Carbohydrates for Endurance

Reviewed and Updated by ERB member Neal Henderson, MS CSCS

Intro: Energy for endurance exercise is fueled by fats and carbohydrates, with carbohydrate utilization increasing as the intensity of the exercise increases. Thus, carbohydrates are crucial to competitive endurance exercise performance. In addition to food based carbohydrates, there are many different energy supplements marketed for sport, which are available in a variety of forms. These carbohydrate supplements are available as a result of demand based upon experiential and research based evidence, but understanding when your body needs each carb in which amount depends on three key areas: capacity, conversion and type.

Capacity: At rest, the human body typically has enough carbohydrates to fuel 3 hrs of exercise at a rate of 10-12 kcal/minute (600-700 kcal/hour) which includes blood, muscle, and liver glycogen stores totaling 1,520 to 2,020kcal. The conversion of carbohydrates to energy is highly efficient compared to fats and protein. Thus, carbohydrates are a great fuel source, but our storage capacity, even with training, is generally insufficient to meet the demands of competitive endurance sports.

Conversion: The ability to rapidly replenish carbohydrates after training, and the ability to consume and convert ingested carbohydrates into a usable form of carbohydrate is important in allowing you to train and compete at the your best. Ingestion of the wrong carbohydrates at the wrong time, or ingesting too little carbohydrate can impair performance both in the short term and long term. Consuming a slowly digested carbohydrate during times where the body is at, or above threshold can lead to disaster. During times where you exercise or race at and above your threshold, your blood circulation is focused on the working muscles and away from the stomach. This makes digestion of foods difficult. In fact, consuming a slowly absorbed sugar during these times will slow gastric emptying (the emptying of fluids and foods from the stomach to the blood stream) and in essence block fluids from being absorbed. This can actually cause dehydration.

The amount of dietary carbohydrate needed to fuel daily training is equally important to the type of carbohydrate that an athlete eats. Unfortunately glycogen stores in both the liver and muscle as well as blood glucose are limited. These stores are often substantially lower than the fuel requirements of many athletes’ daily training programs. Therefore eating adequate amounts of carbohydrate throughout the day and surrounding endurance training is critical to performance.

IE: You are in the middle of a long (3 hour) workout and feel good because you are consuming plenty of carbohydrates and fluids during this time. In the latter half of your workout you notice the urge to constantly urinate. You think ‘this is good, this means I am properly hydrated’. Soon you begin to cramp and your performance dramatically goes down-hill. What actually happened is, your body was not able to properly absorb the slow carbohydrates, slowing gastric emptying and causing dehydration and electrolyte imbalance. Eating the right carbohydrates at the right time is critical. Note: during workouts well below threshold there is still enough blood going to the stomach where absorption is considerably easier.

Type: The biochemical structure of the carbohydrate, the absorption process, the size of the food particle, the degree of processing, the contents and timing of the previous meal, and the co-ingestion of fat, fiber, or protein affect a carbohydrates absorption and glycemic index. (Guezennec, 1995). Trial and error is the only real way to test a product or foods digestibility. Below are some guidelines to further educate you.

What is the glycemic index? Based on a 50g portion size, the glycemic index (GI) of a carbohydrate represents the magnitude of the increase in blood sugar that occurs after ingestion of the carbohydrate. What glycemic index does not define is the portion size of the carbohydrate meal ingested (whether the portion size is 5g or 500g GI is not affected), but portion size can affect blood sugar. Carbohydrates with a higher GI are easily digested and cause a higher rush of sugar into your blood than carbohydrates with low GI. Elevated blood sugar causes insulin to be secreted to help modulate the sugar and a subsequent sugar crash follows. Glycemic Load measures the GI multiplied by the total carbohydrate content giving a more practical and accurate determination of blood sugar response. A complete list of GI for foods can be found at http://diabetes.about.com/library/mendosagi/ngilists.htm

Although the glycemix index (GI) may have implications for the athlete surrounding training, it is not a universal system to rank carbohydrate rich foods. A number of other attributes of foods may be of value to the athlete like nutritional content, gastric comfort, or palatability. In addition, a variety of factors affect the GI of different foods such as degree of processing, presence of fructose or lactose, presence of fat or protein, and the amount of food eaten. Furthermore individuals can have a different glucose response to the same food. Recent data demonstrates that the there is more to the metabolic response of common breakfast cereals than just the glycemic index (Schenk et al., 2003). It will be interesting to see further research on this topic and its application to athletes.

How do sugars differ? Conventional wisdom says that since all carbohydrates are eventually digested and absorbed as glucose, the original food source of the sugar, whether a bean or a candy bar, matters little. Sugar is sugar. Sucrose is sucrose. Not exactly! Fructose has a GI of 20±5 and is a simple sugar (monosaccharide) like glucose and galactose. Natural sources of fructose include honey and fruits. Fructose is 75% sweeter than glucose and is generally found in honey and fruits in addition to its many uses as a food-sweetening additive. It is absorbed more slowly into the bloodstream than straight glucose and sucrose and, therefore, has a less erratic effect on blood sugar levels (at rest). Diabetics or those that are very sensitive to changes in blood sugar find fructose to be advantageous. But, as a result of its slow absorption, beverages that contain fructose can cause gastric upset and slow gastric emptying. Research suggests that fructose is more tolerable when combined with sucrose and glucose. Avoid beverages that list “high fructose corn syrup” as primary ingredients as they will slow fluid uptake and not provide optimal sugars to support exercise energy requirements. As a pre-exercise meal, or between workouts, fructose is an excellent source of carbohydrates.

Galactose is a simple sugar that has recently shown up in sports drinks. Lactose is the primary sugar in dairy products and is composed of one molecule of glucose and one of galactose. Because of its galactose content, it is more slowly absorbed into the bloodstream than pure glucose and is therefore more blood-sugar-friendly. *The GI of Galactose could not be found on any of the official GI lists, though G-Push (a popular sports drink) does claim that Galactose is absorbed quickly like glucose without a subsequent increase in insulin release. This is not confirmed with clinical studies.

Glucose: In terms of immediate use of carbohydrate within the body, glucose (a monosaccharide) with a GI of 99±3 is the most important. Glucose can be directly absorbed by the small intestine and directly transported to the cells to be metabolized. Glucose can also be stored as glycogen (chains of glucose) within muscles and the liver, and can also be converted to fats for energy storage. During exercise, consumption of glucose allows the body to maintain an adequate supply of carbohydrate for metabolism. Glucose is often called dextrose when it is added to foods. The body eventually breaks down all sugars and carbohydrates into glucose, which is the form in which sugar enters cells to be used for energy. During times of exercise at or above threshold, glucose can be easily digested.

Sucrose with a GI of 68±5 (otherwise known as table sugar) is composed of one molecule of glucose and one molecule of fructose. This is the white sugar that comes in many forms, such as powdered or granulated. It is usually made from refining extracts of sugar beets or sugar cane.

Maltodextrin aka Glucose polymers GI=99±3:
Lactose GI=46±2
Maltose GI=105±12
Honey GI=55±5
Gatorade® GI=78±13

Why is glycemic index important? From the corresponding graph it is clearly evident that the GI can affect your primary fuel supply quite dramatically (this graph is at rest). Consuming a high GI carbohydrate immediately before a race or workout can cause your blood sugar to spike, then quickly fall below optimal levels, while a low GI carbohydrate can help stabilize your energy release. Your body’s physiological response to carbohydrates differs considerably before, during and after your workouts, making it critical to choose the appropriate fuel for the appropriate response. (more on this in our recommendation section)

Recommendations: The depletion of carbohydrate stores within the body leads to bonking which hinders your ability to race and/or train hard. The ability to rapidly replenish carbohydrates after training, and the ability to consume and convert ingested carbohydrates into a usable form of carbohydrate is important in allowing you to train and compete at the your best. Ingestion of the wrong carbohydrates at the wrong time, or ingesting too little carbohydrate can impair performance both in the short term and long term.

Before: The most important pre exercise consideration is to make sure you have topped off your carbohydrate stores. The second thing to consider is making certain you DO NOT consume high GI foods or drinks just prior to racing. Consumption of lower GI foods 30-60 min prior to an endurance exercise bout tends to promote some positive effects during exercise including: 1) Minimizing the hypoglycemia that occurs at the start of exercise. 2) Increasing the concentration of fatty acids in the blood. 3) Increases fat oxidation and reducing reliance on carbohydrate fuel. This carbohydrate sparing prolongs your endurance and helps prevent the ‘bonk’. Adding fats, fiber and protein to a food or meal can help reduce the GI of that meal.

During: The GI of a food consumed during exercise is probably less important than at other times because the insulin response to carbohydrate ingestion is suppressed during exercise. Much research has focused on carbohydrate drinks and foods during exercise to slow the depletion of the body’s carbohydrate stores and thus delay the onset of fatigue. Exercise-induced elevation in epinephrine depresses the release of insulin from the pancreas. Thus, concerns about carbohydrate feedings increasing insulin and depressing fatty acid availability is less likely to occur when carbohydrate is fed during exercise. The jury is still out on the ideal type of carbohydrates during exercise, though in theory since insulin is modulated and high GI carbohydrates enter the blood stream quicker, it makes sense to stick to a high GI carbohydrate. Exercising at or above threshold can dramatically reduce your body’s ability to properly digest foods (due to the pooling of blood to the exercising muscle). During these times it is best to consume carbohydrates and foods that are easily digested = High GI. The best advise is to stick to what you are used to.

A recent research study has indicated that during a time trial effort, a carbohydrate drink mouth rinse (not consumption) actually improved performance during a 1-hour cycle TT. The authors feel that additional motivation that occurred when having a mouth rinse with a carbohydrate drink might have provided the benefit compared to a water only rinse. This might be most important for athletes perfoming a very high intensity effort where ingesting drinks may be challenging.

After: Following exercise your primary concern is to replenish lost glycogen stores. The ability to replenish these stores fully determines how ready you will be the next day for another workout. It is at this time where a high GI carbohydrate has the ability to shuttle glycogen into the cell quicker and more efficiently than low or moderate GI carbohydrates. If you have access to a high GI carb, then grab it, if not grab any carbohydrate you can get your hands on and swallow it down with water. Protein and high levels of Glutamine have been shown to improve glycogen resynthesis more than carbohydrates alone.

Glucose Regulation: While the availability of carbohydrate for use within the cells is extremely important, much of the regulation of glucose concentration rests not solely with the type of carbohydrates ingested, but in the hormonal regulation of glucose. Among the hormones that are especially important to glucose concentrations are insulin, glucagon, epinephrine, and cortisol. Exercise, in addition to carbohydrate type and timing of ingestion, also modulates the release of these hormones. As you can see, there’s a whole lot more to carbohydrate than just simple sugars and complex carbohydrates. One of the more important tools that an athlete can use to differentiate the potential impact that a given type of carbohydrate will have on insulin release and subsequent carbohydrate uptake (especially when not exercising) is the glycemic index (GI). Foods with a higher glycemic index will be broken down into glucose faster, and will cause a greater surge in insulin release, which works to speed the transport of glucose into the cells. Foods with a lower glycemic index will more slowly be converted to glucose, and will cause a smaller release of insulin. Immediately before exercise and when resting, you should consume more foods with a lower glycemic index. During exercise, and immediately after exercise, it is better to consume foods with a higher glycemic index. Overall, many nutritionists will suggest that the GI is just splitting hairs, and that consuming adequate carbohydrate is most important. If you’ve already got the right amount, though, getting the right type can help boost your performance to the next level! (Neal Henderson MS CSCS)

Timing and type of CHO intake: One must also consider the timing of consumption to be crucial to the supplement’s effectiveness. Pre exercise it is very important to maximize muscle glycogen stores. Carbohydrates are most beneficial during exercise bouts greater than 30 minutes in length. Remember that more of a good thing is not always better. Too much sugar too fast will decrease absorption of fluids and carbohydrates and will cause GI distress and bloating/cramping. Properly formulated sports drinks (6% carbohydrate or 14g/8oz) are more rapidly absorbed and are more effective at replacing fluids than water, soft drinks or juice. Gatorade Sport Science recommends supplementing 30-60 grams of carbohydrates per hour of exercise (Coggan & Coyle, 1991; Murray et al., 1991). This is equivalent to 32 – 64 ounces of a 6% sports drink per hour. Consuming carbohydrates in liquid form is optimal for absorption during endurance exercise because it not only ensures rehydration but also a more consistent sugar concentration than sugars in solid form. Gels are another option and should be used consistently during exercise with fluids to avoid the pitfalls of the blood sugar rollercoaster.(Sally Warner MA Ph.D.)

References:
Brand Miller, J.C. (1994). Importance of glycemic index in diabetes. Am. J. Clin. Nutr. 59:747S-752S.

Brouns, F., W.H.M. Saris, E.H. Beckers, et al (1989). Metabolic changes induced by sustained exhaustive cycling and diet manipulation. Int. J. Sports Med. 10:549-62.

Burke, L.M., G.R. Collier, S.K. Beasley, P.G. Davis, P.A. Fricker, P. Heeley, K. Walder, and M. Hargreaves (1995). Effect of coingestion of fat and protein with carbohydrate feedings on muscle glycogen storage. J. Appl. Physiol. 78:2187-2192.

Burke, L.M., G.R. Collier, and M. Hargreaves (1993). Muscle glycogen storage after prolonged exercise: effect of the glycemic index of carbohydrate feedings. J. Appl. Physiol. 75:1019-1023.

Carter, J.M. A.E. Jeukendrup, and D.A. Jones (2004). The effect of carbohydrate mouth rinse on 1-h cycle time trial performance. Med. Sci. Sports Exerc. 12: 2107-2111.

Coggan, A.R., and E.E Coyle. Carbohydrate ingestion during prolonged exercise: effects on metabolism and performance. Exerc. Sports Sci. Rev. 19: 1-40, 1991.

Craig, B.W. (1993). The influence of fructose feeding on physical performance. Am. J. Clin. Nutr. 58:815S-819S.

Costill, D.L., W.M. Sherman, W.J. Fink, C.Maresh, M. Witten, and J.M. Miller (1981). The role of dietary carbohydrates in muscle glycogen resynthesis after strenuous running. Am. J. Clin. Nutr. 34:1831-1836.

Foster, C., D.L. Costill, and W.J. Fink (1979). Effects of preexercise feedings on endurance performance. Med. Sci. Sports Exerc. 11:1-5.

Foster-Powell, K. and J. Brand Miller (1995). International tables of glycemic index. Am. J. Clin. Nutr. 62:871S-893S.

Flynn, M.G., D.L. Costill, J.A. Hawley, W.J. Fink, P.D. Neufer, R.A. Fielding, and M.D. Sleeper (1987). Influence of selected carbohydrate drinks on cycling performance and glycogen use. Med. Sci. Sports Exerc. 19:37-40.

Goodpaster, B.H., D.L. Costill, W.J. Fink, T.A. Trappe, A.C. Jozsi, R.D. Starling, S.W. Trappe (1996). The effects of pre-exercise starch ingestion on endurance performance. Int. J. Sports Med. 17:366-372.

Guezennec, C. (1995). Oxidation rates, complex carbohydrates and exercise. Sports Med. 19:365-372.

Guezennec, C.Y., P. Satabin, F. Duforez, J Koziet, J.M. Antoine (1993). The role of type and structure of complex carbohydrates response to physical exercise. Int. J. Sports Med. 14:224-231.

Holt, S., J. Brand, C. Soveny, and J. Hansky (1992). Relationship of satiety to postpreprandial glycaemic, insulin and cholescystokinin responses. Appetite 18:129-141.

Horowitz J.F. and E.F. Coyle (1993). Metabolic responses to preexercise meals containing various carbohydrates and fat. Am. J. Clin. Nutr. 58:235-241.

Jenkins, D.J., T.M. Wolever, G.R. Collier, A.Ocana, A.Venketeshwer Rao, G. Buckley, Y.Lam, A.Mayer, and L.U. Thompson (1987). Metabolic effects of a low-glycemic-index diet. Am. J. Clin. Nutr. 46:968-975.

Jozsi, A.C., T.A. Trappe, R.D. Starling, B.Goodpaster, S.W. Trappe, W.J. Fink, D.L. Costill (1996). The influence of starch structure on glycogen resynthesis and subsequent cycling performance. Int. J. Sports Med. 17:373-378.

Kiens, B. A.B. Raven, A.K. Valeur and E.A. Richter (1990). Benefit of dietary simple carbohydrates on the early postexercise muscle glycogen repletion in male athletes (abstract). Med. Sci. Sports Exerc. 22:S88.

Kiens, B., and E.A. Richter (1996). Types of carbohydrate in an ordinary diet affect insulin action and muscle substrates in humans. Am. J. Clin. Nutr. 63:47-53.

Kirwan, J.P., D. O’Gorman, D. Campbell, G. Sporay, and W.J. Evans (1996). A low glycemic meal 45 minutes before exercise improves performance (abstract). Med. Sci. Sports Exerc. 28:S129.

Massicotte, D., F. Peronnet, C. Allah, C. Hillaire-marcel, M. Ledux, G. Brisson. (1986). Metabolic response to [13C]glucose and [13C]fructose ingestion during exercise. J. Appl. Physiol. 61:1180-1184.

Murray, R., G.L. Paul, J.G. Seifert, D.E. Eddy, and G.A. Halaby (1989). The effects of glucose, fructose, and sucrose ingestion during exercise. Med. Sci. Sports Exerc. 21:275-282.

Murray, R., G.L. Paul, J.G. Seifert, and D.E. Eddy. Responses to varying rates of carbohydrate ingestion during exercise. Med. Sci. Sports Exerc

Robergs, R.A. (1991). Nutrition and exercise determinants of postexercise glycogen synthesis. Int. J. Sport Nutr. 1:307-337.

Schenk, S., Davidson, C.J., Zderic, T.W., Byerley, L.O., & Coyle, E.F. (2003). Different glycemic indexes of breakfast cereals are not due to glucose entry into the blood but to glucose removal by the tissue. American Journal of Clinical Nutrition, 78, 742-748.

Sherman, W.M. (1991). Carbohydrate feedings before and after exercise. In: D.R. Lamb and M.H. Williams (eds.) Perspectives in Exercise Science and Sports Medicine, Vol. 4: Ergogenics: Enhancement of Performance in Exercise and Sport. Indianapolis: Benchmark Press, pp. 1-34.

Thomas, D.E., J.R. Brotherhood and J.C. Brand (1991). Carbohydrate feeding before exercise: effect of glycemic index. Int. J. Sports Med. 112:180-186.

Thomas, D.E., J.R. Brotherhood and J.Brand Miller (1994). Plasma glucose levels after prolonged strenuous exercise correlate inversely with glycemic response to food consumed before exercise. Int. J. Sport Nutr. 4:361-373.

Walberg-Rankin, J. (1995). Dietary carbohydrate as an ergogenic aid for prolonged and brief competitions in sport. Int. J. Sport Nutr. 5 (suppl.):513-528.

Zawadzki,. K.M., B.B. Yaspelkis, and J.L. Ivy (1992). Carbohydrate-protein complex increases the rate of muscle glycogen storage after exercise. J.Appl. Physiol. 72:1854-1859.

Glycemic Index scores: http://diabetes.about.com/library/mendosagi/ngilists.htm

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