Порівняння фази ізокапнічної буферизації лижників по пересіченій місцевості і альпійських лижників
DOI:
https://doi.org/0.15561/18189172.2018.0406Ключові слова:
буферна ємність, максимальне поглинання кисню, поріг вентиляції, точка дихальної компенсаціїАнотація
Мета: Мета цього дослідження полягала в тому, щоб порівняти етап ізокапнічної буферизації у лижників по пересіченій місцевості і альпійських лижників під час інстинктивного тренувального тесту на біговій доріжці. Матеріал: атлети міжнародного рівня, в тому числі дванадцять лижників по пересіченій місцевості і десять альпійських лижників, взяли участь в дослідженні. Всі учасники виконали інстинктивну вправу на біговій доріжці, щоб визначити поріг вентиляції (VT), точку компенсації дихання (RCP) і максимальне поглинання кисню (VO2max). Фаза ізокапнічної буферизації була розрахована як різниця в VO2 (ICBVO2) і швидкості руху (ICBSPEED) між RCP і VT і виражена або в абсолютних, або у відносних значеннях. Результати: VO2max, максимальна швидкість руху, час до виснаження, як абсолютні, так і відносні значення VT і абсолютні значення RCP були вище у лижників по пересіченій місцевості, ніж у альпійських лижників (P -0,05), тоді як відносна RCP показала подібні значення в обох групах (p- 0,05). Абсолютні ICBVO2 і ICBSPEED показали подібні значення в обох групах (p- 0,05), тоді як відносні ICBVO2 і ICBSPEED були виявлені значно вище у альпійських лижників, ніж у лижників по пересіченій місцевості (P -0,05). Максимальний рівень обміну дихальних шляхів був вище у альпійських лижників, ніж у лижників. Висновки. Існуючі результати показують, що анаеробне тренування може викликати специфічні метаболічні адаптації, що призводять до збільшення буферної здатності, що може бути чинником, що сприяє продовженню вправ протягом відносно тривалих періодів часу над VT. Більш тривала фаза ICB у атлетів, які пройшли анаеробну підготовку, може стати важливим фактором у відношенні підвищення толерантності до фізичного навантаження.Посилання
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Ivy JL, Withers RT, Van Handel PJ, Elger DH, Costill DL. Muscle respiratory capacity and fiber type as determinants of the lactate threshold. Journal of applied physiology: respiratory, environmental and exercise physiology. 1980;48:523–527.
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Edge J, Bishop D, Goodman C. The effects of training intensity on muscle buffer capacity in females. European journal of applied physiology. 2006;96:97–105.
Sharp RL, Costill DL, Fink WJ, King DS. Effects of eight weeks of bicycle ergometer sprint training on human muscle buffer capacity. International Journal of Sports Medicine. 1986;7:13–17.
Nakagawa Y, Hattori M. Relationship between muscle buffering capacity and fiber type during anaerobic exercise in human. Journal of physiological anthropology and applied human science. 2002;21:129–131.
Parkhouse WS, Mckenzie DC. Possible contribution of skeletal muscle buffer to enhanced anaerobic performance: a brief review. Medicine and science in sports and exercise. 1984;16:328–338.
Edge EJ, Bishop D, Hill-Haas S, Dawson B, Goodman C. Comparison of muscle buffer capacity and repeated-sprint ability of untrained, endurance-trained and team-sport athletes. European journal of applied physiology. 2006;96:225–234.
Stringer W, Wasserman K, Casaburi R. The VCO2/VO2 relationship during heavy, constant work rate exercise reflects the rate of lactic acid accumulation. European journal of applied physiology and occupational physiology. 1995;72: 25–31.
Holloszy JO, Coyle EF. Adaptations of skeletal muscle to endurance exercise and their metabolic consequences. Journal of applied physiology: respiratory, environmental and exercise physiology. 1984;56(4):831–838.
Mohr M, Krustrup P, Nielsen JJ, Nybo L, Rasmussen MK, Juel C, et al. Effect of two different intense training regimens on skeletal muscle ion transport proteins and fatigue development. American journal of physiology. Regulatory, integrative and comparative physiology. 2007;292:1594–1602.
Beaver WL, Wasserman K, Whipp BJ. A new method for detecting the anaerobic threshold by gas exchange. Journal of applied physiology. 1986;60:2020–2027.
Wasserman K. The anaerobic threshold measurement to evaluate exercise performance. American review of respiratory disease. 1984;129:35–40.
Meyer T, Faude O, Scharhag J, Urhausen A, Kindermann W. Is lactic acidosis a cause of exercise induced hyperventilation at the respiratory compensation point? British journal of sports medicine. 2004;38:622–625.
Whipp BJ, Davis JA, Wasserman K. Ventilatory control of the 'isocapnic buffering' region in rapidly-incremental exercise. Respiration physiology. 1989;76(3):357–67.
Chicharrro J, Hoyos J, Lucia A. Effects of endurance training on the isocapnic buffering and hypocapnic hyperventilation phases in Professional cyclists. British journal of sports medicine. 2000;34:450–455.
Oshima Y, Miyamoto T, Tanaka S, Wadazumi T, Kurihara N, Fujimoto S. Relationship between isocapnic buffering and maximal aerobic capacity in athletes. European journal of applied physiology and occupational physiology. 1997;76:409–14.
Hasanli M, Nikooie R, Aveseh M, Mohammad F. Prediction of aerobic and anaerobic capacities of elite cyclists from changes in lactate during isocapnic buffering phase. Journal of strength and conditioning research. 2015;29(2):321–9.
Takano N. Respiratory compensation point during incremental exercise as related to hypoxic ventilatory chemosensitivity and lactate increase in man. The Japanese journal of physiology. 2000;50(4):449–55.
Rausch SM, Whipp BJ, Wasserman K, Huszczuk A. Role of the carotid bodies in the respiratory compensation for the metabolic acidosis of exercise in humans. The Journal of physiology. 1991;444:567–78.
Hirakoba K, Yunoki T. Blood lactate changes during isocapnic buffering in sprinters and long distance runners. Journal of physiological anthropology and applied human science. 2002;21(3):143–9.
Bentley DJ, Vleck VE, Millet GP. The isocapnic buffering phase and mechanical efficiency: Relationship to cycle time trial performance of short and long duration. Canadian Society for Exercise Physiology. 2005;30(1):46–60.
Röcker, K., Striegel, H., Freund, T., Dickhuth, H.,H., Relative functional buffering capacity in 400-meter runners, long-distance runners and untrained individuals. European journal of applied physiology and occupational physiology. 1994;68:430–434.
Staib JL, Im J, Caldwell Z, Rundell KW. Cross-country ski racing performance predicted by aerobic and anaerobic double poling power. Journal of strength and conditioning research. 2000;14(3):282–288.
Holmberg HC. The elite cross-country skier provides unique insights into human exercise physiology. Scandinavian Journal of Medicine & Science in Sports. 2015;25(4):100–109.
Sandbakk Ø, Holmberg HC. A reappraisal of success factors for olympic cross-country skiing. International journal of sports physiology and performance. 2014;9(1):117–21.
White AT, Johnson SC. Physiological comparison of international, national and regional alpine skiers. International Journal of Sports Medicine. 1991;12(4):374–378.
Hydren JR, Volek JS, Maresh CM, Comstock BA, Kraemer WJ. Review of strength and conditioning for alpine ski racing. Strength & Conditioning Journal. 2013;35:10–28.
Bosco C, Cotelli F, Bonomi R, Mognoni P, Roi GS. Seasonal fluctuations of selected physiological characteristics of elite alpine skiers. European journal of applied physiology and occupational physiology.1994;69:71–74.
Oshima Y, Tanaka S, Miyamoto T. Effects of endurance training above the anaerobic threshold on isocapnic buffering phase during incremental exercise in middle-distance runners. Japanese Journal of Physical Fitness and Sports Medicine. 1998;47:43–52.
Thalheimer W, Cook S. How to calculate effect sizes from published research articles: A simplified methodology. [Internet]. 2002 [updated 2016 Feb 10; cited 2016 Apr 10]. Available from:http://work learning.com/effect_sizes.htm
Lenti M, De Vito G, Scotto di Palumbo A, Sbriccoli P, Quattrini FM, Sacchetti M. Effects of aging and training status on ventilatory response during incremental cycling exercise. Journal of strength and conditioning research. 2011;25(5):1326–1332.
Parkhouse WS, Mckenzie DC, Hochachka PW, Ovalle WK. Buffering capacity of deproteinized human vastuslateralis muscle. Journal of applied physiology. 1985;58:14–17.
Helgerud J. Maximal oxygen uptake, anaerobic threshold and running economy in women and men with similar performance levels in marathons. European journal of applied physiology and occupational physiology. 1994;68:155-61.
Docherty D, Sporer B. A proposed model for examining the interference phenomenon between concurrent aerobic and strength training. Sports medicine. 2000;30(6):385–94.
Ivy JL, Withers RT, Van Handel PJ, Elger DH, Costill DL. Muscle respiratory capacity and fiber type as determinants of the lactate threshold. Journal of applied physiology: respiratory, environmental and exercise physiology. 1980;48:523–527.
Bishop D, Girard O, Mendez-Villanueva A. Repeated-Sprint Ability – Part II Recommendations for Training. Sports medicine. 2011;41(9):741–756.
Edge J, Bishop D, Goodman C. The effects of training intensity on muscle buffer capacity in females. European journal of applied physiology. 2006;96:97–105.
Sharp RL, Costill DL, Fink WJ, King DS. Effects of eight weeks of bicycle ergometer sprint training on human muscle buffer capacity. International Journal of Sports Medicine. 1986;7:13–17.
Nakagawa Y, Hattori M. Relationship between muscle buffering capacity and fiber type during anaerobic exercise in human. Journal of physiological anthropology and applied human science. 2002;21:129–131.
Parkhouse WS, Mckenzie DC. Possible contribution of skeletal muscle buffer to enhanced anaerobic performance: a brief review. Medicine and science in sports and exercise. 1984;16:328–338.
Edge EJ, Bishop D, Hill-Haas S, Dawson B, Goodman C. Comparison of muscle buffer capacity and repeated-sprint ability of untrained, endurance-trained and team-sport athletes. European journal of applied physiology. 2006;96:225–234.
Stringer W, Wasserman K, Casaburi R. The VCO2/VO2 relationship during heavy, constant work rate exercise reflects the rate of lactic acid accumulation. European journal of applied physiology and occupational physiology. 1995;72: 25–31.
Holloszy JO, Coyle EF. Adaptations of skeletal muscle to endurance exercise and their metabolic consequences. Journal of applied physiology: respiratory, environmental and exercise physiology. 1984;56(4):831–838.
Mohr M, Krustrup P, Nielsen JJ, Nybo L, Rasmussen MK, Juel C, et al. Effect of two different intense training regimens on skeletal muscle ion transport proteins and fatigue development. American journal of physiology. Regulatory, integrative and comparative physiology. 2007;292:1594–1602.
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2018-08-30
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Korkmaz ES, Polat M. Порівняння фази ізокапнічної буферизації лижників по пересіченій місцевості і альпійських лижників. Pedagogics, psychology, medical-biological problems of physical training and sports. 30, Серпень 2018;22(4):203-9. доступний у0.15561/18189172.2018.0406
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