Title :
Mechanism for muscle force deactivation during quick length changes
Author :
Palladino, J.L. ; Noordergraaf, A.
Author_Institution :
Dept. of Eng. & Comput. Sci., Trinity Coll., Hartford, CT, USA
Abstract :
Muscle exhibits complex viscoelastic properties. Neither lumped muscle models nor ultrastructural crossbridge models have been successful in satisfactorily describing these properties, or in proposing a mechanism for their origin. A recently developed large-scale distributed model of a single muscle fiber based on myofilament kinetics is shown capable of describing all four stages of force deactivation following a quick change in muscle length during isometric contraction. In essence, this model implicates muscle´s viscoelastic bonds and distributed mechanical properties as the origin of its complex dynamic behavior
Keywords :
biomechanics; muscle; physiological models; complex viscoelastic properties; distributed mechanical properties; force deactivation stages; large-scale distributed model; lumped muscle models; muscle force deactivation mechanism; myofilament kinetics; quick length changes; single muscle fiber; ultrastructural crossbridge models; viscoelastic bonds; Computer science; Creep; Elasticity; Kinetic theory; Large-scale systems; Mechanical factors; Muscles; Stress; Vibrations; Viscosity;
Conference_Titel :
Bioengineering Conference, 1994., Proceedings of the 1994 20th Annual Northeast
Conference_Location :
Springfield, MA
Print_ISBN :
0-7803-1930-3
DOI :
10.1109/NEBC.1994.305163
