Subscribe to RSS
DOI: 10.1055/s-2007-964986
© Georg Thieme Verlag KG Stuttgart · New York
An On-Ice Aerobic Maximal Multistage Shuttle Skate Test for Elite Adolescent Hockey Players
Publication History
accepted after revision September 21, 2006
Publication Date:
29 May 2007 (online)
Abstract
The aim of this study was to design an on-ice test to predict V·O2max in ice hockey players. 30 elite hockey players (age 14.7 ± 1.5 years) participated in this study. The oxygen uptake was assessed at submaximal and maximal velocities during an on-ice intermittent maximal multistage shuttle skate test with a 1-min/0.5-min work/rest ratio. The procedure consisted of skating back and forth on a distance of 45 m (stop and go) while following a pace fixed by an audible signal: initial velocity of 3.5 m · s-1 with increments of 0.2 m · s-1 every stage. The skating multistage aerobic test (SMAT) enabled the prediction of the V·O2max (ml · kg-1 · min-1) from the maximal velocity (m · s-1) by means of the following regression equation: V·O2max = 18.07 × (maximal velocity) - 35.596 (r = 0.97, SEE = 3.01). The test-retest correlation was 0.92 and SEE = 0.56 stage (n = 23). Following the SMAT validation, an additional group of 112 elite male (age = 14.2 ± 1.3 years) and 31 elite female (age = 14.0 ± 1.2 years) ice hockey players performed both the 20-m shuttle run test and the SMAT, which was more specific and accurate to predict V·O2max. The overall results suggest that the SMAT is highly specific, valid and reliable for the prediction of V·O2max of ice hockey players.
Key words
ice hockey - retroextrapolation - oxygen consumption - field test - V·O2max
References
- 1 Boulay M.
L'évaluation, supervision et contrôle de l'élite. Larivière G 4e Colloque sur la Recherche Appliquée au Hockey. Québec; Éditions du Pélican 1978: 47-56 - 2 Cox M H, Miles D S, Verde T J, Rhodes E C. Applied physiology of ice hockey. Sports Med. 1995; 19 184-201
- 3 Daub W B, Green H J, Houston M E, Thomson J A, Fraser I G, Ranney D A. Specificity of physiologic adaptations resulting from ice-hockey training. Med Sci Sports Exerc. 1983; 15 290-294
- 4 Doyon H K, Perrey S, Abe D, Hughson R L. Field testing of V·O2peak in cross-country skiers with portable breath-by-breath system. Can J Appl Physiol. 2001; 26 1-11
- 5 Dreger R W, Quinney H A. Development of a hockey-specific, skate-treadmill V·O2max protocol. Can J Appl Physiol. 1999; 24 559-569
- 6 Hausswirth C, Bigard A X, Le Chevalier J M. The Cosmed K4 telemetry system as an accurate device for oxygen uptake measurements during exercise. Int J Sports Med. 1997; 18 449-453
- 7 Lavoie J M, Léger L A, Leone M, Provencher P J. A maximal multistage swim test to determine the functional and maximal aerobic power of competitive swimmers. J Swimming Res. 1985; 1 17-22
- 8 Lavoie J M, Leone M, Bongbélé J. Functional maximal aerobic power and prediction of swimming performance. J Swimming Res. 1988; 4 17-19
- 9 Léger L, Seliger V, Brassard L. Comparisons among V·O2max values for hockey players and runners. Can J Appl Physiol. 1979; 4 18-23
- 10 Léger L, Boucher R. An indirect continuous running multistage field test: the Université de Montréal track test. Can J Appl Sports Sci. 1980; 5 77-84
- 11 Léger L, Seliger V, Brassard L. Backward extrapolation of V·O2max values from O2 recovery curve. Med Sci Sports Exerc. 1980; 12 24-27
- 12 Léger L, Montpetit R R, Lambert J, Chartrand D. Retroextrapolation of submaximal values from O2 recovery curve. Scan J Sports Sci. 1982; 4 71-73
- 13 Léger L, Lambert J. A maximal multistage 20-m shuttle run test to predict V·O2max. Eur J Appl Physiol. 1982; 49 1-12
- 14 Léger L, Mercier D, Gadoury C, Lambert J. The multistage 20 meter shuttle run test for aerobic fitness. J Sports Sci. 1988; 6 93-101
- 15 Léger L, Gadoury C. Validity of the 20 m shuttle run test with 1 min stages to predict V·O2max in adults. Can J Sports Sci. 1989; 14 1-26
- 16 Léger L.
Aerobic performance. Docherty D Measurement in Pediatric Exercise Science. Champaign, IL; Human Kinetics 1996: 183-223 - 17 Maingourd Y, Libert J-P, Bach V, Jullien H, Tanguy C, Freville M. Aerobic capacity of competitive ice hockey players 10 - 15 years old. Jpn J Physiol. 1994; 44 255-270
- 18 Marcotte G, Poirier G. La préparation physique du joueur de hockey. Québec; Éditions du Pélican 1978: 139
- 19 Marion G A, Léger L. Energetics of indoor track cycling in trained competitors. Int J Sports Med. 1988; 9 234-239
- 20 Marino G W. Analysis of selected factors in the ice skating strides of adolescents. CAHPER J. 1984; 50 4-8
- 21 McArdle W D, Magel J R, Delio D J, Toner M, Chase J M. Specificity of run training on V·O2max and heart rate changes during running and swimming. Med Sci Sports. 1978; 10 16-20
- 22 McLaughlin J E, King G A, Howley E T, Bassett D R, Ainsworth B E. Validation of the Cosmed K4b2 portable metabolic system. Int J Sports Med. 2001; 22 280-284
- 23 Montgomery D L, Dallaire J A.
Physiological characteristics of elite ice hockey players over two consecutive years. Landers DM Sport and Elite Performers. Champaign, IL; Human Kinetics 1986: 133-141 - 24 Montgomery D L. Physiology of ice hockey. Sports Med. 1988; 5 99-126
- 25 Montgomery D L. Physiological profile of professional hockey players - a longitudinal comparison. Appl Physiol Nutr Metab. 2006; 31 181-185
- 26 Norusis M J.
Discriminant analysis. Norusis MJ SPSS for Windows Release 6.0. Chicago; SPSS Inc 1993: 1-37 - 27 Pinnington H C, Wong P, Tay J, Green D, Dawson B. The level of accuracy and agreement in measures of FEO2, FECO2 and V·E between the Cosmed K4b2 portable respiratory gas analysis system and metabolic cart. J Sci Med Sport. 2001; 4 324-335
- 28 Rechichi C, Dawson B, Lawrence S R. A multistage shuttle swim test to assess aerobic fitness in competitive water polo players. J Sci Med Sports. 2000; 3 55-64
Dr. PhD Mario Leone
Université du Québec à Montréal
Kinanthropologie
Case postale 8888, Succursale Centre-ville
H3C 3P8 Montréal
Canada
Phone: + 51 49 87 30 00 50 18
Fax: + 51 49 87 66 16
Email: leone.mario@uqam.ca