An Electrical Field Numerical Simulation of Implantable Pacing Electrodes

Cristina Savastru; Alexandru M. Morega

doi:10.4028/www.scientific.net/KEM.583.119

Paper Titles

Biopolymer Blends as Potential Biomaterials and Cosmetic Materials
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Alternative Approaches Using Animal Model for Implant Biomaterials: Advantages and Disadvantages
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Specific Biomaterials Used within the Department of Anatomy
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Computing Simulation of the Influence of Plate Design, Material, and Screw Positioning on Biomechanical Behavior of Ulna Bone Plates
p.115

An Electrical Field Numerical Simulation of Implantable Pacing Electrodes
p.119

Comparison of Plantar Arch Index Calculated from Ink and Electronic Footprints
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Energy Dispersive Techniques Using X-Ray Fluorescence with Primary X-Rays for Human Hard Tissues Analysis
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Investigation of a Mechanical Valve Impairment after Eight Years of Implantation
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Development of Modified Viscoelastic Solution with Magnetic Nanoparticles – Potential Method for Targeted Treatment of Chondral Injuries
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An Electrical Field Numerical Simulation of Implantable Pacing Electrodes

Abstract:

The heart functions normally when the impulses are produced at a rate of 80 bpm. When less than 60 bpm are triggered, pacemakers may be necessary to sustain the electrical activity of the heart. Pacemaker systems used in cardiac resynchronization therapy are made of an implantable pulse generator, leads, and unipolar or bipolar electrodes. They are aimed to simulate the cardiac depolarization, to sense intrinsic cardiac functions, to provide information stored by the system for deeper diagnosis. This paper presents a mathematical model and numerical simulation results on the ionic current distributed by the electrodes, in the absence of concentration gradients, in the cardiac tissue. The external electrical resistance variation with the anode to cathode spacing obtained by this approach may be used in the design phase of the device.