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Fizička kultura
2017, vol. 71, br. 1, str. 55-62
jezik rada: srpski, engleski
vrsta rada: pregledni članak
doi:10.5937/fizkul1701055N

Creative Commons License 4.0
Nespirografske ili neinvazivne metode za procenu anaerobnog praga
aAutonomni univerzitet Čihuahua, Fakultet nauka o fizičkoj kulturi, Meksiko
bDržavni univerzitet Nju Meksiko, SAD
cUniverzitet u Beogradu, Fakultet sporta i fizičkog vaspitanja

e-adresa: Jnajera@uach.mx

Sažetak

U svetu sportskih istraživanja postoje različiti načini da se odredi fizička kondicija, počev od skupih laboratorijskih invazivnih metoda do jeftinih, neinvazivnih metoda na terenu. Neinvazivno ispitivanje na terenu daje dobru pouzdanost i nije skupo, a između ostalih, koriste se fiziološki parametari kao što su: srčana frekvencija, elektroliti pljuvačke ili laktat, doživljeni napor i elektromiografija. Ovi parametri se mogu koristiti za procenu anaerobnog praga (AnT) kako bi se predvideo sportski učinak, preusmerio trening, a može i da pomogne trenerima i sportistima da budu konkurentniji. Međutim, svaki od ovih parametara ima neke osobenosti i kontroverze usled različitih rezultata koje stručnjaci prijavljuju. Ove razlike se mogu, između ostalog, objasniti protokolom testiranja koji se koristi, uzorkom sportskog nivoa, početnim intenzitetom ili brojem nivoa. Uprkos tome, oni i dalje imaju dobru ponovljivost i primenu u protokolima testiranja na terenu. Navedena ispitivanja se mogu primeniti u velikom obimu, i češće, sa pažnjom usmerenom na stepen korelacije sa prvobitnim invazivnim testovima, kao i na procenat mogućih grešaka u procesu procenjivanja. Jeftinija i jednostavnija ispitivanja (umesto subjektivne procene trenažnog opterećenja) omogućavaju trenerima i sportistima sa manje novca preciznije planiranje i menjanje obima i intenziteta treninga. Osećaj udobnosti koji sportisti imaju, kao i eventualne visoke frekvencije ispitivanja tokom neinvazivnog testa, moraju se istaći kao prednost tokom procesa evaluacije treninga.

Ključne reči

srčana frekvencija; pljuvačka; doživljeni napor; elektromiografija; laktati u krvi; ergometrija

Reference

Novododat članak: provera, normiranje i linkovanje referenci u toku.
Bocanegra, O.L., Diaz, M.M., Teixeira, R.R., Soares, S.S., & Espindola, F.S. (2012). Determination of the lactate threshold by means of salivary biomarkers: chromogranin A as novel marker of exercise intensity. European Journal of Applied Physiology, 112(9), 3195- 3203.
Bodner, M.E., & Rhodes, E.C. (2000). A review of the concept of the heart rate deflection point. Sports Medicine, 30(1), 31-46.
Borg, G.A. (1982). Psychophysical bases of perceived exertion. Medicine & Sciences in Sports & Exercise, 14(5), 377-381.
Bortolini, M.S., De Agostini, G.G., Reis, I.T., Silva Lamounier, R.P.M., Blumberg, J.B., & Espindola, F.S. (2009). Total protein of whole saliva as a biomarker of anaerobic threshold. Research quarterly for exercise and sport, 80(3), 604-610.
Buchheit, M., Solano, R., & Millet, G.P. (2007). Heart-rate deflection point and the second heartrate variability threshold during running exercise in trained boys. Pediatric Exercise Science, 19(2),192-204.
Carvalho, V.O., Bocchi, E.A., & Guimarães, G.V. (2009). The Borg Scale as an Important Tool of Self-Monitoring and Self-Regulation of Exercise Prescription in Heart Failure Patients During Hydrotherapy A Randomized Blinded Controlled Trial. Circulation Journal, 73(10), 1871-1876.
Claver, J.B., Mirón, M.V., & Capitán-Vallvey, L. (2009). Disposable electrochemiluminescent bio-sensor for lactate determination in saliva. Analyst, 134(7), 1423-1432.
Conconi, F., Ferrari, M., Ziglio, P., Droghetti, P., Borsetto, C., Casoni, I., Paolini, A. (1982). Determination of the anaerobic threshold by a non-invasive field test in running and other sport activities: Paper presented at the Current topics in sports medicine, World Congress, Vienna.
Davis, J.A. (1985). Anaerobic threshold: review of the concept and directions for future research. Medicine and Science in Sports and Exercise, 17(1), 6-21.
Damnjanović, I. (2016). Neinvazivne i invazivne metode za procenu individualnog anaerobnog praga [Non-invasive and invasive methods for assessing individual anaerobic threshold. In Serbian] (Unpublished Bchler Thesis). Univerzitet u Beogradu, Fakultet Sporta i fizičkog vaspitanja.
de Assis, P.P., Piubelli, C.V., Mello, R.G., Pereira, D.J., Guerra, R., & Silva, M.d.A.P. (2015). The relationship between the heart rate deflection point test and maximal lactate steady state. The Journal of sports medicine and physical fitness, 11, 124-128.
Debray, P., & Dey, S.K. (2007). A comparison of the point of deflection from linearity of heart rate and the ventilatory threshold in the determination of the anaerobic threshold in Indian boys. Journal of physiological anthropology, 26(1), 31-37.
e Silva, A.C., Dias, M.R.C., Franco, V.H.P., de Lima, J.R.P., & da Silva Novaes, J. (2008). Estimate of the threshold of Conconi through the Borg’s scale in cycloergometer. Fitness & performance journal, 4 (4), 215-219.
Forti, M., Zamunér, A.R., Kunz, V.C., Salviati, M.R., Nery, T.A.G., & Silva, E.d. (2014). Ratings of perceived exertion at anaerobic threshold in patients with coronary artery disease. Fisioterapia e Pesquisa, 21(2), 113-119.
Grant, S., Aitchison, T., Henderson, E., Christie, J., Zare, S., McMurray, J., & Dargie, H. (1999). A comparison of the reproducibility and the sensitivity to change of visual analogue scales, Borg scales, and Likert scales in normal subjects during submaximal exercise. Chest Journal, 116(5), 1208-1217.
Grujić, N., Barak, O., Drapšin, M., Karaba-Jakovljević, D., Klašnja, A., Lukač, D., Baćanović, M., Brkić, P., Vasić, G., Drenjančević, I., Ibročić, P., Jakovljević, Đ., Mitrović, D., Ponorac, N., Radoš, B., Rajković, Ž., Ćeranić, S. (2017). Fiziologija sporta [Sport Physiology. In Serbian]. Novi Sad: Univerzitet u Novom Sadu, Medicinski Fakultet.
Helal, J., Guezennec, C., & Goubel, F. (1987). The aerobic-anaerobic transition: re-examination of the threshold concept including an electromyographic approach. European journal of applied physiology and occupational physiology, 56(6), 643-649.
Ignjatović, A., Hofmann, P., & Radovanović, D. (2008). Non-invasive determination of the anaerobic threshold based on the heart rate deflection point. Facta universitatis-series: Physical Education and Sport, 6(1), 1-10.
Ilić, N., & Rajković, Ž. (2009): Monitoring treninga kroz puls i brzinu u različitim zonama intenziteta u cikličnim sportovima tipa izdržljivosti [Monitoring the training through the pulse and intensity in different zones in a cyclic endurance sports type. In Serbian], First national seminar for sports coaches of the Republic of Serbia, (pp. 136-154). Belgrade: Republic Institute for Sports.
Lopez-Chicharro, J., Calvo, F., Alvarez, J., Vaquero, A., Bandres, F., & Legido, J. (1995). Anaerobic threshold in children: determination from saliva analysis in field tests. European journal of applied physiology and occupational physiology, 70(6), 541-544.
Lopez-Chicharro, J., Legido, J. C., Alvarez, J., Serratosa, L., Bandres, F., & Gamella, C. (1994). Saliva electrolytes as a useful tool for anaerobic threshold determination. European journal of applied physiology and occupational physiology, 68(3), 214-218.
Mahler, P., & Rostan, A. (1990). L’effort perçu: corrélation avec le seuil anaérobie et utilité dans un programme d’entraînement. Schweizerische Zeitschrift für Sportmedizin, 38(4), 187-191.
Matsumoto, T., Ito, K., & Moritani, T. (1991). The relationship between anaerobic threshold and electromyographic fatigue threshold in college women. European journal of applied physiology and occupational physiology, 63(1), 1-5.
Morishita, S., Yamauchi, S., Fujisawa, C., & Domen, K. (2014). Rating of perceived exertion for quantification of the intensity of resistance exercise. International Journal of Physical Medicine & Rehabilitation, 1(172), 2.
Oliveira, L.d.S., Oliveira, S.F., Manchado-Gobatto, F.d.B., & Costa, M.d.C. (2015). Salivary and blood lactate kinetics in response to maximal workload on cycle ergometer. Revista Brasileira de Cineantropometria & Desempenho Humano, 17(5), 565-574.
Pinto, S.S., Brasil, R.M., Alberton, C.L., Ferreira, H.K., Bagatini, N.C., Calatayud, J., & Colado, J.C. (2016). Noninvasive Determination of Anaerobic Threshold Based on the Heart Rate Deflection Point in Water Cycling. The Journal of Strength & Conditioning Research, 30(2), 518-524.
Pokan, R., Hofmann, P., Preidler, K., Leitner, H., Dusleag, J., Eber, B., .Klein, W. (1993). Correlation between inflection of heart rate/work performance curve and myocardial function in exhausting cycle ergometer exercise. European journal of applied physiology and occupational physiology, 67(5), 385-388.
Segura, R., Javierre, C., Ventura, J., Lizarraga, M., Campos, B., & Garrido, E. (1996). A new approach to the assessment of anaerobic metabolism: measurement of lactate in saliva. British Journal of Sports Medicine, 30(4), 305-309.
Sentija, D., Vucetic, V., & Markovic, G. (2007). Validity of the modified Conconi running test. International journal of sports medicine, 28(12), 1006-1011.
Svedahl, K., & MacIntosh, B.R. (2003). Anaerobic threshold: the concept and methods of measurement. Canadian Journal of Applied Physiology, 28(2), 299-323.
Taylor, A., & Bronks, R. (1994). Electromyographic correlates of the transition from aerobic to anaerobic metabolism in treadmill running. European journal of applied physiology and occupational physiology, 69(6), 508-515.
Tékus, É., Kaj, M., Szabó, E., Szénási, N., Kerepesi, I., Figler, M., Wilhelm, M. (2012). Comparison of blood and saliva lactate level after maximum intensity exercise. Acta Biologica Hungarica, 63(Supplement 1), 89-98.
Tyka, A., Pałka, T., Tyka, A., Cisoń, T., & Szyguła, Z. (2009). The influence of ambient temperature on power at anaerobic threshold determined based on blood lactate concentration and myoelectric signals. International journal of occupational medicine and environmental health, 22(1), 1-6.
Vachon, J.A., Bassett, D.R., & Clarke, S. (1999). Validity of the heart rate deflection point as a predictor of lactate threshold during running. Journal of applied physiology, 87(1), 452-459.
Viitalaso, J. T., Luhtanen, P., Rahkila, P., & Rusko, H. (1985). Electromyographic activity related to aerobic and anaerobic threshold in ergometer bicycling. Acta physiologica scandinavica, 124(2), 287-293.
Vucetić, V., Sentija, D., Sporis, G., Trajković, N., & Milanović, Z. (2014). Comparison of ventilation threshold and heart rate deflection point in fast and standard treadmill test protocols. Acta clinica Croatica, 53(2), 190-203.
Wasserman, K., & McIlroy, M.B. (1964). Detecting the threshold of anaerobic metabolism in cardiac patients during exercise. The American journal of cardiology, 14(6), 844-852.
Zamunér, A.R., Moreno, M.A., Camargo, T.M., Graetz, J.P., Rebelo, A.C., Tamburús, N.Y., & da Silva, E. (2011). Assessment of subjective perceived exertion at the anaerobic threshold with the Borg CR-10 scale. Journal of Sports Science and Medicine, 10(1), 130-136.