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R Plonsey

Showing results (51-60 of 84) with videos related to

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Medical & Biological Engineering & Computing|March 1, 1986
Effect of microscopic and macroscopic discontinuities on the response of cardiac tissue to defibrillating (stimulating) currentsR Plonsey, R C Barr
Medical & Biological Engineering & Computing|March 1, 1986
Inclusion of junction elements in a linear cardiac model through secondary sources: application to defibrillationR Plonsey, R C Barr
IEEE Transactions on Bio-Medical Engineering|September 1, 1990
Simulation of propagation along a cylindrical bundle of cardiac tissue--I: Mathematical formulationC S Henriquez, R Plonsey
Journal of Electrocardiology|January 1, 1975
A cellular model for the simulation of activation in the ventricular myocardiumW J Eifler, R Plonsey
Biophysical Journal|May 1, 1992
Electrophysiological interaction through the interstitial space between adjacent unmyelinated parallel fibersR C Barr, R Plonsey
IEEE Transactions on Bio-Medical Engineering|April 1, 1995
Electric field stimulation of excitable tissueR Plonsey, R C Barr
Journal of Electrocardiology|July 1, 1987
Mathematical modeling of electrical activity of the heartR Plonsey, R C Barr
Biophysical Journal|October 1, 1970
A mathematical study of nerve fiber interactionJ W Clark, R Plonsey
Medical & Biological Engineering & Computing|November 1, 1990
Analysis of excitable cell activation: relative effects of external electrical stimuliK W Altman, R Plonsey
Circulation Research|January 1, 1979
The effects of variations in conductivity and geometrical parameters on the electrocardiogram, using an eccentric spheres modelY Rudy, R Plonsey, J Liebman
Pageof 9

Showing results (51-60 of 84) with videos related to

Sort By:
Pageof 9
Medical & Biological Engineering & Computing|March 1, 1986
Effect of microscopic and macroscopic discontinuities on the response of cardiac tissue to defibrillating (stimulating) currentsR Plonsey, R C Barr
Medical & Biological Engineering & Computing|March 1, 1986
Inclusion of junction elements in a linear cardiac model through secondary sources: application to defibrillationR Plonsey, R C Barr
IEEE Transactions on Bio-Medical Engineering|September 1, 1990
Simulation of propagation along a cylindrical bundle of cardiac tissue--I: Mathematical formulationC S Henriquez, R Plonsey
Journal of Electrocardiology|January 1, 1975
A cellular model for the simulation of activation in the ventricular myocardiumW J Eifler, R Plonsey
Biophysical Journal|May 1, 1992
Electrophysiological interaction through the interstitial space between adjacent unmyelinated parallel fibersR C Barr, R Plonsey
IEEE Transactions on Bio-Medical Engineering|April 1, 1995
Electric field stimulation of excitable tissueR Plonsey, R C Barr
Journal of Electrocardiology|July 1, 1987
Mathematical modeling of electrical activity of the heartR Plonsey, R C Barr
Biophysical Journal|October 1, 1970
A mathematical study of nerve fiber interactionJ W Clark, R Plonsey
Medical & Biological Engineering & Computing|November 1, 1990
Analysis of excitable cell activation: relative effects of external electrical stimuliK W Altman, R Plonsey
Circulation Research|January 1, 1979
The effects of variations in conductivity and geometrical parameters on the electrocardiogram, using an eccentric spheres modelY Rudy, R Plonsey, J Liebman
Pageof 9