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研究生: 康乃爾
Kang, Nai-Erh
論文名稱: 拔罐介入對於運動疲勞和肌肉活化電訊號的影響
Effects of cupping therapy on fatigue recovery and electromyography
指導教授: 李恆儒
Lee, Heng-Ju
口試委員: 李恆儒
Lee, Heng-Ju
王信民
Wang, Hsin-Min
黎俊彥
Lee, Jun-Yen
口試日期: 2024/01/18
學位類別: 碩士
Master
系所名稱: 體育與運動科學系
Department of Physical Education and Sport Sciences
論文出版年: 2024
畢業學年度: 112
語文別: 中文
論文頁數: 30
中文關鍵詞: 拔罐疲勞恢復肌電肌肉電訊號肌肉活化
英文關鍵詞: Cupping, Fatigue Recovery, EMG, Electromyography, Muscle Activation
研究方法: 實驗設計法
DOI URL: http://doi.org/10.6345/NTNU202400478
論文種類: 學術論文
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  • 目的:此篇研究的目的為探討肌肉疲勞後進行拔罐介入對運動表現和肌肉活化程度的影響。方法:本篇研究收錄10位有運動習慣之大專男性,每人將接受定罐組、動罐組和控制組三個組別之介入。受試者半年內若有上肢損傷、拔罐區域有傷口、出血以及無法接受拔罐的副作用等等,皆予以排除。實驗過程使用肌電訊號接收器及一臺測力板測量疲勞前、後以及介入後30分鐘內的肌肉活化變化和彈震式伏地挺身的力量峰值。統計方法選用單因子變異數重複量數分析,呈現運動表現和肌電之活化程度及中位頻率之變化趨勢與差異。結果:在受試者疲勞後使用拔罐的介入,無論是定罐或動罐組在不同時間點,統計上皆未發現顯著差異。不過趨勢上看似有立即的力量恢復效果,並且在post30發現定罐組力量恢復的程度最接近前測值。發力率方面,則是定罐組在介入後就有立即恢復的趨勢,但動罐組post30恢復的程度最大,最接近前測的數值。肌肉活化方面,定罐組PM(胸大肌,Pectoralis Major m.)在post30時有較明顯回升,且回升幅度比靜態組更大。雖然動罐組相較於其他兩組在post0時PM和AD(Anterior Deltoid m.)的活化程度有降低的趨勢,但在整體的活化程度上都較為接近mid的值。結論:定罐與動罐組能夠產生力量以及發力率回升的趨勢有可能來自於拔罐時肌肉活化提升,使得更多運動單元幫助出力。後續實驗可針對肌電活化程度和運動表現之關聯性做更進一步探討,以推斷在固定的實驗方法下,拔罐介入使肌電活化程度增加的現象對於運動後疲勞的恢復是否真的具有正面的影響。

    The purpose of this study is to explore the effects of cupping intervention after muscle fatigue on sports performance and muscle activation levels. Methods: The study enrolled 10 male college students with regular exercise habits, each of whom received interventions for the fixed cupping group, the moving cupping group, and the control group. Participants were excluded if they had upper limb injuries, wounds in the cupping area, bleeding, or were unable to accept the side effects of cupping within the last six months. The experimental process used electromyography (EMG) signal receivers and a dynamometer to measure changes in muscle activation and peak power of plyometric push-ups before and after fatigue, as well as within 30 minutes after the intervention. A one-way repeated measures ANOVA was used to present the trends and differences in changes in sports performance, EMG activation levels, and median frequency. Results: There were no significant differences between fixed and moving cup groups. However, the use of cupping intervention after fatigue showed an immediate effect on power recovery, whether with fixed or moving cups, with the fixed cupping group showing a degree of power recovery closest to the pre-test value at post30. In terms of rate of force development, the fixed cupping group showed an immediate recovery trend after the intervention, but the moving cupping group had the greatest degree of recovery at post30, closest to the pre-test values. For muscle activation, the fixed cupping group showed a more significant rebound at post30, and the rebound amplitude was larger than the static group. Although the moving cupping group showed a trend of reduced PM and AD activation at post0 compared to the other two groups, the overall activation level was closer to the mid-value.
    Conclusion: The trends in strength recovery and rate of force development produced by the fixed and moving cupping groups may be due to increased muscle activation during cupping, allowing more motor units to assist in force output. Subsequent experiments could further explore the relationship between the level of EMG activation and sports performance to infer whether the phenomenon of increased EMG activation due to cupping intervention has a genuinely positive effect on the recovery from post-exercise fatigue under a fixed experimental method.

    中文摘要 i 英文摘要 ii 目次 iii 圖次 v 第壹章 緒論 1 第一節 前言 1 第二節 問題背景 2 第三節 研究目的 4 第四節 研究假設 4 第五節 研究範圍與限制 4 第貳章 文獻探討 5 第一節 肌肉疲勞與運動表現 5 第二節 運動疲勞的消除方法 5 第三節 拔罐介入 6 第四節 文獻總結 7 第參章 研究方法 8 第一節 研究對象 8 第二節 研究工具 8 第三節 實驗設計 13 第四節 資料處理 19 第六節 統計分析 19 第肆章 結果與討論 20 第一節 動力學參數 20 第二節 肌電訊號參數 21 第三節 問題與討論 24 第四節 結論 25 參考文獻 27 附錄 30

    Ahmaidi, S., Granier, P., Taoutaou, Z. O. H. R. A., Mercier, J. A. C. Q. U. E. S., Dubouchaud, H. E. R. V. É., & Prefaut, C. H. R. I. S. T. I. A. N. (1996). Effects of active recovery on plasma lactate and anaerobic power following repeated intensive exercise. Medicine & Science in Sports & Exercise, 28(4), 450-456.
    Al-Bedah, A. M., Elsubai, I. S., Qureshi, N. A., Aboushanab, T. S., Ali, G. I., El-Olemy, A. T., ... & Alqaed, M. S. (2019). The medical perspective of cupping therapy: Effects and mechanisms of action. Journal of Traditional and Complementary Medicine, 9(2), 90-97.
    AlKhadhrawi, N., & Alshami, A. (2019). Effects of myofascial trigger point dry cupping on pain and function in patients with plantar heel pain: A randomized controlled trial. Journal of Bodywork and Movement Therapies, 23(3), 532-538.
    Baker, D. German volume training: An alternative method of high volume-load training for stimulating muscle growth. NCSA’s PTJ 8:10–13, 2009.
    Biehl, M. M. (2017). The Therapeutic Effects Of Dry Cupping On Iliotibial Band Tightness. Illinois State University.
    Cheatham, S. W., Kolber, M. J., Cain, M., & Lee, M. (2015). The effects of self‐myofascial release using a foam roll or roller massager on joint range of motion, muscle recovery, and performance: a systematic review. International Journal of Sports Physical Therapy, 10(6), 827.
    Dhahbi, W., Chaouachi, A., Dhahbi, A. B., Cochrane, J., Chèze, L., Burnett, A., & Chamari, K. (2017). The effect of variation of plyometric push-ups on force-application kinetics and perception of intensity. International Journal of Sports Physiology and Performance, 12(2), 190-197.
    Duthie, G., Pyne, D., & Hooper, S. (2003). Applied physiology and game analysis of rugby union. Sports Medicine, 33(13), 973-991.
    Edwards, R. H. (1981, January). Human muscle function and fatigue. In Ciba Found Symp (Vol. 82, pp. 1-18).
    El Sayed, S. M., Mahmoud, H. S., & Nabo, M. M. H. (2013). Methods of wet cupping therapy (Al-Hijamah): in light of modern medicine and prophetic medicine. Alternative & Integrative Medicine, 1-16.
    Emerich, M., Braeunig, M., Clement, H. W., Lüdtke, R., & Huber, R. (2014). Mode of action of cupping—local metabolism and pain thresholds in neck pain patients and healthy subjects. Complementary Therapies in Medicine, 22(1), 148-158.
    Farina, D., Merletti, R., & Enoka, R. M. (2004). The extraction of neural strategies from the surface EMG. Journal of Applied Physiology, 96(4), 1486-1495.
    Gao, C., Wang, M., He, L., He, Y., & Li, T. (2019). Alternations of hemodynamic parameters during Chinese cupping therapy assessed by an embedded near-infrared spectroscopy monitor. Biomedical Optics Express, 10(1), 196-203.
    Gill, N. D., Beaven, C. M., & Cook, C. (2006). Effectiveness of post-match recovery strategies in rugby players. British Journal of Sports Medicine, 40(3), 260-263.
    Golas, A., Maszczyk, A., Pietraszewski, P., Stastny, P., Tufano, J. J., & Zajac, A. (2017). Effects of pre-exhaustion on the patterns of muscular activity in the flat bench press. The Journal of Strength & Conditioning Research, 31(7), 1919-1924.
    Gottschall, J. S., Hastings, B., & Becker, Z. (2018). Muscle activity patterns do not differ between push-up and bench press exercises. Journal of Applied Biomechanics, 34(6), 442-447.
    Guimberteau, J. C., Delage, J. P., McGrouther, D. A., & Wong, J. K. F. (2010). The microvacuolar system: how connective tissue sliding works. Journal of Hand Surgery (European Volume), 35(8), 614-622.
    Gursoy, D., & Kendall, K. W. (2006). Hosting mega events modeling locals’ support. Annals of Tourism Research, 33(3), 603-623.
    Haff, G. G., & Triplett, N. T. (Eds.). (2015). Essentials of strength training and conditioning 4th edition. Human kinetics.
    Hagg, G. M. (1992). Interpretation of EMG spectral alterations and alteration indexes at sustained contraction. Journal of Applied Physiology, 73(4), 1211-1217.
    Hill, E. C., Housh, T. J., Smith, C. M., Cochrane, K. C., Jenkins, N. D. M., Cramer, J. T., ... & Johnson, G. O. (2016). Effect of sex on torque, recovery, EMG, and MMG responses to fatigue. Journal of Musculoskeletal & Neuronal Interactions, 16(4), 310.
    Jakeman, J. R., Byrne, C., & Eston, R. G. (2010). Lower limb compression garment improves recovery from exercise-induced muscle damage in young, active females. European Journal of Applied Physiology, 109(6), 1137-1144.
    Kim, J. E., Cho, J. E., Do, K. S., Lim, S. Y., Kim, H. J., & Yim, J. E. (2017). Effect of cupping therapy on range of motion, pain threshold, and muscle activity of the hamstring muscle compared to passive stretching. Korean Society of Physical Medicine, 12(3), 23-32.
    Kim, S., Kim, E., Jung, G., Lee, S., & Kim, J. G. (2019). The hemodynamic changes during cupping therapy monitored by using an optical sensor embedded cup. Journal of Biophotonics, 12(5), e201800286.
    Kubo, K., Ikebukuro, T., Tsunoda, N., & Kanehisa, H. (2008). Changes in oxygen consumption of human muscle and tendon following repeat muscle contractions. European Journal of Applied Physiology, 104(5), 859.
    Lauche, R., Materdey, S., Cramer, H., Haller, H., Stange, R., Dobos, G., & Rampp, T. (2013). Effectiveness of home-based cupping massage compared to progressive muscle relaxation in patients with chronic neck pain—a randomized controlled trial. PloS one, 8(6).
    Markowski, A., Sanford, S., Pikowski, J., Fauvell, D., Cimino, D., & Caplan, S. (2014). A pilot study analyzing the effects of Chinese cupping as an adjunct treatment for patients with subacute low back pain on relieving pain, improving range of motion, and improving function. The Journal of Alternative and Complementary Medicine, 20(2), 113-117.
    Martin, N. A., Zoeller, R. F., Robertson, R. J., & Lephart, S. M. (1998). The comparative effects of sports massage, active recovery, and rest in promoting blood lactate clearance after supramaximal leg exercise. Journal of Athletic Training, 33(1), 30.
    Minshull, C., Eston, R., Rees, D., & Gleeson, N. (2012). Knee joint neuromuscular activation performance during muscle damage and superimposed fatigue. Journal of Sports Sciences, 30(10), 1015-1024.
    Musial, F., Michalsen, A., & Dobos, G. (2008). Functional chronic pain syndromes and naturopathic treatments: neurobiological foundations. Complementary Medicine Research, 15(2), 97-103.
    Pointon, M., & Duffield, R. (2012). Cold water immersion recovery after simulated collision sport exercise. Medicine & Science in Sports & Exercise, 44(2), 206-216.
    Rozenfeld, E., & Kalichman, L. (2016). New is the well-forgotten old: The use of dry cupping in musculoskeletal medicine. Journal of Bodywork and Movement therapies, 20(1), 173-178.
    Sadek, T. A. R. E. K. (2016). Effects of cupping therapy based on stabilization core exercises on low back pain for soccer players in state of united arab emirates. Ovidius University Annals, Series Physical Education & Sport/Science, Movement & Health, 16.
    Tavares, F., Smith, T. B., & Driller, M. (2017). Fatigue and recovery in rugby: a review. Sports Medicine, 47(8), 1515-1530.
    Thorlund, J. B., Michalsik, L. B., Madsen, K., & Aagaard, P. (2008). Acute fatigue‐induced changes in muscle mechanical properties and neuromuscular activity in elite handball players following a handball match. Scandinavian journal of Medicine & Science in Sports, 18(4), 462-472.
    Wang, R., Hoffman, J. R., Sadres, E., Bartolomei, S., Muddle, T. W., Fukuda, D. H., & Stout, J. R. (2017). Evaluating upper-body strength and power from a single test: The ballistic push-up. The Journal of Strength & Conditioning Research, 31(5), 1338-1345.

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