Introduction to Creatine

Creatine was first discovered by a French scientist, Chevrewul in 1835, and is derived from the Greek word kreas (flesh).¹ Creatine is a non-essential molecule that is produced endogenously, primarily in the liver, and to a lesser degree the pancreas and kidneys. It is an amine constructed from three amino acids, arginine, glycine, and methionine.^2,3 Of the three amino acids, only methionine is considered indispensable. It can be obtained exogenously from dietary food sources and/or supplementation. Food sources rich in creatine include red meat, rabbit, and fish.^2-4 Most adults who consume meat and fish get approximately 1 to 2 grams per day from diet.^2,3 Whereas vegetarians and vegans consume very small amounts, and therefore rely on endogenous production.³ While this coupled with endogenous production is enough to prevent a creatine deficiency, which is rare, it is not enough to significantly improve performance.^3,5 Although research trials with creatine began in the early 1900’s, supplementation with creatine did not gain popularity until the early 1990’s. At this time it was discovered that supplementation with creatine increased the metabolically-active pool of creatine, namely phosphocreatine (Pcr).⁶

Background and Science Principles: Energy Systems & ATP

Creatine is one of the most popular ergogenic sports supplements available today. The popularity of creatine is matched by it repeatedly being demonstrated as the most effective ergogenic supplement for increasing strength, power, and lean mass when combined with resistance training.^2,5,7,12 Some evidence suggests it may also improve high-intensity sprints and endurance training.^2,5,8-11 Understanding the energy systems of the body is fundamental to understanding the role and potential benefits of creatine supplementation. Adenosine triphosphate (ATP) is a high-energy molecule used by all cells in the body for energy. In terms of exercise and sports performance, the focus is on its role in skeletal muscle. The potential energy in ATP is stored in the phosphate bond. When the bond is broken (hydrolyzed), energy is released for the cell to perform work, such as the force needed for the contraction and consequent relaxation of skeletal muscle. ATP that is stored in skeletal muscle, where exercise, even at the highest intensities will only exhaust 20-30% of stored ATP. This will lead to exhaustion, however it also indicates a large pool of stored ATP is not available to be used in force production.¹³ Therefore, ATP is rapidly replaced to provide energy. When ATP is hydrolyzed, it becomes adenosine diphosphate (ADP), a lower energy molecule that must be rephosphorylated to ATP. The body has three energy systems to replenish ATP, namely creatine phosphate, anaerobic glycolysis, and oxidative phosphorylation.^3,13   The table below summarizes the power output, amount of ATP replenished, and example activities for each energy system.

It is important to note that each of the three energy systems can be simultaneously active during a given exercise and/or sport. However, one is generally going to be the predominant source of energy.³ Although evidence suggests creatine supplementation can benefit sports and exercise that predominantly exhaust any one of the three energy systems, the creatine phosphate system is most directly affected, followed by anaerobic glycolysis, and then oxidative phosphorlylation.^2,7-12Creatine exerts its benefits within the creatine phosphate energy system by increasing phosphocreatine (PCr) levels. Like ATP, PCr stores its energy within the phosphate bond, and it is stored in skeletal muscle and other tissue.³ However, unlike ATP, the energy in the phosphate bond of PCr is not used directly to provide energy for force contraction. Rather when ATP is hydrolyzed to ADP, the high energy phosphate from PCr is used to rephosphorylate ADP into ATP. Therefore, PCr acts as a high energy reservoir for skeletal muscle. The ability to replenish ATP is one of the limiting factors during high intensity, short-term exercise.^2,5 The net effect of creatine supplementation on energy is an accelerated rate of ATP resynthesis.

Effects of Creatine Supplementation on Recover

Bassit et al¹⁴ demonstrated a protective effect from creatine supplementation. Specifically, they took blood samples from Ironman triathletes 36 hours before and 60 hours after the race. They measured several markers of muscle damage (creatine kinase, lactate dehydrogenase, aldolase, glutamic oxaloacetic acid transaminase, and glutamic pyruvic acid transaminase), and found that while all five markers increased in the participants receiving a placebo following the race, creatine supplementation decreased three of the five markers and prevented a rise in the other two.¹⁴ 

Creatine supplementation can also decrease oxidative stress via antioxidant activity. The proposed mechanism is via scavenging free radical oxidation that results from nitric oxide production (needed for vasodilation).² Cooke et al¹⁵ found that in addition to antioxidant activity, that it may also enhance the buffering capacity of muscle. Specifically, they speculate that it may reduce calcium-activated proteases. This in turn minimizemyolemma and further influxes calcium into the muscle.¹⁵  

Study Showing Just 7 Days on Creatine Improved Performance

In a 2011 study with recreational, resistance trained males, Rahimi¹⁶ found that 7-days of supplementation with creatine at a loading dose (4 x 5 g/d) not only significantly improved performance, but also reduced DNA damage and lipid peroxidation induced by resistance training.¹⁶ The measurable ergogenic benefit of the antioxidant effect and enhanced recovery from creatine supplementation, is the ability for resistance trained athletes to perform better during subsequent training sessions. Recreational athletes and especially elite athletes in various sports, undertake training sessions on a given muscle group two to three days following a previous training session. Improvement in strength recovery allows athletes to train with a higher load than they otherwise would be able to. The net effect of this likely explains the greater mass and strength gains observed in resistance training athletes supplementing with creatine.^2,7-8,11-12  

Effect of Creatine Supplementation on Aerobic Performance

While an abundance of research has demonstrated creatine supplementation benefits for strength, hypertrophy, and anaerobic endurance, there is also evidence demonstrating positive effects on aerobic endurance. In a randomized, double blind, placebo controlled trial, Chilibeck et al⁸ sought to determine if increased body mass from creatine supplementation would adversely affect aerobic endurance in rugby union players. The researchers stressed that these were rugby union players, as opposed rugby league players, which have been used in past studies involving creatine and rugby. Rugby union requires more aerobic endurance, muscular strength, and muscular endurance. This is due to more continuous play, scrums, unlimited tackles, and heavier weight forwards. While players supplementing with creatine increased lean body mass and improved anaerobic endurance over the placebo group, there was no adverse effect on aerobic endurance.⁸

Hadjicharalambous et al⁹ sought to examine if supplementation with creatine could influence perception of effort during prolonged exercise in the heat, and consequently improve endurance performance. Specifically, the researchers took endurance-trained males and had them exercise on a stationary bike in a climactic chamber. The intensity was based on pre-testing, so a rate could be established where fatigue would set in at 40-60 minutes for each subject. Only the creatine responders (based on estimated Cr uptake) improved endurance performance, which was measured by time improvements to exhaustion. The creatine responders time to exhaustion was 51.7 ± 7.4 min vs. 47.3 ± 4.9 min for non-responders.The enhanced thermal tolerance is speculated to be a result of increased total body water in creatine responders.⁹

In another randomized, double blind, placebo controlled trial Graef et al¹⁰ investigated the effects of creatine citrate supplementation and high intensity interval training (HIIT) on cardiorespiratory fitness. HIIT is a form of exercise that can induce similar adaptations as aerobic training in a time efficient manner. No differences between the creatine and placebo group were observed in terms of total work done or VO_2PEAK. However, ventilatory threshold increased in the creatine group.¹⁰

Generally endurance activities lasting more than 150 seconds, predominantly rely on oxidative phosphorylation as the main energy system. Most research suggests that continuous activity lasting longer than 150 seconds mitigates the benefits from creatine supplementation. However, as demonstrated above there are benefits creatine supplementation can yield for endurance activities. Also some evidence suggests that creatine supplementation may cause a change in the predominant energy system utilized during aerobic activity, which in turn may improve endurance performance.²

Effect of creatine supplementation on anaerobic exercise, hypertrophy, and body composition

Chillibeck et al⁸ observed that creatine increased lean body mass and improved anaerobic endurance in rugby union players.⁸Spillane et al¹⁷ examined the effects of how seven weeks of supplementation with creatine monohydrate, creatine ethyl ester, or placebo combined with resistance training affected body composition, muscle mass, and muscle strength and power. All three groups improved in terms of muscle strength and power (1-RM bench press and leg press). The placebo group and creatine monohydrate group decreased fat mass, however dietary recall was used to determine energy intake. Finally subjects receiving creatine monohydrate had the greatest increase in thigh muscle mass based on DEXA scans.¹⁷

Burke et al⁷ observed that creatine supplementation, combined with a high-volume, heavy load (>70% 1-RM) resistance training program increased type II muscle fiber area of the vastus lateralis by 28% for the creatine users vs. 5% for the placebo group.⁷

In a recent study of elite Brazilian soccer players, Claudino et al¹¹ sought to determine if creatine monohydrate could improve their performance. To test the effects of creatine supplementation, the researchers measured lower limb muscle power. They had the subjects perform a countermovement jump (CMJ); performance was assessed by using a strain-gauge force plate. CMJ performance consisted of 8 jumps with 1 minute of rest between each jump. Subjects had to keep to their hands on their chest to keep the jumps similar in terms of technique. In other words, athletes could not use a technique that may involve using the upper body, such as swinging their arms to increase the jump, taking the better technique variable out of the assessment. At baseline both groups had comparable jumping performance. After intervention the placebo group jumping performance was 0.7% lower than baseline scores and the creatine groups jumping performance was 2.4% greater than baseline. The decrease and relatively low improvement in the creatine group (not statistically significant) is attributed to progressive training-induced lower limb decline due to the rigors of the pre-season games and training. The main effect demonstrated in this study is the ability of creatine supplementation to offset these effects, leading to the jumping performance improvement. The effect in the macro (from baseline to the end of the study) is likely due to the elevated levels of creatine phosphate, leading to a lesser decrease in force production throughout training sessions in the creatine group. However, this could not be verified as taking a muscle biopsy from elite athletes in the pre-season was not feasible.¹¹

Ziegenfuss et al¹² recently examined the effects of a dietary supplement containing creatine monohydrate on power and golf swing performance. The golf swing is an anaerobic movement that can benefit from improved club head speed. Improving club head speed can be accomplished by improved power output. Researchers assessed power by bench press throws, and upper body strength by 1-RM bench press as it is closely correlates with the strength and power needed in a golf swing. Golf swing performance was measured by a 3-D swing analysis system. Power, best drive, and average distance significantly improved in the supplemented group. At baseline the supplemented group had significantly greater maximal strength and peak power production than the placebo group, this may have affected the results of the study.

Creatine Responders vs. Non-responders

A possible confounding variable in much of the research is individual difference in terms of response to creatine supplementation. It is a common limitation in many of the studies I reviewed, and can be viewed in table 2 below. Not everyone responds to creatine supplementation. Hadjicharalambous et al⁹ initially determined that creatine supplementation had no effect on endurance performance. However, upon dividing participants into responders and non-responders based on their intramuscular creatine uptake, they determined that the responders had a significant performance increase over non-responders (51.7 ± 7.4 min vs. 47.3 ± 4.9 min).⁹ 

Burke et al⁷ studied 42 recreationally active individuals (male and female) to compare changes in insulin-growth factor (IGF-I) content from resistance training and creatine supplementation. The individuals were randomized in blocks and classified as vegetarian (lacto-ovo or vegan) or non-vegetarian. Within the creatine group vegetarians, in spite of lower caloric and protein intake gained an average of 2.4 vs. 1.9 kg/lbm for non-vegetarians.Also Pcr levels in the creatine group had an increase of 37% for vegetarians vs. 11% for nonvegetarians.⁷Vegetarians rely on endogenous production of creatine due to a lack of exogenous sources in their diets.³ Therefore, they tend to have a lower initial level of total muscle creatine content.^3,7 This leads to them having a greater potential to improve performance from creatine supplementation.

Response to creatine supplementation amongst individuals can be divided into three classes, responders, quasi responders, and non-responders.² Creatine responders tend to have the characteristics listed below:

• Lower initial level of total muscle creatine content.²
• Greater population of type II muscle fibers.²
• Larger cross sectional area for type I and type II muscle fibers.²
• Possess higher potential to improve performance in response to creatine supplementation.²

Ideally, when feasible (requires a muscle biopsy) researchers should assess intramuscular creatine uptake to determine if non-response played a role in the results of a given study.

Creatine Supplementation Myths

Largely due to the popularity of creatine supplementation, many myths have been attributed to creatine. The sources are generally from anecdotes and media reports linking creatine supplementation to anabolic steroid use. Buford et al⁵ in the position stand of the International Society of Sports Nutrition on creatine supplementation have identified purported myths:

• All weight gained from creatine supplementation is due to water retention.⁵
• Creatine supplementation causes renal distress.⁵
• Long term effects of creatine supplementation are a mystery.⁵
• Creatine supplementation is banned as a PED and it is unethical to use.⁵
• Creatine supplementation causes cramping, dehydration, and/or altered electrolyte status.⁵

Creatine Supplementation Facts

In direct contrast to the myths surrounding creatine supplementation, evidence accumulated from numerous studies on creatine supplementation has demonstrated the following facts:

• There is no scientific evidence that short- or long term creatine use has any detrimental effects in otherwise healthy individuals.⁵
• In addition to being safe, creatine is possibly beneficial for preventing injury and cramping.^2,5
• Creatine monohydrate is the most effective form of supplemental creatine.^2,5
• Creatine is the most effective ergogenic nutritional supplement available today for increasing both lean mass and high-intensity exercise capacity.^2,5

Creatine and Sports

In addition to the above, many sports governing bodies approve creatine supplementation for athletes competing under their jurisdiction. Specifically, creatine is not on the banned lists of the National Collegiate Athletic Association (NCAA) or the World Anti-Doping Agency (WADA).^18-19

References

1. Mesa JL, Ruiz JR, González-Gross MM, Guitiérrez Sáinz A, Castillo Garzón MJ. Oral creatine supplementation and skeletal muscle metabolism in physical exercise. Sports Med. 2002;32(14):903-944.
2. Cooper R, Naclerio F, Allgrove J, Jimenez A. Creatine supplementation with specific view to exercise/sports performance: an update. J Int Soc Sports Nutr.2012 Jul 20;9(1):33. doi: 10.1186/1550-2783-9-33.
3. Dunford M, Doyle JA. Energy Systems and Exercise. In: Dunford M, Doyle JA, ed. Nutrition for Sports and Exercise. 3rd Ed. Stamford, CTY: Cengage Learning; 2015:67-97.
4. Frank K, Orwell S, Woolf P, et al. Examine website. Creatine. Examine.com. http://examine.com/supplements/Creatine/. Updated October 26, 2014. Accessed February 14, 2015.
5. Buford TW, Kreider RB, Stout JR, et al. International Society of Sports Nutrition position stand: creatine supplementation and exercise. J Int Soc Sports Nutr.2007 Aug 30;4:6.
6. Harris RC, Sӧderlund K, Hultman E. Elevation of creatine in resting and exercised muscle of normal subjects by creatine supplementation. Clin Sci (Lond).1992 Sep;83(3)367-374.
7. Burke DG, Candow DG, Chilibeck PD, et al. Effect of creatine supplementation and resistance-exercise on muscle insulin-like growth factor in young adults.Int J Sport Nutr Exerc Metab. 2008 Aug;18(4):389-98.
8. Chilibeck PD, Magnus C, Anderson M. Effect of in-season creatine supplementation on body composition and performance in rugby union football players.Appl Physio Nutr Metab. 2007 Dec;32(6):1052-7.
9. Hadjicharalambous M, Liam KP, Pitsiladis YP. Brain serotonin and dopamine modulators, perceptual responses and endurance performance during exercise in the heat following creatine supplementation. J Int Soc Sports Nutr. 2008; 5:14. doi: 10.1186/1550-2783-5-14.
10. Graef JL, Smith AE, Kendall KL, et al. The effects of four weeks of creatine supplementation and high-intensity interval training on cardiorespiratory fitness: a randomized controlled trial. J Int Soc Sports Nutr. 2009 Nov 12;6:18. doi: 10.1186/1550-2783-6-18.
11. Claudino JG, Mezêncio B, Amaral S, et al. Creatine monohydrate Supplementation on lower-limb muscle power in Brazilian elite soccer players. J Int Soc Sports Nutr. 2014;11:32. doi: 10.1186/1550-2783-11-32.
12. Ziegenfuss TN, Habowski SM, Lemieux R, et al. Effect of a dietary supplement on golf drive distance and functional indices of golf performance. J Int Soc Sports Nutr. 2015 Jan 21;12(1):4. doi: 10.1186/s12970-014-0065-4.
13. Dunford M, Doyle JA. Defining and Measuring Energy. In: Dunford M, Doyle JA, ed. Nutrition for Sports and Exercise. 3rd Ed. Stamford, CTY: Cengage Learning; 2015:37-64.
14. Bassit RA, Pinheiro CH, Vitzel KF, Sproesser AJ, Silveria LR, Curi R. Effect of short-term creatine supplementation on markers of skeletal muscle damage after strenuous contractile activity. Eur J Appl Physiol. 2010 Mar;108(5):945-55. doi: 10.1007/s00421-009-1305-1.  
15. Cooke MB, Rybalka E, Williams AD, Cribb PJ, Hayes A. Creatine supplementation enhances muscle force recovery after eccentrically-induced muscle damage in healthy individuals. J Int Soc Sports Nutr. 2009 Jun 2;6:13. doi: 10.1186/1550-2783-6-13.
16. Rahimi R. Creatine supplementation decreases oxidative DNA damage and lipid peroxidation induced by a single bout of resistance exercise. J Strength Cond Res. 2011 Dec;25(12):3448-55. doi: 10.1519/JSC.0b013e3182162f2b.
17. Spillane M, Schoch R, Cooke M, et al. The effects of creatine ethyl ester supplementation combined with heavy resistance training on body composition, muscle performance, and serum muscle creatine levels. J Int Soc Sports Nutr. 2009 Feb 19;6:6. doi: 10.1186/1550-2783-6-6.
18. National Collegiate Athletic Association. 2014-15 NCAA Banned Drugs. NCAA website. http://www.ncaa.org/health-and-safety/policy/2014-15-ncaa-banned-drugs. Updated November 7, 2014. Accessed February 14, 2015.
19. World Anti-Doping Agency. 2015 List of Prohibited Substances and Methods. https://wada-main-prod.s3.amazonaws.com/resources/files/wada-2015-prohibited-list-en.pdf. Updated September 20, 2014. Accessed February 14, 2015.  
20. Manjarrez-Montes de Coa R, Fargan-Gonzalez F, Camarillo-Romero S, et al. Effect of creatine supplementation in taekwondo practitioners. Nutr Hosp. 2013 Mar-Apr; 28(2):391-9. doi: 10.3305/nh.2013.28.2.6314.