Abstract
The purpose of this study was to address if there is an association between the plateau at V˙O2max and the anaerobic capacity. 9 well-trained cyclists (age 22.2±3.5 yr, height 182.5±5.0 cm, mass 75.7±8.7 kg, V˙O2max 59.3±4.8 ml.kg−1.min−1completed both an incremental step test of 20 W.min−1 starting at 120 W for determination of maximal oxygen uptake (MOU) and a maximally accumulated oxygen deficit (MAOD) trial at 125% MOU for estimation of anaerobic capacity. Throughout all trials expired air was recorded on a breath-by-breath basis. A significant inverse relationship was observed between the MAOD and the Δ V˙O2 during the final 60 s of the MOU test (r=−0.77, p=0.008). Of the 9 participants it was noted that only 4 exhibited a plateau at MOU. There were non-significant differences for V˙O2 and the associated secondary criteria for those exhibiting a plateau and the non-plateau responders, despite a significant difference for MAOD (p=0.041) between groups. These data suggest that incidence of the plateau at MOU is dependent on anaerobic substrate metabolism and that ranges of responses reported in the literature may be a consequence of variations in anaerobic capacity amongst participants.
Key words
maximal oxygen uptake - volitional exhaustion - test termination - criteria - plateau
References
-
1
Astorino TA, Robergs RA, Ghiasvand F, Marks D, Burns S.
Incidence of the oxygen plateau during exercise testing to volitional fatigue.
J Exerc Physiol.
2000;
3
1-12
-
2
Astorino TA, Willey J, Kinnahan J, Larsson SM, Welch H, Dalleck LC.
Elucidating determinants of the plateau in oxygen consumption at VO2max.
Br J Sports Med.
2005;
39
655-660
-
3
Astorino TA.
Alterations in VO2max and the VO2 plateau with manipulation of sampling interval.
Clin Physiol Funct Imag.
2009;
29
60-67
-
4
Astrand PO, Saltin B.
Maximal oxygen uptake and heart rate in various types of muscular work.
J Appl Physiol.
1961;
16
977-981
-
5
Bangsbo J, Michalsik L, Petersen A.
Accumulated O2 deficit during intense exercise and muscle characteristics of elite athletes.
Int J Sports Med.
1993;
14
207-213
-
6
Bangsbo J.
Oxygen deficit: A measure of the anaerobic energy production during intense exercise.
Can J Appl Physiol.
1996;
21
350-363
-
7
Bassett DR, Howley ET.
Maximal oxygen uptake “classical” versus “contemporary” viewpoints.
Med Sci Sports Exerc.
1997;
29
591-603
-
8
Bassett DR, Howley ET.
Limiting factors for maximum oxygen uptake and determinents of endurance performance.
Med Sci Sports Exerc.
2000;
32
70-84
-
9
Billat VL, Koralsztein JP.
Significance of the velocity at VO2max and time to exhaustion at this velocity.
Sports Med.
1994;
22
90-108
-
10
Billat VL, Beillot J, Jan J, Rochcongar P, Carre F.
Gender effect on the relationship of time limit at 100% VO2max with other bioenergetic characteristics.
Med Sci Sports Exerc.
1996;
28
1049-1055
-
11
Brink-Elfegourn T, Kaijser L, Gustafson T, Ekblom B.
Maximal oxygen uptake in not limited by a central nervous system governor.
J Appl Physiol.
2007;
102
781-786
-
12
Doherty M, Smith PM, Schroder K.
Reproducibility of the maximum acculmulated oxygen deficit and run time to exhaustion during short-distance running.
J Sports Sci.
2000;
18
331-338
-
13
Doherty M, Nobbs L, Noakes T.
Low frequency of the “plateau phenomenon” during maximal exercise in elite British athletes.
Eur J Appl Physiol.
2003;
89
619-623
-
14
Duncan GE, Mahon AD, Howe CA, Del Corral P.
Plateau in oxygen uptake at maximal exercise in male children.
Paediatr Exerc Sci.
1996;
8
77-86
-
15
Fitts RH.
The cellular mechanisms of muscle fatigue.
Physiol Rev.
1994;
74
49-94
-
16
Gastin PB, Lawson DL.
Infuence of training status on maximal accumulated oxygen deficit during all out cycle exercise.
Eur J Appl Physiol.
1994;
69
321-330
-
17
Gastin PB.
Energy system interaction and relative contribution during maximal exercise.
Sports Med.
2001;
31
725-741
-
18
Green S.
A definition and systems view of anaerobic capacity.
Eur J Appl Physiol.
1994;
69
168-173
-
19
Harriss DJ, Atkinson G.
International Journal of Sports Medicine – Ethical Standards in Sport and Exercise Science Research.
Int J Sports Med.
2009;
30
701-702
-
20
Heck H, Schulz H, Bartmus U.
Diagnostics of anaerobic power and capacity.
Eur J Sports Sci.
2003;
3
3-23
-
21
Hill AV, Lupton H.
Muscular exercise, lactic acid and the supply and utilisation of oxygen.
Q J Med.
1923;
16
135-171
-
22
Hill AV, Long CNH, Lupton H.
Muscular exercise lactic acid and the supply and utilisation of oxygen: Parts VII-VIII.
Proc R Soc Med.
1924;
97
155-176
-
23
Howley ET, Bassett DR, Welch HG.
Criteria for maximal oxygen uptake: review and commentary.
Med Sci Sports Exerc.
1995;
27
1292-1301
-
24
Inbar O, Bar-Or O.
Anaerobic characteristics in male children and adolecents.
Med Sci Sports Exerc.
1986;
18
264-269
-
25
Issekutz B, Birkhead NC, Rodhal K.
Use of respiratory quotients in assessment of aerobic capacity.
J Appl Physiol.
1962;
17
47-50
-
26
Jones AM, Carter H.
The effect of endurance training on parameters of aerobic fitness.
Sports Med.
2000;
29
373-386
-
27
Jones AM.
The physiology of the world record holder for the women's marathon.
Int J Sports Sci Coach.
2006;
1
101-116
-
28
Kjaer M.
Epinephrine and some other hormonal responses to exercise in man: with special reference to physical training.
Int J Sports Med.
1989;
10
2-15
-
29
Kon Yoon B, Kravitz L, Robergs R.
VO2max protocol duration and the VO2 plateau.
Med Sci Sports Exerc.
2007;
7
1186-1192
-
30
Londeree BR, Moeschberger ML.
Influence of age and other factors on maximal heart rate.
J Card Rehab.
1984;
4
44-49
-
31
MacArthur DG, North KN.
Genes and human athletic performance.
Eur J Appl Physiol.
2005;
5
331-339
-
32
Medbø JI, Mohn AC, Tabata MI, Bahr R, Vaage O, Sejersted OM.
Anaerobic capacity determined by maximal accumulated O2 deficit.
J Appl Physiol.
1988;
64
50-60
-
33
Noakes TD, Wolffe JB.
Memorial Lecture. Challenging beliefs: ex Africa semper aliquid novi.
Med Sci Sports Exerc.
1997;
29
571-590
-
34
Noakes TD, Peltonen JE, Rusko HK.
Evidence that a central governor regulates exercise performance during acute hypoxia and hyperoxia.
J Exp Biol.
2001;
204
3225-3234
-
35
Olesen HL, Raabo E, Bangsbo J, Secher NH.
Maximal oxygen deficit of sprint and middle distance runners.
Eur J Appl Physiol.
1994;
69
140-146
-
36
Rivera-Brown AM, Alvarez M, Rodriguez-Santana JR, Benetti PJ.
Anearobic power and achievement of VO2 plateau in pre-pubertal boys.
Int J Sports Med.
2001;
22
111-115
-
37
Rivera-Brown AM, Frontera WR.
Achievement of plateau and reliability of VO2max in trained adolecents tested with different ergometers.
Pediatr Exerc Sci.
1996;
10
164-175
-
38
Rowell LB.
Human cardiovascular adjustments to exercise and thermal stress.
Physiol Rev.
1974;
54
75-159
-
39
Rowland TW, Cunningham LN.
Oxygen uptake plateau during maximal treadmill exercise in children.
Chest.
1992;
101
485-489
-
40
Scott CB, Roby FB, Lohman TG, Bunt JC.
The maximally accumulated oxygen deficit as an indicator of the anaerobic capacity.
Med Sci Sports Exerc.
1991;
23
618-624
-
41
Shephard RJ.
Is it time to retire the ‘Central Governor’?.
Sports Med.
2009;
39
709-721
-
42
Taylor HL, Buskirk E, Henschell A.
Maximal oxygen intake as an objective measure of cardio-respiratory performance.
J Appl Physiol.
1955;
8
73-80
-
43
Wagner PD.
New ideas on limitations to VO2max.
Exerc Sports Sci Rev.
2000;
10-14
-
44
Wasserman K.
Diagnosing cardiovascular and lung pathophysiology from exercise gas exchange.
Chest.
1997;
112
1091-1101
Correspondence
Dan GordonMSc
Anglia Ruskin University
Life Sciences
Unit for Sport and Exercise
Sciences
CB1 1PT Cambridge
United Kingdom
Phone: +44/0845/1962 774
Fax: +44/01223/417 712
Email: dan.gordon@anglia.ac.uk
