Radivoje Radakovic^1,2, Dragan Radovanovic³, Mirsad Nurkic³, Milovan Bratic³, Borko Katanic³

¹University of Kragujevac, Institute for Information Technologies, Kragujevac, Serbia
²University of Kragujevac, Faculty of Pedagogy, Uzice, Serbia
³University of Nis, Faculty of Physical Education and Sport, Nis, Serbia

Relationship between Maximum Oxygen Consumption and Lactate Metabolism with Situational Efficiency of Highly Selected Young Judoists

Sport Mont 2023, 21(2), 63-70 | DOI: 10.26773/smj.230710

Abstract

Judo is often referred to as an explosive sport, which requires great anaerobic strength and capacity, with a well-developed aerobic system. Attaining a high level of physical fitness, strength, and fatigue tolerance is essential for achieving success in competition. Fatigue leads to decreased muscle strength, prolonged reaction time, reduced agility, neuromuscular coordination, overall body speed, concentration, and agility. The intensity at which this phenomenon occurs is known as the lactate threshold. The primary objective of the planned research was to establish a link between maximal oxygen consumption (VO2max), lactate metabolism, and the situational efficiency of selected young judoists. The sample consisted of 30 cadet and junior judo athletes from the national teams of Serbia (average age of 16.43±0.76 years, body height of 176.94±5.15 cm, and body weight of 69.71±10.64 kg). The research employed precisely standardized protocols and modern equipment to determine anthropometric characteristics, and the values of maximal oxygen consumption, lactate thresholds, and the index of a specific judo fitness test among the selected young judo athletes. Based on the obtained results, there was a moderate negative correlation between VO2max and the index of the special judo fitness test, as well as a low correlation between the first lactate threshold (PLAP) and the second lactate threshold (DLAP) with the index of the special judo fitness test (ISJFT). Additionally, a moderate negative correlation was found between VO2max and anthropometric parameters, while PLAP and DLAP exhibited low correlations with anthropometric parameters. The research results quantitatively illustrate the physiological adaptation of the top young judo athletes to the physical demands encountered during years of specific training. The proposed battery of tests can be utilized to assess the functional status of competitors more accurately and determine the competition profile for elite judo athletes.

Keywords

maximal oxygen uptake, VO2max, aerobic capacity, anaerobic capacity, lactate thresholds, specific judo fitness test, elite judokas

View full article
(PDF – 315KB)

References

Almåsbakk, B., & Hoff, J. (1996). Coordination, the determinant of velocity specificity?. Journal of Applied Physiology, 81(5), 2046-2052.

Athayde, M. S. D. S., Kons, R. L., Fukuda, D. H., & Detanico, D. (2021). Body Size Measurements and Physical Performance of Youth Female Judo Athletes with Differing Menarcheal Status. International Journal of Environmental Research and Public Health, 18(23), 12829

Baxter-Jones, A., Goldstein, H., & Helms, P. (1993). The development of aerobic power in young athletes. Journal of Applied Physiology, 75(3), 1160-1167.

Baldwin, J., Snow, R. J., & Febbraio, M. A. (2000). Effect of training status andrelative exercise intensity on physiological responses in men. Medicine & Science in Sports & Exercise, 32, 1648-54.

Bentley, D. J., McNaughton, L. R., & Thompson, D. (2001). Peak poweroutput, the lactate threshold, and time trial performance incyclists. Medicine & Science in Sports & Exercise , 33, 2077-81.

Bassett, D. R., & Howley, E. T. (2000). Limiting factors for maximum oxygen uptake and determinants of endurance performance. Medicine and Science in Sports and Exercise, 32(1),70–84.

Bentley, D. J., Newell, J., & Bishop, D. (2007). Incremental exercise test design and analysis: implications for performance diagnostics in endurance athletes. Sports Medicine, 37(7), 575-586.

Bogdanis, G. C., Nevill, M. E., & Lakomy, H. K. A. (1994). Effects of previous dynamic arm exercise on power output during repeated maximal sprint cycling. Journal of Sports Science, 12, 363-70.

Bogdanis, G. C., Nevill, M. E., Boobis, L. H., & Lakomy, H. K. A. (1996). Contribution of phosphocreatine and aerobic metabolism to energy supply during repeated sprint exercise. Journal of Applied Physiology, 80, 876-84.

Bosquet, L., Leger, L., & Legros, P. (2002). Methods to determine aerobic endurance. Sports Medicine, 32(11), 675-700.

Bradarić, R. (1991). Biohemija (Biochemistry). Novi Sad, Serbia: Fakultet fiziĉke kulture.

Bratić, M., Nurkić, M., & Stanković, N. (2011). Differences in Functional Abilities in Judo Players of Different Age. Sports Science and Health 1(1), 5-11.

Bratić, M., Radovanović, D., & Nurkić, M. (2007). Comparision of functional charactreristics between elite cadet and young senior judo athletes. Proceedings of 14th International Scietific Conference, Belgrade, Serbia. Belgrade: Faculty of Sport and Physical Education.

Callister, R., Callister, R. J., Fleck, S .J., & Dudley, G. A. (1990). Physiological and performance responses to overtraining in elite judo athletes. Medicine & Science in Sports & Exercise, 22, 816-24.

Callister, R., Callister, R. J., Staron, R. S., Fleck, S. J., Tesch,P., & Dudley, G. A. (1991). Physiological characteristics of elite judo athletes. International Journal of Sports Medicine, 12, 196-203.

Cohen J. (1988). Statistical power analysis for the behavioral sciences. 2nd ed. Hillsdale, NJ: Lawrence Erlbaum Associates.

Di Prampero, P. E. (2003). Factors limiting maximal performance in humans. European Journal of Appllied Physiology, 90, 420–429.

Detanico, D., Pupo, J. D., Franchini, E., & Dos Santos, S. G. (2015). Effects of successive judo matches on fatigue and muscle damage markers. The Journal of Strength & Conditioning Research, 29, 1010–1016.

Draper, N., Brent, S., & Hale, B. (2006). The influence of sampling site and assay method on lactate concentration in response to rock climbing. European Journal of Applied Physiology , 98(4), 363-72.

Dzik, K. P., & Kaczor, J. J. (2019). Mechanisms of vitamin D on skeletal muscle function: oxidative stress, energy metabolism and anabolic state. European Journal of Applied Physiology, 119(4), 825–39.

Dopsaj, M. (2008). Struktura karakteristika sile vuče kod plivača merena metodom plivanja u mestu kraul tehnikom u anaerobno-alaktatnom režimu (Structure of strength characteristics in swimmers measured by in-place swimming technique in anaerobic-alactic regime). Godišnjak fakulteta sporta i fizičkog vaspitanja, 14, 28−53.

Eston, R., & Reilly, T. (2001). Kinanthropometry and exercise physiology laboratory manual: tests, procedures and data. Volume 2: Exercise physiology. 2nd edition. London: Routledge.

Faude, O., Kindermann, T., & Meye, T. (2009). Lactate threshold concepts: how valid are they? Sports Medicine, 39(6), 469-490.

Franchini, E., & Sterkowicz, S. (2000). Techniques used by judoists during the World and Olympic tournaments 1995–1999. Human Movement, 2(2), 24-332.

Franchini, E., Kons, R. L., Panissa, V. L. G., & Detanico, D. (2022). Assessment of the anaerobic speed reserve during specific high-intensity exercise in judo athletes. Journal of Science in Sport and Exercise, 4(3), 266-274.

Franchini, E., Takito, M. Y., & Bertuzzi, R. D. M. (2005). Morphological, physiological and technical variables in high-level college judoists. Archives of Budo, 1(1), 1-7.

Franchini, E., Takito, M. Y., Alves, E. D., Shiroma, S. A., Julio, U. F., & Humberstone, C. (2019). Effects of different fatigue levels on physiological responses and pacing in judo matches. The Journal of Strength & Conditioning Research, 33(3), 783-792.

Forsyth, J. J., & Farrally, M. R. (2000). A comparison of lactate concentration in plasma collected from the toe, ear, and fingertip after a simulated rowing exercise. British Journal of Sports Medicine, 34(1), 35-8.

Gupta, S., Goswami, A., Sadhukhan, A. K., & Mathur, D. N. (1996). Comparative study of lactate removal in short time term massage of extremities, active recovery and a passive recovery period after supramaximal exercices sessions. International Journal of Sports Medicine, 17, 106-10.

Gariod, L., Binzoni, T., Ferretti, G., Le Bas, J. F., Reutenauer, H., & Cerretelli, P. (1994). Standardisation of 31phosphorus-nuclear magnetic resonance spectroscopy determinations of high energy phosphates in humans. European Journal of Applied Physiology, 68(2), 107-10.

Hawkins, M. N., Raven, P. B., Snell, P. G., Stray-Gundersen, J., & Levine, B. D. (2007). Maximal oxygen uptake as a parametric measure of cardiorespiratory capacity. Medicine and Science in Sports and Exercise, 39, 103–107.

Heggelund, J., Fimland, M. S., Helgerud, J., & Hoff, J. (2013). Maximal strength training improves work economy, rate of force development and maximal strength more than conventional strength training. European Journal of Applied Physiology, 113, 1565-1573.

Heimar, S., & Medved, R. (1997). Funkcionalna dijagnostika treniranosti sportaša (Functional diagnostics of athlete's training readiness). Međunarodno savetovanje, Zbornika radova (23-44). Zagreb, Croatia: Fakultet za fizičku kulturu, Sveučilišta u Zagrebu.

Helm, N., Prieske, O., Muehlbauer, T., Krüger, T., Chaabene, H., & Granacher, U. (2018). Validation of a new judo-specific ergometar system in male elite and sub-elite athletes. Journal of Sport Science and Medicine, 17(3), 465-474.

Jacobs, I. (1986). Blood lactate - Implications for training and sports performance. Sports Medicine, 3, 10-25

Jones, A. M., & Carter, H. (2000). The effect of endurance training on parameters of aerobic fitness. Sports Medicine 29 (6), 373-86.

Kindermann, W., Simon, G., & Keul, J. (1979). The significance of the aerobic-anaerobic transition for the determination of work load intensities during endurance training. European Journal of Appllied Physiology, 42, 25-34

Kons, R. L., Detanico, D., & Franchini, E. (2021). Internal versus external focus of attention on high-intensity exercise performance in judo athletes. Sport Sciences for Health, 17, 577-583.

Mayo, X., Iglesias-Soler, E., & Dopico-Calvo, X. (2019) Both unopposed and opposed judo tasks are suitable for analyzing changes in lateral preference. Journal of Sport Science and Medicine. 18(2), 295-300.

Midgley, A. W., McNaughton, L. R., & Jones, A. M. (2007). Training to enhance the physiological determinants of long-distance running performance: can valid recommendations be given to runners and coaches based on current scientific knowledge? Sports Medicine, 37(10), 857-80.

Mujika, I., & Padilla, S. (2001). Cardiorespiratory and metabolic characteristics of detraining in humans. Medicine & Science in Sports & Exercise, 33(3), 413-21.

Nakajima, T., Moriwaki, Y., Takeuchi, M., Wakayama, H., Tanaka, H., & Okuda, R. (1999). International comparison for fundamental physical fitness for elite judo athletes. In Proceedings of International Judo Conference (pp. 52-7). Birmingham, UK: IJF.

Noakes, T. D.(2007). The central governor model of exercise regulation applied to the marathon. Sports Medicine, 37(4-5), 374-7.

Powers, S. K., & Howley, E. T. (2001). Exercise physiology, 4th edition. New York: McGraw-Hill.

Radaković, R. Ž. (2016). Relacije motoričke, funkcionalne i metaboličke pripremljenosti sa takmičarskom performansom vrhunskih fudbalera merenom metodom softverske analize kretanja" tracking motion" (Motor, functional, and metabolic preparedness relationships with competitive performance of elite football players measured by motion tracking software analysis, Unpublished doctoral dissertation) . Belgrade, Serbia: Univerzitet u Beogradu.

Radovanović, D. (2009). Fiziologije za studente Fakulteta sporta i fizičkog vaspitanja (Physiology for students of the Faculty of Sports and Physical Education) . Nis, Serbia: Fakultet sporta i fizičkog vaspitanja.

Radovanovic, D., Bratic, M., & Milovanovic, D. (2008). Effects of creatine monohydrate supplementation and training on anaerobic capacity and body composition in judo athletes. Acta Facultatis Medicae Naissensis, 25(3), 115-120.

Robergs, R. A., Ghiasvand, F., & Parker, D. (2004). Biochemistry of exercise-induced metabolic acidosis. American Journal of Physiology 287, 502–516.

Shiroma, S. A., Julio, U. F., & Franchini, E. (2019). Criterion validity, reliability, and usefulness of a judo-specific maximal aerobic power test. International Journal of Sports Physiology and Performance, 14(7), 987-993.

Svedahl, K., & MacIntosh, B. R. (2003). Anaerobic threshold: the concept and methods of measurement. Canadian Journal of Appllied Physiology, 28(2), 299-323

Thin, A. G., Hamzah, Z., FitzGerald, M. X., McLoughlin, P., & Freaney, R. (1999). Lactate determination in exercise testing using an electrochemical analyser: with or without blood lysis? European Journal of Applied Physiology, 79(2), 155-9.

Todorov, I. (2014). Efekti specifičnog treninga na kardiorespiratornu izdržljivost i kontraktilni potencijal mišića džudista (Effects of specific training on cardiorespiratory endurance and contractile potential of judoka's muscles, Unpublished doctoral dissertation). Nis, Serbia: Univerzitet u Nišu.

Todorov, I., Dopsaj, M., Radovanovic, D., & Bratic, M. (2014). The effects of specific training on cardiorespiratory endurance among young judokas. Facta Universitatis, Series: Physical Education and Sport, 131-137.

Von Duvillard, S. P., Pokan, R., Hofmann, P., Wonish, M., Smekal, G., Beneke, R., & Leithäuser, R. (2005). Comparing blood lactate concentration values of three different handheld lactate analyzers to YSI 1500 blood lactate analyzer. Medicine and Science in Sports and Exercise, 37(5), 25.

Westerblad, H., Allen, D. G., & Lannergren, J. (2002). Muscle fatigue: lactic acid or inorganic phosphate the major cause? Medicine & Science in Sports & Exercise, 30, 1456-60.