Self-restoration of cardiac excitation rhythm by anti-arrhythmic ion channel gating

Rupamanjari Majumder; Tim de Coster; Nina Kudryashova; Arie O. Verkerk; Ivan V. Kazbanov; Balázs Ördög; Niels Harlaar; Ronald Wilders; Antoine Af de Vries; Dirk L. Ypey; Alexander V. Panfilov; Daniël A. Pijnappels

doi:https://doi.org/10.7554/eLife.55921

Self-restoration of cardiac excitation rhythm by anti-arrhythmic ion channel gating

Rupamanjari Majumder, Tim de Coster, Nina Kudryashova, Arie O. Verkerk, Ivan V. Kazbanov, Balázs Ördög, Niels Harlaar, Ronald Wilders, Antoine Af de Vries, Dirk L. Ypey, Alexander V. Panfilov, Daniël A. Pijnappels

Research output: Contribution to journal › Article › Academic › peer-review

12 Citations (Scopus)

Abstract

Homeostatic regulation protects organisms against hazardous physiological changes. However, such regulation is limited in certain organs and associated biological processes. For example, the heart fails to self-restore its normal electrical activity once disturbed, as with sustained arrhythmias. Here we present proof-of-concept of a biological self-restoring system that allows automatic detection and correction of such abnormal excitation rhythms. For the heart, its realization involves the integration of ion channels with newly designed gating properties into cardiomyocytes. This allows cardiac tissue to i) discriminate between normal rhythm and arrhythmia based on frequency-dependent gating and ii) generate an ionic current for termination of the detected arrhythmia. We show in silico, that for both human atrial and ventricular arrhythmias, activation of these channels leads to rapid and repeated restoration of normal excitation rhythm. Experimental validation is provided by injecting the designed channel current for arrhythmia termination in human atrial myocytes using dynamic clamp.

Original language	English
Article number	e55921
Pages (from-to)	1-23
Number of pages	23
Journal	eLife
Volume	9
DOIs	https://doi.org/10.7554/eLife.55921
Publication status	Published - 8 Jun 2020

Keywords

computational biology
computer modelling
defibrillation
dynamic patch clamp
gating properties
human
ion channels
physics of living systems
rhythm disturbances
systems biology

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https://doi.org/10.7554/eLife.55921

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title = "Self-restoration of cardiac excitation rhythm by anti-arrhythmic ion channel gating",

abstract = "Homeostatic regulation protects organisms against hazardous physiological changes. However, such regulation is limited in certain organs and associated biological processes. For example, the heart fails to self-restore its normal electrical activity once disturbed, as with sustained arrhythmias. Here we present proof-of-concept of a biological self-restoring system that allows automatic detection and correction of such abnormal excitation rhythms. For the heart, its realization involves the integration of ion channels with newly designed gating properties into cardiomyocytes. This allows cardiac tissue to i) discriminate between normal rhythm and arrhythmia based on frequency-dependent gating and ii) generate an ionic current for termination of the detected arrhythmia. We show in silico, that for both human atrial and ventricular arrhythmias, activation of these channels leads to rapid and repeated restoration of normal excitation rhythm. Experimental validation is provided by injecting the designed channel current for arrhythmia termination in human atrial myocytes using dynamic clamp.",

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doi = "https://doi.org/10.7554/eLife.55921",

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AU - Majumder, Rupamanjari

AU - de Coster, Tim

AU - Kudryashova, Nina

AU - Verkerk, Arie O.

AU - Kazbanov, Ivan V.

AU - Ördög, Balázs

AU - Harlaar, Niels

AU - Wilders, Ronald

AU - de Vries, Antoine Af

AU - Ypey, Dirk L.

AU - Panfilov, Alexander V.

AU - Pijnappels, Daniël A.

PY - 2020/6/8

Y1 - 2020/6/8

N2 - Homeostatic regulation protects organisms against hazardous physiological changes. However, such regulation is limited in certain organs and associated biological processes. For example, the heart fails to self-restore its normal electrical activity once disturbed, as with sustained arrhythmias. Here we present proof-of-concept of a biological self-restoring system that allows automatic detection and correction of such abnormal excitation rhythms. For the heart, its realization involves the integration of ion channels with newly designed gating properties into cardiomyocytes. This allows cardiac tissue to i) discriminate between normal rhythm and arrhythmia based on frequency-dependent gating and ii) generate an ionic current for termination of the detected arrhythmia. We show in silico, that for both human atrial and ventricular arrhythmias, activation of these channels leads to rapid and repeated restoration of normal excitation rhythm. Experimental validation is provided by injecting the designed channel current for arrhythmia termination in human atrial myocytes using dynamic clamp.

AB - Homeostatic regulation protects organisms against hazardous physiological changes. However, such regulation is limited in certain organs and associated biological processes. For example, the heart fails to self-restore its normal electrical activity once disturbed, as with sustained arrhythmias. Here we present proof-of-concept of a biological self-restoring system that allows automatic detection and correction of such abnormal excitation rhythms. For the heart, its realization involves the integration of ion channels with newly designed gating properties into cardiomyocytes. This allows cardiac tissue to i) discriminate between normal rhythm and arrhythmia based on frequency-dependent gating and ii) generate an ionic current for termination of the detected arrhythmia. We show in silico, that for both human atrial and ventricular arrhythmias, activation of these channels leads to rapid and repeated restoration of normal excitation rhythm. Experimental validation is provided by injecting the designed channel current for arrhythmia termination in human atrial myocytes using dynamic clamp.

KW - computational biology

KW - computer modelling

KW - defibrillation

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KW - gating properties

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KW - rhythm disturbances

KW - systems biology

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JO - eLife

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ER -

Self-restoration of cardiac excitation rhythm by anti-arrhythmic ion channel gating

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Keywords

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