젖산에 의한 혈관 이완: Brief review

서지반출

국문초록

혐기성 해당과정은 젖산을 생성하며, 일부 혈관에서 혈관이완을 유도한다. 현재까지 젖산의 혈관이완은 혈관내피세포 의존적, 그리고 내피세포 독립적으로 이완을 유도한다고 제시되고 있다. 그러나 운동 중 증가되는 젖산이 혈관이완을 어떠한 기전으로 유 도하는지 불명확하며, 운동과학분야에서의 연구결과는 보고되고 있지 않다. 따라서 이 종설은 현재까지 기초연구분야에서 소개된 젖산의 혈관 이완 반응을 중심으로 논의하고, 운동과학분야의 적용에 대해 제안하였다

영문초록

Lactate is produced by anaerobic glycolysis and it is induced vasodilation in some artery. Currently, lactate-induced vasodilation has been suggested endothelial cell dependent and independent manner. However, the increased lactate contribute to vasodilation during exercise is unclear and it has not been reported in exercise science. Therefore, we discuss the vasodilation caused by lactate around the reported findings in basic science, and it is suggested to apply the field of exercise science.

키워드

lactate vasodilation nitric oxide endothelial cells

참고문헌 (30건)

강대길 외 26인 공역(2002). 의학 생리학. 서울, 정담.
이원재, 박기덕, 최경식(2001). 단거리 육상선수들의 최대운동 후 회복능력에 관한 연구. 한국체육학회지, 29(2), 2317-2330.
Arakawa, K. (1993). Antihypertensive mechanism of exercise. Journal of Hypertension, 11(7), 223-229.
Blair, S. N., Cheng, Y., & Holder, J. S. (2001). Is physical activity or physical fitness more important in defining health benefits?Medicine and Science in Sports and Exercise, 33(suppl 6), S379-399.
Brooks, G. A. (2002). Lactate shuttles in nature. Biomedical Society Transactions, 30(2), 258-264.
Cairns, S. P.(2006). Lactic acid and exercise performance-culprit or friend? Sports Medicine, 36(4), 279-297.
Crespo, C. J., Palmieri, M. R., Perdomo, R. P., Mcgee, D. L., Smit, E., Sempos, C. T., Lee, I. M., & Sorlie, P. D. (2002). The relationship of physical activity and body weight with all-cause mortality: results from the Puerto Rico Heart Health Program. Annals of Epidemiology, 12(8), 543-552.
Frøbert, O., Mikkelsen, E. O., Bagger, J. P., & Gravholt, C. H. (2002). Measurement of interstitial lactate during hypoxia-induced dilatation in isolated pressurised porcine coronary arteries. Journal of Physiology, 539(pt 1), 277-284.
Gaskell, W. H. (1880). On the tonicity of the heart and blood vessels. Journal of Physiology, 3, 48-75.
Gladden, L. B. (2004). Lactate metabolism: Journal of Physiology, 558(1), 5-30.
Hein, T. W., Xu, W., & Kuo L. (2006). Dilation of retinal arterioles in response to lactate: Role of nitric oxdie, guanylyl cyclase, and ATP-sensitive potassium channels. Investigative Ophthalmology and Visual Science, 47(2), 693-699.
Hester, R. K., Weiss, G. B., & Willerson, J. T. (1980). Basis of pH-independent inhibitory effects of lactate on 45Ca movements and responses to KCl and PGF2 alpha in canine coronary arteries. Circulation Research, 46(6), 771-779.
Higashi, Y., Sasaki, S., Nakagawa, K., Matsuura, H., Oshima, T., & Chayama, K. (2002). Endothelial function and oxidative stress in renovascular hypertension. New England Journal of Medicine, 346(25), 1954-1962.
Higashi, Y., & Yoshizumi, M. (2004). Exercise and endothelial function: role of endothelium-derived nitric oxide and oxidative stress in healthy subjects and hypertensive patients. Pharmacology and Therapeutics, 102(1), 87-96.
Hultman, E., & Sahlin, K. (1980). Acid-base balance during exercise. Exercise Sport Science Review, 8, 41-128.
Kohno, H., Furukawa, S., Naito, H., Minamitani, K., Ohmori, D., & Yamakura, F. (2002). Contribution of nitric oxide, angiotensin II and uperoxide dismutase to exercise-induced attenuation of blood pressure elevation in spontaneously hypertensive rats. Japanese Heart Journal, 43(1), 25-34.
Kuru, O., Sentürk, U. K., Demir, N., Yeşilkaya, A., Ergüler, G., &　Erkilic, M. (2002). Effect of exercise on blood pressure in rats with chronic NOS inhibition. European Journal of Applied Physiology, 87(2), 134-140.
McKinnon W. Aaronson PI, Knock G, Graves J, Poston L. (1996). Mechanism of lactate-induced relaxation of isolated rat mesenteric resistance arteries. Journal of Physiology, 490(3), 783-792.
Mendrinos E, Petropoulos IK, Mangioris G, Papadopoulou DN, Stangos AN, Pournaras CJ. (2008). Lactate-induced retinal arteriolar vasodilation implicates neuronal nitric oxide synthesis in minipigs. Investigative Ophthalmology and Visual Science, 49(11), 5060-5066.
Miller, F. N., Nolph, K. D., Joshua, I. G., Wiegman, D. L., Harris, P. D., & Andersen, D. B. (1981). Hyperosmolality, acetate, and lactate: dilatory factors during peritoneal dialysis. Kidney International, 20(3), 397-402.
Montoya, J. J., Fernandez, N., Monge, L., Dieguez, G., & Villalon, A. (2011). Nitric oxide-mediated relaxation to lactate of coronary circulation in the isolated perfused rat heart. Journal of Cardiovascular Pharmacology, 58(4), 392-398.
Mori, K., Nakaya, Y., Sakamoto, S., Hayabuchi, Y., Matsuoka, S., & Kuroda, Y. (1998). Lactate-induced vascular relaxationin porcine coronary arteries is mediated by Ca2+-activated K+ channels. Journal of Molecular and Cellular Cardiology, 30(2), 349-356.
Omar, H. A., Figueroa, R., Tejani, N., & Wolin, M. S. (1993). Properties of a lactate-induced relaxation in human placental arteries and veins. American Journal of Obstetrics and Gynecology, 169(4), 912-918.
Palmer, W. K. (1988). Effect of exercise on cardiac cyclic AMP. Medicine and Science in Sports and Exercise, 20(6), 525-530.e weight-relapse
Powers, S., & Howley, E. (2012). Exercise Physiology: Theory and Application to Fitness and Performance. 8th Ed., New York, McGraw Hill.
Sessa, W.C., Pritchard, K., Seyedi, N., Wang, J., & Hintze, T. H. (1994). Chronic exercise in dogs increases coronary vascular nitric oxide production and endothelial cell nitric oxide synthase gene expression. Circulation Research, 74(2), 349-353.
Shimizu, S., Bowman, P. S., Thorne, G. 3rd, Paul, R. J. (2000). Effects of hypoxia on isometric force, intracellular Ca(2+), pH, and energetics in porcine coronary artery. Circulation Research, 86(8), 862-870.
Sung, D. J., So, W. Y., Ryu, H. Y., An, H. S., & Cha, K. S. (2012). Induction of vasodilation by hydrogen peroxide and its application in exercise science. Biology of Sport, 29(2), 87-92.
Uhernik, A. L., Li, L., LaVoy, N., Velasquez, M. J,, & Smith, J. P. (2014). Regulation of monocarboxylic acid transporter-1 by cAMP dependent vesicular trafficking in brain microvascular endothelial cells. PLos One, 9(1); e85957.
Végran, F., Boidot, R., Michiels, C., Sonveaux, P., & Feron, O. (2011). Lactate influx through the endothelial cell monocarboxylate transporter MCT1 supports an NF-κB/IL-8 pathway that drives tumor angiogenesis. Cancer Research, 71(7), 2550-2560.

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