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Development of force-velocity relation, stiffness and isometric tension in frog single muscle fibres

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Summary

The force-velocity (T-V) relation and the force-extension (T 1) relation from single fibres isolated from the muscle tibialis anterior of the frog were determined at preset times during the rise of tension and the plateau of an isometric tetanus.

During the rise of an isometric tetanus the value of V0 (the velocity of shortening at zero load) remained constant, whereas both the forceT exerted during shortening at a given velocity lower than V0 and the slope of the instantaneousT 1 curve increased with time after the beginning of the stimulus volley. However, while the value ofT (a measure of the level of activation) attained its final value much before the isometric tension attained the plateau, the slope of theT 1 curve (the fibre stiffness, a measure of the number of attached crossbridges) increased throughout the course of tension development. In six muscle fibres, at 2.25µm sarcomere length and at about 4° C, at a time during the tetanus rise whenT had attained 81% of its final value, the fibre stiffness and the isometric tension had risen, respectively, to 50% and to 38% of the values attained at the tetanus plateau. Later, whenT had already attained 99% of its final value, the fibre stiffness and the isometric tension had risen, respectively, to 80% and to 76% of their plateau values. In the same muscle fibres, the average value for the amount of step release required to drop the plateau tetanic tension to zero was only 8.62 nm (observed) or 6.16 nm (extrapolated from the linear part of theT 1 curves) per half sarcomere.

It is concluded that the large delay in the development of the isometric tension with respect to the development ofT, and therefore with respect to the development of the wholeT-V relation, cannot be attributed to the passive series compliance of the muscle fibres. It is likely that this delay is due to a specific event in the contractile process.

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References

  • CAMBRIDGE, Q. W. & HAINES, J. (1959) A new versatile transducer system.J. Physiol. 149, 2–3P.

    Google Scholar 

  • CECCHI, G., COLOMO, F. & LOMBARDI, V. (1976) A loudspeaker servo system for determination of mechanical characteristics of isolated muscle fibres.Boll. Soc. ital. Biol. sper. 52, 733–6.

    Google Scholar 

  • CECCHI, G., COLOMO, F. & LOMBARDI, V. (1978) Force-velocity relation in normal and nitrate-treated frog single muscle fibres during rise of tension in an isometric tetanus.J. Physiol. 285, 257–73.

    Google Scholar 

  • CECCHI, G., COLOMO, F., LOMBARDI, V. & PIAZZESI, G. (1979) Development of activation and rise of tension in an isometric tetanus.Pflügers Arch. 381, 71–4.

    Google Scholar 

  • CECCHI, G., GRIFFITHS, P. J. & TAYLOR, S. (1982) Muscular contraction: the kinetics of cross-bridge attachment studied by high frequency stiffness measurements.Science 217, 70–2.

    Google Scholar 

  • EDMAN, K. A. P., MULIERI, L. A. & SCUBON MULIERI, B. (1976) Non-hyperbolic force-velocity relationship in single muscle fibres.Acta Physiol. scand. 98, 143–56.

    Google Scholar 

  • FORD, L. E., HUXLEY, A. F. & SIMMONS, R. M. (1977) Tension responses to sudden length change in stimulated frog muscle fibres near slack length.J. Physiol. 269, 441–515.

    Google Scholar 

  • HILL, A. V. (1938) The heat of shortening and the dynamic constants of muscle.Proc. R. Soc. 126, 136–95.

    Google Scholar 

  • HILL, A. V. (1949) The abrupt transition from rest to activity in muscle.Proc. R. Soc. 136, 399–420.

    Google Scholar 

  • HILL, A. V. (1970)First and Last Experiments in Muscle Mechanics. Cambridge: Cambridge University Press.

    Google Scholar 

  • HUXLEY, A. F. (1957) Muscle structure and theories of contraction.Prog. Biophys. biophys. Chem. 7, 255–318.

    Google Scholar 

  • HUXLEY, A. F. (1974) Muscular contraction.J. Physiol. 243, 1–43.

    Google Scholar 

  • HUXLEY, A. F. & LOMBARDI, V. (1980) A sensitive force-transducer with resonant frequency 50 kHz.J. Physiol. 305, 15–6P.

    Google Scholar 

  • HUXLEY, A. F. & PEACHEY, L. D. (1961) The maximum length for contraction in vertebrate striated muscle.J. Physiol. 156, 150–65.

    Google Scholar 

  • HUXLEY, A. F. & SIMMONS, R. M. (1971) Proposed mechanism of force generation in striated muscle.Nature 233, 533–8.

    Google Scholar 

  • HUXLEY, A. F. & SIMMONS, R. M. (1973) Mechanical transients and the origin of muscular force.Cold Spring Harb. Symp. quant. Biol. 37, 669–80.

    Google Scholar 

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Authors and Affiliations

  1. Istituto di Fisiologia, Università degli Studi di Firenze, Viale G.B. Morgagni 63, I-50134, Firenze, Italy

    C. Ambrogi-Lorenzini, F. Colomo & V. Lombardi

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  1. C. Ambrogi-Lorenzini
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  2. F. Colomo
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  3. V. Lombardi
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Ambrogi-Lorenzini, C., Colomo, F. & Lombardi, V. Development of force-velocity relation, stiffness and isometric tension in frog single muscle fibres. J Muscle Res Cell Motil 4, 177–189 (1983). https://doi.org/10.1007/BF00712029

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  • DOI: https://doi.org/10.1007/BF00712029

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