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European Journal of Applied Physiology
Published in: European Journal of Applied Physiology 6/2003

01-08-2003 | Original Article

Blood glucose threshold and the metabolic responses to incremental exercise tests with and without prior lactic acidosis induction

Authors: Herbert Gustavo Simões, Carmen S. G. Campbell, Michael R. Kushnick, Akiko Nakamura, Christos S. Katsanos, Vilmar Baldissera, Robert J. Moffatt

Published in: European Journal of Applied Physiology | Issue 6/2003

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Abstract

This study compared the metabolic–ventilatory responses and the glycemic threshold identified during lactate minimum (LM) and individual anaerobic threshold (IAT) tests. In addition, the ability to determine the anaerobic power, aerobic–anaerobic transition (Trans) (e.g. ventilatory threshold; VT) and the maximal oxygen consumption (O2max) all within a single incremental treadmill test (IT) was investigated. Fifteen physically fit men [25.9 (5.5) years; 77.4 (6.5) kg] performed the following: test 1, IT for IAT; and test 2, LM: 30-s Wingate test followed by 8 min rest and then an IT that was the same as test 1. Blood lactate concentration [lac], glucose concentration [gluc], pH, PO2, PCO2, base excess (BE) and ventilatory variables were measured. At the beginning of the IT for LM, the ventilation, PO2 andO2 were higher and the pH, BE and PCO2 were lower in relation to IAT (P<0.05), while no differences were observed after reaching LM intensity during IT. Moreover, the Trans could be identified by [lac] (IAT, LM), minute ventilation [ E; VT identified during IAT protocol (VT–IAT) and VT identified during LM protocol (VT–LM)], and [gluc] (IGT, GM) during the IT for IAT and LM. The velocities (kilometers per hour) corresponding to IAT (12.6±1.6), VT–IAT (12.5±1.7), IGT (12.6±1.6), LM (12.5±1.5), VT–LM (12.3±1.5), and GM (12.6±1.9) were not different from each other and the LM and IAT protocols resulted in the similarO2max. We concluded that: (1) after reaching the LM the metabolic responses during IT are similar to IAT; (2) performing a Wingate test prior to an IT does not interfere with the Trans andO2max attainment; (3) and the IGT and GM can predict the Trans.
Literature
Ahmaidi S, Masse-Biron J, Choquet BAD, Freville M, Libert JP, Perfaut C (1998) Effects of interval training at the ventilatory threshold on clinical and cardiorespiratory responses in elderly humans. Eur J Appl Physiol 78:170–176CrossRef
Anderson GS, Rhodes EC (1989) A review of blood lactate and ventilatory methods of detecting transition thresholds. Sports Med 8:43–45PubMed
Bar-Or O (1987) The Wingate anaerobic test. An update on methodology, reliability and validity. Sports Med 4:381–394PubMed
Beaver WL, Wasserman K, Whipp BJ (1986) Bicarbonate buffering of lactic acid generated during exercise. J Appl Physiol 60:472–478PubMed
Berry MJ, Stoneman JV, Weyrich AS, Burney B (1991) Dissociation of the ventilatory and lactate thresholds following caffeine ingestion. Med Sci Sports Exerc 23:463–469PubMed
Borg GAV (1982) Psycophysical bases of perceived exertion Med Sci Sports Exerc 14:377–381
Carter H, Jones AM, Doust JH (1999a) Effects of endurance training on the lactate minimum speed. J Sports Sci 17:957–967CrossRefPubMed
Carter H, Jones AM, Doust JH (1999b). Effect of incremental test protocol on the lactate minimum speed. Med Sci Sports Exerc 31:837–845PubMed
Carter H, Jones AM, Doust JH (2000) Changes in blood lactate to pyruvate concentrations and the lactate-to-pyruvate ratio during the lactate minimum speed test. J Sports Sci 18:213–225CrossRefPubMed
Coen B, Schwarz L, Urhausen A, Kinderman W (1991) Control of training in middle- and long-distance running by means of the individual anaerobic threshold. Int J Sports Med 12:519–524PubMed
Coen B, Urhausen A, Kindermann W (2001) Individual anaerobic threshold: methodological aspects of its assessment in running. Int J Sports Med 22: 8–16CrossRefPubMed
Demello JJ, Cureton KJ, Boineau RE, Singh MM (1987) Ratings of perceived exertion at the lactate threshold in trained and untrained men and women. Med Sci Sports Exerc 19:354–362PubMed
Di Pamprero PE (1986) The energy cost of human locomotion on land and water. Int J Sports Med 7:55–72PubMed
Dotan R, Bar-Or O (1983) Load optimization for the wingate anaerobic test. Eur J Appl Physiol 51:409–417
Guedes DP, Guedes JE (1991) Proposed equations for predicting the amount of body fat in young adults. Semina 12:61–70PubMed
Hill DW, Howell AL (1996) Running velocity atO2max. Med Sci Sports Exerc 114–119
Jones AM, Doust JH (1998) The validity of the lactate minimum test for determination of the maximal lactate steady state. Med Sci Sports Exerc 30:1304–1313PubMed
Koyal SN, Whipp BJ, Huntsman D, Bray GA, Wasserman K (1976) Ventilatory responses to the metabolic acidosis of treadmill and cycle ergometry. J Appl Physiol 40:864–867PubMed
MacIntosh BR, Esau S, Svedahl K (2002) The lactate minimum test for cycling: estimation of the maximal lactate steady state. Can J Appl Physiol 27:232–249PubMed
McLellan T, Jacobs I (1993) Reliability, reproducibility and validity of the Individual Anaerobic Threshold. Eur J Appl Physiol 67:125–131
Medbo JI, Sejersted OM (1985) Acid-base and electrolyte balance after exhausting exercise in endurance-trained and sprint-trained subjects. Acta Physiol Scand 125:97–109PubMed
Neary PJ, MacDougall, Bachus R, Wenger HA (1985) The relationship between lactate and ventilatory thresholds: coincidental or cause and effect Eur J Appl Physiol 54:104–108
Noble BJ, Borg GAV, Jacobs I, Ceci R, Kaiser P (1983) A category–ratio perceived exertion scale: relationship to blood and muscle lactates and heart rate. Med Sci Sports Exerc 15:523–528
Oren A, Whipp BJ, Wasserman K (1982) Effect of acid-base status on the kinetics of the ventilatory response to moderate exercise. J Appl Physiol 52:1013–1017
Prefaut C, Durand F, Mucci P, Caillaud C (2000) Exercise-induced arterial hypoxaemia in athletes: a review. Sports Med 30:47–61PubMed
Ribeiro JP, Yang J, Adams RP, Kuca B, Knutten HG (1986) Effect of different incremental exercise protocols on the determination of lactate and ventilatory thresholds. Braz J Med Biol Res 19:109–117PubMed
Seip RL, Snead D, Pierce EF, Stein P, Weltman A (1991) Perceptual responses and blood lactate concentration: effect of training state. Med Sci Sports Exerc 23:80–87PubMed
Simões HG, Campbell CSG, Baldissera V, Denadai V, Kokubun E (1998) Determination of the anaerobic threshold by blood lactate and glucose measurements in track tests for runners. Rev Paul Educ Fís 12:17–30
Simões HG, Campbell CSG, Kokubun E, Denadai BS, Baldissera V (1999) Blood glucose responses in humans mirror lactate responses for individual anaerobic threshold and for lactate minimum in track tests. Eur J Appl Physiol 80:34–40CrossRef
Stegmann H, Kinderman W, Schnabel A (1981) Lactate kinetics and individual anaerobic threshold. Int J Sports Med 2:160–165PubMed
Tegtbur U, Busse MW, Braumann KM (1993) Estimation of an individual equilibrium between lactate production and removal during exercise. Med Sci Sports Exerc 25:620–627PubMed
Wasserman DH, Connolly CC, Pagliassotti MJ (1991) Regulation of hepatic lactate balance during exercise. Med Sci Sports Exerc 23:912–919PubMed
Wasserman K, Van Kessel AL, Burton GG (1967) Interaction of physiological mechanisms during exercise. J Appl Physiol 22:71–85PubMed
Weltman A (1995) The blood lactate response to exercise—current issues in exercise science. Monograph no. 4. Human Kinetics, Champaign, Ill.
Weltman A, Snead D, Stein P, Seip R, Schurrer R, Rutt R, Weltman J (1990) Reliability and validity of a continuous incremental treadmill protocol for the determination of lactate threshold, fixed blood lactate concentrations, andO2max. Int J Sports Med 11:26–32PubMed
Metadata
Title
Blood glucose threshold and the metabolic responses to incremental exercise tests with and without prior lactic acidosis induction
Authors
Herbert Gustavo Simões
Carmen S. G. Campbell
Michael R. Kushnick
Akiko Nakamura
Christos S. Katsanos
Vilmar Baldissera
Robert J. Moffatt
Publication date
01-08-2003
Publisher
Springer-Verlag
Published in
European Journal of Applied Physiology / Issue 6/2003
Print ISSN: 1439-6319
Electronic ISSN: 1439-6327
DOI
https://doi.org/10.1007/s00421-003-0851-1

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