Interpreting VO2 kinetics in heavy exercise revisited

doi:10.1152/japplphysiol.00045.2003

HOME

HELP

FEEDBACK

SUBSCRIPTIONS

Interpreting $V$ O₂ kinetics in heavy exercise revisited

The following is the abstract of the article discussed in the subsequent letter:

	ABSTRACT

Tordi, N., S. Perrey, A. Harvey, and R. L. Hughson. Oxygen uptake kinetics during two bouts of heavy cycling separatedby fatiguing sprint exercise in humans. J Appl Physiol 94: 533-541,2003. First published October 11, 2002; 10.1152/japplphysiol.00532.2002. $---$ Wetested the hypothesis that O₂ uptake ( $V$ O₂) kinetics at the onsetof heavy exercise would be altered in a state of muscle fatigueand prior metabolic acidosis. Eight well-trained cyclists completedtwo identical bouts of 6-min cycling exercise at >85% of peak $V$ O₂ separated by three successive bouts of 30 s of sprint cycling.Not only was baseline $V$ O₂ elevated after prior sprint exercisesbut also the time constant of phase II $V$ O₂ kinetics was faster(28.9 ± 2.4 vs. 22.2 ± 1.7 s; P < 0.05). CO₂ output ( $V$ CO₂) wassignificantly reduced throughout the second exercise bout. Subsequently $V$ O₂ was greater at 3 min and increased less after this afterprior sprint exercise. Cardiac output, estimated by impedancecardiography, was significantly higher in the first 2 min of thesecond heavy exercise bout. Normalized integrated surface electromyographyof four leg muscles and normalized mean power frequency were notdifferent between exercise bouts. $V$ O₂ and $V$ CO₂ kinetic responsesto heavy exercise were markedly altered by prior multiple sprintexercises.

	LETTER

To the Editor: We read with interest the recent paper of Tordi et al. (12) in which it was reported that prior high-intensitycycle exercise caused a speeding of the phase II O₂ uptake ( $V$ O₂)kinetics in a subsequent bout of heavy-intensity cycle exercise.These results are important because the effect of prior exerciseon $V$ O₂ kinetics provides important clues about the control ofmuscle energetics at exercise onset. However, we believe thatthere are a number of significant problems with the data and theirinterpretation in the paper (12) that should be bought to readers'attention.

In discussing their results, Tordi et al. (12) state that it is important to "optimize" the experimental conditions if thephase II time constant is to be altered. It is then argued thatthe large number of previous studies (2-7, 9, 11) that didnot detect a change in the phase II kinetics failed to do so because1) the prior exercise did not result in a sufficiently markedacidosis, 2) the curve fitting in these studies was not sensitiveenough to detect a change in the phase II time constant, 3) thestudies lacked statistical power, and 4) differences in baseline $V$ O₂ obscured the results. None of these arguments stands up toscrutiny. First, to support the contention that the acidosis imposedby previous studies was insufficient, Tordi et al. should haveincluded a condition in their study whereby a modest degree oflactacidosis did not speed the phase II $V$ O₂ kinetics. They shouldhave also measured blood lactate concentration and/or pH to demonstratethat their protocol resulted in a greater lactic acidosis in comparisonto that resulting from a single sprint (5). Thus their conclusionthat "the acidosis probably contributed to enhanced vasodilatationearly in exercise" is made without measuring lactate, pH, or vasodilatation.Our laboratory (3-6) has demonstrated no change in the phaseII $V$ O₂ time constant when baseline whole blood lactate concentration(not plasma lactate concentration, as incorrectly stated in Ref.12) was elevated by up to 7.6 mM and despite indirect evidencethat vasodilatation in the exercising muscle was enhanced (3).Second, performing only one test for the acquisition of breath-by-breathdata, as Tordi et al. did, is unlikely to provide sufficient confidencein the parameters derived from curve-fitting procedures (8).Thus Tordi et al. have no grounds to question the curve-fittingprocedures used in previous studies in which subjects performedtwo to four transitions (2-6, 9, 11), since these studiesused methods that were more sensitive than their own. Third, thecharge that previous studies lacked statistical power is alsoincorrect because the sample sizes involved previously were equalor superior to those of Tordi et al. Fourth, the primary timeconstant is unchanged as a result of prior heavy exercise irrespectiveof whether there are differences in baseline $V$ O₂ (2, 4,6, 9, 11).

We are also concerned that Tordi et al. (12) make inappropriate interpretations from previously reported data in order tosupport their position that an O₂ delivery limitation exists atthe onset of heavy exercise. For example, the authors use thedata of Krustrup et al. (10) to show that blood flow (and O₂availability) is increased at the onset of a second high-intensityexercise bout and argue that this is responsible for the higher $V$ O₂ observed in the early phase of exercise. However, Krustrupet al. come to the opposite conclusion based on evidence thatmuscle O₂ delivery was far in excess of muscle $V$ O₂ throughoutthe transient phase of high-intensity exercise even when priorexercise was not performed (1, 10), indicating that O₂ availabilitydid not limit muscle $V$ O₂ during the ontransient.

We would also point out an inconsistency between the data presented by Tordi et al. (12) in their Fig. 4 and the data presentedin their Table 1. Figure 4 demonstrates an increased phase II $V$ O₂ amplitude with no obvious change in the rate of adaptation,as has been shown previously (2-7). Therefore, the response profilethat they present does not support their interpretation (basedon the data in their Table 1) that phase II $V$ O₂ kinetics arespeeded. These inconsistencies highlight the limited sensitivityof the methods and analyses employed in thepaper.

In summary, the paper of Tordi et al. (12) is at odds with the large body of work that demonstrates that prior high-intensity(including sprint) exercise does not speed the phase II $V$ O₂ kineticsduring subsequent heavy or severe upright cycle exercise (2-7,9, 11). We believe that this difference is related to significantmethodological shortcomings in their study, as well as to markeddifferences in datainterpretation.

	REFERENCES

1. Bangsbo, J, Krustrup P, Gonzalez-Alonso J, and Saltin B. ATP production and efficiency of human skeletal muscle during intense exercise: effect of previous exercise. Am J Physiol Endocrinol Metab 280: E956-E964, 2001[Abstract/Free Full Text].

2. Bearden, SE, and Moffatt RJ. $V$ O₂ and heart rate kinetics in cycling: transitions from an elevated baseline. J Appl Physiol 90: 2081-2087, 2001[Abstract/Free Full Text].

3. Burnley, M, Doust JH, Ball D, and Jones AM. Effects of prior heavy exercise on $V$ O₂ kinetics during heavy exercise are related to changes in muscle activity. J Appl Physiol 93: 167-174, 2002[Abstract/Free Full Text].

4. Burnley, M, Doust JH, Carter HH, and Jones AM. Effects of prior exercise and recovery duration on oxygen uptake kinetics during heavy exercise in humans. Exp Physiol 86: 417-425, 2001[Abstract].

5. Burnley, M, Doust JH, and Jones AM. Effects of prior heavy exercise, prior sprint exercise and passive warming on oxygen uptake kinetics during heavy exercise in humans. Eur J Appl Physiol 87: 424-432, 2002[Web of Science][Medline].

6. Burnley, M, Jones AM, Carter H, and Doust JH. Effects of prior heavy exercise on phase II pulmonary oxygen uptake kinetics during heavy exercise. J Appl Physiol 89: 1387-1396, 2000[Abstract/Free Full Text].

7. Fukuba, Y, Hayashi N, Koga S, and Yoshida T. $V$ O₂ kinetics in heavy exercise is not altered by prior exercise with a different muscle group. J Appl Physiol 92: 2467-2474, 2002[Abstract/Free Full Text].

8. Gerbino, A, Ward SA, and Whipp BJ. Effects of prior exercise on pulmonary gas exchange kinetics during high-intensity exercise in humans. J Appl Physiol 80: 99-107, 1996[Abstract/Free Full Text].

9. Koppo, K, and Bouckaert J. The effect of prior high-intensity cycling exercise on the $V$ O₂ kinetics during high-intensity cycling exercise is situated at the additional slow component. Int J Sports Med 22: 21-26, 2001[Web of Science][Medline].

10. Krustrup, P, Gonzalez-Alonso J, Quistorff B, and Bangsbo J. Muscle heat production and anaerobic energy turnover during repeated intense dynamic exercise in humans. J Physiol 536: 947-956, 2001[Abstract/Free Full Text].

11. Scheuermann, BW, Hoelting BD, Noble ML, and Barstow TJ. The slow component of O₂ is not accompanied by changes in EMG during repeated bouts of heavy exercise. J Physiol 531: 245-256, 2001[Abstract/Free Full Text].

12. Tordi, N, Perrey S, Harvey A, and Hughson RL. Oxygen uptake kinetics during two bouts of heavy cycling separated by fatiguing sprint exercise in humans. J Appl Physiol 94: 533-541, 2003[Abstract/Free Full Text].

Mark Burnley
Department of Sport and Exercise Science
University of Wales
Aberystwyth SY23 3DA, United Kingdom
E-mail: mhb{at}aber.ac.uk

Andrew M. Jones
Department of Exercise and Sports Science
Manchester Metropolitan University
Alsager ST7 2HL, United Kingdom
E-mail: a.m.jones{at}mmu.ac.uk

To the Editor: Burnley and Jones have asked us to believe that a mechanism exists so "that muscle O₂ delivery was far in excessof muscle $V$ O₂ throughout the transient phase of high intensityexercise." They suggest also that, despite over 20 years of experiencecollecting and analyzing breath-by-breath $V$ O₂ (7), "thereare a number of significant problems with the data" from our laboratory.We will first deal with the erroneous and selective referencingby Burnley and Jones, and then we will attempt once again to explainwhy the system properties that we observed are consistent withknown human physiology and basic concepts of controltheory.

In their first point, Burnley and Jones failed to recognize that we referenced prior work showing that three repetitions ofsprint exercise would cause a more marked and sustained metabolicacidosis (13, 16) than the single sprint employed by Burnleyet al. (3). They did not appreciate that an enhanced, sustainedacidosis would facilitate vasodilation at the onset of exerciseas well as enhance O₂ off-loading from the hemoglobin to exercisingtissues (10, 12). The second and third points of Burnley andJones reveal a misrepresentation of statistics and statisticalconfidence. The signal-to-noise ratio determines the confidencefor curve-fitting parameters [note the high signal-to-noise ratioin Fig. 4 and the clear separation of means and 95% confidenceintervals for $V$ O₂ in Fig. 5 of Tordi et al. (17)]. In contrastto Burnley and Jones' visual misanalysis of our data, the phaseII time constants were 20.6 and 16.4 s for pre- and postexercise,respectively. Furthermore, statistical power is not determinedby sample size alone, as suggested by Burnley and Jones, but alsoby differences between mean values and standard deviation of differencesbetween the means (SAS System for Windows, release 8.01). Thefourth point by Burnley and Jones that "the primary time constantis unchanged" simply is not true as our data, as well as the recentresults of Rossiter et al. (15), have clearly shown a fasterphase II time constant after prior heavyexercise.

Returning to the notion that "O₂ delivery was far in excess of muscle $V$ O₂," it is important for Burnley and Jones to understandwhat is meant by "transient phase of high intensity exercise."Grassi et al. (4) referred to the "early phase of the transient,"in which during the first ~15 s O₂ extraction was not increased.Also, the data of Bangsbo et al. (2) showed that O₂ deliveryminus $V$ O₂ increased only during the first ~15 s. As our laboratoryhas previously indicated (9, 18), the excess delivery ofO₂ within the first 15 s of exercise is to be expected becausethe muscle pump "indiscriminately" increases flow throughout themuscle and because substrates for oxidative metabolism increase(5). The main point here is that the first 15 s does not constitutethe entire transient phase as implied by Burnley and Jones; anotherapproximately five times the time constant (at least 100 s) occursbefore the transient phase is complete. O₂ delivery is dependenton appropriate vasodilation to match blood flow to the sites ofmetabolic demand. Although some feedforward-type controls formuscle blood flow such as muscle pump and flow-mediated dilationdo exist, "the prevailing view is that skeletal muscle functionalhyperemia ... [is] mediated primarily by local control mechanisms"and that "oxygen delivery to the tissues, not blood flow per se,is the controlled variable producing exercise hyperemia" (11),although myogenic, endothelial, and baroreflex factors can alsoinfluence blood flow. Studies that have measured O₂ extractionacross exercising muscle show that this variable reaches an upperlimit relatively early (40-60 s) and that further increases inmuscle $V$ O₂ are related to further increases in blood flow (2,8, 10, 19).

Previously (9, 18), we and our colleagues described the elegant work of Wilson and Rumsey (20) and Arthur et al. (1),who demonstrated the O₂ dependence of muscle metabolism. For anygiven ATP flux rate, the intracellular redox and phosphorylationpotentials must change if mitochondrial PO₂ is less than ~20 Torr.Clearly, from the work of Richardson et al. (14) showing thatintracellular PO₂ is $<=$ 5 Torr across a wide range of work ratesand from the more recent work from members of the same team (6)that demonstrated dependence of phosphocreatine kinetics on bloodPO₂ during recovery, the intracellular environment is in thisdependent region. That is, both O₂ delivery and O₂ utilizationmust adapt during the transient phase of exercise to attain theappropriate ATP flux rates (18). This precludes simple one-componentkinetics even during the so-called primary phase (phase II) andpoints strongly to O₂ delivery being one of the key factors determining $V$ O₂ kinetics. Thus, in "optimizing" the conditions of our experimentby achieving a high, sustained level of metabolic acidosis, weenhanced O₂ delivery so that we were able to detect a statisticallysignificant acceleration of the phase II time constant where previousexperiments did not (3). These data and conclusions are consistentwith the notion that, like other exquisite feedback control systemsin the human body, the delivery of O₂ to muscle during heavy exerciseis also regulated by feedback control of skeletal muscle bloodflow.

	FOOTNOTES

10.1152/japplphysiol.00045.2003

REFERENCES

1. Arthur, PG, Hogan MC, Bebout DE, Wagner PD, and Hochachka PW. Modeling the effects of hypoxia on ATP turnover in exercising muscle. J Appl Physiol 73: 737-742, 1992[Abstract/Free Full Text].

2. Bangsbo, J, Krustrup P, González-Alonso J, Boushel R, and Saltin B. Muscle oxygen kinetics at onset of intense dynamic exercise in humans. Am J Physiol Regul Integr Comp Physiol 279: R899-R906, 2000[Abstract/Free Full Text].

3. Burnley, M, Doust JH, and Jones AM. Effects of prior heavy exercise, prior sprint exercise and passive warming on oxygen uptake kinetics during heavy exercise in humans. Eur J Appl Physiol 87: 424-432, 2002[Web of Science][Medline].

4. Grassi, B, Poole DC, Richardson RS, Knight DR, Erickson BK, and Wagner PD. Muscle O₂ uptake kinetics in humans: implications for metabolic control. J Appl Physiol 80: 988-998, 1996[Abstract/Free Full Text].

5. Greenhaff, PL, Campbell-O'Sullivan SP, Constantin-Teodosiu D, Poucher SM, Roberts PA, and Timmons JA. An acetyl group deficit limits mitochondrial ATP production at the onset of exercise. Biochem Soc Trans 30: 275-280, 2002[Web of Science][Medline].

6. Haseler, LJ, Hogan MC, and Richardson RS. Skeletal muscle phosphocreatine recovery in exercise-trained humans is dependent on O₂ availability. J Appl Physiol 86: 2013-2018, 1999[Abstract/Free Full Text].

7. Hughson, RL. Alterations in the oxygen deficit-oxygen debt relationships with $beta$ -adrenergic receptor blockade in man. J Physiol 349: 375-387, 1984[Abstract/Free Full Text].

8. Hughson, RL, Shoemaker JK, Tschakovsky M, and Kowalchuk JM. Dependence of muscle $V$ O₂ on blood flow dynamics at the onset of forearm exercise. J Appl Physiol 81: 1619-1626, 1996[Abstract/Free Full Text].

9. Hughson, RL, Tschakovsky ME, and Houston ME. Regulation of oxygen consumption at the onset of exercise. Exerc Sports Sci Rev 29: 129-133, 2001.

10. Krustrup, P, González-Alonso J, Quistorff B, and Bangsbo J. Muscle heat production and anaerobic energy turnover during repeated intense dynamic exercise in humans. J Physiol 536: 947-956, 2001[Abstract/Free Full Text].

11. Laughlin, MH, Korthuis RJ, Duncker DJ, and Bache RJ. Control of blood flow to cardiac and skeletal muscle during exercise. In: Handbook of Physiology. Exercise: Regulation and Integration of Multiple Systems. Bethesda, MD: Am. Physiol. Soc, 1996, p. 705-769, sect. 12, chapt. 16.

12. MacDonald, MJ, Naylor HL, Tschakovsky ME, and Hughson RL. Evidence that peripheral circulatory factors limit the rate of increase in muscle O₂ uptake at the onset of heavy exercise. J Appl Physiol 90: 83-89, 2001[Abstract/Free Full Text].

13. McCartney, N, Spriet LL, Heigenhauser GJ, Kowalchuk JM, Sutton JR, and Jones NL. Muscle power and metabolism in maximal intermittent exercise. J Appl Physiol 60: 1164-1169, 1986[Abstract/Free Full Text].

14. Richardson, RS, Noyszewski EA, Kendrick KF, Leigh JS, and Wagner PD. Myoglobin O₂ desaturation during exercise $---$ evidence of limited O₂ transport. J Clin Invest 96: 1916-1926, 1995[Web of Science][Medline].

15. Rossiter, HB, Ward SA, Kowalchuk JM, Howe FA, Griffiths JR, and Whipp BJ. Effects of prior exercise on oxygen uptake and phosphocreatine kinetics during high-intensity knee-extension exercise in humans. J Physiol 537: 291-303, 2001[Abstract/Free Full Text].

16. Spriet, LL, Lindinger MI, McKelvie RS, Heigenhauser GJF, and Jones NL. Muscle glycogenolysis and H⁺ concentration during maximal intermittent cycling. J Appl Physiol 66: 8-13, 1989[Abstract/Free Full Text].

17. Tordi, N, Perrey S, Harvey A, and Hughson RL. Oxygen uptake kinetics during two bouts of heavy cycling separated by fatiguing sprint exercise in humans. J Appl Physiol 94: 533-541, 2003.

18. Tschakovsky, ME, and Hughson RL. Interaction of factors determining oxygen uptake at the onset of exercise. J Appl Physiol 86: 1101-1113, 1999[Abstract/Free Full Text].

19. Van Beekvelt, MC, Shoemaker JK, Tschakovsky ME, Hopman MT, and Hughson RL. Blood flow and muscle oxygen uptake at the onset and end of moderate and heavy dynamic forearm exercise. Am J Physiol Regul Integr Comp Physiol 280: R1741-R1747, 2001[Abstract/Free Full Text].

20. Wilson, DF, and Rumsey WL. Factors modulating the oxygen dependence of mitochondrial oxidative phosphorylation. Adv Exp Biol Med 222: 121-131, 1988[Medline].

Richard L. Hughson
Department of Kinesiology
University of Waterloo
Waterloo, Ontario, Canada N2L 3G1
E-mail: hughson{at}uwaterloo.ca

Nicolas Tordi
Laboratoire des Sciences du Sport
25030 Besançon Cedex, France

Stephane Perrey
UPRES-EA 2991, Faculté des Sciences du Sport
34090 Montpellier, France

This Article

	Full Text (PDF) Free
	Submit a response
	Alert me when this article is cited
	Alert me when eLetters are posted
	Alert me if a correction is posted
	Citation Map

Services

	Email this article to a friend
	Similar articles in this journal
	Similar articles in Web of Science
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager

Citing Articles

	Citing Articles via Google Scholar

Google Scholar

	Articles by Burnley, M.
	Articles by Perrey, S.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Burnley, M.
	Articles by Perrey, S.

Interpreting O2 kinetics in heavy exercise revisited

Interpreting $V$ O₂ kinetics in heavy exercise revisited