Literature DB >> 18265985

Ephaptic coupling of cardiac cells through the junctional electric potential.

Elizabeth D Copene1, James P Keener.   

Abstract

Cardiac cells are electrically coupled through gap junction channels, which allow ionic current to spread intercellularly from one cell to the next. In addition, it is possible that cardiac cells are coupled through the electric potential in the junctional cleft space between neighboring cells. We develop and analyze a mathematical model of two cells coupled through a common junctional cleft potential. Consistent with more detailed models, we find that the coupling mechanism is highly parameter dependent. Analysis of our model reveals that there are two time scales involved, and the dynamics of the slow subsystem provide new mathematical insight into how the coupling mechanism works. We find that there are two distinct types of propagation failure and we are able to characterize parameter space into regions of propagation success and the two different types of propagation failure.

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Year:  2008        PMID: 18265985     DOI: 10.1007/s00285-008-0157-3

Source DB:  PubMed          Journal:  J Math Biol        ISSN: 0303-6812            Impact factor:   2.259


  18 in total

Review 1.  Electric field interactions between closely abutting excitable cells. .

Authors:  Nicholas Sperelakis; Keith McConnell
Journal:  IEEE Eng Med Biol Mag       Date:  2002 Jan-Feb

2.  Localization of sodium channels in intercalated disks modulates cardiac conduction.

Authors:  Jan P Kucera; Stephan Rohr; Yoram Rudy
Journal:  Circ Res       Date:  2002-12-13       Impact factor: 17.367

3.  Transition from a continuous to discontinuous understanding of cardiac conduction.

Authors:  Madison S Spach
Journal:  Circ Res       Date:  2003-02-07       Impact factor: 17.367

Review 4.  Structure of cardiac gap junction intercellular channels.

Authors:  M Yeager
Journal:  J Struct Biol       Date:  1998       Impact factor: 2.867

5.  Slow ventricular conduction in mice heterozygous for a connexin43 null mutation.

Authors:  P A Guerrero; R B Schuessler; L M Davis; E C Beyer; C M Johnson; K A Yamada; J E Saffitz
Journal:  J Clin Invest       Date:  1997-04-15       Impact factor: 14.808

6.  Disparate effects of deficient expression of connexin43 on atrial and ventricular conduction: evidence for chamber-specific molecular determinants of conduction.

Authors:  S A Thomas; R B Schuessler; C I Berul; M A Beardslee; E C Beyer; M E Mendelsohn; J E Saffitz
Journal:  Circulation       Date:  1998-02-24       Impact factor: 29.690

7.  Immunocytochemical localization of rH1 sodium channel in adult rat heart atria and ventricle. Presence in terminal intercalated disks.

Authors:  S A Cohen
Journal:  Circulation       Date:  1996-12-15       Impact factor: 29.690

8.  High resolution optical mapping reveals conduction slowing in connexin43 deficient mice.

Authors:  B C Eloff; D L Lerner; K A Yamada; R B Schuessler; J E Saffitz; D S Rosenbaum
Journal:  Cardiovasc Res       Date:  2001-09       Impact factor: 10.787

9.  Electrical propagation in synthetic ventricular myocyte strands from germline connexin43 knockout mice.

Authors:  Philippe Beauchamp; Cécile Choby; Thomas Desplantez; Karin de Peyer; Karen Green; Kathryn A Yamada; Robert Weingart; Jeffrey E Saffitz; André G Kléber
Journal:  Circ Res       Date:  2004-06-10       Impact factor: 17.367

10.  A dynamic model of the cardiac ventricular action potential. I. Simulations of ionic currents and concentration changes.

Authors:  C H Luo; Y Rudy
Journal:  Circ Res       Date:  1994-06       Impact factor: 17.367
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  16 in total

1.  Adaptive multiscale model for simulating cardiac conduction.

Authors:  Paul E Hand; Boyce E Griffith
Journal:  Proc Natl Acad Sci U S A       Date:  2010-07-29       Impact factor: 11.205

2.  Modeling electrical activity of myocardial cells incorporating the effects of ephaptic coupling.

Authors:  Joyce Lin; James P Keener
Journal:  Proc Natl Acad Sci U S A       Date:  2010-11-15       Impact factor: 11.205

3.  The Cardiac Gap Junction has Discrete Functions in Electrotonic and Ephaptic Coupling.

Authors:  Robert G Gourdie
Journal:  Anat Rec (Hoboken)       Date:  2018-12-18       Impact factor: 2.064

4.  Microdomain effects on transverse cardiac propagation.

Authors:  Joyce Lin; James P Keener
Journal:  Biophys J       Date:  2014-02-18       Impact factor: 4.033

5.  Does ephaptic coupling contribute to propagation in cardiac tissue?

Authors:  Bradley J Roth
Journal:  Biophys J       Date:  2014-02-18       Impact factor: 4.033

Review 6.  Mechanisms of cardiac conduction: a history of revisions.

Authors:  Rengasayee Veeraraghavan; Robert G Gourdie; Steven Poelzing
Journal:  Am J Physiol Heart Circ Physiol       Date:  2014-01-10       Impact factor: 4.733

Review 7.  Old cogs, new tricks: a scaffolding role for connexin43 and a junctional role for sodium channels?

Authors:  Rengasayee Veeraraghavan; Steven Poelzing; Robert G Gourdie
Journal:  FEBS Lett       Date:  2014-01-28       Impact factor: 4.124

8.  Electrophysiology.

Authors:  Boyce E Griffith; Charles S Peskin
Journal:  Commun Pure Appl Math       Date:  2013-10-09       Impact factor: 2.774

Review 9.  Intercellular electrical communication in the heart: a new, active role for the intercalated disk.

Authors:  Rengasayee Veeraraghavan; Steven Poelzing; Robert G Gourdie
Journal:  Cell Commun Adhes       Date:  2014-04-15

Review 10.  The role of the gap junction perinexus in cardiac conduction: Potential as a novel anti-arrhythmic drug target.

Authors:  Daniel T Hoagland; Webster Santos; Steven Poelzing; Robert G Gourdie
Journal:  Prog Biophys Mol Biol       Date:  2018-09-19       Impact factor: 4.799
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