Title :
Understanding crossbridge dynamics from a modeling perspective
Author_Institution :
Dept. of Anatomy, British Columbia Univ., Vancouver, BC, Canada
Abstract :
A new computer modeling system for determining crossbridge cycle dynamics is described. The transition rates from one state to another are defined by rate coefficients that can either be constant or vary with the position of the crossbridge relative to the thin-filament attachment site. This leads to a system of differential equations defining the rates of change for the fractions of bridges in each state. Solutions for this system of equations are obtained at specified times during and after a length change using a method for systems with widely varying time constants (C.W. Gear, 1971, Numerical Initial Value Problems in Ordinary Differential Equations, Prentice-Hall, Englewood Cliffs. NJ). Crossbridges are divided into discrete populations that differ both in their axial displacement with respect to thin filament attachment sites and with respect to the twist of the actin helix. Separate solutions are made for the individual populations and are then averaged to obtain the ensemble response
Keywords :
biology computing; biomechanics; differential equations; molecular biophysics; muscle; physiological models; proteins; actin helix twist; axial displacement; computer modeling; crossbridge cycle dynamics; crossbridge dynamics; differential equations; discrete populations; ensemble response; individual populations; muscle contraction; myosin; rate coefficients; thin filament attachment sites; thin-filament attachment site; time constants; transition rates; Anatomy; Bridges; Chemicals; Differential equations; Gears; Muscles; Power system modeling; Predictive models;
Conference_Titel :
Engineering in Medicine and Biology Society, 1995., IEEE 17th Annual Conference
Conference_Location :
Montreal, Que.
Print_ISBN :
0-7803-2475-7
DOI :
10.1109/IEMBS.1995.575013
