-hydroxy beta-methylbutyric acid (HMB) as each may benefit older adults.
The authors declare that they have no competing interests.
VJD developed the concept and wrote the review paper. MDR contributed in writing the review and aided in the development of the tables. CML, PST, RBK and CMK critically reviewed the manuscript. All authors read and approved the final manuscript.
© 2009 Dalbo et al; licensee BioMed Central Ltd.
This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
1. Giresi PG, Stevenson EJ, Theilhaber J, Koncarevic A, Parkington J, Fielding RA, Kandarian SC: Identification of a molecular signature of sarcopenia.Physiol Genomics 2005, 21:253-263.
2. Janssen I, Shepard DS, Katzmarzyk PT, Roubenoff R: The healthcare costs of sarcopenia in the United States. J Am Geriatr Soc 2004, 52:80-85.
3. Borst SE: Interventions for sarcopenia and muscle weakness in older people. Age Ageing 2004, 33:548-555.
4. Kamel HK: Sarcopenia and aging. Nutr Rev 2003, 61:157-167.
5. Calof OM, Singh AB, Lee ML, Kenny AM, Urban RJ, Tenover JL, Bhasin S: Adverse events associated with testosterone replacement in middle-aged and older men: a meta-analysis of randomized, placebo-controlled trials. J Gerontol A Biol Sci Med Sci 2005, 60:1451-1457.
6. Arciero PJ, Hannibal NS, Nindl BC, Gentile CL, Hamed J, Vukovich MD: Comparison of creatine ingestion and resistance training on energy expenditure and limb blood flow. Metabolism 2001, 50:1429-1434.
7. Sipila I, Rapola J, Simell O, Vannas A: Supplementary creatine as a treatment for gyrate atrophy of the choroid and retina. N Engl J Med 1981, 304:867-870.
8. Becque MD, Lochmann JD, Melrose DR: Effects of oral creatine supplementation on muscular strength and body composition. Med Sci Sports Exerc 2000, 32:654-658.
9. Earnest CP, Snell PG, Rodriguez R, Almada AL, Mitchell TL: The effect of creatine monohydrate ingestion on anaerobic power indices, muscular strength and body composition. Acta Physiol Scand 1995, 153:207-209.
10. Kelly V, Jenkins D: Effect of oral creatine supplmentation on near-maximal strength and repeated sets of high-intensity bench press exercise. Journal of Strength and Conditioning Research 1998, 12:109-115.
11. Noonan D, Berg K, Latin R, Wagner J, Reimers K: Effects of varying dosages of oral creatine relative to fat free body mass on strength and body composition. Journal of Strength and Conditioning Research 1998, 12:104-108.
12. Pearson D, Hamby D, Russel W, Harris T: Long-term effects of creatine monohydrate on strength and power. Journal of Strength and Conditioning Research 1999, 13:187-192.
13. Peeters B, Lantz C, Mayhew J: Effect of oral creatine monohydrate and creatine phosphate supplementation on maximal strength indices, body composition, and blood pressure. The Journal of Strength and Conditioning Research 1999, 13:3-9.
14. Vandenberghe K, Goris M, Van Hecke P, Van Leemputte M, Vangerven L, Hespel P: Long-term creatine intake is beneficial to muscle performance during resistance training. J Appl Physiol 1997, 83:2055-2063.
15. Willoughby DS, Rosene J: Effects of oral creatine and resistance training on myosin heavy chain expression. Med Sci Sports Exerc 2001, 33:1674-1681.
16. Rawson ES, Wehnert ML, Clarkson PM: Effects of 30 days of creatine ingestion in older men. Eur J Appl Physiol Occup Physiol 1999, 80:139-144.
17. Gotshalk LA, Kraemer WJ, Mendonca MA, Vingren JL, Kenny AM, Spiering BA, Hatfield DL, Fragala MS, Volek JS: Creatine supplementation improves muscular performance in older women. Eur J Appl Physiol 2008, 102:223-231.
18. Rawson ES, Clarkson PM, Price TB, Miles MP: Differential response of muscle phosphocreatine to creatine supplementation in young and old subjects. Acta Physiol Scand 2002, 174:57-65.
19. Candow DG, Chilibeck PD, Chad KE, Chrusch MJ, Davison KS, Burke DG: Effect of ceasing creatine supplementation while maintaining resistance training in older men. J Aging Phys Act 2004, 12:219-231.
20. Eijnde BO, Van Leemputte M, Goris M, Labarque V, Taes Y, Verbessem P, Vanhees L, Ramaekers M, Eynde B, Van Schuylenbergh R, et al.: Effects of creatine supplementation and exercise training on fitness in men 55-75 yr old. J Appl Physiol 2003, 95:818-828.
21. Rawson ES, Clarkson PM: Acute creatine supplementation in older men. Int J Sports Med 2000, 21:71-75.
22. Gotshalk LA, Volek JS, Staron RS, Denegar CR, Hagerman FC, Kraemer WJ: Creatine supplementation improves muscular performance in older men. Med Sci Sports Exerc 2002, 34:537-543.
23. Bermon S, Venembre P, Sachet C, Valour S, Dolisi C: Effects of creatine monohydrate ingestion in sedentary and weight-trained older adults. Acta Physiol Scand 1998, 164:147-155.
24. Chrusch MJ, Chilibeck PD, Chad KE, Davison KS, Burke DG: Creatine supplementation combined with resistance training in older men. Med Sci Sports Exerc 2001, 33:2111-2117.
25. Brose A, Parise G, Tarnopolsky MA: Creatine supplementation enhances isometric strength and body composition improvements following strength exercise training in older adults. J Gerontol A Biol Sci Med Sci 2003, 58:11-19.
26. Wiroth JB, Bermon S, Andrei S, Dalloz E, Hebuterne X, Dolisi C: Effects of oral creatine supplementation on maximal pedalling performance in older adults. Eur J Appl Physiol 2001, 84:533-539.
27. Imamura K, Ashida H, Ishikawa T, Fujii M: Human major psoas muscle and sacrospinalis muscle in relation to age: a study by computed tomography. J Gerontol 1983, 38:678-681.
28. Lexell J, Henriksson-Larsen K, Winblad B, Sjostrom M: Distribution of different fiber types in human skeletal muscles: effects of aging studied in whole muscle cross sections. Muscle Nerve 1983, 6:588-595.
29. Kyle UG, Genton L, Hans D, Karsegard L, Slosman DO, Pichard C: Age-related differences in fat-free mass, skeletal muscle, body cell mass and fat mass between 18 and 94 years. Eur J Clin Nutr 2001, 55:663-672.
30. Moller P, Bergstrom J, Furst P, Hellstrom K: Effect of aging on energy-rich phosphagens in human skeletal muscles. Clin Sci (Lond) 1980, 58:553-555.
31. Moller P, Brandt R: The effect of physical training in elderly subjects with special reference to energy-rich phosphagens and myoglobin in leg skeletal muscle. Clin Physiol 1982, 2:307-314.
32. Bastien C, Sanchez J: Phosphagens and glycogen content in skeletal muscle after treadmill training in young and old rats. Eur J Appl Physiol Occup Physiol 1984, 52:291-295.
33. Coggan AR, Spina RJ, Rogers MA, King DS, Brown M, Nemeth PM, Holloszy JO: Histochemical and enzymatic characteristics of skeletal muscle in master athletes. J Appl Physiol 1990, 68:1896-1901.
34. Berneis K, Ninnis R, Haussinger D, Keller U: Effects of hyper- and hypoosmolality on whole body protein and glucose kinetics in humans. Am J Physiol 1999, 276:E188-195.
35. Hespel P, Op't Eijnde B, Van Leemputte M, Urso B, Greenhaff PL, Labarque V, Dymarkowski S, Van Hecke P, Richter EA: Oral creatine supplementation facilitates the rehabilitation of disuse atrophy and alters the expression of muscle myogenic factors in humans. J Physiol 2001, 536:625-633.
36. Ingwall JS: Creatine and the control of muscle-specific protein synthesis in cardiac and skeletal muscle. Circ Res 1976, 38:I115-123.
37. Young RB, Denome RM: Effect of creatine on contents of myosin heavy chain and myosin-heavy-chain mRNA in steady-state chicken muscle-cell cultures. Biochem J 1984, 218:871-876.
38. Dangott B, Schultz E, Mozdziak PE: Dietary creatine monohydrate supplementation increases satellite cell mitotic activity during compensatory hypertrophy. Int J Sports Med 2000, 21:13-16.
39. Olsen S, Aagaard P, Kadi F, Tufekovic G, Verney J, Olesen JL, Suetta C, Kjaer M: Creatine supplementation augments the increase in satellite cell and myonuclei number in human skeletal muscle induced by strength training. J Physiol 2006, 573:525-534.
40. Casey A, Constantin-Teodosiu D, Howell S, Hultman E, Greenhaff PL: Creatine ingestion favorably affects performance and muscle metabolism during maximal exercise in humans. Am J Physiol 1996, 271:E31-37.
41. Rawson ES, Volek JS: Effects of creatine supplementation and resistance training on muscle strength and weightlifting performance. J Strength Cond Res 2003, 17:822-831.
42. Campbell WW, Barton ML Jr, Cyr-Campbell D, Davey SL, Beard JL, Parise G, Evans WJ: Effects of an omnivorous diet compared with a lactoovovegetarian diet on resistance-training-induced changes in body composition and skeletal muscle in older men. Am J Clin Nutr 1999, 70:1032-1039.
43. Harris RC, Soderlund K, Hultman E: Elevation of creatine in resting and exercised muscle of normal subjects by creatine supplementation. Clin Sci (Lond) 1992, 83:367-374.
44. Balsom PD, Soderlund K, Sjodin B, Ekblom B: Skeletal muscle metabolism during short duration high-intensity exercise: influence of creatine supplementation. Acta Physiol Scand 1995, 154:303-310.
45. Volek JS, Duncan ND, Mazzetti SA, Staron RS, Putukian M, Gomez AL, Pearson DR, Fink WJ, Kraemer WJ: Performance and muscle fiber adaptations to creatine supplementation and heavy resistance training. Med Sci Sports Exerc 1999, 31:1147-1156.
46. Tarnopolsky MA: Potential benefits of creatine monohydrate supplementation in the elderly. Curr Opin Clin Nutr Metab Care 2000, 3:497-502.
47. Forsberg AM, Nilsson E, Werneman J, Bergstrom J, Hultman E: Muscle composition in relation to age and sex. Clin Sci (Lond) 1991, 81:249-256.
48. Smith SA, Montain SJ, Matott RP, Zientara GP, Jolesz FA, Fielding RA: Creatine supplementation and age influence muscle metabolism during exercise. J Appl Physiol 1998, 85:1349-1356.
49. Burke DG, Chilibeck PD, Parise G, Candow DG, Mahoney D, Tarnopolsky M: Effect of creatine and weight training on muscle creatine and performance in vegetarians. Med Sci Sports Exerc 2003, 35:1946-1955.
50. Shomrat A, Weinstein Y, Katz A: Effect of creatine feeding on maximal exercise performance in vegetarians. Eur J Appl Physiol 2000, 82:321-325.
51. Derave W, Eijnde BO, Ramaekers M, Hespel P: No effects of lifelong creatine supplementation on sarcopenia in senescence-accelerated mice (SAMP8). Am J Physiol Endocrinol Metab 2005, 289:E272-277.
52. Bender A, Beckers J, Schneider I, Holter SM, Haack T, Ruthsatz T, Vogt-Weisenhorn DM, Becker L, Genius J, Rujescu D, et al.: Creatine improves health and survival of mice. Neurobiol Aging 2008, 29:1404-1411.
53. Rangarajan A, Weinberg RA: Opinion: Comparative biology of mouse versus human cells: modelling human cancer in mice. Nat Rev Cancer 2003, 3:952-959.
54. Jakobi JM, Rice CL, Curtin SV, Marsh GD: Neuromuscular properties and fatigue in older men following acute creatine supplementation. Eur J Appl Physiol 2001, 84:321-328.
55. Stout J, Graves S, Cramer J, Goldstein E, Costa P, Smith A, Walter A: Effects of creatine supplementation on the onset of neuromuscular fatigue threshold and muscle strength in elderly men and women (64 - 86 years). Journal of Nutrition, Health & Aging 2007, 11:459-464.
56. Candow DG, Little JP, Chilibeck PD, Abeysekara S, Zello GA, Kazachkov M, Cornish SM, Yu PH: Low-Dose Creatine Combined with Protein during Resistance Training in Older Men. Med Sci Sports Exerc 2008, 40(9):1645-1652.
57. Greenhaff PL, Bodin K, Soderlund K, Hultman E: Effect of oral creatine supplementation on skeletal muscle phosphocreatine resynthesis. Am J Physiol 1994, 266:E725-730.
58. Syrotuik DG, Bell GJ: Acute creatine monohydrate supplementation: a descriptive physiological profile of responders vs. nonresponders. J Strength Cond Res 2004, 18:610-617.
59. Gollnick PD, Armstrong RB, Saubert CWt, Piehl K, Saltin B: Enzyme activity and fiber composition in skeletal muscle of untrained and trained men. J Appl Physiol 1972, 33:312-319.
60. Larsson L, Karlsson J: Isometric and dynamic endurance as a function of age and skeletal muscle characteristics. Acta Physiol Scand 1978, 104:129-136.
61. Lexell J, Downham D: What is the effect of ageing on type 2 muscle fibres? J Neurol Sci 1992, 107:250-251.
62. Lexell J, Taylor CC, Sjostrom M: What is the cause of the ageing atrophy? Total number, size and proportion of different fiber types studied in whole vastus lateralis muscle from 15- to 83-year-old men. J Neurol Sci 1988, 84:275-294.
63. Dolan PL, Boyd SG, Dohm GL: Differential effect of maturation on insulin- vs. contraction-stimulated glucose transport in Zucker rats. Am J Physiol 1995, 268:E1154-1160.
64. Ku CP, Passow H: Creatine and creatinine transport in old and young human red blood cells. Biochim Biophys Acta 1980, 600:212-227.
65. Harris RC, Hultman E, Nordesjo LO: Glycogen, glycolytic intermediates and high-energy phosphates determined in biopsy samples of musculus quadriceps femoris of man at rest. Methods and variance of values. Scand J Clin Lab Invest 1974, 33:109-120.
66. Green AL, Hultman E, Macdonald IA, Sewell DA, Greenhaff PL: Carbohydrate ingestion augments skeletal muscle creatine accumulation during creatine supplementation in humans. Am J Physiol 1996, 271:E821-826.
67. van Loon LJ, Oosterlaar AM, Hartgens F, Hesselink MK, Snow RJ, Wagenmakers AJ: Effects of creatine loading and prolonged creatine supplementation on body composition, fuel selection, sprint and endurance performance in humans. Clin Sci (Lond) 2003, 104:153-162.
68. Sewell DA, Robinson TM, Greenhaff PL: Creatine supplementation does not affect human skeletal muscle glycogen content in the absence of prior exercise. J Appl Physiol 2008, 104:508-512.
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