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Open Access 01-12-2021 | Invited Review

A critical review of citrulline malate supplementation and exercise performance

Authors: Lewis A. Gough, S. Andy Sparks, Lars R. McNaughton, Matthew F. Higgins, Josh W. Newbury, Eric Trexler, Mark A. Faghy, Craig A. Bridge

Published in: European Journal of Applied Physiology | Issue 12/2021

Abstract

As a nitric oxide (NO) enhancer, citrulline malate (CM) has recently been touted as a potential ergogenic aid to both resistance and high-intensity exercise performance, as well as the recovery of muscular performance. The mechanism has been associated with enhanced blood flow to active musculature, however, it might be more far-reaching as either ammonia homeostasis could be improved, or ATP production could be increased via greater availability of malate. Moreover, CM might improve muscle recovery via increased nutrient delivery and/or removal of waste products. To date, a single acute 8 g dose of CM on either resistance exercise performance or cycling has been the most common approach, which has produced equivocal results. This makes the effectiveness of CM to improve exercise performance difficult to determine. Reasons for the disparity in conclusions seem to be due to methodological discrepancies such as the testing protocols and the associated test–retest reliability, dosing strategy (i.e., amount and timing), and the recent discovery of quality control issues with some manufacturers stated (i.e., citrulline:malate ratios). Further exploration of the optimal dose is therefore required including quantification of the bioavailability of NO, citrulline, and malate following ingestion of a range of CM doses. Similarly, further well-controlled studies using highly repeatable exercise protocols with a large aerobic component are required to assess the mechanisms associated with this supplement appropriately. Until such studies are completed, the efficacy of CM supplementation to improve exercise performance remains ambiguous.

Agudelo LZ, Ferreira DM, Dadvar S, Cervenka I, Ketscher L, Izadi M, Ruas JL (2019) Skeletal muscle PGC-1α1 reroutes kynurenine metabolism to increase energy efficiency and fatigue-resistance. Nat Commun 10(1):1–12CrossRef

Bahri S, Curis E, El Wafi FZ, Aussel C, Chaumeil JC, Cynober L, Zerrouk N (2008) Mechanisms and kinetics of citrulline uptake in a model of human intestinal epithelial cells. Clin Nutr 27(6):872–880CrossRef

Bendahan D, Mattei JP, Ghattas B, Confort-Gouny S, Le Guern ME, Cozzone PJ (2002) Citrulline/malate promotes aerobic energy production in human exercising muscle. Br J Sports Med 36(4):282–289CrossRef

Breuillard C, Cynober L, Moinard C (2015) Citrulline and nitrogen homeostasis: an overview. Amino Acids 47(4):685–691CrossRef

Casonatto J, Enokida DM, Grandolfi K (2019) Inter-Individual Responses to Citrulline Malate Oral Supplementation on Post-Exercise Hypotension in Hypertensives: A 24-Hour Analysis. Arq Bras Cardiol 113(2):218–228PubMedPubMedCentral

Chappell AJ, Allwood DM, Simper TN (2018a) Citrulline malate fails to improve german volume training performance in healthy young men and women. J Diet Suppl 21:1–12

Chappell AJ, Allwood DM, Johns R, Brown S, Sultana K, Anand A et al (2018b) Citrulline malate supplementation does not improve german volume training performance or reduce muscle soreness in moderately trained males and females. J Int Soc Sports Nutr 15(1):8CrossRef

Churchward-Venne TA, Cotie LM, MacDonald MJ, Mitchell CJ, Prior T, Baker SK et al (2014) Citrulline does not enhance blood flow, microvascular circulation, or myofibrillar protein synthesis in elderly men at rest or following exercise. Am J Physiol 307:83CrossRef

Cunniffe B, Papageorgiou M, O’Brien B, Davies NA, Grimble GK, Cardinale M (2016) Acute citrulline-malate supplementation and high-intensity cycling performance. J Strength Cond Res 30(9):2638–2647CrossRef

Currell K, Jeukendrup AE (2008) Validity, reliability and sensitivity of measures of sporting performance. Sports Med 38:297–316CrossRef

da Silva DK, Jacinto JL, de Andrade WB, Roveratti MC, Estoche JM, Balvedi MCW et al (2017) Citrulline malate does not improve muscle recovery after resistance exercise in untrained young adult men. Nutrients 9(10):1132CrossRef

Davis AR, Webber CL, Fish WW, Wehner TC, King S, Perkins-Veazie P (2011) L-citrulline levels in watermelon cultigens tested in two environments. HortScience 46(12):1572–1575CrossRef

Ehlers GG, Ball TE, Liston L (2002) Creatine kinase levels are elevated during 2-a-day practices in collegiate football players. J Athl Train 37(2):151PubMedPubMedCentral

Farney TM, Bliss MV, Hearon CM, Salazar DA (2019) The effect of citrulline malate supplementation on muscle fatigue among healthy participants. J Strength Cond Res 33(9):2464–2470CrossRef

Gibala MJ, Young ME, Taegtmeyer H (2000) Anaplerosis of the citric acid cycle: role in energy metabolism of heart and skeletal muscle. Acta Physiol Scand 168(4):657–665CrossRef

Gills JL, Glenn JM, Gray M, Romer B, Lu H (2021) Acute citrulline-malate supplementation is ineffective during aerobic cycling and subsequent anaerobic performance in recreationally active males. Eur J Sport Sci 18:1–7CrossRef

Glenn JM, Gray M, Wethington LN, Stone MS, Stewart RW, Moyen NE (2017) Acute citrulline malate supplementation improves upper- and lower-body submaximal weightlifting exercise performance in resistance-trained females. Eur J Nutr 56(2):775–784CrossRef

Gonzalez AM, Trexler ET (2020) Effects of citrulline supplementation on exercise performance in humans: A review of the current literature. J Strength Cond Res 34(5):1480–1495CrossRef

Gonzalez AM, Spitz RW, Ghigiarelli JJ, Sell KM, Mangine GT (2018) Acute effect of citrulline malate supplementation on upper-body resistance exercise performance in recreationally resistance-trained men. J Strength Cond Res 32(11):3088–3094CrossRef

Grimble GK (2007) Adverse gastrointestinal effects of arginine and related amino acids. J Nutr 6(2):1693–1701CrossRef

Hargreaves M, Spriet LL (2020) Skeletal muscle energy metabolism during exercise. Nat Metab 2:817–828CrossRef

Hultström M, Amorim de Paula C, Fontes AP, M., Porcelli, S., Bellistri, G., Pugliese, L., et al (2015) Commentaries on Viewpoint: Can elite athletes benefit from dietary nitrate supplementation? J Appl Physiol 119(6):762–769CrossRef

Hwang P, Marroquín FEM, Gann J, Andre T, McKinley-Barnard S, Kim C et al (2018a) Eight weeks of resistance training in conjunction with glutathione and L-Citrulline supplementation increases lean mass and has no adverse effects on blood clinical safety markers in resistance-trained males. J Int Soc Sports Nutr 15(1):1–10CrossRef

Hwang P, Morales Marroquin FE, Gann J, Andre T, McKinley-Barnard S, Kim C et al (2018b) Eight weeks of resistance training in conjunction with glutathione and L-citrulline supplementation increases lean mass and has no adverse effects on blood clinical safety markers in resistance-trained males. J Int Soc Sports Nutr 15(1):30CrossRef

Inman LA, Rennie MJ, Watsford ML, Gibbs NJ, Green J et al (2018) Reference values for the creatine kinase response to professional Australian football match-play. J Sci Med Sport 21(8):852–857CrossRef

Jones AM, Vanhatalo A, Seals DR, Rossman MJ, Piknova B, Jonvik KL (2020) Dietary nitrate and nitric oxide metabolism: mouth, circulation, skeletal muscle, and exercise performance. Med Sci Sports Exerc 53(2):280–294CrossRef

Lucero AA, Addae G, Lawrence W, Neway B, Credeur DP, Faulkner J, Stoner L (2018) Reliability of muscle blood flow and oxygen consumption response from exercise using near-infrared spectroscopy. Exp Physiol 103(1):90–100CrossRef

Moinard C, Nicolis I, Neveux N, Darquy S, Benazeth S, Cynober L (2008) Dose-ranging effects of citrulline administration on plasma amino acids and hormonal patterns in healthy subjects: The citrudose pharmacokinetic study. Br J Nutr 99(4):855–862CrossRef

Owens DJ, Twist C, Cobley JN, Howatson G, Close GL (2019) Exercise-induced muscle damage: What is it, what causes it and what are the nutritional solutions? Eur J Sport Sci 19(1):71–85CrossRef

Perez-Guisado J, Jakeman PM (2010) Citrulline malate enhances athletic anaerobic performance and relieves muscle soreness. J Strength Cond Res 24(5):1215–1222CrossRef

Schwedhelm E, Maas R, Freese R, Jung D, Lukacs Z, Jambrecina A et al (2008) Pharmacokinetic and pharmacodynamic properties of oral L-citrulline and L-arginine: impact on nitric oxide metabolism. Br J Clin Pharmacol 65(1):51–59CrossRef

Sindelar JJ, Milkowski AL (2012) Human safety controversies surrounding nitrate and nitrite in the diet. Nitric Oxide 26(4):259–266CrossRef

Stamler JS, Meissner G (2001) Physiology of nitric oxide in skeletal muscle. Physiol Rev 81(1):209–237CrossRef

Takeda K, Machida M, Kohara A, Omi N, Takemasa T (2011) Effects of citrulline supplementation on fatigue and exercise performance in mice. J Nutr Sci Vitaminol 57(3):246–250CrossRef

Trexler ET, Persky AM, Ryan ED, Schwartz TA, Stoner L, Smith-Ryan AE (2019a) Acute effects of citrulline supplementation on high-intensity strength and power performance: a systematic review and meta-analysis. Sports Med 49(5):707–718CrossRef

Trexler ET, Keith DS, Schwartz TA, Ryan ED, Stoner L, Persky AM, Smith-Ryan AE (2019b) Effects of citrulline malate and beetroot juice supplementation on blood flow, energy metabolism, and performance during maximum effort leg extension exercise. The J Strength Cond Res 33(9):2321–2329CrossRef

Vanhoutte PM, Zhao Y, Xu A, Leung SW (2016) Thirty years of saying NO: sources, fate, actions, and misfortunes of the endothelium-derived vasodilator mediator. Circ Res 119(2):375–396CrossRef

Vårvik FT, Bjørnsen T, Gonzalez AM (2021) Acute effect of citrulline malate on repetition performance during strength training: a systematic review and meta-analysis. Int J Sport Nutrit Exer Metabol 1(aop):1–9

Wax B, Kavazis AN, Weldon K, Sperlak J (2015) Effects of supplemental citrulline malate ingestion during repeated bouts of lower-body exercise in advanced weightlifters. J Strength Cond Res 29(3):786–792CrossRef

Wax B, Kavazis AN, Luckett W (2016) Effects of supplemental citrulline-malate ingestion on blood lactate, cardiovascular dynamics, and resistance exercise performance in trained males. J Diet Suppl 13(3):269–282CrossRef

Wu JL, Wu QP, Huang JM, Chen R, Cai M, Tan JB (2007) Effects of L-malate on physical stamina and activities of enzymes related to the malate-aspartate shuttle in liver of mice. Physiol Res 56(2):213–220CrossRef

Title: A critical review of citrulline malate supplementation and exercise performance
Authors: Lewis A. Gough
S. Andy Sparks
Lars R. McNaughton
Matthew F. Higgins
Josh W. Newbury
Eric Trexler
Mark A. Faghy
Craig A. Bridge
Publication date: 01-12-2021
Publisher: Springer Berlin Heidelberg
Published in: European Journal of Applied Physiology / Issue 12/2021
Print ISSN: 1439-6319
Electronic ISSN: 1439-6327
DOI: https://doi.org/10.1007/s00421-021-04774-6

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A critical review of citrulline malate supplementation and exercise performance

Abstract

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