Excitable systems display memory, but how memory affects the excitation dynamics of such systems remains to be elucidated. Here we use computer simulation of cardiac action potential models to demonstrate that memory can cause dynamical instabilities that result in complex excitation dynamics and chaos. We develop an iterated map model that correctly describes these dynamics and show that memory converts a monotonic first return map of action potential duration into a nonmonotonic one, resulting in a period-doubling bifurcation route to chaos
AbstractThe degeneration of a regular heart rhythm into fibrillation (a chaotic or chaos-like sequen...
The spatiotemporal dynamics of excitable media may exhibit chaotic transients. We investigate this t...
Biological excitable media, such as cardiac or neural cells and tissue, exhibit memory in which a ch...
International audienceThe aim of this work is the analysis of the nonlinear dynamics of two-dimensio...
Dynamical instabilities in the heart promote arrhythmias and sudden cardiac death (SCD), one of the ...
A series of related new models for the local dynamics of cardiac tissue is introduced. The models ar...
Arrhythmias are potentially fatal disruptions to the normal heart rhythm, but their underlying dynam...
Cardiac myocytes are excitable cells in which an external current stimulus depolarizes the membr...
Instabilities in cardiac dynamics have been widely investigated in recent years. One facet of this w...
Self-organized activation patterns in excitable media such as spiral waves and spatio-temporal chaos...
Heart rhythm disorders represent a significant global health concern, affecting millions of people w...
Cardiac muscle cells can exhibit complex patterns including irregular behaviour such as chaos or (ch...
Toad ventricles were externally driven by periodic pulses while monophasic action potential (MAP) si...
AbstractIrregularly occurring early afterdepolarizations (EADs) in cardiac myocytes are traditionall...
ABSTRACT The degeneration of a regular heart rhythm into fibrillation (a chaotic or chaos-like seque...
AbstractThe degeneration of a regular heart rhythm into fibrillation (a chaotic or chaos-like sequen...
The spatiotemporal dynamics of excitable media may exhibit chaotic transients. We investigate this t...
Biological excitable media, such as cardiac or neural cells and tissue, exhibit memory in which a ch...
International audienceThe aim of this work is the analysis of the nonlinear dynamics of two-dimensio...
Dynamical instabilities in the heart promote arrhythmias and sudden cardiac death (SCD), one of the ...
A series of related new models for the local dynamics of cardiac tissue is introduced. The models ar...
Arrhythmias are potentially fatal disruptions to the normal heart rhythm, but their underlying dynam...
Cardiac myocytes are excitable cells in which an external current stimulus depolarizes the membr...
Instabilities in cardiac dynamics have been widely investigated in recent years. One facet of this w...
Self-organized activation patterns in excitable media such as spiral waves and spatio-temporal chaos...
Heart rhythm disorders represent a significant global health concern, affecting millions of people w...
Cardiac muscle cells can exhibit complex patterns including irregular behaviour such as chaos or (ch...
Toad ventricles were externally driven by periodic pulses while monophasic action potential (MAP) si...
AbstractIrregularly occurring early afterdepolarizations (EADs) in cardiac myocytes are traditionall...
ABSTRACT The degeneration of a regular heart rhythm into fibrillation (a chaotic or chaos-like seque...
AbstractThe degeneration of a regular heart rhythm into fibrillation (a chaotic or chaos-like sequen...
The spatiotemporal dynamics of excitable media may exhibit chaotic transients. We investigate this t...
Biological excitable media, such as cardiac or neural cells and tissue, exhibit memory in which a ch...