Publication: The effect of fiber orientation on volume measurement using conductance catheter techniques
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0
Issued Date
2006
Resource Type
File Type
application/pdf
ISSN
5891019
Other identifier(s)
2-s2.0-34047134973
Rights Holder(s)
มหาวิทยาลัยศรีนครินทรวิโรฒ
Bibliographic Citation
Annual International Conference of the IEEE Engineering in Medicine and Biology - Proceedings. (2006), p.5981-5984
Suggested Citation
Thaijiam C., Gale T.J. The effect of fiber orientation on volume measurement using conductance catheter techniques. Annual International Conference of the IEEE Engineering in Medicine and Biology - Proceedings. (2006), p.5981-5984. doi:10.1109/IEMBS.2006.260422 Retrieved from: https://hdl.handle.net/20.500.14740/5236
Author(s)
Abstract
Estimation of parallel conductance using the impedance electrode technique is usually done assuming isotropic conditions. This may not be the best solution since the myocardium is an anisotropic material. This paper exposes the effect of fiber orientation for volume measurement using a conductor model with asymmetrical source electrodes. Simulation results show calculated volumes between surrounding materials with and without myocardial fiber orientation included in the model. We plan to extend these study results to the real heart for developing conductance catheter techniques for use in blood volume measurements in the right ventricle. © 2006 IEEE.
Subject(s)
Anisotropy
Computer simulation
Electrodes
Mathematical models
Volume measurement
Anisotropic materials
Catheter techniques
Myocardium
Parallel conductance
Fiber reinforced materials
Animal
Anisotropy
Article
Biological model
Computer simulation
Dog
Electric conductivity
Electrode
Equipment
Equipment design
Heart muscle
Heart ventricle
Human
Impedance
Impedance cardiography
Methodology
Pathology
Theoretical model
Animals
Anisotropy
Cardiography, Impedance
Computer Simulation
Dogs
Electric Conductivity
Electric Impedance
Electrodes
Equipment Design
Heart Ventricles
Humans
Models, Cardiovascular
Models, Theoretical
Myocardium
Computer simulation
Electrodes
Mathematical models
Volume measurement
Anisotropic materials
Catheter techniques
Myocardium
Parallel conductance
Fiber reinforced materials
Animal
Anisotropy
Article
Biological model
Computer simulation
Dog
Electric conductivity
Electrode
Equipment
Equipment design
Heart muscle
Heart ventricle
Human
Impedance
Impedance cardiography
Methodology
Pathology
Theoretical model
Animals
Anisotropy
Cardiography, Impedance
Computer Simulation
Dogs
Electric Conductivity
Electric Impedance
Electrodes
Equipment Design
Heart Ventricles
Humans
Models, Cardiovascular
Models, Theoretical
Myocardium
