簡易檢索 / 詳目顯示

研究生: 黃君秦
Chun-Chin Huang
論文名稱: 下坡跑與離心阻力運動對脂締素及脈波傳導速率之影響
Effect of downhill running and eccentric resistance exercise on pulse wave velocity and adiponectin
指導教授: 王鶴森
Wang, Ho-Seng
林信甫
Lin, Hsin-Fu
學位類別: 碩士
Master
系所名稱: 體育學系
Department of Physical Education
論文出版年: 2012
畢業學年度: 100
語文別: 中文
論文頁數: 47
中文關鍵詞: 心血管疾病動脈硬化肌肉損傷延遲性肌肉酸痛發炎反應
英文關鍵詞: cardiovascular disease, arterial stiffness, muscle damage, delayed onset muscle soreness, inflammatory response
論文種類: 學術論文
相關次數: 點閱:421下載:22
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
  • 背景: 近年來心血管疾病的問題與日俱增,脈波傳導速率 (pulse wave velocity, PWV) 及脂締素 (adiponectin) 皆是臨床上用以預測心臟血管疾病的指標,同時脂締素於人體中具有抗發炎及減緩動脈粥狀硬化等作用,然而離心運動所誘發之發炎反應是否會改變脂締素濃度並且影響脈波傳導速率,以及脂締素與 PWV 的關係仍需進一步釐清。目的:探討單次下坡跑與離心阻力運動對脂締素及PWV的影響,以及了解脂締素與 PWV 之相關。方法:招募18名自願參與的健康男性為研究對象,並隨機分派至下坡跑組(EE組;n=9)與離心阻力運動組(RE組;n=9),正式實驗前EE組需在跑步機上進行攝氧峰值 (VO2peak) 測驗;RE組則在斜式腿部推舉機接受下肢最大肌肉力量 (1RM) 測驗。接著讓EE組在跑步機上以75% VO2peak的強度進行一次30分鐘的下坡跑 (-10°) ;RE組則在斜式腿部推舉機上以120% 1RM 強度進行離心阻力運動(每組反覆次數6次,共計10組)。兩組別在運動前、運動後90分鐘、24及48小時檢測 PWV 與血清脂締素、肌酸激酶 (Creatine kinese, CK) 及C反應蛋白 (C-reactive protein, CRP) 濃度。結果:下坡跑與離心阻力運動組之平均CK值於運動後各時間點均顯著高於運動前 (p<.05),同時,平均PWV也於運動後24 (5.47 ± 0.59 m/s) 及48 (5.44 ± 0.68 m/s) 小時顯著高於運動前 (5.18 ± 0.47 m/s) (p<.05),但脂締素及CRP 濃度皆無顯著改變 (p>.05);而 PWV 與脂締素濃度變化量在運動後90分鐘呈顯著負相關 (r= -.501) (p<.05)。兩組別在所有依變項上,於不同時間點均無顯著差異 (p>.05)。結論: 單次下坡跑與離心阻力運動皆會引發肌肉損傷及動脈硬化指標─脈波傳導速率的顯著提升,但不會造成脂締素濃度的改變;因此從事下坡跑與離心阻力運動將可能導致短暫性中心動脈的發炎,而其途徑或許與脂締素無直接關係。

    Background: with the increasing prevalence of cardiovascular disease in modern society, pulse wave velocity (PWV) and adiponectin are both predictive markers for cardiovascular diseases in clinical settings. Adiponectin has been found vessel- protective that could exert anti-inflammatory effects and ameliorate atherosclerosis. However, it is still unknown whether inflammatory responses induced by eccentric exercise would interact with adiponectin as well as PWV. Purpose: to determine the effects of muscle damage induced by acute downhill running and eccentric resistance exercise on adiponectin and PWV as well as the relationship between adiponectin and PWV. Methods: eighteen apparent healthy males were recruited to participate this study. Participants were randomly assigned into downhill running (EE, n=9) and eccentric resistance exercise (RE, n=9) groups. Maximal oxygen uptake (VO2peak= 50.5 ± 7.6 ml/kg/min) of EE and one prepetition maximum of inclined leg press (1RM= 222.4 ± 55.2 kg) were determined prior to experiment. EE group performed 30 minutes of the downhill running at -10° of slope that could elicit 75% of individual VO2peak whereas RE group performed 120% 1RM eccentric contractions for 6 reps × 10 sets. PWV, serum adiponectin, creatine kinese (CK), and C-reactive protein (CRP) were measured pre-exercise, 90 minutes, 24 and 48 hours post-exercise. Results: CK of EE and RE group were significantly higher than the pre-exercise (p<.05); PWV of two groups were also significantly higher on 24 (5.47 ± 0.59 m/s) and 48 hours post-exercise (5.44 ± 0.68 m/s) as compared to pre-exercise (5.18 ± 0.47 m/s) (p<.05) respectively. Compared with pre-exercise, adiponectin and CRP were no altered after performing eccentric exercise (p>.05). However, PWV was negative correlated with adiponectin on 24 hours post-exercise (r= -.501) (p<.05). There were no significant differences among groups in all dependent variables (p>.05). Conclusion: muscle damage induced by an acute bout of downhill running and eccentric resistance exercise both increased PWV, but did not altered adiponectin response. This transient aortic arterial inflammatory may not directly relate to adiponectin.

    中文摘要...................................................i 英文摘要...................................................ii 謝誌.....................................................iii 目次.....................................................iv 後篇部分..................................................vi 表次....................................................vii 圖次...................................................viii 第壹章 緒論 第一節 問題背景.............................................1 第二節 研究目的.............................................2 第三節 研究假設.............................................2 第四節 名詞操作性定義.......................................2 第五節 研究限制.............................................4 第六節 研究的重要性.........................................4 第貳章 文獻探討 第一節 PWV、脂締素其影響因子與動脈硬化之相關研究...............5 第二節 離心運動對 PWV 的影響.................................7 第三節 離心運動與脂締素的關係................................9 第四節 本章總結............................................10 第参章 研究方法與步驟 第一章 受試對象...........................................11 第二章 實驗時間...........................................11 第三章 實驗流程...........................................11 第四章 實驗工具與測驗方法..................................14 第五章 檢測分析...........................................17 第六章 資料處理...........................................20 第肆章 結果 第一節 受試者基本資料 .....................................21 第二節 脈波傳導速率 .......................................22 第三節 脂締素 ............................................23 第四節 脈波傳導速率與脂締素變化量之相關......................24 第五節 血液中 CK、CRP 濃度 ................................25 第六節 肌肉酸痛指數........................................27 第伍章 討論與建議 第一節 血液中 CK、CRP 濃度與肌肉酸痛指數.....................28 第二節 脈波傳導速率........................................29 第三節 脂締素 ............................................30 第四節 脈波傳導速率與脂締素變化量之相關性.....................31 第五節 結論與建議..........................................32 參考文獻 中文文獻...................................................33 英文文獻...................................................33 後篇部分 一 附錄 附錄一 受試者需知 ..........................................39 附錄二 受試者健康問卷調查表 .................................40 附錄三 受試者同意書 ........................................41 附錄四 最大肌肉力量記錄表 ...................................42 附錄五 攝氧峰值記錄表 .......................... ...........43 附錄六 各依變項之原始資料表..................................44 附錄七 不同組別與不同時間點之 PWV 變異數分析摘要...............45 附錄八 不同組別與不同時間點之脂締素變異數分析摘要表............ 45 附錄九 不同組別與不同時間點之 CK 變異數分析摘要表..............45 附錄十 不同組別與不同時間點之 CRP 變異數分析摘要表.............46 附錄十一 不同組別與不同時間點之肌肉酸痛指標變異數分析摘要表......46 表次 表 4-1 受試者基本資料.......................................21 表 4-2 離心運動後 PWV 與脂締素濃度變化量之相關................24 圖次 圖 1-1 脈波傳導速率量測方式..................................3 圖 1-2 單次離心運動與脂締素及脈波傳導速率關係之示意圖............4 圖 3-1 實驗流程圖..........................................13 圖 3-2 實驗處理操作流程圖 ..................................14 圖 3-3 離心阻力運動步驟說明.................................16 圖 3-4 本研究受試者接受離心阻力運動的情形 ....................16 圖 3-5 本研究下坡跑採用跑步機................................17 圖 3-6 本研究受試者接受下坡跑運動的情形.......................17 圖 3-7 本研究受試者接受專業護士採血的情形.....................18 圖 3-8 applanation tonometry 波形偵測器....................19 圖 4-1 下坡跑與離心阻力運動組在不同時間點之脈波傳導速率的變化....22 圖 4-2 下坡跑與離心阻力運動組在不同時間點之脂締素濃度的變化.....23 圖 4-3 下坡跑與離心阻力運動組在不同時間點之 CK 濃度的變化.......25 圖 4-4 下坡跑與離心阻力運動組在不同時間點之 CRP 濃度的變化......26 圖 4-5 下坡跑與離心阻力運動組在不同時間點之肌肉酸痛指數的變化....27

    內政部(2011)。內正統計通報。2011年11月12日,取自內政部統計處
    http://sowf.moi.gov.tw/stat/week/week10040.doc

    吳家慶(2005)。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。
    未出版碩士論文,國立臺灣師範大學,臺北市。

    陳忠慶(2004)。運動引起肌肉損傷的原因之探討。運動生理暨體能學報,1,
    19-32。

    陳姿吟(譯)(2007)。精篇圖解生理學。臺北市:合記。(Ward, J. P.,
    Clark, R. W., & Linden, R. W. A., 2004)

    衛生署(2011)。民國99年死因結果摘要表。2011年11月12日,取自行政院
    衛生署http://www.doh.gov.tw/CHT2006/DM/DM2_2_p02.aspx?
    class_no=440&now_fod_list_no=11962&level_no=4&doc_no=
    81294

    American College of Sports Medicine. (2006). ACSM’s
    guideline for exercise testing and prescription.
    Baltimore : Lippincott Williams and Wilkins.

    Asmar, R., Benetos, A., Topouchian, J., Laurent, P.,
    Pannier, B., Brisac, A. M., & Levy, B. I. (1995).
    Assessment of arterial distensibility by automatic
    pulse wave velocity measurement :validation and
    clinical application studies. Hypertension, 26(3), 485-
    490.

    Barnes, J. N., Trombold, J. R., Dhindsa, M., Lin, H. F., &
    Tanaka, H. (2010). Arterial stiffening following
    eccentric exercise-induced muscle damage. Journal of
    Applied Physiology, 109(4), 1102-1108.

    Berggren, J. R., Hulver, M. W., & Houmard, J. A. (2005).
    Fat as an endocrine organ: influence of exercise.
    Journal of Applied Physiology, 99(2), 757-764.

    Blacher, J., Asmar, R., Djane, S., London, G. M., & Safar,
    M. E. (1999). Aortic pulse wave velocity as a marker of
    cardiovascular risk in hypertensive patients. Journal
    of Hypertension, 33(5), 1111-1117.

    Blacher, J., & Safar, M. E. (2005). Large-artery stiffness,
    hypertension and cardiovascular risk in older patients.
    Nature Clinical Practice Cardiovascular Medicine, 2(9),
    450-455.

    Borg, G. A. (1982). Psychophysical bases of perceived
    exertion. Medicine and Science in Sports and Exercise,
    14(5), 377-381.

    Bruce, R. A., & Dehn, M. M. (1972). Longitudinal variations
    in maximal oxygen intake with age and activity. Journal
    of Applied Physiology, 33(6), 805-807.

    Byrne, C., & Eston, R. (2002). Maximal-intensity isometric
    and dynamic exercise performance after eccentric muscle
    actions. Journal of Sports Sciences, 20(12), 951-959.

    Chen, H. L., & Chen, C. C. (2004). Effects of a single bout
    of intensive eccentric contractions at varying
    repetitions on muscle damage. Annual Journal of
    Physical Education and Sports Science, (4), 103-117.

    Cortez-Cooper, M. Y., DeVan, A. E., Anton, M. M., Farrar,
    R. P., Beckwith, K. A., Todd, J. S., & Tanaka, H.
    (2005). Effects of high intensity resistance training
    on arterial stiffness and wave reflection in women.
    American Journal of Hypertension, 18(7), 930-934.

    Coutinho, T., Rooke, T. W., & Kullo, I. J. (2011). Arterial
    dysfunction and functional performance in patients with
    peripheral artery disease: A review. Vascular Medicine,
    16(3), 203-211.

    Cruickshank, J. M., & Smith, J. C. (1989). The beta-
    receptor, atheroma and cardiovascular damage.
    Pharmacology and Therapeutics, 42(3), 385-404.

    Deepa, S. S., & Dong, L. Q. (2009). APPL1: Role in
    adiponectin signaling and beyond. American Journal of
    Physiology-Endocrinology and Metabolism, 296(1), E22-
    E36.

    DeVan, A. E., Anton, M. M., Cook, J. N., Neidre, D. B.,
    Cortez-Cooper, M. Y., & Tanaka, H. (2005). Acute
    effects of resistance exercise on arterial compliance.
    Journal of Applied Physiology, 98(6), 2287-2291.

    Diez, J. J., & Iglesias, P. (2003). The role of the novel
    adipocyte-derived hormone adiponectin in human disease.
    European Journal of Endocrinology, 148(3), 293-300.

    Drexel, H., Saely, C. H., Langer, P., Loruenser, G., Marte,
    T., Risch, L., & Aczel, S. (2008). Metabolic and anti-
    inflammatory benefits of eccentric endurance exercise -
    A pilot study. European Journal of Clinical
    Investigation, 38(4), 218-226.

    Engeli, S., Feldpausch, M., Gorzelniak, K., Hartwig, F.,
    Heintze, U., Janke, J., & Sharma, A. M. (2003).
    Association between adiponectin and mediators of
    inflammation in obese women. American Diabetes
    Association, 52(4), 942-947.

    Ferguson, M. A., White, L. J., McCoy, S., Kim, H. W.,
    Petty, T., & Wilsey, J. (2004). Plasma adiponectin
    response to acute exercise in healthy subjects.
    European Journal of Applied Physiology, 91(2-3), 324-
    329.

    Fernandez-Real, J. M., Lopez-Bermejo, A., Casamitjana, R.,
    & Ricart, W. (2003). Novel interactions of adiponectin
    with the endocrine system and inflammatory parameters.
    Journal of Clinical Endocrinology and Metabolism, 88
    (6), 2714-2718.

    Fitzgerald, G. K., Rothstein, J. M., Mayhew, T. P., & Lamb,
    R. L. (1991). Exercise-Induced muscle soreness after
    concentric and eccentric isokinetic
    contractions.Physical Therapy, 71(7), 505-513.

    Han, S. H., Quon, M. J., Kim, J., & Koh, K. K. (2007).
    Adiponectin and cardiovas-cular disease - Response to
    therapeutic interventions. Journal of the American
    College of Cardiology, 49(5), 531-538.

    Heffernan, K. S., Collier, S. R., Kelly, E. E., Jae, S. Y.,
    & Fernhall, B. (2007). Arterial stiffness and
    baroreflex sensitivity following bouts of aerobic and
    resistance exercise. International Journal of Sports
    Medicine, 28(3), 197-203.

    Jurimae, J., Hofmann, P., Jurimae, T., Maestu, J., Purge,
    P., Wonisch, M., & von Duvillard, S. P. (2006). Plasma
    adiponectin response to sculling exercise at individual
    anaerobic threshold in college level male rowers.
    International Journal of Sports Medicine, 27(4), 272-
    277.

    Jurimae, J., Purge, P., & Jurimae, T. (2005). Adiponectin
    is altered after maximal exercise in highly trained
    male rowers. European Journal of Applied Physiology,93
    (4), 502-505.

    Kingwell, B. A., Berry, K. L., Cameron, J. D., Jennings, G.
    L., & Dart, A. M. (1997). Arterial compliance increases
    after moderate-intensity cycling. American Journal of
    Physiology-Heart and Circulatory Physiology, 273(5),
    H2186-H2191.

    Kobayashi, H., Ouchi, N., Kihara, S., Walsh, K., Kumada,
    M., Abe, Y., & Matsuzawa, Y. (2004). Selective
    suppression of endothelial cell apoptosis by the high
    molecular weight form of adiponectin. Circulation
    Research, 94(4), E27-E31.

    Kraemer, R. R., Aboudehen, K. S., Carruth, A. A., Durand,
    R. J., Acevedo, E. O., & Castracane, V. D. (2003).
    Adiponectin responses to continuous and progressively
    intense intermittent exercise. The Journal of the
    Federation of American Societies for Experimental
    Biology, 17(5), A943-A944.

    Kraemer, R. R., & Castracane, V. D. (2007). Exercise and
    humoral mediators of peripheral energy balance: Ghrelin
    and adiponectin. Experimental Biology and Medicine, 232
    (2), 184-194.

    Lieber, R. L., & Friden, J. (2002). Mechanisms of muscle
    injury gleaned from animal models. American Journal of
    Physical Medicine and Rehabilitation, 81(11), S70-S79.

    London, G. M., & Guerin, A. P. (1999). Influence of
    arterial pulse and reflected waves on blood pressure
    and cardiac function. American Heart Journal, 138(3),
    220-224.

    Maeda, S., Otsuki, T., Iemitsu, M., Kamioka, M., Sugawara,
    J., Kuno, S., & Tanaka, H. (2006). Effects of leg
    resistance training on arterial function in older men.
    British Journal of Sports Medicine, 40(10), 867-869.

    Mahmud, A., & Feely, J. (2005). Adiponectin and arterial
    stiffness. American Journal of Hypertension, 18(12),
    1543-1548.

    Marinou, K., Tousoulis, D., Antonopoulos, A. S., Stefanadi,
    E., & Stefanadis, C. (2010). Obesity and cardiovascular
    disease: From pathophysiology to risk stratification.
    International Journal of Cardiology, 138(1), 3-8.

    McMiken, D. F., & Daniels, J. T. (1976). Aerobic
    requirements and maximum aerobic power in treadmill and
    track running. Medicine and Science in Sports and
    Exercise, 8(1), 14-17.

    Miyachi, M., Kawano, H., Sugawara, J., Takahashi, K.,
    Hayashi, K., Yamazaki, K., & Tanaka, H. (2004).
    Unfavorable effects of resistance training on central
    arterial compliance - A randomized intervention study.
    Circulation, 110(18), 2858-2863.

    Nosaka, K., & Clarkson, P. M. (1996). Changes in indicators
    of inflammation after eccentric exercise of the elbow
    flexors. Medicine and Science in Sports and Exercise, 28
    (8), 953-961.

    Nosaka, K., Newton, M., & Sacc, P. (2002). Delayed-onset
    muscle soreness does not reflect the magnitude of
    eccentric exercise-induced muscle damage.Scandinavian
    Journal of Medicine and Science in Sports, 12(6), 337-
    346.

    Okamoto, T., Masuhara, M., & Ikuta, K. (2006). Effects of
    eccentric and concentric resistance training on
    arterial stiffness. Journal of Human Hypertension, 20
    (5), 348-354.

    Paschalis, V., Nikolaidis, M. G., Giakas, G., Theodorou, A.
    A., Sakellariou, G. K., Fatouros, I. G., & Jamurtas, A.
    Z. (2010a). Beneficial changes in energy expenditure
    and lipid profile after eccentric exercise in
    overweight and lean women. Scandinavian Journal of
    Medicine and Science in Sports, 20(1), e103-111.

    Paschalis, V., Nikolaidis, M. G., Theodorou, A. A.,
    Panayiotou, G., Fatouros, I. G., Koutedakis, Y., &
    Jamurtas, A. Z. (2010b). A weekly bout of eccentric
    exercise is sufficient to induce health-promoting
    effects. Medicine and Science in Sports and Exercise, 43
    (1), 64-73.

    Peake, J., Nosaka, K., & Suzuki, K. (2005).Characterization
    of inflammatory responses to eccentric exercise in
    humans. Exercise Immunology Review, 11, 64-85.

    Pischon, T., Girman, C. J., Hotamisligil, G. S., Rifai, N.,
    Hu, F. B., & Rimm, E. B.(2004). Plasma adiponectin
    levels and risk of myocardial infarction in men.The
    Journal of the American Medical Association, 291(14),
    1730-1737.

    Punyadeera, C., Zorenc, A. H. G., Koopman, R., McAinch, A.
    J., Smit, E., Manders, R., & van Loon, L. J. C. (2005).
    The effects of exercise and adipose tissue lipolysis on
    plasma adiponectin concentration and adiponectin
    receptor expression in human skeletal muscle. European
    Journal of Endocrinology, 152 (3), 427-436.

    Roig, M., O'Brien, K., Kirk, G., Murray, R., McKinnon, P.,
    Shadgan, B., & Reid, W. D. (2008). The effects of
    eccentric versus concentric resistance training on
    muscle strength and mass in healthy adults: A
    systematic review with meta-analysis. British Journal
    of Sports Medicine, 43(8), 556-568.

    Sato, H., Hayashi, J., Harashima, K., Shimazu, H., &
    Kitamoto, K. (2005). A population-based study of
    arterial stiffness index in relation to cardiovascular
    risk factors. Journal of Atherosclerosis and
    Thrombosis, 12(3), 175-180.

    Saxton, J. M., Donnelly, A. E., & Roper, H. P. (1994).
    Indices of free-radical-mediated damage following
    maximum voluntary eccentric and concentric muscular
    work. European Journal of Applied Physiology and
    Occupational Physiology, 68(3), 189-193.

    Schwane, J. A., Johnson, S. R., Vandenakker, C. B., &
    Armstrong, R. B. (1983). Delayed-onset muscular
    soreness and plasma CPK and LDH activities after
    downhill running. Medicine and Science in Sports and
    Exercise, 15(1), 51-56.

    Simpson, K. A., & Singh, M. A. (2008). Effects of exercise
    on adiponectin: A systematic review. Journal of
    Obesity, 16(2), 241-256.

    Sung, S. H., Chuang, S. Y., Sheu, W. H., Lee, W. J., Chou,
    P., & Chen, C. H. (2009). Relation of adiponectin and
    high-sensitivity C-reactive protein to pulse-wave
    velocity and N-terminal pro-B-type natriuretic peptide
    in the general population. The American Journal of
    Cardiology, 103(10), 1411-1416.

    Thomas, S., Reading, J., & Shephard, R. J. (1992). Revision
    of the physical-activity readiness questionnaire (Par
    -Q). Canadian Journal of Sport Sciences-Revue
    Canadienne Des Sciences Du Sport, 17(4), 338-345.

    Totsuka, M., Nakaji, S., Suzuki, K., Sugawara, K., & Sato,
    K. (2002). Break point of serum creatine kinase release
    after endurance exercise. Journal of Applied
    Physiology, 93(4), 1280-1286.

    Vaiopoulos, A. G., Marinou, K., Christodoulides, C., &
    Koutsilieris, M. (2012). The role of adiponectin in
    human vascular physiology. International Journal of
    Cardiology, 155(2), 188-193.

    Vallejo, A. F., Schroeder, E. T., Zheng, L., Jensky, N. E.,
    & Sattler, F. R. (2006). Cardiopulmonary responses to
    eccentric and concentric resistance exercise in older
    adults. Age and Ageing, 35(3), 291-297.

    Varady, K. A., Bhutani, S., Church, E. C., & Phillips, S.
    A. (2010). Adipokine responses to acute resistance
    exercise in trained and untrained men. Medicine and
    Science in Sports and Exercise, 42(3), 456-462.

    Verma, S., Li, S. H., Badiwala, M. V., Weisel, R. D.,
    Fedak, P. W. M., Li, R. K., & Mickle, D. A. G. (2002).
    Endothelin antagonism and interleukin-6 inhibition
    attenuate the proatherogenic effects of C-reactive
    protein. Circulation, 105(16), 1890-1896.

    Vlachopoulos, C., Dima, I., Aznaouridis, K., Vasiliadou,
    C., Ioakeimidis, N., Aggeli, C., & Stefanadis, C.
    (2005). Acute systemic inflammation increases arterial
    stiffness and decreases wave reflections in healthy
    individuals. Circulation, 112(14), 2193-2200.

    Yang, W. S., Lee, W. J., Funahashi, T., Tanaka, S.,
    Matsuzawa, Y., Chao, C. L., & Chuang, L. M. (2001).
    Weight reduction increases plasma levels of an adipose-
    derived anti-inflammatory protein, adiponectin. Journal
    of Clinical Endocrinology and Metabolism, 86(8), 3815-
    3819.

    Youn, J. C., Kim, C., Park, S., Lee, S. H., Kang, S. M.,
    Choi, D., & Jang, Y. (2011). Adiponectin and
    progression of arterial stiffness in hypertensive
    patients. International Journal of Cardiology, 1-4.

    Zhu, W. D., Cheng, K. K. Y., Vanhoutte, P. M., Lam, K. S.
    L., & Xu, A. M. (2008). Vascular effects of
    adiponectin: molecular mechanisms and potential
    therapeutic intervention. Clinical Science, 114(5-6),
    361-374.

    下載圖示
    QR CODE