Spatial distribution of cardiac transmembrane potentials around an extracellular electrode: dependence on fiber orientation.

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Spatial distribution of cardiac transmembrane potentials around an extracellular electrode: dependence on fiber orientation.

M Neunlist and L Tung

INSERM U381, Strasbourg, France.

ABSTRACT

Recent theoretical models of cardiac electrical stimulationor defibrillation predict a complex spatial pattern of transmembranepotential (Vm) around a stimulating electrode, resulting fromthe formation of virtual electrodes of reversed polarity. Thepattern of membrane polarization has been attributed to theanisotropic structure of the tissue. To verify such model predictionsexperimentally, an optical technique using a fluorescent voltage-sensitivedye was used to map the spatial distribution of Vm around a150-microns-radius extracellular unipolar electrode. An S1-S2stimulation protocol was used, and vm was measured during anS2 pulse having an intensity equal to 10x the cathodal diastolicthreshold of excitation. The recordings were obtained on theendocardial surface of bullfrog atrium in directions paralleland perpendicular to the cardiac fibers. In the longitudinalfiber direction, the membrane depolarized for cathodal pulses(and hyperpolarized for anodal pulses) but only in a regionwithin 445 +/- 112 microns (and 616 +/- 78 microns for anodalpulses) from the center of the electrode (n = 9). Outside thisregion, vm reversed polarity and reached a local maximum at922 +/- 136 microns (and 988 +/- 117 microns for anodal pulses)(n = 9). Beyond this point vm decayed to zero over a distanceof 1.5-2 mm. In the transverse fiber direction, the membranedepolarized for cathodal pulses (and hyperpolarized for anodalpulses) at all distances from the electrode. The amplitude ofthe response decreased with distance from the electrode withan exponential decay constant of 343 +/- 110 microns for cathodalpulses and 253 +/- 91 microns for anodal pulses (n = 7). Theresults were qualitatively similar in both fiber directionswhen the atrium was bathed in a solution containing ionic channelblockers. A two-dimensional computer model was formulated forthe case of highly anisotropic cardiac tissue and qualitativelyaccounts for nearly all the observed spatial and temporal behaviorof vm in the two fiber directions. The relationships betweenvm and both the "activating function" and extracellular potentialgradient are discussed.

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				F. G. Akar, B. J. Roth, and D. S. Rosenbaum Optical measurement of cell-to-cell coupling in intact heart using subthreshold electrical stimulation Am J Physiol Heart Circ Physiol, August 1, 2001; 281(2): H533 - H542. [Abstract] [Full Text] [PDF]

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