Title :
Modeling electric field transfer of excitation at cell junctions
Author :
Sperelakis, Nicholas ; Ramasamy, L.
Author_Institution :
Dept. of Molecular & Cellular Physiol., Univ. of Cincinnati Coll. of Medicine, OH, USA
Abstract :
The electric field (EF) model was first developed on a "breadboard" using physical electric components (e.g., resistors, capacitors, batteries) and was then modeled mathematically by a series of differential equations and matrix equations and simulated on a large computer (CDC-6400). The results obtained by the two methods agreed very closely. However, these two methods of analysis are quite cumbersome. Therefore, in order to simplify the EF simulation, we wanted to model it on the PSpice program. In this article we discuss how we succeeded in demonstrating transmission of excitation from cell to cell in cardiac muscle and smooth muscle based on EF transmission at the cell junctions.
Keywords :
SPICE; bioelectric potentials; biology computing; biomembrane transport; cardiology; muscle; physiological models; PSpice program; batteries; breadboard; capacitors; cardiac muscle; cell junction excitation; differential equations; electric field model; electric field transfer modeling; junctional membrane; matrix equations; physical electric components; resistors; smooth muscle based; surface membrane unit; Biomembranes; Capacitance; Circuits; Computational modeling; Corrugated surfaces; Differential equations; Mathematical model; Muscles; RNA; Resistors; Action Potentials; Cell Membrane; Computer Simulation; Electric Stimulation; Electromagnetic Fields; Gap Junctions; Heart; Membrane Potentials; Models, Neurological; Muscle, Smooth; Myocytes, Cardiac; Myocytes, Smooth Muscle; Nerve Net; Neural Conduction; Reproducibility of Results; Sensitivity and Specificity; Synaptic Transmission;
Journal_Title :
Engineering in Medicine and Biology Magazine, IEEE
DOI :
10.1109/MEMB.2002.1175149
