Wf. Brechue et Wn. Stainsby, LACTATE AND ACID-BASE EXCHANGE DURING BRIEF INTENSE CONTRACTIONS OF SKELETAL-MUSCLE IN-SITU, Journal of applied physiology, 77(1), 1994, pp. 223-230
Our goal was to design a stimulation-contraction paradigm using an iso
lated in situ dog gastrocnemius muscle preparation that would provide
an experimental model for brief intense intermittent (IC) exercise in
humans. Second, acid-base and ion exchanges across the muscle were inv
estigated using four 30-s bouts of isotonic tetanic contractions (2 s(
-1), 100-ms train, 50 impulses/s) with 4 min of rest between bouts. Du
ring the bouts, peak power output (W) was 18.2 mW/g in the first bout;
it declined by 4.4% by the fourth bout and by 12-16% in each bout. Co
mpared with repetitive continuous contractions (CC) at maximal O-2 upt
ake (Vo(2)), W was greater and Vo(2) (similar to 3.5 mu mol.g(-1).min(
-1)) and CO2 production (similar to 4.5 mu mol.g(-1).min(-1)) were les
s with IC. Venous-arterial (v-a) differences and lactate output peaked
immediately after each bout and were not different from the values re
ported for CC at maximal Vo(2). Thus, with IC, Vo(2)/W as lower and th
e CO2 production/Vo(2) and lactate output/Vo(2) ratios were greater th
an those seen with CC. These differences suggest that this stimulation
-contraction paradigm may be an appropriate model for brief intense ex
ercise. The v-a [H+] difference was a direct result of the v-a Pco(2),
difference. The venous strong ion difference was always greater than
or equal to the arterial strong ion difference because the v-a [Cl-] d
ifference was opposite and greater than the v-a lactate concentration
difference, whereas the v-a [Na+] and [K+] differences were small. Qua
ntitative estimates for the contribution of active muscle to arterial
[H+] and lactate concentration during in vivo exercise from the in sit
u experiments suggest that active muscle does not account completely f
or the change in either.