G. Citterio scite author profile

1. The force-velocity relationship and the stress-strain curve of the so-called series elastic component (s.e.c.) of frog sartorius, semitendinosus and gastrocnemius have been determined during shortening against a given force (isotonic quick-release) and at high speed (controlled release): (a) from a state of isometric contraction and (b) after stretching of the contracted muscle. In both cases the muscle was released from the same length: this was usually slightly greater than the muscle's resting length.2. The muscle released immediately after being stretched is able to shorten against a constant force, P, equal to or even greater than the isometric force, P(0), at the same length. When the force P applied to the muscle is reduced below P(0) the velocity of shortening is greater after stretching, and the force-velocity curve is therefore shifted along the velocity axis: the shift is maximal when P is near to P(0) and it decreases rapidly with decreasing P.3. The extent of shortening of the s.e.c. required to make the force fall from P(0) to zero is 50-100% greater when the muscle is released immediately after stretching than when it is released from a state of isometric contraction. This difference is found by using either the controlled release method or the isotonic quick-release method.4. If a time interval is left between the end of stretching and the onset of shortening of the contracted muscle (controlled release method), the length change of the s.e.c., for a given fall of the force, is reduced and approaches that taking place when the muscle is released from a state of isometric contraction.5. Curare does not affect the results described above, indicating that these do not depend on modification of the neuromuscular transmission.6. It is concluded that stretching a contracted muscle modifies temporarily: (a) its elastic characteristics, as shown by the greater amount of mechanical energy released for a given fall of the force at the muscle's extremities, and (b) its contractile machinery, as it is suggested by the change of the force-velocity relationship.

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Decay of inspiratory muscle activity in chronic airway obstruction

Citterio¹,

Agostoni²,

Santo³

et al. 1981

Journal of Applied Physiology

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Relative decay rate of inspiratory muscle electrical activity (RDRI) in patients with chronic airway obstruction increased with decreasing expiratory time (TE), being faster than in normal subjects for a given TE. Time course of decay was similar in shape to that of normal subjects, whereas persistence time of activity during expiration was about half. Hence, braking action of inspiratory muscles in patients was smaller than in normal subjects. No tonic activity of inspiratory muscles was found in patients, even when frequency was increased and hyperinflation enhanced. Hence tonic activity of inspiratory muscles found by others in asymptomatic asthmatic or normal subjects after histamine inhalation seems elicited by histamine. In normal subjects breathing under resistive load, RDRI became similar to that of patients for a given TE: tonic activity of extradiaphragmatic inspiratory muscles occurred only if frequency was voluntarily increased at least three times, an unphysiological condition with resistive load. Under discontinuous inspiratory elastic load, RDRI of patients decreased or did not change, whereas previously that of normal subjects was found to increase.

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Mechanical transients initiated by ramp stretch and release to Po in frog muscle fibers

Cavagna¹,

Mazzanti²,

Heglund³

et al. 1986

American Journal of Physiology-Cell Physiology

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Single fibers from the tibialis muscle of Rana temporaria were subjected to ramp stretches during tetanic stimulation at a sarcomere length of approximately 2 microns. Immediately after the stretch, or after different time delays, the active fiber was released against a constant force equal to the isometric force (Po) exerted immediately before the stretch. Four phases were detected after release: an elastic recoil of the fiber's undamped elements, a transient rapid shortening, a marked reduction in the velocity of shortening (often to 0), and an apparently steady shortening (sometimes absent). Increasing the amplitude of the stretch from approximately 2 to 10% of the fiber rest length led to an increase in phase 2 shortening from approximately 5 to 10 nm per half-sarcomere. Phase 2 shortening increased further (up to 14 nm per half-sarcomere) if a time interval of 5-10 ms was left between the end of large ramp stretches and release to Po. After 50- to 100-ms time intervals, shortening occurred in two steps of approximately 5 nm per half-sarcomere each. These findings suggest that phase 2 is due to charging, during and after the stretch, of a damped element, which can then shorten against Po in at least two steps of approximately 5 nm/half sarcomere each.

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Selective activation of quadriceps muscle fibers according to bicycling rate

Citterio¹,

Agostoni²

1984

Journal of Applied Physiology

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Moving average electromyography (MA) of quadriceps muscle bellies has been recorded during bicycling at different rates (30-70 cycles/min) or forces (1-3 kg). For power increments (50-100%) achieved by increasing force at constant rate, MA during pedal downstroke always increased. For similar power increments achieved by increasing the rate at constant force, MA did not increase (37% of cases), increased less (37%), or increased similarly (26%). Investigations by others on the rat suggest that the lack of increase of MA despite power increment was not compensated by other muscle activity; hence it indicates a shift from slow to fast fibers, which provide greater power per unit stimulus. Smaller increase of MA with increasing rate rather than force at isopower could depend on this shift or on muscle properties, if operating on ascending limb of power-velocity curve. This, however, does not seem the case for slow fibers, which should develop peak power at about 25 cycles/min. Hence, fibers of quadriceps muscle of humans seem selectively activated according to movement speed, as previously found in inspiratory muscles of rabbits.

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Relative decay rate of inspiratory muscle pressure and breath timing in man

Agostoni

Citterio

1979

Respiration Physiology

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G. Citterio

Effect of stretching on the elastic characteristics and the contractile component of frog striated muscle

Decay of inspiratory muscle activity in chronic airway obstruction

Mechanical transients initiated by ramp stretch and release to Po in frog muscle fibers

Selective activation of quadriceps muscle fibers according to bicycling rate

Relative decay rate of inspiratory muscle pressure and breath timing in man

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