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Effects of ‘warm-up’ exercise on energy provision and exercise performance in horses and humans: a comparative review

Published online by Cambridge University Press:  09 March 2007

Mark Burnley*
Affiliation:
Department of Sport and Exercise Science, Carwyn James Building, University of Wales, Aberystwyth, Ceredigion SY23 3FD, UK
Andrew M. Jones
Affiliation:
School of Sport and Health Sciences, St. Luke's Campus, University of Exeter, EX1 2LU
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Abstract

Equine and human athletic endeavour often requires near-maximal rates of aerobic metabolism. It, therefore, follows that any practical method of increasing the aerobic contribution to exercise should be of benefit to athletic performance. Prior ‘warm-up’ exercise is widely advocated before exercise performance in order to ‘prime’ the physiological mechanisms of power generation and energy supply. In the present review, we examine evidence that prior exercise, in both the horse and the human, results in marked increases in O2 supply and utilization during subsequent intense exercise. Much of this evidence stems from the study of pulmonary oxygen uptake dynamics and the related concepts of oxygen deficit and critical power. We, therefore, also review the effect of prior exercise in light of the exercise intensity domains in which the prior and subsequent exercise performances take place. Recent evidence suggests that both moderate and heavy exercise should improve subsequent severe exercise performance in both species by ∼2–3%, although much work remains to be done to establish the ‘optimal’ warm-up regime(s).

Type
Research Article
Copyright
Copyright © Cambridge University Press 2005

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References

1Poole, DC (2004). Current concepts of oxygen transport during exercise. Equine and Comparative Exercise Physiology 1: 522.CrossRefGoogle Scholar
2Bramble, DM and Lieberman, DE (2004). Endurance running and the evolution of Homo. Nature 432: 345352.CrossRefGoogle ScholarPubMed
3Whipp, BJ (1994). The slow component of O2 uptake kinetics during heavy exercise. Medicine and Science in Sports and Exercise 26: 13191326.CrossRefGoogle ScholarPubMed
4Jones, AM and Koppo, K (2004). Effect of training on VO2 kinetics and performance. In: Jones, AM & Poole, DC (eds), Oxygen Uptake Kinetics in Sport, Exercise and Medicine. London: Routledge.Google Scholar
5Jones, AM, Koppo, K and Burnley, M (2003). Effects of prior exercise on metabolic and gas exchange responses to exercise. Sports Medicine 33: 949971.Google Scholar
6Burnley, M, Koppo, K and Jones, AM (2004). “Priming exercise” and VO_2 kinetics. In: Jones, AM & Poole, DC (eds), Oxygen Uptake Kinetics in Sport, Exercise and Medicine. London: Routledge, pp. 230260.Google Scholar
7Whipp, BJ and Mahler, M (1980). Dynamics of pulmonary gas exchange during exercise. In: West, JB (ed.), Pulmonary Gas Exchange (Volume II) Organism and Environment. London: Academic Press, pp. 3396.Google Scholar
8Behnke, BJ, Barstow, TJ and Poole, DC (2005). Relationship between VO_2 responses at the mouth and across the exercising muscles. In: Jones, AM & Poole, DC (eds), Oxygen Uptake Kinetics in Sport, Exercise and Medicine. London: Routledge, pp. 140153.Google Scholar
9Rossiter, HB, Howe, FA and Ward, SA (2005). Intramuscular phosphate and pulmonary VO2 kinetics during exercise. In: Jones, AM & Poole, DC (eds), Oxygen Uptake Kinetics in Sport, Exercise and Medicine. London: Routledge, pp. 230260.Google Scholar
10Grassi, B, Poole, DC, Richardson, RS, Knight, DR, Erickson, BK and Wagner, PD (1996). Muscle O2 uptake kinetics in humans: implications for metabolic control. Journal of Applied Physiology 80: 988998.Google Scholar
11Rossiter, HB, Ward, SA, Doyle, VL, Howe, FA, Griffiths, JR and Whipp, BJ (1999). Inferences from pulmonary O2 uptake with respect to intramuscular [phosphocreatine] kinetics during moderate intensity exercise in humans. Journal of Physiology 518: 921932.Google Scholar
12Rossiter, HB, Ward, SA, Kowalchuck, JM, Howe, FA, Griffiths, JR and Whipp, BJ (2002). Dynamic asymmetry of phosphocreatine concentration and O2 uptake between the on- and off-transients of moderate- and high-intensity exercise in humans. Journal of Physiology 541: 9911002.CrossRefGoogle ScholarPubMed
13Kindig, CA, Howlett, RA, Stary, CM, Walsh, B and Hogan, MC (2005). Effects of acute creatine kinase inhibition on metabolism and tension development in isolated single myocytes. Journal of Applied Physiology 98: 541549.Google Scholar
14Grassi, B, Gladden, LB, Samaja, M, Stary, CM and Hogan, MC (1998). Faster adjustment of O2 delivery does not affect VO2-on kinetics in isolated in situ canine muscle. Journal of Applied Physiology 84: 13981403.Google Scholar
15Grassi, B, Hogan, MC, Greenhaff, PL, Hamann, JJ, Kelley, KM, Aschenbach, WG, Constantin-Teodosiu, D and Gladden, LB (2002). VO2 -on kinetics in dog gastrocnemius in situ following activation of pyruvate dehydrogenase by dichloroacetate. Journal of Physiology 538: 195207.CrossRefGoogle ScholarPubMed
16Bangsbo, J, Gibala, MJ, Krustrup, P, Gonzalez-Alonso, J and Saltin, B (2002). Enhanced pyruvate dehydrogenase activity does not affect muscle O2 uptake at onset of intense exercise in humans. American Journal of Physiology 282: R273R280.Google Scholar
17Rossiter, HB, Ward, SA, Howe, FA, Wood, DM, Kowalchuck, JM, Griffiths, JR and Whipp, BJ (2002). Effects of dichloroacetate on VO2 and intramuscular 31P metabolite kinetics during high-intensity exercise in humans. Journal of Applied Physiology 95: 11051115.Google Scholar
18Jones, AM, Wilkerson, DP, Wilmshurst, S and Campbell, IT (2004). Dichloroacetate does not speed phase II pulmonary VO2 kinetics following the onset of heavy intensity cycle exercise. Pflugers Archives 447: 867874.CrossRefGoogle Scholar
19Koppo, K, Wilkerson, DP, Bouckaert, J, Wilmshurst, S, Campbell, IT and Jones, AM (2004). Influence of DCA on pulmonary VO2 kinetics during moderate-intensity cycle exercise. Medicine and Science in Sports and Exercise 36: 11591164.Google Scholar
20Langsetmo, I, Weigle, GE, Fedde, MR, Erickson, HH, Barstow, TJ and Poole, DC (1997). VO2 kinetics in the horse during moderate and heavy exercise. Journal of Applied Physiology 83: 12351241.Google Scholar
21Langsetmo, I and Poole, DC (1999). VO2 recovery kinetics in the horse following moderate, heavy, and severe exercise. Journal of Applied Physiology 86: 11701177.CrossRefGoogle ScholarPubMed
22Gaesser, GA and Poole, DC (1996). The slow component of oxygen uptake kinetics in humans. In: Holloszy, JO (ed.), Exercise and Sports Science Reviews. Philadelphia: Williams and Wilkins, pp. 3570.Google Scholar
23Carter, H, Pringle, JS, Jones, AM and Doust, JH (2002). Oxygen uptake kinetics during treadmill running across exercise intensity domains. European Journal of Applied Physiology 86: 347354.Google Scholar
24Hill, DW, Poole, DC and Smith, JC (2002). The relationship between power and time to achieve VO2max. Medicine and Science in Sports and Exercise 34: 709714.Google Scholar
25Whipp, BJ, Ward, SA, Lamarra, N, Davis, JA and Wasserman, K (1982). Parameters of ventilatory and gas exchange dynamics during exercise. Journal of Applied Physiology 52: 15061513.CrossRefGoogle ScholarPubMed
26Monod, H and Scherrer, J (1965). The work capacity of a synergic muscle group. Ergonomics 8: 329338.CrossRefGoogle Scholar
27Pringle, JS and Jones, AM (2002). Maximal steady state, critical power and EMG during cycling. European Journal of Applied Physiology 88: 214226.CrossRefGoogle ScholarPubMed
28Beneke, R and von Duvillard, SP (1996). Determination of maximal lactate steady state response in selected sports events. Medicine and Science in Sports and Exercise 28: 241246.Google Scholar
29Coats, EM, Rossiter, HB, Day, JR, Miura, A, Fukuba, Y and Whipp, BJ (2003). Intensity dependent tolerance to exercise after attaining VO2 in humans. Journal of Applied Physiology 95: 483490.CrossRefGoogle ScholarPubMed
30Coyle, EF (2004). Fluid and fuel intake during exercise. Journal of Sports Sciences 22: 3955.Google Scholar
31Poole, DC, Ward, SA, Gardner, GW and Whipp, BJ (1988). Metabolic and respiratory profile of the upper limit for prolonged exercise in man. Ergonomics 31: 12651279.CrossRefGoogle ScholarPubMed
32Medbø, JF, Mohn, A-C, Tabata, I, Bahr, R, Vaage, O and Sejersted, OM (1988). Anaerobic capacity determined by maximal accumulated O2 deficit. Journal of Applied Physiology 64: 5060.CrossRefGoogle ScholarPubMed
33Marlin, D and Nankervis, K (2002). Equine Exercise Physiology Oxford: Blackwell Publishing.Google Scholar
34Rose, RJ, Hodgson, DR, Kelso, TB, McCutcheon, LJ, Reid, T-A, Bayly, WM and Gollnick, PD (1988). Maximum O2 uptake, O2 debt and deficit, and muscle metabolites in Thoroughbred horses. Journal of Applied Physiology 64: 781788.CrossRefGoogle ScholarPubMed
35Eaton, MD, Evans, DL, Hodgson, DR and Rose, RJ (1995). Maximal accumulated oxygen deficit in Thoroughbred horses. Journal of Applied Physiology 78: 15641568.CrossRefGoogle ScholarPubMed
36Tyler, CM, Hodgson, DR and Rose, RJ (1996). Effect of a warm-up on energy supply during high intensity exercise in horses. Equine Veterinary Journal 28: 117120.CrossRefGoogle ScholarPubMed
37McCutcheon, LJ, Geor, RJ and Hinchcliff, KW (1999). Effects of prior exercise on muscle metabolism during sprint exercise in horses. Journal of Applied Physiology 87: 19141922.Google Scholar
38Hinchcliff, KW, Lauderdale, MA, Geor, RJ, Lacombe, VA and Taylor, LE (2002). High intensity exercise conditioning increases accumulated oxygen deficit in horses. Equine Veterinary Journal 34: 916.CrossRefGoogle Scholar
39Fukuba, Y and Whipp, BJ (1999). A metabolic limit on the ability to make up for lost time in endurance events. Journal of Applied Physiology 87: 853861.CrossRefGoogle ScholarPubMed
40Fukuba, Y, Miura, A, Endo, M, Kan, A, Yanagawa, K and Whipp, BJ (2003). The curvature constant parameter of the power-duration curve for varied-power exercise. Medicine and Science in Sports and Exercise 35: 14131418.CrossRefGoogle ScholarPubMed
41Wilkerson, DP, Koppo, K, Barstow, TJ and Jones, AM (2004). Effect of prior multiple-sprint exercise on pulmonary O2 uptake kinetics following the onset of perimaximal exercise. Journal of Applied Physiology 97: 12271236.CrossRefGoogle ScholarPubMed
42Geor, RJ, McCutcheon, LJ and Hinchcliff, KW (2000). Effects of warm-up intensity on kinetics of oxygen consumption and carbon dioxide production during high-intensity exercise in horses. American Journal of Veterinary Research 61: 638645.CrossRefGoogle ScholarPubMed
43Hughson, RL, O'leary, DD, Betik, AC and Hebestreit, H (2000). Kinetics of oxygen uptake at the onset of exercise near or above peak oxygen uptake. Journal of Applied Physiology 88: 18121819.Google Scholar
44Scheuermann, BW and Barstow, TJ (2003). O2 uptake kinetics during exercise at peak O2 uptake. Journal of Applied Physiology 95: 20142022.Google Scholar
45Gerbino, A, Ward, SA and Whipp, BJ (1996). Effects of prior exercise on pulmonary gas exchange kinetics during high-intensity exercise in humans. Journal of Applied Physiology 80: 99107.CrossRefGoogle ScholarPubMed
46MacDonald, M, Pedersen, PK and Hughson, RL (1997). Acceleration of VO2 kinetics in heavy submaximal exercise by hyperoxia and prior high-intensity exercise. Journal of Applied Physiology 83: 13181325.CrossRefGoogle ScholarPubMed
47Burnley, M, Jones, AM, Carter, H and Doust, JH (2000). Effects of prior heavy exercise on phase II pulmonary oxygen uptake kinetics during heavy exercise. Journal of Applied Physiology 89: 13871396.Google Scholar
48Burnley, M, Doust, JH, Carter, H and Jones, AM (2001). Effects of prior exercise and recovery duration on oxygen uptake kinetics during heavy exercise in humans. Experimental Physiology 86: 417425.Google Scholar
49Rossiter, HB, Howe, FA, Ward, SA, Kowalchuck, JM, Doyle, VL, Griffiths, JR and Whipp, BJ (2001). Effects of prior exercise on oxygen uptake and phosphocreatine kinetics during high-intensity knee-extension exercise in humans. Journal of Physiology 537: 291303.Google Scholar
50Tordi, N, Perrey, S, Harvey, A and Hughson, RL (2003). Oxygen uptake kinetics during two bouts of heavy cycling separated by fatiguing sprint exercise in humans. Journal of Applied Physiology 94: 533541.Google Scholar
51Koppo, K and Bouckaert, J (2001). The effect of prior high-intensity cycling exercise on the VO2 kinetics during high-intensity cycling exercise is situated at the additional slow component. International Journal of Sports Medicine 22: 2126.Google Scholar
52Scheuermann, B, Hoelting, BD, Noble, ML and Barstow, TJ (2001). The slow component of O2 uptake is not accompanied by changes in muscle EMG during repeated bouts of heavy exercise in humans. Journal of Physiology 531: 245256.Google Scholar
53Bearden, SE and Moffatt, RJ (2001). VO2 and heart rate kinetics in cycling: transitions from an elevated baseline. Journal of Applied Physiology 90: 20812087.Google Scholar
54Fukuba, Y, Hayashi, N, Koga, S and Yoshida, T (2002). VO2 kinetics in heavy exercise is not altered by prior exercise with a different muscle group. Journal of Applied Physiology 92: 24672474.CrossRefGoogle Scholar
55Krustrup, P, Gonzalez-Alonso, J, Quistorff, B and Bangsbo, J (2001). Muscle heat production and anaerobic energy turnover during repeated intense dynamic exercise in humans. Journal of Physiology 536: 947956.Google Scholar
56Gray, SC, Devito, G and Nimmo, MA (2002). Effect of active warm-up on metabolism prior to and during intense dynamic exercise. Medicine and Science in Sports and Exercise 34: 20912096.Google Scholar
57Campbell-O'Sullivan, SP, Constantin-Teodosiu, D, Peirce, N and Greenhaff, PL (2002). Low intensity exercise in humans accelerates mitochondrial ATP production and pulmonary oxygen kinetics during subsequent more intense exercise. Journal of Physiology 538: 931939.Google Scholar
58Burnley, M, Doust, JH, Ball, D and Jones, AM (2002). Effects of prior heavy exercise on heavy exercise VO2 kinetics are related to changes in muscle activity. Journal of Applied Physiology 93: 167174.Google Scholar
59Sahlin, K, Sørensen, JB, Gladden, LB, Rossiter, HB and Pedersen, PK (2005). Prior heavy exercise eliminates VO2 slow component and reduces efficiency during submaximal exercise in humans. Journal of Physiology 564: 765773.Google Scholar
60Sargeant, AJ and Dolan, P (1987). Effect of prior exercise on maximal short-term power output in males. Journal of Applied Physiology 63: 14751480.Google Scholar
61Åstrand, P-O and Saltin, B (1961). Maximal oxygen uptake and heart rate in various types of muscular activity. Journal of Applied Physiology 16: 977981.Google ScholarPubMed
62Jones, AM, Wilkerson, DP, Burnley, M and Koppo, K (2003). Prior heavy exercise enhances performance during subsequent perimaximal exercise. Medicine and Science in Sports and Exercise 35: 20852092.Google Scholar
63Lauderdale, MA and Hinchcliff, KW (1999). Hyperbolic relationship between time-to-fatigue and workload. Equine Veterinary Journal Supplement 30: 586590.CrossRefGoogle Scholar
64Hopkins, WG, Hawley, JA and Burke, LM (1999). Design and analysis of research on sport performance enhancement. Medicine and Science in Sports and Exercise 31: 472485.CrossRefGoogle ScholarPubMed
65Burnley, M, Doust, JH and Jones, AM (2005). Effects of prior warm-up regime on severe-intensity cycling performance. Medicine and Science in Sports and Exercise 37: 838845.Google Scholar
66Patel, R, Rossiter, HB and Whipp, BJ (2001). The effect of recovery time between repeated bouts of high-intensity exercise on the on-transient VO2 kinetics in humans. Journal of Physiology 533P: 123124P [abstract].Google Scholar