Isotonic velocity transients in frog muscle fibres following quick changes in load.

AUTOR(ES)

Sugi, H

RESUMO

1. The isotonic velocity transients following quick changes in load were studied on tetanized frog skeletal muscle fibres with special reference to those following quick increases in load. 2. When the load was increased quickly from the maximum isometric force P0 to 1.05-1.3 P0, the fibres exhibited markedly oscillatory length changes with distinct reversal in the direction of movement before starting to lengthen with a nearly constant velocity. 3. The period of the oscillatory length changes increased with increasing magnitude of the load step, and decreased with increasing temperature. The amplitude of oscillatory length changes never exceeded 0.5% of the slack length L0, i.e. about 50 A per half-sarcomere. 4. If the load was increased quickly from P0 to 1.3-1.6 P0, the fibres lengthened continuously with velocities decreasing with time. 5. The response of fibres, shortening isotonically under a large load (about 0.8 P0), to quick increases in load was qualitatively similar to that of isometrically contracting fibres. 6. When quick increases in load were applied during isotonic shortening under a moderate or small load (0.1-0.6 P0), the fibres showed initial transient lengthening before starting to shorten against a new load, indicating a decrease in the ability of the fibres to sustain a load after a period of isotonic shortening and its restoration during the transient lengthening. 7. The extent of decrease in load-sustaining ability as well as its subsequent restoration process was dependent on both the amount of load and the duration of preceding isotonic shortening. 8. The decrease in the load-sustaining ability during the course of isotonic shortening appeared to be complete within 30-50 msec after the beginning of shortening. 9. These results are discussed in relation to the kinetic properties of the crossbridges responsible for muscle contraction.

Documentos Relacionados

• Enhancement of mechanical performance in frog muscle fibres after quick increases in load.
• Force-velocity relation of frog skeletal muscle fibres shortening under continuously changing load.
• Calcium transients in frog skeletal muscle fibres following conditioning stimuli
• CROSS-BRIDGE PROPERTIES DERIVED FROM MUSCLE ISOTONIC VELOCITY TRANSIENTS
• Aequorin-calcium transients in frog twitch muscle fibres.