Central European Journal of Sport Sciences and Medicine

ISSN: 2300-9705     eISSN: 2353-2807    OAI    DOI: 10.18276/cej.2018.3-03
CC BY-SA   Open Access   DOAJ  DOAJ

Issue archive / Vol. 23, No. 3/2018
Effect of Variable-Intensity Running Training and Circuit Training on Selected Physiological Parameters of Soccer Players

Authors: Tadeusz Ambroży
Academy of Physical Education in Cracow, Department of Physical Education and Sport, Cracow, Poland

Mateusz Nowak
Academy of Physical Education in Cracow, Department of Physical Education and Sport, Cracow, Poland

Jarosław Omorczyk
Academy of Physical Education in Cracow, Department of Physical Education and Sport, Cracow, Poland

Krzysztof Wrześniewski
Academy of Physical Education in Cracow, Department of Physical Education and Sport, Cracow, Poland

Mariusz Ozimek
Academy of Physical Education in Cracow, Department of Physical Education and Sport, Cracow, Poland

Henryk Duda
Academy of Physical Education in Cracow, Department of Physical Education and Sport, Cracow, Poland

Dawid Mucha
Podhale State College of Applied Sciences in Nowy Targ, Institute of Humanities, Social Sciences and Tourism, Nowy Targ, Poland

Piotr Ceranowicz
Department of Physiology, Medical College, Jagiellonian University, Kraków, Poland

Tomasz Pałka
Academy of Physical Education in Cracow, Department of Physical Education and Sport, Cracow, Poland

Arkadiusz Stanula
The Jerzy Kukuczka Academy of Physical Education in Katowice, Katowice, Poland

Dariusz Mucha
Academy of Physical Education in Cracow, Department of Physical Education and Sport, Cracow, Poland
Keywords: variable-intensity running training circuit training soccer
Data publikacji całości:2018-09
Page range:11 (25-35)
Cited-by (Crossref) ?:

Abstract

Proper planning of the training process based on individual LT and AT metabolic thresholds is essential to improve athletic performance. Development of endurance in soccer players is mainly based on continuous runs and variable-intensity runs, supplemented with strength conditioning and sport-specific training. The aim of the study was to analyse selected parameters of physical capacity of soccer players after 8-week variable-intensity running training and circuit training. The experiment was carried out in a group of 34 soccer players aged 21 to 26 years. The athletes were divided into two groups: 17 people in the experimental group and 17 people in the control group. The experimental group was involved in 30-minute tempo runs two times a week for 8 weeks with variable intensity at AT. In the same period, the control group performed two 60-minute continuous runs at the intensity of 70-75%HRmax. The determination of metabolic thresholds used two indirect tests: the multistage shuttle run test (beep test) and maximal lactate steady state test (MLSS) with author's own modification. In order to evaluate maximal heart rate (HRmax), the research procedure was started from the beep test (distance: 20 m). The speed at the first level was 8.5 km/h and increased with each level by 0.5 km/h. Training of the experimental group where variable exercise intensity was used caused a statistically significant increase in HRmax (by 1.9%) and blood lactate levels at the AT (by 20.5%). The training in the experimental group led to the statistically significant (p < 0.05) increase in the parameters of the following variables: HRmax (by 1.9%); lactate level (by 7.85); HR at the AT (by 1,9%); lactate level at the AT (by 20.5%). The assumptions of the experimental training did not cause statistically significant changes in pretest vs. posttest HRmax and blood lactate levels for the LT. Endurance training with high intensity is more effective in soccer players compared to training with moderate intensity. Development of special endurance in soccer should also assume the intensity and method of working similar to the method used during sport competition.
Download file

Article file

Bibliography

1.Bangsbo, J. (2014). Physiological Demands of Football. Sports Science Exchange, 27 (125), 1–6.
2.Beneke, R. (2003). Methodological aspects of maximal lactate steady state: implications for performance testing. Eur J ApplPhysiol Marc, 89 (1), 95–99.
3.Billat, L. (1996). Use of blood lactate measurements for prediction of exercise performance and for control of training. Sports Med, 22, 157–175.
4.Billat, V.L., Sirvent, P., Py, G. (2003). The Concept of Maximal Lactate Steady State. A bridge between biochemistry, physiology, and sport science. Med Sci Sports Exerc, 33 (6), 407–426.
5.Cohen, J. (1988). Statistical power analysis for the behavioral sciences (2nd ed.). Hillsdale, NJ: Erlbaum.
6.Cohen, J., Cohen, P., West, S. (2003). Applied multiple regression/correlation analysis for the behavioral sciences. Third Edition. New York: Routledge.
7.Cotterman, M.L., Darby, L.A., Skelly, W.A. (2005). Comparison of muscle force production using the Smith machine and freeweights for benchpress and squatexercises. J Strength Cond Res, 19 (1), 169–176.
8.Claessens, A.L., Lefevre, J. (1992). Secular trends in somatic and motor characteristics of physical education students. American Journal of Human Biology, 4 (3): 301–311.
9.Denadai, B.S., Figueira, T.R., Favaro, O.R. (2004). Effect of the aerobic capacity on the validity of the anaerobic threshold for determination of the maximal lactate steady state in cycling. Braz J Med Biol Res, 37 (10), 1551–1556.
10.Denis, C., Fouquet, R., Poty, P. (1982). Effect of 40weeks of endurancetraining on the anaerobic threshold. Int J Sports Med, 3 (4), 208–214.
11.Faude, O., Kindermann, W., Meyer, T. (2009). Lactate threshold concepts: how valid are they? Sports Med, 39 (6), 469–490.
12.Goodwin, M.L., Harris, J.E., Hernández, A. (2007). Blood lactate measurements and analysis during exercise: a guide for clinicians. J Diabetes Sci Technol, 1 (4), 558–569.
13.Gormley, S.E., Swain, D.P., High, R. (2008). Effect of intensity of aerobic training on VO2max. Med Sci Sports Exerc, 40 (7), 1336–1343.
14.Helgerud, J., Høydal, K., Wang, E. (2007). Aerobichigh-intensity intervals improve VO2max more than moderate training. MedSci Sports Exerc, 39 (4), 665–671.
15.Hill-Haas, S.V., Dowson, B.T., Couts, A.J. (2010). Time-motion characteristics and physiological responses of small-sided games in elite youth players: the influence of player number and rule changes. Journal of Strength and Conditioning Research, 24 (8), 2149-2156.
16.Hoff, J., Helgerud, J. (2004). Endurance and strength training for soccer players: physiological considerations. Sports Med, 34 (3), 165–180. Review.
17.Johnson, R.E., Quinn, T.J., Kertzer, R. (1997). Strength Training in Female Distance Runners: Impact on Running Economy. J Strength Cond Res, 11 (4), 224.
18.Karp, J.R. (2010). Strength Training For Distance Running: A Scientific Perspective. Strength and Cond J, 33, 83–88.
19.Londeree, B.R. (1997). Effect of training on lactate/ventilatory thresholds: a meta-analysis. MedSci Sports Exerc, 29 (6), 837–843.
20.Miles, J., Shevlin, M. (2001). Applying Regression and Correlation: A Guide for Students and Researchers. London: Sage.
21.Marcinik, E.J. (1988). Effect of circuit weight training on endurance performance: Muscular strength, power endurance and lactate threshold correlates. ProQuest Dissertations and Theses.
22.Marcinik, E.J, Potts, J., Schlabach, G. (1991). Effects of strength training on lactate threshold and endurance performance. MedSci Sports Exerc, 23 (6), 739–743.
23.Palmer, A.S., Potteiger, J.A., Nau, K.L. (1999). A 1-day maximal lactate steady-state assessment protocol for trained runners. MedSci Sports Exerc, 31 (9), 1336–1341.
24.Stanton, R., Reaburn, P.R., Humphries, B. (2004). The effect of short-term Swis sballt raining on corestability and running economy. J Strength Cond Res, 18 (3), 522–528.
25.Schick, E.E., Coburn, J.W., Brown, L.E. (2010). A comparison of muscle activation between a Smith machine and free weight benchpress. J Strength Cond Res, 24 (3), 779–784.
26.Tabata, I., Nishimura, K., Kouzaki, M. (1996). Effects of moderate-intensity endurance and high-intensity intermittent training on anaerobic capacity and VO2max. Med Sci Sports Exerc, 28 (10), 1327–1330.
27.Vobejda, C., Fromme, K., Samson, W. (2006). Maximal constant heart rate a heart rate based method to estimate maximal lactate steady state in running. Int J Sports Med., 27 (5), 368–372.