Slow-to-fast transformation of denervated soleus muscles by chronic high-frequency stimulation in the rat.

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Slow-to-fast transformation of denervated soleus muscles by chronic high-frequency stimulation in the rat.

L Gorza, K Gundersen, T Lømo, S Schiaffino and R H Westgaard

Institute of Neurophysiology, Oslo, Norway.

1. Adult soleus muscles were denervated and stimulated directlyfor 2-130 days with 'fast' (short pulse trains at 100 Hz) or'slow' (continuously at 10 Hz, or long pulse trains at 15 Hz)stimulus patterns. 2. At the end of the period of stimulationisometric twitches and tetani and isotonic shortening velocitieswere measured. Frozen cross-sections were later examined withantibodies against myosin heavy chains specific for adult fast,adult slow and fetal myosin. 3. Isometric twitch duration (twitchtime-to-peak and half-relaxation time) decreased during intermittent100 Hz stimulation to values that were almost as fast as inthe normal extensor digitorum longus (EDL) (95 and 94% transformation).The major part of the decrease occurred between 2 and 21 daysafter the onset of stimulation, and was accompanied by post-tetanicpotentiation of the twitch, 'sag' in tension during an unfusedtetanus, lower twitch/tetanus ratio and marked shifts to theright (higher frequencies) of the tension-frequency curve ofthe muscle. In contrast, during 10 or 15 Hz stimulation theisometric twitch duration remained slow, the twitch continuedto show post-tetanic depression and absence of 'sag', whilethe twitch/tetanus ratio increased. 4. Denervation per se ledto a slight increase and, then, after about a month, to a moderateand gradual decrease in twitch duration. The twitch/tetanusratio increased markedly and post-tetanic depression becameless pronounced or disappeared. Muscle weight and particularlytetanic tension were markedly reduced and these reductions wereto a large extent counteracted by electrical stimulation. 5.Implantation of sham electrodes had no effect on twitch durationof denervated or innervated control muscles, but reduced tetanictension in the innervated control muscles. 6. Maximum isotonicshortening velocity of the whole muscle (mm/s) increased duringintermittent 100 Hz stimulation to a value as fast as in thenormal EDL (110% transformation). Since the muscle fibres alsoincreased in length (35%) maximum intrinsic shortening velocity(fibre lengths/s) was only incompletely transformed (55%). Theincrease in Vmax occurred between 7 and 14 days after the onsetof stimulation. 7. All the fibres stimulated intermittentlyat 100 Hz were strongly labelled with anti-fast myosin and morethan 90% were in addition weakly labelled by anti-slow myosin.Weak and variable labelling with anti-fast myosin was firstdetected 7 days after the onset of stimulation. In contrast,essentially all the fibres stimulated at 10 or 15 Hz showedno binding of anti-fast but strong binding of anti-slow myosin.(ABSTRACTTRUNCATED AT 400 WORDS)

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