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Mechanistically based mapping of human cardiac fibrillation

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Zeitschriftentitel: The Journal of Physiology
Personen und Körperschaften: Narayan, Sanjiv M., Zaman, Junaid A. B.
In: The Journal of Physiology, 594, 2016, 9, S. 2399-2415
Format: E-Article
Sprache: Englisch
veröffentlicht:
Wiley
Schlagwörter:
Physiology
author_facet Narayan, Sanjiv M.
Zaman, Junaid A. B.
Narayan, Sanjiv M.
Zaman, Junaid A. B.
author Narayan, Sanjiv M.
Zaman, Junaid A. B.
spellingShingle Narayan, Sanjiv M.
Zaman, Junaid A. B.
The Journal of Physiology
Mechanistically based mapping of human cardiac fibrillation
Physiology
author_sort narayan, sanjiv m.
spelling Narayan, Sanjiv M. Zaman, Junaid A. B. 0022-3751 1469-7793 Wiley Physiology http://dx.doi.org/10.1113/jp270513 <jats:title>Abstract</jats:title><jats:p>The mechanisms underpinning human cardiac fibrillation remain elusive. In his 1913 paper ‘On dynamic equilibrium in the heart’, Mines proposed that an activation wave front could propagate repeatedly in a circle, initiated by a stimulus in the vulnerable period. While the dynamics of activation and recovery are central to cardiac fibrillation, these physiological data are rarely used in clinical mapping. Fibrillation is a rapid irregular rhythm with spatiotemporal disorder resulting from two fundamental mechanisms – sources in preferred cardiac regions or spatially diffuse self‐sustaining activity, i.e. with no preferred source. On close inspection, however, this debate may also reflect mapping technique. Fibrillation is initiated from triggers by regional dispersion in repolarization, slow conduction and wavebreak, then sustained by non‐uniform interactions of these mechanisms. Notably, optical mapping of action potentials in atrial fibrillation (AF) show spiral wave sources (rotors) in nearly all studies including humans, while most traditional electrogram analyses of AF do not. Techniques may diverge in fibrillation because electrograms summate non‐coherent waves within an undefined field whereas optical maps define waves with a visually defined field. Also fibrillation operates at the limits of activation and recovery, which are well represented by action potentials while fibrillatory electrograms poorly represent repolarization. We conclude by suggesting areas for study that may be used, until such time as optical mapping is clinically feasible, to improve mechanistic understanding and therapy of human cardiac fibrillation. <jats:boxed-text content-type="graphic" position="anchor"><jats:graphic xmlns:xlink="http://www.w3.org/1999/xlink" mimetype="image/png" position="anchor" specific-use="enlarged-web-image" xlink:href="graphic/tjp6987-gra-0001-m.png"><jats:alt-text>image</jats:alt-text></jats:graphic></jats:boxed-text> </jats:p> Mechanistically based mapping of human cardiac fibrillation The Journal of Physiology
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title Mechanistically based mapping of human cardiac fibrillation
title_unstemmed Mechanistically based mapping of human cardiac fibrillation
title_full Mechanistically based mapping of human cardiac fibrillation
title_fullStr Mechanistically based mapping of human cardiac fibrillation
title_full_unstemmed Mechanistically based mapping of human cardiac fibrillation
title_short Mechanistically based mapping of human cardiac fibrillation
title_sort mechanistically based mapping of human cardiac fibrillation
topic Physiology
url http://dx.doi.org/10.1113/jp270513
publishDate 2016
physical 2399-2415
description <jats:title>Abstract</jats:title><jats:p>The mechanisms underpinning human cardiac fibrillation remain elusive. In his 1913 paper ‘On dynamic equilibrium in the heart’, Mines proposed that an activation wave front could propagate repeatedly in a circle, initiated by a stimulus in the vulnerable period. While the dynamics of activation and recovery are central to cardiac fibrillation, these physiological data are rarely used in clinical mapping. Fibrillation is a rapid irregular rhythm with spatiotemporal disorder resulting from two fundamental mechanisms – sources in preferred cardiac regions or spatially diffuse self‐sustaining activity, i.e. with no preferred source. On close inspection, however, this debate may also reflect mapping technique. Fibrillation is initiated from triggers by regional dispersion in repolarization, slow conduction and wavebreak, then sustained by non‐uniform interactions of these mechanisms. Notably, optical mapping of action potentials in atrial fibrillation (AF) show spiral wave sources (rotors) in nearly all studies including humans, while most traditional electrogram analyses of AF do not. Techniques may diverge in fibrillation because electrograms summate non‐coherent waves within an undefined field whereas optical maps define waves with a visually defined field. Also fibrillation operates at the limits of activation and recovery, which are well represented by action potentials while fibrillatory electrograms poorly represent repolarization. We conclude by suggesting areas for study that may be used, until such time as optical mapping is clinically feasible, to improve mechanistic understanding and therapy of human cardiac fibrillation. <jats:boxed-text content-type="graphic" position="anchor"><jats:graphic xmlns:xlink="http://www.w3.org/1999/xlink" mimetype="image/png" position="anchor" specific-use="enlarged-web-image" xlink:href="graphic/tjp6987-gra-0001-m.png"><jats:alt-text>image</jats:alt-text></jats:graphic></jats:boxed-text> </jats:p>
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author Narayan, Sanjiv M., Zaman, Junaid A. B.
author_facet Narayan, Sanjiv M., Zaman, Junaid A. B., Narayan, Sanjiv M., Zaman, Junaid A. B.
author_sort narayan, sanjiv m.
container_issue 9
container_start_page 2399
container_title The Journal of Physiology
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description <jats:title>Abstract</jats:title><jats:p>The mechanisms underpinning human cardiac fibrillation remain elusive. In his 1913 paper ‘On dynamic equilibrium in the heart’, Mines proposed that an activation wave front could propagate repeatedly in a circle, initiated by a stimulus in the vulnerable period. While the dynamics of activation and recovery are central to cardiac fibrillation, these physiological data are rarely used in clinical mapping. Fibrillation is a rapid irregular rhythm with spatiotemporal disorder resulting from two fundamental mechanisms – sources in preferred cardiac regions or spatially diffuse self‐sustaining activity, i.e. with no preferred source. On close inspection, however, this debate may also reflect mapping technique. Fibrillation is initiated from triggers by regional dispersion in repolarization, slow conduction and wavebreak, then sustained by non‐uniform interactions of these mechanisms. Notably, optical mapping of action potentials in atrial fibrillation (AF) show spiral wave sources (rotors) in nearly all studies including humans, while most traditional electrogram analyses of AF do not. Techniques may diverge in fibrillation because electrograms summate non‐coherent waves within an undefined field whereas optical maps define waves with a visually defined field. Also fibrillation operates at the limits of activation and recovery, which are well represented by action potentials while fibrillatory electrograms poorly represent repolarization. We conclude by suggesting areas for study that may be used, until such time as optical mapping is clinically feasible, to improve mechanistic understanding and therapy of human cardiac fibrillation. <jats:boxed-text content-type="graphic" position="anchor"><jats:graphic xmlns:xlink="http://www.w3.org/1999/xlink" mimetype="image/png" position="anchor" specific-use="enlarged-web-image" xlink:href="graphic/tjp6987-gra-0001-m.png"><jats:alt-text>image</jats:alt-text></jats:graphic></jats:boxed-text> </jats:p>
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spelling Narayan, Sanjiv M. Zaman, Junaid A. B. 0022-3751 1469-7793 Wiley Physiology http://dx.doi.org/10.1113/jp270513 <jats:title>Abstract</jats:title><jats:p>The mechanisms underpinning human cardiac fibrillation remain elusive. In his 1913 paper ‘On dynamic equilibrium in the heart’, Mines proposed that an activation wave front could propagate repeatedly in a circle, initiated by a stimulus in the vulnerable period. While the dynamics of activation and recovery are central to cardiac fibrillation, these physiological data are rarely used in clinical mapping. Fibrillation is a rapid irregular rhythm with spatiotemporal disorder resulting from two fundamental mechanisms – sources in preferred cardiac regions or spatially diffuse self‐sustaining activity, i.e. with no preferred source. On close inspection, however, this debate may also reflect mapping technique. Fibrillation is initiated from triggers by regional dispersion in repolarization, slow conduction and wavebreak, then sustained by non‐uniform interactions of these mechanisms. Notably, optical mapping of action potentials in atrial fibrillation (AF) show spiral wave sources (rotors) in nearly all studies including humans, while most traditional electrogram analyses of AF do not. Techniques may diverge in fibrillation because electrograms summate non‐coherent waves within an undefined field whereas optical maps define waves with a visually defined field. Also fibrillation operates at the limits of activation and recovery, which are well represented by action potentials while fibrillatory electrograms poorly represent repolarization. We conclude by suggesting areas for study that may be used, until such time as optical mapping is clinically feasible, to improve mechanistic understanding and therapy of human cardiac fibrillation. <jats:boxed-text content-type="graphic" position="anchor"><jats:graphic xmlns:xlink="http://www.w3.org/1999/xlink" mimetype="image/png" position="anchor" specific-use="enlarged-web-image" xlink:href="graphic/tjp6987-gra-0001-m.png"><jats:alt-text>image</jats:alt-text></jats:graphic></jats:boxed-text> </jats:p> Mechanistically based mapping of human cardiac fibrillation The Journal of Physiology
spellingShingle Narayan, Sanjiv M., Zaman, Junaid A. B., The Journal of Physiology, Mechanistically based mapping of human cardiac fibrillation, Physiology
title Mechanistically based mapping of human cardiac fibrillation
title_full Mechanistically based mapping of human cardiac fibrillation
title_fullStr Mechanistically based mapping of human cardiac fibrillation
title_full_unstemmed Mechanistically based mapping of human cardiac fibrillation
title_short Mechanistically based mapping of human cardiac fibrillation
title_sort mechanistically based mapping of human cardiac fibrillation
title_unstemmed Mechanistically based mapping of human cardiac fibrillation
topic Physiology
url http://dx.doi.org/10.1113/jp270513