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CreaPureTM is 100% creatine monohydrate, the most effective and soluble form of creatine, and is the ultimate complement to your hard work at the gym and/or on the field. Free of additives and impurities, CreaPureTM stands behind its name, delivering a pure, untainted form of creatine monohydrate.
Creatine supplementation has grown increasingly popular since its introduction into the supplement industry in the early 1990s. The growing popularity of creatine monohydrate was accompanied by a growing number of supporting clinical research studies, making it the most scientifically-examined form of creatine to this day. Unfortunately, the quality of many creatine products began to suffer as other forms of creatine started being introduced into the market.
Many supplement companies will cut corners in their budget by outsourcing cheaper [potentially cross-contaminated] ingredients from other countries, sacrificing the purity and quality of the creatine with less effective forms of creatine and fillers. Other companies introduce unproven, buffered forms of creatine, and hype them to the skies, despite the complete lack of clinical data. Then they jack up their prices accordingly.
Unfortunately, you're literally flushing all your money down the toilet with many of these products, peeing them out (in the form of creatinine), with little to none of it going to your muscles. CreaPureTM provides you with the highest quality of creatine monohydrate, delivering creatine straight to your muscles. And, in the case of ProSource Creatine Monohydrate, you can get your CreaPureTM at a price you can be excited about.
The Science Behind Creatine
Creatine is a naturally occurring nitrogenous compound stored primarily in skeletal muscle in the form of phosphocreatine [phosphorylated creatine] and free creatine.(1,2) Phosphocreatine (PCr) aids in the production of energy for the body, particularly high-intensity, short-duration exercise of anaerobic nature such as weightlifting or sprinting. Exercise of this nature relies largely on the phosphagen energy system (also known as the ATP-PC system). The ATP-PC system produces energy at the fastest out of the all other energy systems (anaerobic glycolysis, aerobic glycolysis, beta-oxidation); however, its duration is the shortest.
During high-intensity exercise, muscle contraction is fueled via splitting of the bond holding adenosine triphosphate (ATP) together, releasing energy and creating an accumulation of adenosine diphosphate (ADP) as a byproduct. Intramuscular PCr stores quickly regenerate ATP by donating its phosphate to ADP, catalyzed by the enzyme, creatine phosphokinase (CPK). Prolonged, repeated muscle contractions of high-intensity inevitably lead to fatigue once ATP and PCr levels become low. Resynthesis of ATP at a rate fast enough to supply the energy demands of high-intensity exercise depends on PCr stores. Thus, once PCr stores become depleted, the ability to maintain maximum-effort ceases and ATP is produced at a slower rate via other metabolic pathways (i.e. anaerobic glycolysis) depending on the nature of exercise. Therefore, increasing intramuscular PCr stores is conducive to maintaining ATP turnover rates during exercise that require maximal muscular strength or power.(3)
Endogenous production of creatine occurs in the liver via conversion of arginine, glycine and methionine.(4) Dietary creatine has a high bioavailability and passes through the digestive system intact into the blood stream to muscle as PCr. Exogenous creatine may be obtained through dietary sources like fish (i.e. herring, salmon, tuna) and red meat (i.e. farmed meat, wild game). The amount of meat and fish consumption, however, required to elicit an ergogenic benefit may not be convenient, practical or cost-efficient. For example, a 1.1 kg of raw steak contains 5 grams of creatine.(3) Creatine monohydrate (CM) powder, however, provides a practical, convenient and cost-efficient method of increasing intramuscular PCr, while also facilitating manipulation of dosage.
Creatine monohydrate is the most extensively studied form of creatine. One of the most consumed dietary supplements, creatine monohydrate has consistently demonstrated successful increases in PCr stores following acute and chronic consumption.(1,3,5,6) Research has also demonstrated significant increases in strength performance resultant of increased PCr stores.(7,8) Additional supporting research has observed significant increases in strength performance as a result of both, short- and long-term creatine monohydrate intake.(9,10) Izquierdo (et al.11) found significant improvements in lower body strength and power output, as well as repeated-sprint performance and jumping ability in a fatigued state, when male subjects underwent a five-day CM loading phase. Additional literature further supports the advantageous effects of CM intake, observing enhancements in various indices of exercise performance (i.e. cycling power, bench press repetition volume, swimming performance, soccer-specific skills).(12-15)
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Both acute (five-day load) and chronic (lower/maintenance dose) methods of creatine consumption have shown significant, favorable effects on body composition, increasing lean muscle mass.(8-10) Research examining the chronic consumption of creatine has demonstrated significant increases in lean muscle mass accompanied by significant decreases in body fat. Creatine loading (e.g. five grams, four times a day for five days) elicits the most dramatic increase in PCr stores. Lower creatine doses (i.e. 5-10 grams per day), however, have also demonstrated significant increases in parameters associated with enhancement of high-intensity, short-duration physical activity/exercise. (16-19) A long-term, lower dose of creatine intake increases PCr stores to the same extent as with loading, however, at a gradual rate.(6)
It is common practice to initiate a creatine regimen with a loading phase followed by a maintenance phase (10,20) or start with a [lower] maintenance dose alone. It has been reported that creatine loading is associated with an increase in body weight of approximately 2-4 pounds.(21) Therefore, creatine loading may not be ideal for athletes whose performance may be negatively affected by weight gain (i.e. running, swimming).(22) Initiating creatine intake with a long-term, lower dose provides the ergogenic benefits while avoiding the potential for the [minor] adverse effects (i.e. gastrointestinal distress) and weight gain that have been reported with loading/high dose.(23-25) Candow et al.(17) reported greater muscle gains from resistance training when creatine was combined with a superior-quality protein such as NytroWhey Ultra Elite, versus creatine alone. Thus, incorporating protein and creatine in your nutrient-timing regimen may provide optimal anabolic effects.
Creatine and Resistance Training
Creatine monohydrate optimizes resistance-training adaptations via augmentation of satellite cell proliferation and increased myonuclei within skeletal muscle fibers, both translating to enhanced muscle hypertrophy. In response to physiological stimuli (i.e. high-intensity resistance exercise/strength training) skeletal muscle regenerates and repairs itself with the help of satellite cells. Satellite cells are the resident stem cells located along the peripheral of muscle fibers (between the basal lamina and sarcolemma of the muscle fiber). (26) Upon disruption of the basal lamina (i.e. resistance exercise-induced muscle damage), satellite cells proliferate, generating myoblasts for the purpose of muscle growth, repair and regeneration.(27) Thus, myonuclei count increases occur concomitantly with satellite cell proliferation, promoting additional satellite cell concentration to accommodate to the increased number of muscle cells.(28) The more satellite cells you have, the more muscle cells you will acquire, translating to an increase in cross-sectional areas of muscle fiber size.
Olsen et al.29 found that creatine monohydrate (7-day loading phase followed by a 15-week maintenance phase [of 6 grams per day]) intake significantly increased myonuclei concentration per muscle fiber and amplified the satellite cell count greater than resistance training alone. Hence, creatine monohydrate consumption is complementary to the hypertrophic effects of resistance training, increasing muscle fiber size to a greater extent than expected. In addition, creatine monohydrate supplementation, in combination with heavy resistance training, has also demonstrated significant enhancements in myosin heavy chain protein synthesis.(30)
Creatine monohydrate intake, in combination with resistance training, has also been associated with increases in insulin-like growth factor I (IGF-1), an anabolic hormone known to induce skeletal muscle hypertrophy. Burke (et al.31) found significant increases in IGF-1 following 8 weeks of creatine monohydrate consumption, combined with resistance training, among male and females subjects. Not surprisingly, vegetarians, who typically have low initial creatine stores, showed the greatest response to creatine in this study, experiencing the greatest increase in lean mass compared to non-vegetarians. Vegetarians are often classified as "responders" to creatine supplementation due to their lack of creatine in diet, thereby, increasing sensitivity and dramatic responses to supplementation.(32)
Creatine and Women
Previous research has found negligible effects of creatine on females supported by the theory that they may be classified as "nonresponders".(33) Nonresponders may be characterized by having substantial total creatine levels (free creatine and PCr), a higher type I to type II muscle fiber ratio, smaller muscle cross-sectional area and/or lower fat-free mass.(2,7) Female muscle composition, typically, encompasses a greater size distribution of Type I to Type II (IIa and IIx) muscle fibers.(34) This may pose as a deterrent for women, and men with nonresponder characteristics, seeking to benefit from creatine supplementation. However, the aforementioned traits simply suggest that the nonresponders may not respond to creatine loading, but may benefit from long-term, lower-dose creatine supplementation.
Research findings classifying females as nonresponders is inconsistent. A number of studies have observed increases in PCr stores, increases in lean mass, decreases in body fat and improvements in strength and high-intensity exercise capacity in female subjects (including non-vegetarians) assigned to loading and maintenance doses of creatine monohydrate. (20,35-38) Research has also observed creatine loading without increases in body weight in female subjects.(36) Creatine monohydrate provides an abundance of benefits that are not gender-exclusive.
Benefits of Creatine: In-and-Out of the Weight Room
In addition to the consistent research supporting creatine monohydrate's efficacy for enhancing body composition and weightlifting/athletic performance, creatine also provides benefit to brain function. Rae (et al.39) observed significant improvements in working memory and performance among young, adult vegetarians assigned to 5 grams of creatine monohydrate a day for six weeks. Recent research has also observed significant improvements when creatine monohydrate was administered to patients with major depression.(40,41)
Creatine is also of great benefit for the elderly whose total creatine stores in skeletal muscle decline with age. Creatine monohydrate consumption has shown to improve physical functional capacity (i.e. promote skeletal muscle hypertrophy, increase strength, increase muscular endurance, promote movement speed, delay neuromuscular fatigue)(42-44), supporting optimal health and independence among the elderly.
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With so many creatine products to choose from it becomes difficult for consumers to know which creatine is best. Some products will contain various forms of creatine (i.e. creatine ethyl ester, creatine pyruvate, creatine citrate). The efficacy and safety of these other forms of creatine, however, remains in question. Other forms of creatine lack the abundance of data to support the efficacy, bioavailability and safety demonstrated by research analyzing creatine monohydrate.(48) Spillane et al.(49) revealed superior bioavailability and increases in intramuscular creatine stores with creatine monohydrate when compared to creatine ethyl ester. Creatine ethyl ester significantly increased creatinine levels, indicating increased degradation/low bioavailability.
Nothing Compares to CreaPureTM!
Avoid the costs, questionable ingredients and overall dubious quality of other forms of creatine and buy a pure and reliable creatine monohydrate, like CreaPureTM, as found in ProSource Creatine Monohydrate. CreaPureTM provides a superior form of 100% creatine monohydrate that surpasses its competitors; free of the impurities found in other brands (i.e. dihydrotriazine, creatinine, sodium, and dicyandiamide). Unlike multi-ingredient products that typically contain an undisclosed amount of creatine, CreaPureTM allows you to successfully manipulate your dose of creatine intake at your discretion, without interfering with other components of your overall supplement regimen. When you buy ProSource brand creatine, you get CreaPureTM an ultra-low cost without sacrificing the integrity and efficacy of the product. Achieve gains in exercise/sport performance while reaping the aforementioned benefits of creatine monohydrate intake with CreaPureTM.
1. Casey A, Constantin-Teodosiu D, Howell S, Hultman E, Greenhaff PL. (1996). Creatine ingestions favorably affects performance and muscle metabolism during maximal exercise in humans. Am J Phyiol. 271: E31-E37.
2. Demant TW, Rhodes EC. (1999). Effects of creatine supplementation on exercise performance. Sports Med. 28(1):49-60.
3. Harris RC, Söderlund K, Hultman E. (1992). Elevation of creatine in resting and exercised muscle of normal subjects by creatine supplementation. Clinical Science. 83:367-374.
4. Wyss M and Kaddurah-Daouk R. (2000). Creatine and creatinine metabolism. Physiological Reviews. 80(2):1107-1213.
5. Smith SA, Montain SJ, Matott RP, Zientara GP, Jolesz FA, Fielding RA. (1999). Effects of creatine supplementation on the energy cost of muscle contraction: a 31P-MRS study. Journal of Applied Physiology. 87(1):116-123.
6. Hultman E, Söderlund K, Timmons JA, Cederblad G, Greenhaff PL. (1996). Muscle creatine loading in men. Journal of Applied Physiology. 81(1):232-237.
7. Syrotuik DG, Bell GJ. (2004). Acute creatine monohydrate supplementation: a descriptive physiological profile of responders vs. nonresponders. JSCR. 18(3):610-7.
8. Kilduff LP, Vidakovic P, Cooney G, Twycross-Lewis R, Amuna P, Parker M. (2002). Effects of creatine on isometric bench-press performance in resistance-trained humans. Med Sci Sports Exerc. 34(7):1176-83.
9. Becque MD, Lochmann JD, Melrose DR. (2000). Effects of oral creatine supplementation on muscular strength and body composition. Med Sci Sports Exerc. 32(3):654-8.
10. Kerksick CM, Wilborn CD, Campbell WI, Harvey TM, Marcello BM, Roberts MD, Parker AG, Byars AG, Greenwood LD, Almada AL, Kreider RB, Greenwood M. (2009).The effects of creatine monohydrate supplementation with and without D-pinitol on resitance training adaptations. JSCR. 23(9):2673-82.
11. Izquierdo M, Ibañez J, González-Badillo JJ, Gorostiaga EM. (2002). Effects of creatine supplementation on muscle power, endurance, and sprint performance. Med Sci Sports Exerc.34(2):332-43.
12. Wiroth JB, Bermon S, Andrei S, Dalloz E, Heberturne X, Dolisi C. (2001). Effects of oral creatine supplementation on maximal pedaling performance in older adults. Eur J Appl Physiol. 84:533-9.
13. Volek JS, Kraemer WJ, Bush JA, Boetes M, Incledon T, Clark KL, Lynch JM. (1997). Creatine supplementation enhances muscular performance during high-intensity resistance exercise. J Am Diet Assoc. 97:765-70.
14. Juhász I, Györe I, Csende Z, Rácz L, Tihanyi J. (2009). Creatine supplementation improves the anaerobic performance of elite junior fin swimmers. Acta Physiol Hung. 96(3):325-36.
15. Ostojic SM. (2004). Creatine supplementation in young soccer players. Int J Sport Nutr Exerc Metab. 14:95-103.
16. Burke DG, Silver S, Holt LE, Smith Palmer T, Culligan CJ, Chilibeck PD. (2000). The effect of continuous low dose creatine supplementation on force, power and total work. International Journal of Sport Nutrition and Exercise Metabolism. 10(3):235-244.
17. Candow DG, Little JP, Chilibeck PD, Abeysekara S, Zello GA, Kazachkov M, Cornish SM, Yu PH. (2008). Low-dose creatine combined with protein during resistance training in older men. Med Sci Sports Exerc. 40(9):1645-52.
18. Hoffman JR, Stout JR, Falvo MJ, Kang J, Ratamess NA. (2005). Effect of low-dose, short duration creatine supplementation on anaerobic exercise performance. JSCR. 19(2).
19. Anomasiri W, Sanguanrungsirikul S, Saichandee P. (2004). Low dose creatine supplementation enhances sprint phase of 400 meters swimming performance. Journal of the Medical Association of Thailand, Chotmaihet Thangphaet. 87(Suppl 2):S228-32.
20. Vandenberghe K, Goris M, Van Hecke P, Van Leemputte M, Vangerven L, Hespel P. (1997). Long-term creatine intake is beneficial to muscle performance during resistance training. Journal of Applied Physiology. 83(6):2055-2063.
21. Kreider RB. Creatine in Sports. In Essentials of Sport Nutrition & Supplements. Edited by Antonio J, Kalman D, Stout J, et al. Humana Press Inc., Totowa, NJ. 2007:in press.
22. Buford TW, Kreider RB, Stout JR, Greenwood M, Campbell B, Spano M, Ziegenfuss T, Lopez H, Landis J, Antonio J. (2007). International Society of Sports Nutrition position stand: creatine supplementation and exercise. JISSN. 4:6.
23. Rawson ES, Stec MJ, Frederickson SJ, Miles MP. (2011). Low-dose creatine supplementation enhances fatigue resistance in the absence of weight gain. Nutrition. 27(4):451-5.
24. Kutz MR, Gunter MJ. (2003). Creatine monohydrate supplementation on body weight and percent body fat. JSCR. 17(4):817-21.
25. Ostojic SM, Ahmetovic Z. (2008). Gastrointestinal distress after creatine supplementation in athletes: are side effects dose dependent. Res Sports Med. 16(1):15-22.
26. Muir AR, Kanji AH, Allbrook D. (1965). The structure of the satellite cells in skeletal muscle. J. Anat. 99:435–444.
27. Siegel AL, Kuhlmann PK, Cornelison DDW. (2011). Muscle satellite cell proliferation and assocation: new insights from myofiber time-lapse imaging. Skeletal Muscle.1:7.
28. Fawzi K, Thornell LE. (2000). Concomitant increases in myonuclear and satellite cell content in female trapezius muscle following strength training. Histochemistry & Cell Biology. 113(2):99.
29. Olsen S, Aagaard P, Kadi F, Tufekovic G, Verney J, Olesen JL, Suetta C, Kjaer M. (2006). Creatine supplementation augments the increase in satellite cell and myonuclei number in human skeletal muscle induced by strength training. J Physiol. 573(Pt 2):525-34.
30. Willoughby DS, Rosene J. (2001). Effects of oral creatine and resistance training on mysosin heavy chain expression. Med Sci Sports Exerc. 33(10):1674-81.
31. Burke DG, Candow DG, Chilibeck PD, MacNeil LG, Roy BD, Tarnopolsky MA, Ziegenfuss T. (2008). Effect of creatine supplementation and resistance-exercise training on muscle insulin-like growth factor in young adults. Int J Sport Nutr Exerc Metab. 18:389-398.
32. Watt KK, Garnham AP, Snow RJ. (2004). Skeletal muscle total creatine content and creatine transporter gene expression in vegetarians prior to and following creatine supplementation. Int J Sport Nutr Exerc Metab. 14(5):517-31.
33. Ferguson TB, Syrotuik DG. (2006). Effects of creatine monohydrate supplementation on body composition and strength indices in experienced resistance trained women. JSCR. 20(4):939-46.
34. Staron RS, Hagerman FC, Hikida RS, Murray TF, Hostler DP, Crill MT, Ragg KE, Toma K. (2000). Fiber type composition of the vastus lateralis muscle of young men and women. The Journal of Histochemistry & Cytochemistry. 48 (5):623-629.
35. Smith AE, Walter AA, Herda TJ, Ryan ED, Moon JR, Cramer JT, Stout JR. (2007). Effects of creatine loading on electromyographic fatigue threshold during cycle ergometry in college-aged women. J Int Soc Sports Nutr. 4:20.
36. Eckerson JM, Stout JR, Moore GA, Stone NJ, Nishimura K, Tamura K. (2004). Effect of two and five days of creatine loading on anaerobic working capacity in women. JSCR. 18(1):168–73.
37. Tarnopolsky MA, MacLennan DP. (2000). Creatine monohydrate supplementation enhances high-intensity exercise performance in males and females. Int J Sport Nutr Exerc Metab.10(4):452–63.
38. Brenner M, Walberg-Rankin J, Sebolt D. (2000). The effect of creatine
supplementation during resistance training in women. JSCR. 14(2):207–13.
39. Rae C, Digney AL, McEwan SR, Bates TC. (2003). Oral creatine monohydrate supplementation improves brain performance: a double-blind, placebo-controlled, cross-over trial. Proc Biol Sci. 270(1529):2147-2150.
40.Lyoo IK, Yoon S, Hwang J, Kim JE, Won W, Bae S, Renshaw PF. (2012). A randomized, double-blind placebo-controlled trial of oral creatine monohydrate augmentation for enhanced response to a selective serotonin reuptake inhibitor in women with major depressive disorder. Am J Psychiatry.169(9):937-45.
41. Roitman S, Green T, Osher Y, Karni N, Levine J. (2007). Creatine monohydrate in resistant depression: a preliminary study. Bipolar disorders. 9(7):754-758.
42. Brose A, Parise G, Tarnopolsky MA. (2003). Creatine supplementation enhances isometric strength and body composition improvements following strength exercise training in older adults. J Gerontol A Biol Sci Med Sci. 58(1):11-9.
43. Stout JR, Graves SB, Cramer JT, Goldstein ER, Costa PB, Smith AE, Walter AA. (2007). Effects of creatine supplementation on the onset of neuromuscular fatigue threshold and muscle strength in elderly men and women (64-86). J Nutr Health Aging. 11(6):459-64.
44. Cañete S, San Juan AF, Pérez M, Gómez-Gallego F, López-Mojares LM, Earnest CP, Fleck SJ, Lucia A. (2006). Does creatine improve functional capacity in elderly women? JSCR. 20(1):22-8.
45. Sestili P, Martinelli C, Bravi C, Piccoli G, Curci R, Battistelli M, Falcieri E, Agostini D, Gioacchini AM, Stocchi V. (2006). Creatine supplementation affords cytoprotection in oxidatively injured cultured mammalian cells via direct antioxidant activity. Free Radic Biol Med. 40(5):837-49.
46. Tarnopolsky MA, Mahoney DJ, Vajsar J, Rodríguez C, Doherty TJ, Roy BD, Biggar D. (2004). Creatine monohydrate enhances strength and body composition in Duchenne muscular dystrophy. Neurology. 62(10):1771-7.
47. The NINDS NET-PD Investigators. (2006). A randomized, double-blind, futility clinical trial of creatine and minocycline in early Parkinson disease. Neurology. 66(5):664-671.
48. Jäger R, Purpura M, Shao A, Inoue T, Kreider RB. (2011). Analysis of the efficacy, safety, regulatory status of novel forms of creatine. Amino Acids. 40(5):1369-1383.
49. Spillane M, Cooke M, Harvey T, Greenwood M, Kreider R, Willoughby DS. (2009). The effects of creatine ethyl ester supplementation combined with heavy resistance training on body composition, muscle performance, and serum and muscle creatine levels. JISSN. 6:6.