Simultaneous Quantification of Spatially Discordant Alternans in Voltage and Intracellular Calcium in Langendorff-Perfused Rabbit Hearts and Inconsistencies with Models of Cardiac Action Potentials and Ca Transients

Overview

Journal Front Physiol

Date 2017 Nov 7

PMID 29104543

Citations 29

Authors

Ilija Uzelac

Yanyan C Ji

Daniel Hornung

Johannes Schroder-Scheteling

Stefan Luther

Richard A Gray

Elizabeth M Cherry

Flavio H Fenton

Affiliations

Soon will be listed here.

Abstract

Discordant alternans, a phenomenon in which the action potential duration (APDs) and/or intracellular calcium transient durations (CaDs) in different spatial regions of cardiac tissue are out of phase, present a dynamical instability for complex spatial dispersion that can be associated with long-QT syndrome (LQTS) and the initiation of reentrant arrhythmias. Because the use of numerical simulations to investigate arrhythmic effects, such as acquired LQTS by drugs is beginning to be studied by the FDA, it is crucial to validate mathematical models that may be used during this process. In this study, we characterized with high spatio-temporal resolution the development of discordant alternans patterns in transmembrane voltage (V) and intracellular calcium concentration ([Ca]) as a function of pacing period in rabbit hearts. Then we compared the dynamics to that of the latest state-of-the-art model for ventricular action potentials and calcium transients to better understand the underlying mechanisms of discordant alternans and compared the experimental data to the mathematical models representing V and [Ca] dynamics. We performed simultaneous dual optical mapping imaging of V and [Ca] in Langendorff-perfused rabbit hearts with higher spatial resolutions compared with previous studies. The rabbit hearts developed discordant alternans through decreased pacing period protocols and we quantified the presence of multiple nodal points along the direction of wave propagation, both in APD and CaD, and compared these findings with results from theoretical models. In experiments, the nodal lines of CaD alternans have a steeper slope than those of APD alternans, but not as steep as predicted by numerical simulations in rabbit models. We further quantified several additional discrepancies between models and experiments. Alternans in CaD have nodal lines that are about an order of magnitude steeper compared to those of APD alternans. Current action potential models lack the necessary coupling between voltage and calcium compared to experiments and fail to reproduce some key dynamics such as, voltage amplitude alternans, smooth development of calcium alternans in time, conduction velocity and the steepness of the nodal lines of APD and CaD.

Citing Articles

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Horning M, Loppini A, Erhardt J, Fenton F, Filippi S, Gizzi A Conf Eur Study Group Cardiovasc Oscil. 2025; 2022.

PMID: 40070815 PMC: 11894612. DOI: 10.1109/esgco55423.2022.9931369.

Role of ephaptic coupling in discordant alternans domain sizes and action potential propagation in the heart.

Otani N, Figueroa E, Garrison J, Hewson M, Munoz L, Fenton F Phys Rev E. 2023; 107(5-1):054407.

PMID: 37329030 PMC: 10688036. DOI: 10.1103/PhysRevE.107.054407.

Ephaptic Coupling as a Resolution to the Paradox of Action Potential Wave Speed and Discordant Alternans Spatial Scales in the Heart.

Otani N, Figueroa E, Garrison J, Hewson M, Munoz L, Fenton F Phys Rev Lett. 2023; 130(21):218401.

PMID: 37295103 PMC: 10688031. DOI: 10.1103/PhysRevLett.130.218401.

Optical Ultrastructure of Large Mammalian Hearts Recovers Discordant Alternans by Data Assimilation.

Loppini A, Erhardt J, Fenton F, Filippi S, Horning M, Gizzi A Front Netw Physiol. 2023; 2:866101.

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Fiber Organization has Little Effect on Electrical Activation Patterns during Focal Arrhythmias in the Left Atrium.

He J, Pertsov A, Cherry E, Fenton F, Roney C, Niederer S ArXiv. 2023; .

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