Publication: 補充支鏈胺基酸與精胺酸對連續兩天籃球比賽體能與技術表現之影響
| dc.contributor.advisor | 張振崗 | |
| dc.contributor.advisor | Chang, Chen-Kang | |
| dc.creator | 邱名穗 | |
| dc.creator | Chiu, Ming-Sui | |
| dc.date | 2012 | |
| dc.date.accessioned | 2017-02-27T07:56:51Z | |
| dc.date.accessioned | 2025-07-30T15:34:17Z | |
| dc.date.available | 2017-02-27T07:56:51Z | |
| dc.date.issued | 2017-02-27T07:56:51Z | |
| dc.description | 學位類別:碩士 | |
| dc.description | 校院名稱:國立臺灣體育運動大學 | |
| dc.description | 系所名稱:運動健康科學系碩士班 | |
| dc.description | 學號:19906010 | |
| dc.description | 畢業學年度:100年 | |
| dc.description | 論文頁數:102頁 | |
| dc.description.abstract | 支鏈胺基酸(branched–chain amino acids, BCAA)與精胺酸(arginine, Arg)具有多重生理功能,補充BCAA可能可以降低游離色胺酸(free tryptophan)進入腦部,減少腦部血清素(serotonin)形成,進而延緩中樞疲勞;亦可能刺激胰島素分泌,促進肌肉蛋白質合成,與減少肌肉異化作用,進而減少運動後肌肉損傷。補充Arg可能可以藉由合成一氧化氮(nitric oxide),刺激血管擴張及血流量增加,進而加速代謝產物的移除;亦可能促進尿素循環,增加將氨轉換成尿素。目的:本研究目的為探討合併補充BCAA與Arg,對連續二天籃球模擬比賽之專項體能表現、投籃命中率、技術測驗及運動後肌肉損傷的影響。方法:以11名甲二級大學男子籃球校隊為研究對象,採隨機交叉設計,每次測試為期二天。於運動前1小時補充0.17 g/kg BCAA與0.04 g/kg Arg(AA測試)或安慰劑(placebo測試)。運動測試以間歇性運動型態模擬籃球比賽,上、下半場各20分鐘,中場休息15分鐘,上、下半場各2節,每節10分鐘,每節包括連續10次跳、四線折返衝刺、底線衝刺跳投、Z字防守後跳投、罰球10顆、禁區組合運動、全場組合運動、5方向投籃及6次邊線折返跑;記錄各項時間與投籃命中率,以評估體能表現與投籃技術表現。並於運動前、中場休息及運動後進行體能測驗,包括反動作跳測量(counter movement jump)與技術測驗(包括球員挑戰運球、過人、傳球、上籃、投籃等專項技術)。運動前與每節運動後詢問自覺量表(Ratings of Perceived Exertion)。於第一天運動前、後及運動後2小時,與第二天運動前、後,採取靜脈血液樣本,分析血漿肌酸激酶、乳酸脫氫酶、乳酸、氨、尿素、葡萄糖、甘油、非酯化脂肪酸、睪固酮、皮質固醇濃度。結果:AA測試於第二天第三節的籃球專項體能表現顯著快於placebo測試,第二天第四節呈現快於placebo測試的趨勢;投籃命中率與技術測驗在二測試間無顯著影響。血液生化值部分,AA測試兩天之血漿尿素濃度曲線下增加面積均呈現高於placebo測試的趨勢;而肌酸激酶、乳酸脫氫酶、乳酸、氨、葡萄糖、甘油與非酯化脂肪酸、睪固酮、皮質固醇濃度在二測試間則無顯著差異。結論:籃球選手於運動前合併補充BCAA與Arg,可能可提升連續天的比賽中,第二天運動後期的籃球專項體能表現,且補充Arg可能可以增加將運動期間產生的氨轉換成尿素;但對投籃等技術表現、能量代謝、肌肉損傷及自覺疲勞程度則無顯著影響。補充BCAA與Arg可能可以讓受測者在相同的自覺疲勞程度下,達到更佳的體能表現,但對中樞疲勞的影響機轉,仍需要進一步研究。 | |
| dc.description.abstract | Branched-chain amino acids (BCAA) and arginine (Arg) have multiple physiological functions that may improve exercise performance. BCAA supplementation could suppress central fatigue by reducing the entry of free tryptophan, the precursor for serotonin, to the brain. BCAA can also stimulate insulin secretion, muscle protein synthesis, reduce muscle catabolism and reduce post-exercise skeletal muscle damage. Arg supplementation may stimulate endothelium-dependent vasodilation by increasing nitric oxide synthesis, resulted in the accelerated removal of the metabolites that may influence exercise performance. Objective: The purpose of this study was to investigate the effects of BCAA and Arg supplementation on basketball-specific physical performance, shooting, skill test and muscle damage in two consecutive days of simulated basketball games. Methods: Eleven male basketball players from a Division II university were recruited as the subjects. The study used a randomized cross-over design. Each trial contained two days. The subjects consumed either 0.17g/kg BCAA and 0.04g/kg Arg (AA trial) or placebo (placebo trial) 1 hour before the exercise test. The exercise test was a simulated basketball game with 20 min in each half and a 15-min rest in between. Each half contains 2 10-min periods with a 2-min rest in between. Each quarter includes 10 consecutive jumps, ladder suicide sprint, baseline jump shots, foul-line jump shots, free-throw shooting, key combination, full court combination, 5 directions shooting, and 6 court-width sprints. The time required to finish each tasks and the shooting percentage were recorded as the marker for basketball-specific physical performance and shooting skills, respectively. A counter movement jump test was performed before and after the simulated game, as well as at the half-time. A skill test, including dribbling, passing, layups and shooting was performed before and after the game and the time required to finish the test was recorded. The Ratings of Perceived Exertion were recorded before, at the half-time, and after the game. Blood samples were collected from the antecubital vein before, after, and 2 hours after the first simulated game, and before and after the second simulated game. The plasma concentrations of creatine kinase, lactate dehydrogenase, lactate, ammonia, urea, glucose, glycerol, non-esterified fatty acid, testosterone and cortisol were measured. Results: The time required to finish the task in AA trial was significantly decreased in the third period, while it showed a trend of decrease in the fourth period, compared to placebo trial. There was no significant difference between the 2 trials in the shooting percentage and skill test. The incremental area under the curve of the plasma urea concentration showed a trend of decrease on both days of the AA trial compared to that of placebo trial. There were no difference in the concentrations of creatine kinase, lactate dehydrogenase, lactate, ammonia, glucose, glycerol, non-esterified fatty acid, testosterone and cortisol between the 2 trials. Conclusion: The study suggested that BCAA and Arg supplementation may improve the physical performance on the second day of two consecutive days of simulated basketball games. In addition, Arg may help to increase the conversion of ammonia to urea. Nevertheless, the supplementation had no effect on skill performance, energy metabolism, muscle damage and perceived exertion. BCAA and Arg supplementation may allow the subjects to improve physical performance at the same level of perceived exertion. The mechanism through which BCAA and Arg may influence central fatigue requires further investigation. | |
| dc.description.tableofcontents | 目 次 第壹章 緒論……………………………………………………………1 第一節 研究背景……………………………………………………1 第二節 研究目的……………………………………………………3 第三節 研究假設……………………………………………………4 第四節 研究範圍與限制……………………………………………4 第貳章 文獻探討………………………………………………………5 第一節 支鏈胺基酸在運動期間的代謝……………………………5 第二節 支鏈胺基酸與肌肉損傷……………………………………7 第三節 支鏈胺基酸與中樞疲勞……………………………………12 第四節 支鏈胺基酸與運動表現……………………………………16 第五節 精胺酸對運動表現的影響…………………………………19 第參章 研究方法與步驟………………………………………………22 第一節 實驗對象……………………………………………………22 第二節 實驗設計與步驟……………………………………………22 第三節 飲食與身體活動控制………………………………………25 第四節 爆發力與模擬比賽運動測試………………………………25 第五節 血液採集與分析……………………………………………34 第六節 血漿體積校正方法…………………………………………38 第七節 資料分析……………………………………………………39 第肆章 結果……………………………………………………………40 第一節 受試者基本資料……………………………………………40 第二節 籃球專項體能表現…………………………………………41 第三節 投籃命中率…………………………………………………46 第四節 反動作跳測量與技術測驗…………………………………51 第五節 血液生化值…………………………………………………54 第六節 心跳率與自覺量表…………………………………………70 第伍章 討論……………………………………………………………73 第陸章 結論與建議……………………………………………………82 | |
| dc.format.extent | 1861300 bytes | |
| dc.format.mimetype | application/pdf | |
| dc.identifier.uri | https://ir.ntus.edu.tw/handle/987654321/71187 | |
| dc.language | zh-TW | |
| dc.publisher | 運動健康科學系碩士班 | |
| dc.relation.isbasedon | 黃玫嫙(民99)。補充支鏈胺基酸與精胺酸對連續二天手球運動表現及肌肉損傷之影響(未出版之碩士論文)。國立臺灣體育運動大學,臺中市。 Armstrong, R. B. (1984). Mechanisms of exercise-induced delayed onset muscular soreness: a brief review. Medicine & Science in Sports & Exercise, 16(6), 529-538. Atkinson, G. (2002). Analysis of repeated measurements in physical therapy research: multiple comparisons amongst level means and multi-factorial designs. Physical Therapy in Sport, 3(4), 191-203. Baker, L. B., Dougherty, K. A., Chow, M., & Kenney, W. L. (2007). Progressive dehydration causes a progressive decline in basketball skill performance. Medicine & Science in Sports & Exercise, 39(7), 1114-1123. Banister, E. W., & Cameron, B. J. (1990). Exercise-induced hyperammonemia: peripheral and central effects. International Journal of Sports Medicine, 11 (Suppl 2), S129-142. Bednarz, B., Wolk, R., Chamiec, T., Herbaczynska-Cedro, K., Winek, D., & Ceremuzynski, L. (2000). Effects of oral L-arginine supplementation on exercise-induced QT dispersion and exercise tolerance in stable angina pectoris. International Journal of Cardiology, 75(2-3), 205-210. Bescos, R., Gonzalez-Haro, C., Pujol, P., Drobnic, F., Alonso, E., Santolaria, M. L., & Galilea, P. (2009). Effects of dietary L-arginine intake on cardiorespiratory and metabolic adaptation in athletes. International Journal of Sport Nutrition and Exercise Metabolism, 19(4), 355-365. Blomstrand, E. (2006). A role for branched-chain amino acids in reducing central fatigue. Journal of Nutrition, 136(2), 544S-547S. Blomstrand, E., Andersson, S., Hassmen, P., Ekblom, B., & Newsholme, E. A. (1995). Effect of branched-chain amino acid and carbohydrate supplementation on the exercise-induced change in plasma and muscle concentration of amino acids in human subjects. Acta Physiologica Scandinavica, 153(2), 87-96. Blomstrand, E., Celsing, F., & Newsholme, E. A. (1988). Changes in plasma concentrations of aromatic and branched-chain amino acids during sustained exercise in man and their possible role in fatigue. Acta Physiologica Scandinavica, 133(1), 115-121. Blomstrand, E., Hassmen, P., Ek, S., Ekblom, B., & Newsholme, E. A. (1997). Influence of ingesting a solution of branched-chain amino acids on perceived exertion during exercise. Acta Physiologica Scandinavica, 159(1), 41-49. Blomstrand, E., Hassmen, P., Ekblom, B., & Newsholme, E. A. (1991). Administration of branched-chain amino acids during sustained exercise--effects on performance and on plasma concentration of some amino acids. European Journal of Applied Physiology and Occupational Physiology, 63(2), 83-88. Blomstrand, E., Moller, K., Secher, N. H., & Nybo, L. (2005). Effect of carbohydrate ingestion on brain exchange of amino acids during sustained exercise in human subjects. Acta Physiologica Scandinavica, 185(3), 203-209. Cheuvront, S. N., Carter, R., 3rd, Kolka, M. A., Lieberman, H. R., Kellogg, M. D., & Sawka, M. N. (2004). Branched-chain amino acid supplementation and human performance when hypohydrated in the heat. Journal of Applied Physiology, 97(4), 1275-1282. Coombes, J. S., & McNaughton, L. R. (2000). Effects of branched-chain amino acid supplementation on serum creatine kinase and lactate dehydrogenase after prolonged exercise. The Journal of Sports Medicine and Physical Fitness, 40(3), 240-246. Davis, J. M. (1995). Carbohydrates, branched-chain amino acids, and endurance: the central fatigue hypothesis. International Journal of Sport Nutrition, 5 (Suppl), S29-38. Davis, J. M., Alderson, N. L., & Welsh, R. S. (2000). Serotonin and central nervous system fatigue: nutritional considerations. The American Journal of Clinical Nutrition, 72(2 Suppl), 573S-578S. Davis, J. M., Bailey, S. P., Woods, J. A., Galiano, F. J., Hamilton, M. T., & Bartoli, W. P. (1992). Effects of carbohydrate feedings on plasma free tryptophan and branched-chain amino acids during prolonged cycling. European Journal of Applied Physiology and Occupational Physiology, 65(6), 513-519. Davis, J. M., Welsh, R. S., De Volve, K. L., & Alderson, N. A. (1999). Effects of branched-chain amino acids and carbohydrate on fatigue during intermittent, high-intensity running. International Journal of Sports Medicine, 20(5), 309-314. Doutreleau, S., Mettauer, B., Piquard, F., Rouyer, O., Schaefer, A., Lonsdorfer, J., & Geny, B. (2006). Chronic L-arginine supplementation enhances endurance exercise tolerance in heart failure patients. International Journal of Sports Medicine, 27(7), 567-572. Endemann, D. H., & Schiffrin, E. L. (2004). Endothelial dysfunction. Journal of the American Society of Nephrology, 15(8), 1983-1992. Eto, B., Peres, G., & Le Moel, G. (1994). Effects of an ingested glutamate arginine salt on ammonemia during and after long lasting cycling. Archives Internationales de Physiologie, de Biochimie et de Biophysique, 102(3), 161-162. Goldberg, A. L., & Chang, T. W. (1978). Regulation and significance of amino acid metabolism in skeletal muscle. Federation Proceedings, 37(9), 2301-2307. Graham, T. E., Turcotte, L. P., Kiens, B., & Richter, E. A. (1997). Effect of endurance training on ammonia and amino acid metabolism in humans. Medicine & Science in Sports & Exercise, 29(5), 646-653. Greer, B. K., White, J. P., Arguello, E. M., & Haymes, E. M. (2011). Branched-chain amino acid supplementation lowers perceived exertion but does not affect performance in untrained males. Journal of Strength and Conditioning Research, 25(2), 539-544. Greer, B. K., Woodard, J. L., White, J. P., Arguello, E. M., & Haymes, E. M. (2007). Branched-chain amino acid supplementation and indicators of muscle damage after endurance exercise. International Journal of Sport Nutrition and Exercise Metabolism, 17(6), 595-607. Griggs, R. C., Kingston, W., Jozefowicz, R. F., Herr, B. E., Forbes, G., & Halliday, D. (1989). Effect of testosterone on muscle mass and muscle protein synthesis. Journal of Applied Physiology, 66(1), 498-503. Gualano, A. B., Bozza, T., Lopes De Campos, P., Roschel, H., Dos Santos Costa, A., Luiz Marquezi, M., & Herbert Lancha Junior, A. (2011). Branched-chain amino acids supplementation enhances exercise capacity and lipid oxidation during endurance exercise after muscle glycogen depletion. The Journal of Sports Medicine and Physical Fitness, 51(1), 82-88. Hug, M., Mullis, P. E., Vogt, M., Ventura, N., & Hoppeler, H. (2003). Training modalities: over-reaching and over-training in athletes, including a study of the role of hormones. Best Practice & Research Clinical Endocrinology & Metabolism, 17(2), 191-209. Ivy, J. L., Res, P. T., Sprague, R. C., & Widzer, M. O. (2003). Effect of a carbohydrate-protein supplement on endurance performance during exercise of varying intensity. International Journal of Sport Nutrition and Exercise Metabolism, 13(3), 382-395. Jang, T. R., Wu, C. L., Chang, C. M., Hung, W., Fang, S. H., & Chang, C. K. (2011). Effects of carbohydrate, branched-chain amino acids, and arginine in recovery period on the subsequent performance in wrestlers. Journal of the International Society of Sports Nutrition, 8, 21. Jurimae, J., Jurimae, T., & Purge, P. (2001). Plasma testosterone and cortisol responses to prolonged sculling in male competitive rowers. Journal of Sports Sciences, 19(11), 893-898. Kacsoh, B. (2000). Endocrine Physiology, New York: McGraw-Hill. Koba, T., Hamada, K., Sakurai, M., Matsumoto, K., Hayase, H., Imaizumi, K., & Mitsuzono, R. (2007). Branched-chain amino acids supplementation attenuates the accumulation of blood lactate dehydrogenase during distance running. The Journal of Sports Medicine and Physical Fitness, 47(3), 316-322. Koopman, R., Pannemans, D. L., Jeukendrup, A. E., Gijsen, A. P., Senden, J. M., Halliday, D., & Wagenmakers, A. J. (2004). Combined ingestion of protein and carbohydrate improves protein balance during ultra-endurance exercise. American Journal of Physiology - Endocrinology and Metabolism, 287(4), E712-720. Layman, D. K. (2002). Role of leucine in protein metabolism during exercise and recovery. Journal of Applied Physiology, 27(6), 646-663. Liu, T. H., Wu, C. L., Chiang, C. W., Lo, Y. W., Tseng, H. F., & Chang, C. K. (2009). No effect of short-term arginine supplementation on nitric oxide production, metabolism and performance in intermittent exercise in athletes. The Journal of Nutritional Biochemistry, 20(6), 462-468. MacLean, D. A., & Graham, T. E. (1993). Branched-chain amino acid supplementation augments plasma ammonia responses during exercise in humans. Journal of Applied Physiology, 74(6), 2711-2717. MacLean, D. A., Graham, T. E., & Saltin, B. (1994). Branched-chain amino acids augment ammonia metabolism while attenuating protein breakdown during exercise. American Journal of Physiology, 267(6), E1010-1022. MacLean, D. A., Graham, T. E., & Saltin, B. (1996). Stimulation of muscle ammonia production during exercise following branched-chain amino acid supplementation in humans. The Journal of Physiology, 493, 909-922. Madsen, K., MacLean, D. A., Kiens, B., & Christensen, D. (1996). Effects of glucose, glucose plus branched-chain amino acids, or placebo on bike performance over 100 km. Journal of Applied Physiology, 81(6), 2644-2650. Matsumoto, K., Koba, T., Hamada, K., Sakurai, M., Higuchi, T., & Miyata, H. (2009). Branched-chain amino acid supplementation attenuates muscle soreness, muscle damage and inflammation during an intensive training program. The Journal of Sports Medicine and Physical Fitness, 49(4), 424-431. Matsumoto, K., Mizuno, M., Mizuno, T., Dilling-Hansen, B., Lahoz, A., Bertelsen, V., & Doi, T. (2007). Branched-chain amino acids and arginine supplementation attenuates skeletal muscle proteolysis induced by moderate exercise in young individuals. International Journal of Sports Medicine, 28(6), 531-538. Mittleman, K. D., Ricci, M. R., & Bailey, S. P. (1998). Branched-chain amino acids prolong exercise during heat stress in men and women. Medicine & Science in Sports & Exercise, 30(1), 83-91. Morehouse, L. E. (1972). The C.V. Mosby. Laboratory Manual for Physiology of Exercise, 161-167. Mourier, A., Gautier, J. F., De Kerviler, E., Bigard, A. X., Villette, J. M., Garnier, J. P., & Cathelineau, G. (1997). Mobilization of visceral adipose tissue related to the improvement in insulin sensitivity in response to physical training in NIDDM. Effects of branched-chain amino acid supplements. Diabetes Care, 20(3), 385-391. Newsholme, E. A., & Blomstrand, E. (2006). Branched-chain amino acids and central fatigue. Journal of Nutrition, 136(1 Suppl), 274S-276S. Riazi, R., Wykes, L. J., Ball, R. O., & Pencharz, P. B. (2003). The total branched-chain amino acid requirement in young healthy adult men determined by indicator amino acid oxidation by use of L-[1-13C]phenylalanine. Journal of Nutrition, 133(5), 1383-1389. Schaefer, A., Piquard, F., Geny, B., Doutreleau, S., Lampert, E., Mettauer, B., & Lonsdorfer, J. (2002). L-arginine reduces exercise-induced increase in plasma lactate and ammonia. International Journal of Sports Medicine, 23(6), 403-407. Segura, R., & Ventura, J. L. (1988). Effect of L-tryptophan supplementation on exercise performance. International Journal of Sports Medicine, 9(5), 301-305. Sharp, C. P., & Pearson, D. R. (2010). Amino acid supplements and recovery from high-intensity resistance training. Journal of Strength and Conditioning Research, 24(4), 1125-1130. Shimomura, Y., Yamamoto, Y., Bajotto, G., Sato, J., Murakami, T., Shimomura, N., & Mawatari, K. (2006). Nutraceutical effects of branched-chain amino acids on skeletal muscle. Journal of Nutrition, 136(2), 529S-532S. Silber, B. Y., & Schmitt, J. A. (2010). Effects of tryptophan loading on human cognition, mood, and sleep. Neuroscience & Biobehavioral Reviews, 34(3), 387-407. Struder, H. K., Hollmann, W., Platen, P., Wostmann, R., Weicker, H., & Molderings, G. J. (1999). Effect of acute and chronic exercise on plasma amino acids and prolactin concentrations and on [3H]ketanserin binding to serotonin2A receptors on human platelets. European Journal of Applied Physiology and Occupational Physiology, 79(4), 318-324. Tsuei, B. J., Bernard, A. C., Barksdale, A. R., Rockich, A. K., Meier, C. F., & Kearney, P. A. (2005). Supplemental enteral arginine is metabolized to ornithine in injured patients. Journal of Surgical Research, 123(1), 17-24. Urhausen, A., & Kindermann, W. (2002). Diagnosis of overtraining: what tools do we have? Sports Medicine, 32(2), 95-102. van Hall, G., Raaymakers, J. S., Saris, W. H., & Wagenmakers, A. J. (1995). Ingestion of branched-chain amino acids and tryptophan during sustained exercise in man: failure to affect performance. The Journal of Physiology, 486, 789-794. Watson, P., Shirreffs, S. M., & Maughan, R. J. (2004). The effect of acute branched-chain amino acid supplementation on prolonged exercise capacity in a warm environment. European Journal of Applied Physiology, 93(3), 306-314. Wells, J. G., Balke, B., & Van Fossan, D. D. (1957). Lactic acid accumulation during work; a suggested standardization of work classification. Journal of Applied Physiology, 10(1), 51-55. | |
| dc.subject | 支鏈胺基酸;精胺酸;肌肉損傷;中樞疲勞;運動表現 | |
| dc.subject | branched–chain amino acids;arginine;muscle damage;central fatigue;performance | |
| dc.title | 補充支鏈胺基酸與精胺酸對連續兩天籃球比賽體能與技術表現之影響 | |
| dc.title | EFFECTS OF BRANCHED-CHAIN AMINO ACIDS AND ARGININE SUPPLEMENTATION ON PHYSICAL AND SKILL PERFORMANCE IN TWO CONSECUTIVE DAYS OF BASKETBALL GAMES | |
| dc.type | thesis | |
| dspace.entity.type | Publication |
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