Cardiac ion channels

Dan M. Roden; Jeffrey R. Balser; Alfred L. George; Mark E. Anderson

doi:10.1146/annurev.physiol.64.083101.145105

Cardiac ion channels

Dan M. Roden, Jeffrey R. Balser, Alfred L. George, Mark E. Anderson

Research output: Contribution to journal › Review article › peer-review

221 Scopus citations

Abstract

The normal electrophysiologic behavior of the heart is determined by ordered propagation of excitatory stimuli that result in rapid depolarization and slow repolarization, thereby generating action potentials in individual myocytes. Abnormalities of impulse generation, propagation, or the duration and configuration of individual cardiac action potentials form the basis of disorders of cardiac rhythm, a continuing major public health problem for which available drugs are incompletetly effective and often dangerous. The integrated activity of specific ionic currents generates action potentials, and the genes whose expression results in the molecular components underlying individual ion currents in heart have been cloned. This review discusses these new tools and how their application to the problem of arrhythmias is generating new mechanistic insights to identify patients at risk for this condition and developing improved antiarrhythmic therapies.

Original language	English (US)
Pages (from-to)	431-475
Number of pages	45
Journal	Annual review of physiology
Volume	64
DOIs	https://doi.org/10.1146/annurev.physiol.64.083101.145105
State	Published - 2002
Externally published	Yes

Keywords

Arrhythmias
Heart
Ion channel function
Ion channel structure

ASJC Scopus subject areas

Physiology

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10.1146/annurev.physiol.64.083101.145105

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title = "Cardiac ion channels",

abstract = "The normal electrophysiologic behavior of the heart is determined by ordered propagation of excitatory stimuli that result in rapid depolarization and slow repolarization, thereby generating action potentials in individual myocytes. Abnormalities of impulse generation, propagation, or the duration and configuration of individual cardiac action potentials form the basis of disorders of cardiac rhythm, a continuing major public health problem for which available drugs are incompletetly effective and often dangerous. The integrated activity of specific ionic currents generates action potentials, and the genes whose expression results in the molecular components underlying individual ion currents in heart have been cloned. This review discusses these new tools and how their application to the problem of arrhythmias is generating new mechanistic insights to identify patients at risk for this condition and developing improved antiarrhythmic therapies.",

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T1 - Cardiac ion channels

AU - Roden, Dan M.

AU - Balser, Jeffrey R.

AU - George, Alfred L.

AU - Anderson, Mark E.

PY - 2002

Y1 - 2002

N2 - The normal electrophysiologic behavior of the heart is determined by ordered propagation of excitatory stimuli that result in rapid depolarization and slow repolarization, thereby generating action potentials in individual myocytes. Abnormalities of impulse generation, propagation, or the duration and configuration of individual cardiac action potentials form the basis of disorders of cardiac rhythm, a continuing major public health problem for which available drugs are incompletetly effective and often dangerous. The integrated activity of specific ionic currents generates action potentials, and the genes whose expression results in the molecular components underlying individual ion currents in heart have been cloned. This review discusses these new tools and how their application to the problem of arrhythmias is generating new mechanistic insights to identify patients at risk for this condition and developing improved antiarrhythmic therapies.

AB - The normal electrophysiologic behavior of the heart is determined by ordered propagation of excitatory stimuli that result in rapid depolarization and slow repolarization, thereby generating action potentials in individual myocytes. Abnormalities of impulse generation, propagation, or the duration and configuration of individual cardiac action potentials form the basis of disorders of cardiac rhythm, a continuing major public health problem for which available drugs are incompletetly effective and often dangerous. The integrated activity of specific ionic currents generates action potentials, and the genes whose expression results in the molecular components underlying individual ion currents in heart have been cloned. This review discusses these new tools and how their application to the problem of arrhythmias is generating new mechanistic insights to identify patients at risk for this condition and developing improved antiarrhythmic therapies.

KW - Arrhythmias

KW - Heart

KW - Ion channel function

KW - Ion channel structure

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JO - Annual review of physiology

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Cardiac ion channels

Abstract

Keywords

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