Uric Acid and Nutrient Intake of Adolescent Soccer Players in Yogyakarta
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Abstract
The aim of this study was to view uric acid levels and nutrient intake of soccer players. This study examined the uric acid level differences based on nutrient intake of adolescent soccer players. Indeed, nutritional status monitoring is needed to evaluate health status which can contribute to athletes’ performance. This was an observational study conducted at SSB Real Madrid in April-September 2017. Subjects involved in this study were 27 active joined U-13 or U-16 in SSB Read Madrid UNY, Yogyakarta. Uric acid data were obtained by measuring peripheral blood sample. Nutrient intake data were obtained by using SQFFQ form. The differences in uric acid levels based on nutritional intake category were tested using ANOVA test. The average of uric acid levels were 6.72±1.21 mg/dl with average protein intake of 87.38±27.41 grams. The average of energy, fat, and carbohydrate intake was 2,189.02±464.87 kcal, 46.92±15.75 grams, and 365.61±82.32 grams. There was no difference in uric acid levels based on energy, protein, fat, and carbohydrates intake (p=0.216; p=0.489; p=0.587; and p=0.845) of adolescent soccer players. The clearance of uric acid, the amount and type of fluid intake, the type of animal protein, and the purine-source food probably contributed to athletes’ uric acid levels.
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References
Bangsbo, J. (2003). Physiology of training. In T. Reilly (Ed.), Science and Soccer (pp. 51–65). Liverpool, UK: Taylor & Francis e-Library.
Brandao, F., Fernandes, H. M., Alves, J. V., Fonseca, S., & Reis, V. M. (2014). Hematological and biochemical markers after a Brazilian Jiu-Jitsu tournament in world-class athletes. Rev Bras Cineantropom Desempenho Hum, 16(2), 144–151.
Choi, H. K., Liu, S., & Curhan, G. (2005). Intake of purine-rich foods, protein, and dairy products and relationship to serum levels of uric acid. Arthritis & Rheumatism, 52(1), 283–289. https://doi.org/10.1002/art.20761
de Souza Jr, T. P., de Oliveira, P. R., & Pereira, B. (2005). Physical exercise and oxidative stress effect of intense physical exercise on the urinary chemiluminescence and plasmatic malondialdehyde. Rev Bras Med Esporte, 11(1), 97–101.
Hoffman, J. R., & Falvo, M. J. (2004). Protein – Which is best? Journal of Sports Science and Medicine, 3, 118–130. Retrieved from http://www.jssm.org
Huang, L.-L., Huang, C.-T., Chen, M.-L., & Mao, I.-F. (2010). Effects of profuse sweating induced by exercise on urinary uric acid excretion in a hot environment. Chinese Journal of Physiology, 53(110), 254–261. https://doi.org/10.4077/CJP.2010.AMK060
Kandar, R., Stramova, X., Drabkova, P., & Krenkova, J. (2014). A monitoring of allantoin, uric acid , and malondialdehyde levels in plasma and erythrocytes after ten minutes of running activity. Physiol. Res., 63, 753–762.
Kementrian Kesehatan RI Direktorat Jenderal Bina Gizi dan Kesehatan Ibu dan Anak Direktorat Bina Gizi. (2011). Keputusan Menteri Kesehatan Republik Indonesia Nomor: 1995/MENKES/SK/XII/2010 tentang standar antropometri penilaian status gizi anak. Jakarta: Kementerian Kesehatan RI.
Metin, G., Atukeren, P., Alturfan, A. A., Gulyasar, T., Kaya, M., & Gumustas, M. K. (2003). Lipid peroxidation, erythrocyte superoxide-dismutase activity and trace metals in young male footballers. Yonsei Medical Journal, 44(6), 979–986.
Metin, G., Gumustas, M. K., Uslu, E., Belce, A., & Kayserilioglu, A. (2003). Effect of regular training on plasma thiols, malondialdehyde and carnitine concentrations in young soccer players. Chinese Journal of Physiology, 46(1), 35–39.
Morales, A. P., Maciel, R. N., Jorge, F. S., Neto, N. T. A., Cordeiro, D. de C., Viana, M. A. S., & de Oliveira, C. J. L. (2013). Changes in serum creatinine, uric acid, creatine kinase and glomerular filtration in street runners. Rev Bras Cineantropom Desempenho Hum, 15(1), 71–81. https://doi.org/10.5007/1980-0037.2013v15n1p71
Puspaningtyas, D. E., Afriani, Y., Mahfida, S. L., & Kushartanti, W. (2018). Effect of exercise on lipid peroxidation in student soccer players, 50(1), 91–100.
Sariri, R., Damirchi, A., & Nazari, Y. (2013). Salivary antioxidant variations in athletes after intense exercise. Medicina Sportiva, IX(1), 2043–2050.
Saw, A. E., Main, L. C., & Gastin, P. B. (2016). Monitoring the athlete training response: subjective self-reported measures trump commonly used objective measures: a systematic review. Br J Sports Med, 50, 281–291. https://doi.org/10.1136/bjsports-2015-094758
Tipton, K. D., & Wolfe, R. R. (2001). Exercise, protein metabolism, and muscle growth. International Journal of Sport Nutrition and Exercise Metablism, 11, 109–132.
Valado, A., Pereira, L., Tavares, P. C., & Ribeiro, C. F. (2007). Effect of the intense anaerobic exercise on nitric oxide and malondialdehyde in studies of oxidative stress. International Journal of Biology and Biomedical Engineering, 1(1), 32–36.
Waring, W., Convery, A., Mishra, V., Shenkin, A., Webb, D., & Maxwell, S. (2003). Uric acid reduces exercise-induced oxidative stress in healthy adults. Clinical Scienc, 105, 425–430.
Wijaya, M. Q. A., & Riyadi, H. (2015). Konsumsi suplemen atlet remaja di SMA Ragunan Jakarta. J. Gizi Pangan, 10(1), 41–48.
Wu, G. (2016). Dietary protein intake and human health. Food Funct, 7, 1251–1265. https://doi.org/10.1039/c5fo01530h
Zhao, S., Snow, R. J., Stathis, C. G., Febbraio, M. A., & Carey, M. F. (2000). Muscle adenine nucleotide metabolism during and in recovery from maximal exercise in humans. J Appl Physiol, 88, 1513–1519.