簡易檢索 / 詳目顯示

研究生: 吳家慶
Chia-Ching Wu
論文名稱: 不同強度動態恢復對損傷肌肉之功能及跑步經濟性的影響
The effect of different intensities of active recovery on muscle function and running economy after exercise-induced muscle damage
指導教授: 謝伸裕
Hsieh, Shen-Yu
學位類別: 博士
Doctor
系所名稱: 體育學系
Department of Physical Education
論文出版年: 2005
畢業學年度: 93
語文別: 中文
論文頁數: 91
中文關鍵詞: 動態恢復肌肉損傷跑步經濟性
英文關鍵詞: active recovery, muscle damage, running economy
論文種類: 學術論文
相關次數: 點閱:300下載:49
分享至:
查詢本校圖書館目錄 查詢臺灣博碩士論文知識加值系統 勘誤回報
  • 不同強度動態恢復對損傷肌肉之功能及跑步經濟性的影響
    研 究 生:吳家慶
    2005年6月 指導教授:謝伸裕
    中文摘要
    背景:當激烈運動後,在肌肉有酸痛及損傷的情形下,是否應該繼續從事運動?關於這個問題,現有文獻尚未有完整的論述。有許多運動員在肌肉損傷及酸痛的情況下仍然會繼續運動,而過去的文獻只有探討讓損傷的肌肉繼續運動,是否會加重受傷情形或者會增進肌肉功能的恢復。對於耐力性運動項目,肌肉功能不應是被考量的唯一指標,與耐力表現具有高度相關的跑步經濟性也應一併討論。目的:在探討肌肉損傷後從事6天不同強度的動態恢復活動(50%、60%、70% VO2max),對肌肉功能恢復及跑步經濟性的影響。方法:本研究以40名自願參加本實驗之大學體育相關科系學生(男性32人;女性8人)為受試對象。受試者先接受VO2max及跑步經濟性測驗後,再將受試者隨機分派E50組(50% VO2max;n=10;♂=8、♀=2)、E60組(60% VO2max;n=10;♂=8、♀=2)、E70組(70% VO2max;n=10;♂=8、♀=2)、CON組(控制組;n=10;♂=8、♀=2)。之後讓受試者在跑步機上以70% VO2max 的強度進行一次30分鐘的下坡跑(-15%),來誘發股四頭肌產生肌肉損傷。在下坡跑後第1-6天期間,分別以不同的強度進行每天30分鐘的跑步運動。各組在下坡跑前、後第0-7天接受肌肉酸痛及最大自主等長收縮肌力(MVC)測量;各組在下坡跑前、後第1、3、5、7天抽血檢驗肌酸激酉每(CK)、乳酸脫氫酉每(LDH)活性;各組在下坡跑後第2、5、7天接受跑步經濟性測驗。結果:在下坡跑後第4-7天,CON組、E50組這兩組的MVC恢復情形顯著高於E70組 (p<.05)。在下坡跑後第7天的跑步經濟性測驗中,E50組顯著優於CON組、E70組這兩組 (p<.05)。在CK、LDH、肌肉酸痛指數等指標上,不同四組在不同時間點上均無顯著差異 (p>.05)。結論:1.最大肌力值若要儘速恢復,採用完全休息或中強度的動態恢復(約50﹪VO2max),是較好的選擇。越高的動態恢復強度,越會延緩MVC的恢復時程。2.過高的動態恢復強度(70% VO2max)或不做動態恢復的處理方式,則對跑步經濟性有不利的影響。3.同時考量跑步經濟性及MVC恢復情形因素,則中強度的動態恢復(50% VO2max)比不從事動態恢復和高強度動態恢復來得好。

    關鍵詞:動態恢復、肌肉損傷、跑步經濟性

    The effect of the different intensities of active recovery on muscle function and running economy after exercise-induced muscle damage

    June 2005 Student:Chia-Ching Wu
    Advisor:Sandy Shen-Yu Hsieh
    ABSTRACT
    Background:Should athlete continue to exercise when muscles are sored after strenuous exercise? Current literatures do not provide clear answers to this question. Post studies discussed the effect of exercise on muscle function after exercise-induced muscle damage. However, muscle function is not the only concern for endurance runners. Running economy should also be considered. Purpose:To determine the effect of a 6-day different intensities active recovery (50%、60%、70% VO2max) on muscle function and running economy after exercise-induced muscle damage. Methods:Forty Physical Education students (32 males & 8 females) took the VO2max and running economy test first. Then they were randomly assigned into 4 groups: E50(50% VO2max;n=10;♂=8、♀=2), E60(60% VO2max;n=10;♂=8、♀=2), E70(70% VO2max;n=10;♂=8、♀=2) and CON(control;n=10;♂=8、♀=2). A 30-min downhill running (-15%) at 70% VO2max was used to cause muscle damage. A 30-min active recovery running exercise was performed everyday for the following 6 days. Maximal isometric voluntary contraction strength (MVC) and muscle soreness were measured before, immediately after and 1, 2, 3, 4, 5, 6, 7 days after downhill running. Creatine kinase (CK) and lactate dehydrogenase (LDH) activities were also tested before, immediately after and 1, 3, 5, 7 days after downhill running. Running economy was determined 2, 5, 7 days after downhill running. Results:On the days 4 –7, both the CON’s and E50’s MVC were significantly higher than the E70 (p<.05). On the seventh day of the running economy test after downhill running, E50 was significantly different as compared to CON and E70(p<.05). No significant differences among groups in CK activity, LDH activity and muscle soreness (p>.05) were observed. Conclusions:1. Rest or moderate intensity active recovery (about 50% VO2max) is better for MVC recovery. Higher intensity of active recovery, will delay the normal course of MVC recovery. 2. Higher intensity of active recovery or rest was harmful to running economy. 3. When consider running economy and MVC together, moderate intensity of active recovery (about 50% VO2max) was better than rest or high intensity active recovery.

    Key words:active recovery, muscle damage, running economy.

    目 次 前序部分: 中文摘要………………………………………………………..i 英文摘要……………………………………………………….ii 謝誌……………………………………………………………iii 目次……………………………………………………………iv 表次…………………………………………………………….x 圖次……………………………………………………………xi 本文部分: 第壹章、緒論 一、前言………………………………………………………..1 二、研究目的…………………………………………………..9 三、研究假設…………………………………………………..9 四、名詞操作性定義………………………….………………..9 五、研究限制……………………………………………….…11 六、研究的重要性……………………………….……………12 第貳章、文獻探討 一、運動導致肌肉損傷的假說…..…………………………...13 二、引發延遲性肌肉酸痛的理論…..………………………...16 三、肌肉損傷後對肌肉功能及運動表現的影響………….....19 四、運動或訓練對肌肉損傷恢復的影響………………….…22 五、肌肉損傷對能量代謝與能量儲存的影響…..…………...26 六、結語……………………………………………..………...28 第參章、研究方法 一、受試者…..…………………………………………….…..30 二、實驗步驟………..………………………………….……..31 三、實驗工具與測驗方法…..………………………………...33 四、實驗控制………………………..………………………...39 五、統計分析…………………………………..……………...39 第四章、結果 一、受試者基本資料………………………………………….40 二、最大自主等長收縮肌力……………………….…………41 三、肌肉酸痛指數…………………………………………….42 四、血液中CK、LDH活性…………………………………..43 五、跑步經濟性……………………………………………….45 六、其他生理指標…………………………………………….46 第五章、討論 一、最大自主等長收縮肌力(MVC)………………………51 二、肌肉酸痛指數……………………………………………54 三、血液中CK、LDH活性………………………………….55 四、跑步經濟性……………………………………………….57 五、其他生理指標…………………………………………….60 六、結論與建議……………………………………………….63 引用文獻 中文部分……………………………………………………...65 英文部分……………………………………………………...65 後篇部分 一、附錄 附錄一、受試者參與實驗同意書……………………………77 附錄二、受試者健康情況調查表……………………………80 附錄三、不同組別與不同時間點之MVC變異數分析摘要表…………………………………………………...82 附錄四、不同組別與不同時間點之MVC簡單主要效果分析摘要表..…………………………………………… 82 附錄五、不同組別與不同時間點之肌肉酸痛指數變異數分析摘要表……………………………………………...83 附錄六、不同組別與不同時間點之肌肉酸痛指數主要效果分析摘要表…………………………………………...83 附錄七、不同組別與不同時間點之CK活性值變異數分析摘要表………………………………………………...84 附錄八、不同組別與不同時間點之CK活性值簡單主要效果分析摘要表………………………………………...84 附錄九、不同組別與不同時間點之LDH活性值變異數分析摘要表……………………………………………...85 附錄十、不同組別與不同時間點之LDH活性值簡單主要效果分析摘要表……………………………………...85 附錄十一、不同組別與不同時間點在跑步經濟性測驗中之攝氧量變異數分析摘要表…………………………...86 附錄十二、不同組別與不同時間點在跑步經濟性測驗中之攝氧量簡單主要效果分析摘要表…………………...86 附錄十三、不同組別與不同時間點在跑步經濟性測驗中之換氣量變異數分析摘要表…………………………...87 附錄十四、不同組別與不同時間點在跑步經濟性測驗中之換氣量簡單主要效果分析摘要表…………………...87 附錄十五、不同組別與不同時間點在跑步經濟性測驗中之呼吸交換率變異數分析摘要表……………………...88 附錄十六、不同組別與不同時間點在跑步經濟性測驗中之呼吸交換率簡單主要效果分析摘要表……………...88 附錄十七、不同組別與不同時間點在跑步經濟性測驗中之血乳酸變異數分析摘要表…………………………...89 附錄十八、不同組別與不同時間點在跑步經濟性測驗中之血乳酸簡單主要效果分析摘要表…………………...89 附錄十九、不同組別與不同時間點在跑步經濟性測驗中之心跳率變異數分析摘要表…………………………...90 附錄二十、不同組別與不同時間點在跑步經濟性測驗中之心跳率簡單主要效果分析摘要表…………………...90 二、個人小傳…………………………………………….91 表 次 表一、肌肉損傷後對其他運動表現測驗的影響…………….20 表二、短期廢訓、肌肉損傷後運動生理反應及生化改變…...28 表三、依變項測量時間表……………………………………32 表四、受試者基本資料………………………………………41 圖 次 圖一、實驗流程簡圖…………………………………………32 圖二、本研究的一名受試者接受最大攝氧量測驗的情形…34 圖三、本研究的一名受試者接受下坡跑的情形……………36 圖四、受試者接受動態恢復的情形…………………………38 圖五、不同四組受試者在不同時間點中MVC的變化情形.42 圖六、不同四組的受試者在不同時間點中肌肉酸痛的變化情形……………………………………………………...43 圖七、不同四組的受試者在不同時間點中CK活性值變化情形……………………………………………………...44 圖八、不同四組的受試者在不同時間點中LDH活性值變化情形…………………………………………………...44 圖九、不同組別在跑步經濟性測驗中不同時間點之攝氧量的變化情形……………………………………………...45 圖十、不同組別在跑步經濟性測驗中不同時間點之換氣量的變化情形……………………………………………...47 圖十一、不同組別在跑步經濟性測驗中不同時間點之換氣量的變化情形…………………………………………...48 圖十二、不同組別在跑步經濟性測驗中不同時間點之血乳酸濃度變化情形………………………………………...50 圖十三、不同組別在跑步經濟性測驗中不同時間點之心跳率變化情形……………………………………………...50

    引用文獻

    一、中文部分
    吳家慶、黃滄海 & 謝伸裕(2005)。鐵人三項比賽對肌肉酸痛指標與脂質過氧化的影響。運動生理暨體能學報,2,93-102。
    林正常(1986)。長時間持續運動後血清肌酸肌酉每反應的研究。大專體育研究集刊,1,305-386。
    譚傳明(1990)。肌肉向心收縮及離心收縮機轉之探討。未出版的碩士論文,國立成功大學,台南市,台灣。
    陳忠慶(2002)。重複訓練效應對肌肉損傷的影響。未出版的博士論文,國立台灣師範大學體育研究所,台北市,台灣。

    二、英文部分
    Appell, H. J., Soares, J. M. C., & Duarte, J. A. R. (1992). Muscle damage and fatigue. Sports Medicine, 13(2), 108-115.
    Armstrong, R. B. (1984). Mechanisms of exercise-induced delay onset of muscular soreness: a brief review. Medicine & Science in Sport & Exercise, 16, 529-538.
    Armstrong, R. B. (1986). Muscle damage and endurance events. Sports Medicine, 3, 370-381.
    Armstrong, R. B. (1990). Initial events in exercise-induced muscular injury. Medicine & Science in Sports & Exercise, 22, 429-35.
    Armstrong, R. B., Warren, G. L., and Warren, J. A. (1991). Mechanisms of exercise- induced muscle fibre injury. Sports Medicine, 12, 184-207.
    Asp, S., Daugaard, J. R., & Richter, E. A. (1995a). Eccentric exercise decreases glucose transporter GLUT4 protein in human skeletal muscle. Journal of Physiology, 482, 705-712.
    Asp, S., Daugaard, J. R., & Richter, E. A. (1995b). Eccentric muscle damage transiently decreases rat muscle GLUT-4 protein. Journal of Applied Physiology, 79(4), 1338-1345.
    Bigland-Richie, B., & Woods, J. J. (1976). Intergrated EMG and O2 uptake during positive and negative work. Journal of Physiology, 260, 267-277.
    Braun, W. A., & Dutto, D. J. (2003). The effect of a single bout of downhill running and ensuing delayed onset of muscle soreness on running economy performed 48h later. European Journal of Applied Physiology, 90, 29-34.
    Bompa, T. O. (1999). Periodization: Theory and methodology of training (4th ed.). Champaign, IL: Human Kinatic.
    Byrne, C., & Eston, R. (2002a). The effect of exercise- induced muscle damage on isometric and dynamic knee extensor strength and vertical jump performance. Journal of Sports Sciences, 20, 417-425.
    Byrne, C., & Eston, R. (2002b). Maximal-intensity isometric and dynamic exercise performance after eccentric muscle actions. Journal of Sports Sciences, 20, 951-959.
    Byrnes, W. C., Clarkson, P. M., White, J. S., Hsieh, S. S., & Fryman, P. N. (1985). Delayed onset muscle soreness following repeated bouts of downhill running. Journal of Applied Physiology, 59, 710-715.
    Chambers, C., Noakes, T. D., & Lambert, E. V. (1998). Time course of recovery of vertical jump height and heart rate versus running speed after a 90-km foot race. Journal of Sports Sciences, 16, 645-651.
    Chen, T. C., & Hsieh, S. S. (2000). The effects of repeated maximal voluntary isokinetic eccentric exercise on recovery from muscle damage. Research Quarterly for Exercise and Sport, 71(3), 260-266.
    Chen, T. C., & Hsieh, S. S. (2001). Effects a 7-days eccentric training period on muscle damage and inflammation. Medicine & Science in Sports & Exercise, 33(10), 1732-1738.
    Cheung, K., Hume, P. A., & Maxwell, L. (2003). Delayed onset muscle soreness: Treatment strategies and performance factors. Sports Medicine, 33(2), 145-164.
    Clarkson, P. M. (1997). Eccentric exercise and muscle damage. International Journal of Sports Medicine, 18, S314-S317.
    Clarkson, P. M., Nosaka, K., & Braun, B. (1992). Muscle function after exercise-induces muscle damage and rapid adaptation. Medicine & Science in Sports & Exercise, 24, 512-520.
    Cleak, M. J., & Eston, R. G. (1992). Delayed onset muscle soreness:Mechanisms and management. Journal of Sports Sciences, 10(4), 325-341.
    Clemente, R. F., Matulions, D. H., Barron, K. W., & Currier, D. P. (1991). Effect of motor neuromuscular electrical stimulation on microvascular perfusion of stimulated rat skeletal muscle. Physical Therapy, 71, 397-406.
    Close, G. L., Ashton, T., Cable, T., Doran. D., & MacLaren, D. P. M. (2004). Eccentric exercise, isokinetic muscle torque and delayed onset muscle soreness: The role of reactive oxygen species. European Journal of Applied Physilogy, 91, 615-612.
    Conley, D. L. (1980). Running economy and distance running performance of highly trained athletes. Medicine & Science in Sports & Exercise, 5(4), 248-252.
    Connolly, D. A. J., Sayers, S. P., & McHugh, M. P. (2003). Treatment and prevention of delayed onset of muscle soreness. Journal of Strength & Conditioning Research, 17(1), 197-208.
    Constatin-Teodosiu, D., Casey, A., Short, A. H., Hultman, E., & Greenhaff, P. L. (1996). The effect of repeated muscle biopy sampling on ATP and glycogen resynthesis folloeing exercise in man. European Journal of Applied Physiology, 73, 186-190.
    Costill, D. L. (1973). The relationship between selected physiological variables and distance running performance. Journal of Sports Medicine & Physical Fitness, 7(2), 61-66.
    Coyle, E. F., Hemmert, M. K., & Coggan, A. R. (1986). Effects of detraining on cardiovascular responses to exercise: role of blood volume. Journal of Applied Physiology, 60(1), 95-99.
    Dolezal, B. A., Potteiger, J. A., Jacobsen, D. J., & Benedict, S. H. (2000). Muscle damage and resting metabolic rate after acute resistance exercise with an eccentric overload. Medicine & Science in Sports & Exercise, 32(7), 1202-1207.
    Donnelly, A. E., Clarkson, P. M., & Maughan, R. J. (1992). Exercise-induced muscle damage: effects of light exercise on damaged muscle. European Journal of Applied Physiology, 64, 350-353.
    Dutto, T. J. (2004). DOMS-Associated Changes in Ankle and Knee Joint Dynamics during Running. Medicine & Science in Sports & Exercise, 36(4), 560-567.
    Ebbeling, C. B., & Clarkson, P. M. (1989). Exercise-induced muscle damage and adaptation. Sports Medicine, 7(4), 207-234.
    Ellis, L., Gastin, P., Lawrence, S., Savage, B., Andrea, B., Stapff, A., Tumilty, D., Quinn, A., Woolford, S., & Young, W. (2000). Protocols for the physiological assessment of team sport players. In C. J. Gore (Ed.). Physiological tests for elite athletes (pp. 128-144). Champaign, IL: Human Kinatic.
    Eston, R. G., Lemmey, A. B., McHugh, P., Byrne, C., & Walsh, S. E. (2000). Effect of stride length on symptoms of exercise-induced muscle damage during a repeated bout of downhill running. Scandinavian Journal of Medicine & Science in Sports, 10, 199-204.
    Fallon, K. E. (1996). Musculoskeletal injuries in the ultramarathon: the 1990 Westfield Sydney to Melbourne run. British Journal of Sports Medicine, 30, 319-323.
    Fox, E., Bowes, R., & Foss, M. (1989). The physiological basis of physical education and athletics. Dubuque. IA:Brown.
    Friden, J., & Lieber, R. L. (1992). Structural and mechanical basis of exercise-induced muscle injuly. Medicine & Science in Sports & Exercise, 24(5), 521-530.
    Friden, J., Sfakisnos, P. N., Hargens, A. R., & Akeson, W. H. (1988). Residual muscular swelling after repetitive eccentric contraction. Journal of Orthopaedic Research, 6, 493-498.
    Friden, J., Sjostrom, M., & Ekblom, B. (1983). Myofibrillar damage following intense eccentric exercise in man. International Journal of Sports Medicine, 4, 170-176.
    Friel, J., & Byrn G. (2003). Going long: Training for ironman-distance triathlete. Boulde, CO: VeloPress.
    Friman, G. (1979). Effects of clinical bed rest for seven days of physical performance. Acta Medica Scandinavica, 205(5), 389-393.
    Glesson, M., Blannin, A. K., & Zhu, B. (1995). Cardiorespiratory, hormonal and haematological responses to submaximal cycling performed 2 days after eccentric or concentric exercise bouts. Journal of Sports Science, 13, 471-479.
    Gleeson, M., Blannin, A. K., Walsh, N. P., Field, C. N. E., & Pritchard, J. C. (1998). Effect of exercise–induced muscle damage on the blood lactate response to incremental exercise in humans. European Journal of Applied Physiology, 77, 292-295.
    Gulick, D. T., & Kimura, I. F. (1996). Delayed onset muscle soreness: What is it and how do we treat it? Journal of Sport Rehabilitation, 5, 234-243.
    Hortobagyi, T., Houmard, J. A., Stevenson, J. R., Fraser, D. D., & Johns, R. A. (1993). The effects of detraining on power athlete. Medicine & Science in Sports & Exercise, 25(8), 929-935.
    Houmard, J. A., Hortobagyi, T., Johns, R. A, Neufer, P. D., Fraser, D. D., & Israel, R. G. (1992). Effect of short-term training cessation on performance measure in distance runners. International Journal of Sports Medicine, 13(8), 572-576.
    Hunt, M. E. (1990). Physiotheraphy in sports medicine. In T. S Torg, P. R. Welsh, & R. J. Shephard (Eds.). Current therapy in sports medicine. (pp. 48-50). Toronto: B. C. Decker.
    Jones, D. A., Newham, D. J., & Torgan, C. (1989). Mechanical influences on long-lasting human muscle fatigue and delayed-onset pain. Journal of Physilogy, 142, 415-427.
    Kirwan, J. P., Hickner, R. C., Yaresheski, K. E., Kohrt, W. M., Wiethop, B. V., & Holloszy, J. O. (1992). Eccentric exercise induces transient insulin resistance in healthy individuals. Journal of Applied Physiology, 72, 2197-2202.
    Kraemer, W. J., Gomez, A. L., Ratamess, N. A., Hoffman, J. R., Volek, J. S., Rubin, M. R., Scheett, T. P., McGuigan, M. R., French, D., VanHeest, J. L., Wickham, R. B., Doan, B., Mazzetti, S. A., Newton, R. U., & Maresh C. M. (2002). Effects of Vicoprofen and Ibuprofen on anaerobic performance after muscle damage. Journal of Sport Rehabilitation, 11(2), 104-119.
    Kuipers, H. (1994). Exercise-induced muscle damage. International Journal of Sports Medicine, 15, 132-135.
    Kyrolainen, H., Pullinen, T., Candau, R., Avela, J, Huttunen, P., & Komi, P. V. (2000). Effects of marathon running on running economy and kinematics. European Journal of Applied Physiology, 82, 297-304.
    Madsen, K., Pedersen, P. K., Djurhus, M. S., & Klitgaurd, N. S. (1993). Effects of detraining on endurance capacity and metabolic change during prolonged exhaustive exercise. Journal of Applied Physiology, 75(4), 1444-1451.
    Margaritis, I., Tessier, F., Verdera, F., Bermon, S. & Marconnet, P. (1999). Muscle enzyme release does not predict muscle function impairment after triathlon. The Journal of Sports Medicine & Physical Fitness, 39, 133-139.
    Miles, M. P. & Clarkson, P. M. (1994). Exercise-induced muscle pain, soreness, and cramps. Journal of Sports Medicine and Physical Fitness, 34, 203-216.
    Mohr, T., Akers, T. K., & Wessman, H. C. (1987). Effect of high voltage stimulation on blood flow in the rat hindlimb. Physical Therapy, 67, 526-533.
    Mujika, I., & Padilla, S. (2000). Detraining: Loss of training-induced physiological and performance adaptation. Part I. Sports Medicine, 30(2), 79-87.
    Mujika, I., & Padilla, S. (2001). Cardiorespiratory and metabolic characteristics of detraining in human. Medicine & Science in Sports & Exercise, 33(3), 413-421.
    Newham, D. J., Jones, D. A., & Edwards, R. H. T. (1983). Large delayed plasma creatine kinase changes after stepping exercise. Muscle & Nerve, 6, 380-385.
    Newham, D. J., McPhail, G., Milla, K. R., & Edward, R. H. T. (1983). Ultrastructural changes after concentric and eccentric contractions of human muscle. Journal of Neurological Science, 61, 109-122.
    Nigg, B. M., Bahlsen, H. A., Luethi, S. M., & Stokes, S. (1987). The influence of running velocity and midsole hardness on external impact forces in heel-toe running. Journal of Biomechincs, 20(10), 951-959.
    Nosaka, K., Newton, M., & Sacco, P. (2002). Muscle damage and soreness after endurance exercise of elbow flexors. Medicine & Science in Sports & Exercise, 34(6), 920-927.
    O’Reilly, K. P., Warhol, M. J., Fielding, R. A., Frontera, W. R., Meredith, C. N., & Evans W. J. (1987). Eccentric exercise-induced muscle damage impairs muscle glycogen repletion. Journal of Applied Physiology, 63, 252-256.
    Peeze-Binkhorst F. M., Kuipers, H., Tangelder, G. J., Slaaf, D. W., & Reneman, R. S. (1989). Exercise- induced focal skeletal muscle fiber degeneration and capillary morphology. Journal of Applied Physiology, 66, 2857-2865.
    Powers, S. K., & Howley, E. T. (2001). Exercise physiology (4th ed.). Dubuque. IA: McGraw Hill.
    Rinard, J., Clarkson, P. M., Smith, L., & Grossman, M. (2000). Response of males and females to high-force eccentric exercise. Journal of Sports Sciences, 18, 229-236.
    Robergs, R. A., Icenogle, M. V., Hudson, T. L., & Greene, E. R. (1997). Temporal inhomogeneity in brachial artery blood flow during forearm exercise. Medicine & Science in Sports & Exercise, 29, 1021-1027.
    Rowlands, A. V., Eston, R. G., & Tilzey, C. (2001). Effect of stride length manipulation on symptoms of exercise-induced muscle damage and the repeated bout effect. Journal of Sports Sciences, 19, 333-340.
    Sargeant, A. J., & Dolan, P. (1987). Human muscle function following prolonged eccentric exercise. European Journal of Applied Physiology, 56, 704-711.
    Saunders, P. U., Pyne, D. B., Telford, R. D., & Hawley, J. A. (2004). Factors affecting running economy in trained distance runner. Sports Medicine, 34(7), 465-485.
    Saxton, J. M., & Donnelly, A. E. (1995). Light concentric exercise during recovery from exercised-induced muscle damage. International Journal of Sports Medicine, 16, 347-351.
    Saxton, J. M., Donnelly, A. E., & Roper, H. P. (1994). Indices of free-radical-mediated damage following maximun voluntary eccentric and concentric musclar work. European Journal of Applied Physiology, 68, 189-193.
    Sayers, S. P., Clarkson, P. M., & Lee, J. (2000). Activity and immobilization after eccentric exercise: I. Recovery of muscle function. Medicine & Science in Sports & Exercise, 32(9), 1587-1592.
    Schwane, J. A., Johnson, S. R., Vandenkker, C. B., & Armstorng, R. B. (1983). Delayed-onset musclar soreness and plasma CPK and LDH activities after dowmhill running. Medicine & Science in Sports & Exercise, 15(1), 51-56.
    Semark, A., Noakes, T. D., Clair Gibson, A. St., Lambert, M. I. (1999). The effect of a prophylactic dose of flurbiprofen on muscle soreness and sprinting performance in trained subjects. Journal of Sports Sciences, 17(3), 197-203.
    Sherman, W. M., Armstrong, L. E., Murray, T. M., Hagerman, F. C., Costill, D. L., Staron, R. C., & Ivy, J. L. (1984). Effect of a 42.2-km footrace and subsequent rest or exercise on muscular strength and work capacity. Journal of Applied Physiology, 57(6), 1668-1673.
    Smith, L. K., Weiss, E. L., & Lehmkuhl, L. D. (1996). Knee region. In L. K. Smith, E. L. Weiss, & L. D. Lehmkuhl (Eds.) Brunnstrom's clinical kinesiology (pp. 301-331). Singapore: Info Access & Distribution Ltd.
    Szasz, G., Gruber, W., & Bernt, E. (1976). Creatine kinase in serum: 1. determination of optimum reaction conditions. Clinical Chemistry, 22(5), 650-656.
    Tittel, K., & Wutscherk, H. (1995). Anatomical and anthropometric fundamentals of endurance. In R. J. Shephard, & P. O. Astrand (Eds.). Endurance in sport (pp. 56-57). London: Blackwell Science Ltd.
    Wilmore, J. H., & Costill, D. L. (1999). Physiology of sport and exercise (2nd ed.). Champaign, IL: Human Kinetics.
    Warren, G. L., Lowe, D. A., & Armstrong, R. B. (1999). Measurement tools used in the study of eccentric contraction-induced injury. Sports Mdicine, 27(1), 43-59.
    Zerba, E., Kamarowski, T. E., & Faulkner, J. A. (1990). Free radical injury to skeletal muscles of young, adult, and old mice. American Journal of Physiology, 258, C429-C435.

    QR CODE