VO2 max is unaffected by altering the temporal pattern of stimulation frequency in rat hindlimb in situ

doi:10.1152/japplphysiol.00058.2003

$V$ O_{2 max} is unaffected by altering the temporal pattern of stimulation frequency in rat hindlimb in situ

Russell T. Hepple,¹^,2 Daniel J. Krause,² Jason L. Hagen,¹ and Cory C. Jackson¹

¹Faculty of Kinesiology and ²Faculty of Medicine, University of Calgary, Calgary, Alberta, Canada T2N 1N4

Submitted 21 January 2003 ; accepted in final form 8 April 2003

It might be anticipated that fatiguing contractions would impairthe aerobic metabolic response in skeletal muscle if significantfatigue developed before full activation of aerobic metabolism.On the basis of this premise, we examined two groups of ratsto test the hypothesis that a gradual increase in stimulationfrequency would yield a higher maximal O₂ uptake (O_2max) than beginning immediately with an intense stimulationfrequency because of a slower progression of fatigue underthe former conditions. In one group of animals, the distalhindlimb muscles were electrically stimulated at a frequencyof 60 tetani/min for 4 min (F₆₀; n = 6 rats); in the other group, the muscles were incrementally stimulated for 1 min ateach of 7.5, 15, 30, and 60 tetani/min and for 2 min at 90tetani/min (F_Inc; n = 5 rats). Despite large differences inrate of fatigue [time to 60% of initial force was 47 ±3 (SE) vs. 188 ± 1 s in F₆₀ and F_Inc, respectively]and the time at which O_{2 max} occurred (120 ± 15 vs. 264 ± 6 s), O_{2 max}was not different (419 ± 24 vs. 381 ± 44 µmol· min^-1 · 100 g^-1). Furthermore, time x tensionintegral at O_{2 max} (3.82 ± 0.41vs. 4.07 ± 0.31 N · s) and peak lactate efflux(910 ± 45 vs. 800 ± 98 µmol · min^-1· 100 g^-1) were not different between groups. Thus ourresults show that the more rapid progression of fatigue inF₆₀ did not compromise the aerobic metabolic response in electricallystimulated rat hindlimb muscles. However, in both groups, O₂uptake and lactate efflux declined after O_2max was attained in similar proportion to a further fall inforce, suggesting that ongoing fatigue with intense contractionsreduced ATP demand below that requiring maximal aerobic andglycolytic metabolic responses once O_{2 max}was reached.

maximal O₂ uptake; aerobic metabolism; anaerobic metabolism; lactate

Address for reprint requests and other correspondence: R. T. Hepple, Faculty of Kinesiology, 2500 Univ. Dr. NW, Calgary, AB, Canada T2N 1N4 (E-mail: hepple{at}ucalgary.ca).

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