Force decline due to fatigue and intracellular acidification in isolated fibres from mouse skeletal muscle.

Abstract

1. Single, intact muscle fibres from the flexor brevis foot muscle of the mouse have been fatigued at 25 degrees C by 350 ms, 70 Hz stimulation trains, initially delivered every 3.8 s and then at stepwise decreasing intervals until tension was down to about 30% of the original (Po). Rested fibres generated a specific force of 372 +/‐ 8.4 kPa (mean +/‐ S.E.M., n = 25). 2. Endurance, defined as time to attain 0.5 Po, varied from 2.5 to 24 min, with the majority of fibres falling in the range 4‐8 min, corresponding to 70‐160 tetani. In all fibres where it was followed, tension recovery after cessation of stimulation was 90% or better. 3. Tetanic force declined in a characteristic way during fatiguing stimulation: initially tension fell to about 0.85 Po during eight to fourteen tetani (phase 1), then followed a long period of nearly steady tension generation (phase 2) and finally there was a rapid force decline (phase 3). 4. Caffeine (15 or 25 mM) caused a slight potentiation of tetanic force in the rested state (4.7 +/‐ 0.9%, n = 21) and slowed relaxation. No change in resting tension was seen with caffeine at concentrations up to 25 mM. 5. Caffeine (15‐25 mM) caused a rapid and dramatic increase in tetanic force when applied to severely fatigued fibres: force output rose from 29.8 +/‐ 1.5 to 82.5 +/‐ 1.2% (n = 13) of Po. During phase 2 force potentiation with caffeine was much smaller. 6. A 10 s pause resulted in a large, transient force increase when imposed during phase 3 but had little effect on force production during phase 2. 7. Intracellular acidosis, induced by superfusion with Tyrode solution gassed with 30% CO2 instead of the normal 5% (extracellular pH 6.5 vs. 7.3), resulted in a fall in tetanic tension to about 0.85 Po (n = 7). This depression could to some extent be counteracted by 15 mM‐caffeine, which brought tension back to about 0.90 Po. 8. It is concluded that there are at least two mechanisms for force decline during fatiguing stimulation: one which manifests itself early and is likely to be related to cross‐bridge function and another representing deficient Ca2+ handling which becomes prominent at a later stage. For severe fatigue (0.3 Po) the latter mechanism is dominant.