Mechanical Properties of the Sarcolemma and Myoplasm in Frog Muscle as a Function of Sarcomere Length

doi:10.1085/jgp.59.5.559

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Mechanical Properties of the Sarcolemma and Myoplasm in Frog Muscle as a Function of Sarcomere Length

Stanley I. Rapoport ¹

¹ From the Laboratory of Neurophysiology, National Institute of Mental Health, Bethesda, Maryland 20014

The elastimeter method was applied to the single muscle fiberof the frog semitendinosus to obtain the elastic moduli of thesarcolemma and myoplasm, as well as their relative contributionsto resting fiber tension at different extensions. A bleb whichwas sucked into a flat-mouthed pipette at the fiber surfaceseparated into an external sarcolemmal membrane and a thickinner myoplasmic region. Measurements showed that the sarcolemmadoes not contribute to intact fiber tension at sarcomere lengthsbelow 3 µ. It was estimated that the sarcolemma contributedon the order of 10% to intact fiber tension at sarcomere lengthsbetween 3 and 3.75 µ, and more so with further extension.Between these sarcomere lengths, the sarcolemma can be linearlyextended and has a longitudinal elastic modulus of 5 x 10⁶ dyne/cm²(assuming a thickness of 0.1 µ). Resistance to deformationof the inner bleb region is due to myoplasmic elasticity. Themyoplasmic elastic modulus was estimated by use of a model andwas used to predict a fiber length-tension curve which agreedapproximately with observations.

Submitted on August 30, 1971

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