Carbohydrate loading, commonly referred to as carb-loading, or carbo-loading, is a strategy used by endurance athletes, such as marathoners and triathletes, to reduce fatigue during an endurance event by maximizing the storage of glycogen (or energy) in the muscles and liver.[1] Carbohydrate consumption is increased in the days before an endurance event.
Carbohydrate loading is generally recommended for endurance events lasting longer than 90 minutes.[2][3] Foods with low glycemic indices are generally preferred for carbo-loading due to their minimal effect on serum glucose levels. Low glycemic foods commonly include vegetables, whole wheat pasta, and grains. Many endurance athletes have large pasta dinners the night before an event. Since muscles also use amino acids extensively when functioning within aerobic limits, meals should also include adequate protein.[4] Large portions before a race can, however, decrease race-day performance if the digestive system has not had the time to process the food regimen.
Without depletion
editResearch in the 1980s led to a modified carbo-loading regimen that eliminates the depletion phase, instead calling for increased carbohydrate intake (to about 70% of total calories) and decreased training for three days before the event.[5]
Short workout
editA new carbo-loading regimen developed by scientists at the University of Western Australia calls for a normal diet with light training until the day before the race. On the day before the race, the athlete performs a very short, extremely high-intensity workout (such as a few minutes of sprinting) then consumes 12 g of carbohydrate per kilogram of lean mass over the next 24 hours. The regimen resulted in a 90% increase in glycogen storage when compared to before the carbo-load, which is comparable to or higher than the results achieved with other 2 day – 6 day carbo-loading regimes.[6]
Transient hypoglycemia
editCarbohydrate ingestion within 2 hours before aerobic exercise triggers elevated levels of insulin in the blood which may dramatically decrease serum glucose levels. This can limit aerobic performance, especially in events lasting longer than 60 minutes. This is known as transient or reactive hypoglycemia, and can be a limiting factor in elite athletes. Individuals susceptible to hypoglycemia are especially at risk for elevated insulin responses and thus will likely suffer from performance-limiting transient hypoglycemia if they do not follow the correct regimen.[7]
Diet composition
editThe composition of carbohydrates in the athlete's diet during carbohydrate loading is as important as their share of the overall caloric regimen .[citation needed]
Most dietary carbohydrates consist of varying proportions of two simple sugars, glucose and fructose. Fructose may be metabolized into liver glycogen[citation needed], but it is ineffective at raising muscle glycogen levels (which is the objective of carbohydrate loading).[citation needed] Consequently, sources of high-fructose carbohydrates, such as fruit and sugar-based foods, are less than optimal for the task. The classic carb-loading meal is pasta, whose caloric content is primarily due to starch, a polymer of glucose. Other high-starch meals which include bread, rice, and potatoes are also part of the correct regimen.
References
edit- ^ "The Science of Carbohydrate Loading". 21 June 2022. Archived from the original on 21 April 2022.
- ^ Mayo Clinic Staff. "Carbohydrate-loading diet". Mayo Clinic. Archived from the original on 30 April 2022. Retrieved 30 April 2022.
- ^ Jensen, Christopher D. "Carbohydrate Loading". Archived from the original on 2012-03-24.[unreliable medical source?]
- ^ Martini, Frederic H.; Timmons, Michael J.; Tallitsch, Robert B. (2008). Human Anatomy (6th ed.). Benjamin Cummings. p. 292. ISBN 978-0-321-50042-7.
- ^ Fitzgerald, Matt (September 2015). "The Evolving Art of Carbo-Loading".[unreliable medical source?]
- ^ Fairchild, TJ; Fletcher, S; Steele, P; Goodman, C; Dawson, B; Fournier, PA (June 2002). "Rapid carbohydrate loading after a short bout of near maximal-intensity exercise". Med Sci Sports Exerc. 34 (6): 980–6. doi:10.1097/00005768-200206000-00012. PMID 12048325. S2CID 23711139.[unreliable medical source?]
- ^ Fraser, Bev Lott & Blair. (2019). Physiology of Sports and Exercise. EDTECH. ISBN 978-1-83947-372-2. OCLC 1132386547.
Further reading
edit- Wax, Benjamin; Brown, Stanley P; Webb, Heather E; Kavazis, Andreas N; Kinzey, Steve (2011). "Effects of Carbohydrate Supplementation on Force Output and Time to Exhaustion during Static Leg Contractions Superimposed with Electromyostimulation". Journal of Strength and Conditioning Research. 26 (6): 1. doi:10.1519/JSC.0b013e318234ec0e. PMID 21912287. S2CID 43706133.
- Hawley, John A.; Schabort, Elske J.; Noakes, Timothy D.; Dennis, Steven C. (1997). "Carbohydrate-Loading and Exercise Performance". Sports Medicine. 24 (2): 73–81. doi:10.2165/00007256-199724020-00001. PMID 9291549. S2CID 11613942.
- Sedlock, Darlene A. (2008). "The Latest on Carbohydrate Loading: A Practical Approach". Current Sports Medicine Reports. 7 (4): 209–13. doi:10.1249/JSR.0b013e31817ef9cb. PMID 18607222. S2CID 1046337.
- Burke, Louise M.; Millet, Gregoire; Tarnopolsky, Mark A.; International Association of Athletics Federations (2007). "Nutrition for distance events". Journal of Sports Sciences. 25: S29–38. doi:10.1080/02640410701607239. PMID 18049981. S2CID 27239894.
- Bentley, David J.; Cox, Gregory R.; Green, Daniel; Laursen, Paul B. (2008). "Maximising performance in triathlon: Applied physiological and nutritional aspects of elite and non-elite competitions". Journal of Science and Medicine in Sport. 11 (4): 407–16. doi:10.1016/j.jsams.2007.07.010. PMID 17869183.
- Hatfield, Disa L.; Kraemer, William J.; Volek, Jeff S.; Rubin, Martyn R.; Grebien, Bianca; Gómez, Ana L.; French, Duncan N.; Scheett, Timothy P.; et al. (2006). "The Effects of Carbohydrate Loading on Repetitive Jump Squat Power Performance". The Journal of Strength and Conditioning Research. 20 (1): 167–71. doi:10.1519/R-18300.1. PMID 16503677. S2CID 38547333.
- Havemann, L.; West, SJ; Goedecke, JH; MacDonald, IA; St Clair Gibson, A; Noakes, TD; Lambert, EV (2006). "Fat adaptation followed by carbohydrate loading compromises high-intensity sprint performance". Journal of Applied Physiology. 100 (1): 194–202. doi:10.1152/japplphysiol.00813.2005. PMID 16141377. S2CID 7101399.
- Andrews, Jessica L.; Sedlock, Darlene A.; Flynn, Michael G.; Navalta, James W.; Ji, Hongguang (2003). "Carbohydrate loading and supplementation in endurance-trained women runners". Journal of Applied Physiology. 95 (2): 584–90. CiteSeerX 10.1.1.538.4614. doi:10.1152/japplphysiol.00855.2002. PMID 12716874.
- Bussau, Vanessa; Fairchild, Timothy; Rao, Arjun; Steele, Peter; Fournier, Paul (2002). "Carbohydrate loading in human muscle: An improved 1 day protocol". European Journal of Applied Physiology. 87 (3): 290–5. doi:10.1007/s00421-002-0621-5. PMID 12111292. S2CID 9875213.