Summary
Three principal cellular mechanisms have been proposed to explain the ergogenic potential of caffeine during exercise: (a) increased myofilament affinity for calcium and/or increased release of calcium from the sarcoplasmic reticulum in skeletal muscle; (b) cellular actions caused by accumulation of cyclic-3′,5′-adenosine monophosphate (cAMP) in various tissues including skeletal muscle and adipocytes; and (c) cellular actions mediated by competitive inhibition of adenosine receptors in the central nervous system and somatic cells. The relative importance of each of the above mechanisms in explaining in vivo physiological effects of caffeine during exercise continues to be debated. However, growing evidence suggests that inhibition of adenosine receptors is one of the most important, if not the most important, mechanism to explain the physiological effects of caffeine at nontoxic plasma concentrations. Numerous animal studies using high caffeine doses have reported increased force development in isolated skeletal muscle in both in vitro and in situ preparations. In contrast, in vivo human studies have not consistently shown caffeine to enhance muscular performance during high intensity, short term exercise. Further, recent evidence supports previous work that shows caffeine does not improve performance during short term incremental exercise. Although controversy exists, the major part of published evidence evaluating performance supports the notion that caffeine is ergogenic during prolonged (>30 min), moderate intensity (≈75 to 80% V̇2max) exercise. The mechanism to explain these findings may be linked to a caffeine-mediated glycogen sparing effect secondary to an increased rate of lipolysis.
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References
Aragon J, Tornheim J, Lowenstein J. On a possible role of IMP in the regulation of Phosphorylase activity in skeletal muscle. FEBS Letters 117 (Suppl.): K56–K64, 1980
Arogyasami J, Yang HT, Winder WW. Effect of caffeine on glycogenosis during exercise in endurance trained rats. Medicine and Science in Sports and Exercise 21: 173–177, 1989a
Arogyasami J, Yang HT, Winder WW. Effect of intravenous caffeine on muscle glycogenosis in fasted exercising rats. Medicine and Science in Sports and Exercise 21: 167–172, 1989b
Berglund B, Hemmingsson P. Effects of caffeine ingestion on exercise performance at low and high altitudes in crosscountry skiers. International Journal of Sports Medicine 3: 234–236, 1982
Bond V, Gresham K, McRae J, Tearney RW. Caffeine ingestion and isokinetic strength. British Journal of Sports Medicine 20: 135–137, 1986
Butts NK, Crowell D. Effect of caffeine ingestion on cardiores-piratory endurance in men and women. Research Quarterly for Exercise and Sport 56: 301–305, 1985
Cadarette B, Levine L, Berube C, Posner B, Evans W. Effects of varied doses of caffeie on endurance exercise to fatigue. Biochemistry of Exercise 13: 871–877, 1983
Casal DC, Leon AS. Failure of caffeine to affect substrate utilization during prolonged running. Medicine and Science in Sports and Exercise 17: 17–179, 1985
Coffin V, Spealman R. Behavioral and cardiovascular effects of analogs of adenosine in cynomologous monkeys. Journal of Pharmacology and Experimental Therapeutics 241: 76–83, 1987
Conlee RK. Muscle glycogen and exercise endurance: a twentyyear perspective. Exercise and Sports Sciences Review 15: 1–28, 1987
Conlee RK. Amphetamine, caffeine, and cocaine. In Lamb & Murray (Eds) Perspectives in Exercise Science and Sports Medicine, Volume 2, pp. 285–310, Benchmark Press, New York, 1990
Costili D, Dalsky G, Fink W. Effects of caffeine ingestion on metabolism and exercise performance. Medicine and Science in Sports and Exercise 10: 155–158, 1978
Dobson G, Yamamoto E, Hochachka P. Phosphofructokinase control in muscle: nature and reversal of pH-dependent ATP inhibition. American Journal of Physiology 250: R71–R76, 1986
Dodd SL, Brooks E, Powers SK, Tulley R. The effects of caffeine on graded exercise performance in caffeine naive versus habituated subjects. European Journal of Applied Physiology 62: 424–429, 1991
Erickson MA, Schwarzkopf RJ, McKenzie RD. Effects of caffeine, fructose, and glucose ingestion on muscle glycogen utilization during exercise. Medicine and Science in Sports and Exercise 19: 579–583, 1987
Essig D, Costili DL, VanHandel PJ. Effects of caffeine ingestion on utilization of muscle glycogen and lipid during leg ergometer cycling. International Journal of Sports Medicine 1: 86–90, 1980
Falk B, Burstein R, Ashkenazi I, Spilberg O, Alter J, et al. The effect of caffeine ingestion on physical performance after prolonged exercise. European Journal of Applied Physiology 59: 168–173, 1989
Flinn S, Gregory J, McNaughton LR, Tristram S, Davies P. Caffeine ingestion prior to incremental cycling to exhaustion in recreational cyclists. International Journal of Sports Medicine 11:188–193, 1990
Fredholm B. On the mechanism of action of theophylline and caffeine. Acta Medica Scandinavica 217: 149–153, 1985
Fryer MW, Neering IR. Actions of caffeine on fast- and slowtwitch muscles of the rat. Journal of Physiology 416: 435–454, 1989
Gaesser GA Rich RG. Influence of caffeine on blood lactate response during incremental exercise. International Journal of Sports Medicine 6: 207–211, 1985
Gastin PB, Misner JE, Boileau RA, Slaughter MH. Failure of caffeine to enhance exercise performance in incremental treadmill running. Australian Journal of Science and Medicine in Sports 22: 23–27, 1990
Graham TE, Spriet L. Performance and metabolic responses to a high caffeine dose during prolonged exercise. Journal of Applied Physiology 71: 2292–2298, 1991
Green H. How important is endogenous muscle glycogen to fatigue in prolonged exercise? Canadian Journal of Physiology and Pharmacology 69: 290–297, 1990
Gulati J, Babu A. Contraction kinetics of intact and skinned frog fibers and degree of activation. Journal of General Physiology 86: 479–500, 1985
Holtzman S, Mante S, Minneman K. Role of adenosine receptors in caffeine tolerance. Journal of Pharmacology and Experimental Therapeutics 256: 62–68, 1991
Ivy J, Costili D, Fink W, Lower R. Influence of caffeine and carbohydrate feedings on endurance performance. Medicine and Science in Sports and Exercise 11: 6–11, 1979
Jacobson BH, Kulling FA. Health and ergogenic effects of caffeine. British Journal of Sports Medicine 23: 34–40, 1989
Kovacs L, Szucs G. Effect of caffeine on intramembrane change movement and calcium transients in cut skeletal muscle fibres of the frog. Journal of Physiology 341: 559–578, 1983
Lopes JM, Aubier M, Jardim J, Aranda JV, Maclen PT. Effect of caffeine on skeletal muscle function before and after fatigue. Journal of Applied Physiology 54: 1303–1305, 1983
Macintosh BR, Gardiner PF. Posttetanic potentiation and skeletal muscle fatigue: interaction with caffeine. Canadian Journal of Physiology and Pharmacology 65: 260–268, 1987
Macintosh BR, Kupsh CC. Staircase, fatigue, and caffeine in skeletal muscle in situ. Muscle and Nerve 10: 717–722, 1987
Marangos P, Boulenger J. Basic and clinical aspects of adenosinergic neuromodulation. Neuroscience and Biobehavior Review 9: 421–430, 1985
McNaughton L. Two levels of caffeine ingestion on blood lactate and free fatty acid response during incremental exercise. Research Quarterly for Exercise and Sport 58: 255–259, 1987
Newsholme E, Leech A. Biochemistry for the medical sciences, Wiley and Sons, New York, 1988
Poehlman ET, Despres J-P, Bessette H, Fontaine E, Tremblay A, et al. Influence of caffeine on the resting metabolic rate of exercise-trained and inactive subjects. Medicine and Science in Sports and Exercise 17: 689–694, 1985
Powers SK, Byrd RJ, Tulley R, Callender T. Effects of caffeine ingestion on metabolism and performance during graded exercise. Journal of Applied Physiology 50: 301–307, 1983
Powers SK, Dodd SL. Caffeine and endurance performance. Sports Medicine 2: 165–174, 1985
Rall TW. Central nervous system stimulants. In Goodman et al. (Eds) The pharmacological basis of therapeutics, 5th ed., pp. 592–607, Macmillan, New York, 1980
Sahlin K, Katz A, Broberg S. Tricarboxylic acid cycle intermediates in human muscle during prolonged exercise. American Journal of Physiology 28: C834–C841, 1990
Sasaki H, Maeda J, Usui S, Ishiko T. Effect of sucrose and caffeine ingestion on performance of prolonged strenuous running. International Journal of Sports Medicine 8: 261–265, 1987a
Sasaki H, Takaoka I, Ishiko T. Effects of sucrose or caffeine ingestion on running performance and biochemical responses to endurance running. International Journal of Sports Medicine 8: 203–207, 1987b
Slavin JL, Joensen DJ. Caffeine and sports performance. Physician and Sportsmedicine 13(5): 191–193, 1985
Snyder S. Adenosine as neuromodulator. Annual Review of Neuroscience 8: 103–124, 1985
Spriet L, MacLean D, Dyck D, Hultman E, Cederblad G, et al. Effects of caffeine on muscle glycogenolysis and acetyl group metabolism during prolonged exercise in humans. American Journal of Physiology, in press, 1992
Stephenson D, Williams D. Calcium activated force responses in fast and slow twitch skinned muscle fibers of the rat at different temperatures. Journal of Physiology 317: 281–302, 1981
Su J, Hasselbach W. Caffeine-induced calcium release from isolated sarcoplasmic reticulum of rabbit skeletal muscle. Pflugers Archiv — European Journal of Physiology 400: 1921, 1984
Tarnopolsky MA, Atkinson SA, MacDougall JD, Sale DG, Sutton JR. Physiological responses to caffeine during endurance running in habitual caffeine users. Medicine and Science in Sports and Exercise 21: 418–424, 1989
Wendt I, Stephenson D. Effects of caffeine on calcium-activated force production in skinned cardiac and skeletal muscle fibers of the rat. Pflugers Archiv — European Journal of Pysiology 398: 210–216, 1983
Williams JH, Barnes WS, Gadberry WL. Influence of caffeine on force aud EMG in rested and fatigued muscle. American Journal of Physical Medicine 6: 169–183, 1987
Williams JH, Signorile JF, Barnes WS, Henrich TW. Caffeine, maximal power output and fatigue. British Journal of Sports Medicine 229: 132–134, 1988
Winder WW. Effect of intravenous caffeine on liver glycogenosis during prolonged exercise. Medicine and Science in Sports and Exercise 18: 192–196, 1986
Zhang Y, Wells J. The effects of chronic caffeine administration on peripheral adenosine receptors. Journal of Pharmacology and Experimental Therapeutics 254: 757–763, 1990
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Dodd, S.L., Herb, R.A. & Powers, S.K. Caffeine and Exercise Performance. Sports Medicine 15, 14–23 (1993). https://doi.org/10.2165/00007256-199315010-00003
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DOI: https://doi.org/10.2165/00007256-199315010-00003