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Commentary on The Optimum Composition for Endurance Sports Drinks

David S Rowlands

Sportscience 10, 71-73, 2006 (sportsci.org/2006/dsr.htm)
Institute of Food, Nutrition and Human Health, Massey University, Wellington, New Zealand. Email.
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Sports drinks containing carbohydrate, electrolytes, and fluid are widely recommended for use by endurance athletes during competition and training. Fluid replacement probably improves performance by off setting the disturbances to cardiovascular function associated with dehydration (e.g. elevated blood pressure and modified distribution, impaired thermoregulation), while carbohydrate  ingestion may aid performance by attenuating liver and skeletal-muscle glycogen depletion. Carbohydrate and fluid have been found to independently improve endurance performance, and there appears to be some synergism in their action (Coombes and Hamilton, 2000). The electrolyte sodium may enhance water and glucose intestinal absorption, and help to replace sweat losses by retention of extracellular-fluid sodium homeostasis. Hopkins and Wood provide an up-to-date summary of the physiological rationale for sports drinks and present the likely best average composition for most events of about one hour duration or more: composite carbohydrate (fructose or sucrose and glucose polymers), sodium chloride at a palatable concentration, and fluid.

In the absence of hard data to the contrary, we can assume that more is better, so the carbohydrate composite could be ingested at a rate aimed at maximizing delivery to the circulation, oxidation, and subsequent endogenous-carbohydrate sparing; there is evidence, although variable, for the latter (e.g., Jentjens et al., 2006; Jentjens and Jeukendrup, 2005; Jentjens et al., 2004). Oxidation rates for ingested carbohydrate of up to 1.5 g per minute can be expected with the ingestion of around 72 g glucose polymer (maltodextrin) and 36 g fructose per hour (Wallis et al., 2005). The ingestion scheme will approximately double carbohydrate delivery compared with even the high-end previous recommendation of 50-60 g per hour, and retain drink osmolality around isotonic levels (280-300 mOsm) avoiding the reduction in gastric emptying, fluid uptake, and risk of GI distress with osmolalities >500 (Brouns and Kovacs, 1997).

While the ingestion of fluid or carbohydrate-containing beverages compared with nothing or water only generally improves endurance performance (for reviews see Brouns and Kovacs, 1997; Coombes and Hamilton, 2000), there is no conclusive evidence to date that one drink formulation is better than another. This uncertainty is due largely to a lack of appropriately designed and controlled studies specifically aimed at determining the effect of drink composition on performance. Additionally, there is no performance data I have been able to find on the effects of composite carbohydrate formulations ingested at high rates and concentrations vs appropriate controls. Consequently, both those of Hopkins and Wood and the pool of present guidelines for sports drink formulations (e.g., Brouns and Kovacs, 1997; Coombes and Hamilton, 2000; Coyle, 1994; Gisolfi and Duchman, 1992) are based largely on interpolation of a performance benefit based on physiological correlates. With the exception of a negative effect of fructose in isolation and in high concentrations (e.g., Maughan et al., 1989), as far as we know there is no difference in the effectiveness of one formulation over another. More publications would be welcomed in this area.

Hopkins and Wood, citing Nancy Rehrer (2001), propose that in events of increasing duration from 2 to 8 hours, sodium concentration might be increased from 20 to 40-50 mM. This recommendation is due in part from the concern about the (rare) occurrence of hyponatremia (plasma [Na+] <130 mM) during prolonged exercise with high levels of fluid ingestion. Commercial sports drink formulations promote greater voluntary consumption than that of water, which is viewed as positive under the paradigm where any dehydration is negative. Under circumstances of high sweat rates sustained for several hours or more, the consumption of large amounts of sports drinks to meet fluid needs containing 20 mM NaCl (1.17 g/L) may, however, be insufficient to maintain plasma sodium concentrations, which might increase the chance of hyponatremia. In this instance, the higher sodium intake may be better (Rehrer, 2001), or perhaps more simply consuming less sports drink which can have the added benefit of increased power-to-weight ratio. Such functional dehydration with intakes less than that required to maintain body weight is common in elite endurance athletes such as marathon runners and triathletes and is rarely a health risk (Noakes, 1995). Tolerance to dehydration is probably improved through exposure during training and may have downstream benefits to haematology–plasma volume expansion and erythropoiesis, as alluded to in the article.

The main function of sodium in sports drinks is not to prevent hyponatremia, but rather to enhance palatability and promote water and glucose absorption (Gisolfi and Duchman, 1992). Many commercial sports drinks also contain other salts, such as, potassium chloride and magnesium sulphate. Hopkins and Wood did not include other electrolytes in their optimal drink. As far as I am aware, there is presently only a theoretical argument for the inclusion of potassium. Interested readers are referred to Cunningham (1997). The most attractive justification for the inclusion of potassium in sports drinks (usually 2-5 mM) is that losses in sweat contribute to a relative exercising plasma hypokalemia (low potassium). Normally potassium concentration in the extracellular fluid (at rest 4.0-4.5 mM) increases during heavy exercise (Sejersted, 1992), owing to efflux of potassium from muscle fibers exceeding the capacity the sodium-potassium pump to restore ion gradients. This exercise-induced hyperkalemia (e.g., 5-7 mM) may stimulate sodium-potassium pump activity and is probably a key regulator of breathing during exercise. Hence, potassium losses in sweat coupled with dilution of extracellular-fluid potassium concentration with low-potassium beverages may be linked to physiological processes that act to hinder endurance performance.

So while Hopkins and Wood propose an optimal formulation, which is not too dissimilar to most commercially-available products, we still do not know what combination of ingredients are actually better for performance. Nor do we know if the quantity and quality of carbohydrate, salt, and fluid actually matters. With evidence of a possible oral sugar sensor facilitating performance in response to a mouthwash (Carter et al., 2004) and the lack of any consistent pattern as to the effects of carbohydrate type or electrolytes in the studies that have made it to publication (Coombes and Hamilton, 2000), it may not matter what carbohydrate-electrolyte beverage the athlete ingests, providing it contains a reasonable amount of fluid to offset dehydration to a level that does not adversely affect performance (probably <2% body weight loss) and some carbohydrate. Whether salts are a necessary component of sports drinks to enhance performance remains to be determined.

 

Brouns F, Kovacs E (1997). Functional drinks for athletes. Trends in Food Science Technology 8, 414-421

Carter JM, Jeukendrup AE, Jones DA (2004). The Effect of Carbohydrate Mouth Rinse on 1-h Cycle Time Trial Performance. Medicine and Science in Sports and Exercise 36, 2107-2111

Coombes JS, Hamilton KL (2000). The effectiveness of commercially available sports drinks. Sports Medicine 29, 181-209

Coyle EF (1994). Fluid and carbohydrate replacement during exercise: how much and why? Sports Science Exchange 7

Cunningham JJ (1997). Is potassium needed in sports drinks for fluid replacement during exercise? . International Journal of Sports Nutrition and Exercise Metabolism 7, 154-159

Gisolfi CV, Duchman SM (1992). Guidelines for optimal replacement beverages for different athletic events. Medicine and Science in Sports and Exercise 24, 679-687

Jentjens R, Underwood K, Achten J, Currell K, Mann CH, Jeukendrup AE (2006). Exogenous carbohydrate oxidation rates are elevated after combined ingestion of glucose and fructose during exercise in the heat. Journal of Applied Physiology 100, 807-816

Jentjens RL, Jeukendrup AE (2005). High rates of exogenous carbohydrate oxidation from a mixture of glucose and fructose ingested during prolonged cycling exercise. British Journal of Nutrition 93, 485-492

Jentjens RLPG, Venables MC, Jeukendrup AE (2004). Oxidation of exogenous glucose, sucrose, and maltose during prolonged cycling exercise. Journal of Applied Physiology 96, 1285-1291

Maughan RJ, Fenn CE, Leiper JB (1989). Effects of fluid, electrolyte and substrate ingestion on endurance capacity. European Journal of Applied Physiology 58, 481-486

Noakes TD (1995). Dehydration during exercise: what are the real dangers? Clinical Journal of Sport Medicine 5, 123-128

Rehrer NJ (2001). Fluid and electrolyte balance in ultra-endurance sport. Sports Medicine 31, 701-715

Sejersted OM (1992). Electrolyte imbalance in body fluids as a mechanism of fatigue during exercise. In: Lamb DR, Gisolfi CV (editors) Energy Metabolism (Perspectives in exercise science and sports medicine.). Dubuque, IA: Brown and Benchmark, 149-205

Wallis GA, Rowlands DS, Shaw C, Jentjens RLPG, Jeukendrup AE (2005). Oxidation of combined ingestion of maltodextrins and fructose during exercise. Medicine and Science in Sports and Exercise 37, 426-432

 

Published Jan 2007.
©2006

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