|
Bishop, D., Jenkins, D. and Howard, A. (1998) The critical power function
is dependent on the duration of the predictive exercise tests chosen.
International Journal of Sports Medicine 119, 125-129.
Bosquet, L., Duchene, A., Lecot, F., Dupont, G. and Leger, L. (2006) Vmax
estimate from three-parameter critical velocity models: validity and impact
on 800 m running performance prediction. European Journal of Applied
Physiology 97, 34-42.
Chin, M.I., Wong, A.S.K., So, R.C.H, Siu, O.T., Steininger, K. and Lo,
D.T. (1995) Sport specific fitness testing of elite badminton players.
British Journal of Sports Medicine 29, 153-157.
Clingeleffer, A., McNaughton, L.R. and Davoren, B. (1994) The use of critical
power as a determinant for establishing the onset of blood lactate accumulation.
European Journal of Applied Physiology and Occupational Physiology
68, 182-187.
Dekerle, J., Sidney, M., Hespel, J. and Pelayo, P. (2002) Validity and
reliability of critical speed, critical stroke rate, and anaerobic capacity
in relation to front crawl swimming performances. International Journal
of Sports Medicine 223, 93-98.
Devries, H.A., Moritani, T., Nagata, A. and Magnussen, K. (1982) The relation
between critical power and neuromuscular fatigue as estimated from electromyographic
data. Ergonomics 25, 783-791.
Di Prampero, P.E., Dekerle, J., Capelli, C., and Zamparo, P. (2008) The
critical velocity in swimming. European Journal of Applied Physiology
1102, 165-171.
Faccini, P., Faina, M., Scarpillini, E. and Dal Monte, A. (1989) Il costo
energetico nel tennistavolo. Scuola Dello Sport 17, 38-42.
Girard, O., Chevalier, R., Leveque, F., Micallefe, J.P. and Millet, G.P.
(2006) Specific incremental field test for aerobic fitness in tennis.
British Journal of Sports Medicine 440, 791-796.
Girard, O., Sciberras, P., Habrard, M., Hot, P., Chevalier, R. and Mollet,
G.P. (2005) Specific incremental test in elite squash players. British
Journal of Sports Medicine 339, 921-926.
Gobatto, C.A., Mello, M.A.R., Sibuya, C.Y., Azevedo, J.R.M., Santos, L.A.,
Kokubun, E. (2001) Maximal lactate steady state in rats submitted to swimming
exercise. Comparative Biochemistry and Physiology, Part A 130,
21-27.
Heck, H., Mader, A., Hess, G., Mücke, S., Muller, R. and Hollmann, W.
(1985) Justification of the 4-mmol/l lactate threshold. International
of Journal Sports Medicine 66, 117-130.
Housh, D.J., Housh, T.J. and Bauge, S.M. (1990) A methodological consideration
for the determination of critical power and anaerobic work capacity. Research
Quarterly of Exercise and Sport 661, 406-409.
Jenkins, D.G. and Quigley, B.M. (1990) Blood lactate in trained cyclists
during cycle ergometry at critical power. European Journal of Applied
Physiology and Occupational Physiology 61, 278-283.
Jenkins, D.G. and Quigley, B.M. (1992) Endurance training enhances critical
power. Medicine and Science in Sports and Exercise 24, 1283-1289.
MacIntosh, B.R., Esau, S. and Svedahl, K. (2002) The lactate minimum test
for cycling: estimation of the maximal lactate steady state. Canadian
Journal of Applied Physiology 27, 232-249.
McLellan, T.M. and Cheung, K.S. (1992) A comparative evaluation of the
individual anaerobic threshold and the critical power. Medicine and
Science in Sports and Exercise 24, 543-550.
Monod, H. and Scherrer, J. (1965) The work capacity of a synergic muscular
group. Ergonomics 8, 329-338.
Morel, E.A. and Zagatto, A.M. (2008) Adaptation of the lactate minimum,
critical power and anaerobic threshold tests for assessment of the aerobic/anaerobic
transition in a protocol specific for table tennis. Revista Brasileira
de Medicina do Esporte 14, 518-522.
Moritani, T., Nagata, A., deVries, H.A. and Muro, M (1981) Critical power
as a measure of physical work capacity and anaerobic threshold. Ergonomics
24(5), 339-350.
Papoti, M., Zagatto, A., Mendes, O.C. and Gobatto, C. (2005) Use of invasive
and non-invasive protocol tests on aerobic and anaerobic performances
prediction in Brazilian swimmers. Portuguese Journal of Sports Science
5, 7-14.
Poole, D. (1986) Letter-to the editor-in-chief. Medicine and Science
in Sports and Exercise 18, 703-705
Pringle, J.S. and Jones, A.M. (2002) Maximal lactate steady state, critical
power and EMG during cycling. European Journal of Applied Physiology
88, 214-226.
Smekal G, Pokan R, Von Duvillard SP, Baron, R., Tschan, H. and Bachl,
N. (2000) Comparison of laboratory and "on-court" endurance testing in
tennis. International Journal of Sports Medicine 21, 242-249.
Smith, C.G. and Jones, A.M. (2001) The relationship between critical velocity,
maximal lactate steady-state velocity and lactate turnpoint velocity in
runners. European Journal of Applied Physiology 885, 19-26.
Toubekis, A.G., Tsami, A.P. and Tokmakidis, S.P. (2006) Critical velocity
and lactate threshold in young swimmers. International Journal of Sports
Medicine 27, 117-123.
Wakayoshi K, Yoshida T, Udo M, Harada, T., Moritani, T., Mutoh, Y. and
Miyashita, M. (1993) Does critical swimming velocity represent exercise
intensity at maximal lactate steady state? European Journal of Applied
Physiology and Occupational Physiology 666, 90-95.
Wonisch, M., Hofmann, P., Schwaberger, G., Von Duvillard, S.P. and Klein,
W. (2003) Validation of a field test for the non-invasive determination
of badminton specific aerobic performance. British Journal of Sports
Medicine 337, 115-118.
Zagatto, A.M. and Gobatto, C.A. (2002) Determination of an aerobic evaluation
model on table tennis in a specific protocol using a robot. Table Tennis
Player 15, 10-11. (In Portuguese: English abstract)
Zagatto, A.M. and Gobatto, C.A. (2007) Validação do modelo de freqüência
crítica em protocolo específico através de método indireto, para o tênis
de mesa. Lecturas Educación Física y Deportes 110, 1-7. (In Portuguese:
English Abstract).
Zagatto, A.M., Papoti, M. and Gobatto, C.A. (2008) Anaerobic capacity
may not be determined by critical power model in elite table tennis players.
Journal of Sports Science and Medicine 77, 54-59.
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