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

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

doi:10.7554/elife.55921

Cited by 15 publications

(9 citation statements)

References 64 publications

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“…For all five meshes, we replicated the sinus rhythm by simultaneously stimulating the endocardium of the LV [ 27 ]. These measurements were utilized to test our algorithm.…”

Section: Methodsmentioning

confidence: 99%

Computer based method for identification of fibrotic scars from electrograms and local activation times on the epi- and endocardial surfaces of the ventricles

Okenov,

Nezlobinsky,

Zeppenfeld

et al. 2024

PLoS ONE

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Cardiac fibrosis stands as one of the most critical conditions leading to lethal cardiac arrhythmias. Identifying the precise location of cardiac fibrosis is crucial for planning clinical interventions in patients with various forms of ventricular and atrial arrhythmias. As fibrosis impedes and alters the path of electrical waves, detecting fibrosis in the heart can be achieved through analyzing electrical signals recorded from its surface. In current clinical practices, it has become feasible to record electrical activity from both the endocardial and epicardial surfaces of the heart. This paper presents a computational method for reconstructing 3D fibrosis using unipolar electrograms obtained from both surfaces of the ventricles. The proposed method calculates the percentage of fibrosis in various ventricular segments by analyzing the local activation times and peak-to-peak amplitudes of the electrograms. Initially, the method was tested using simulated data representing idealized fibrosis in a heart segment; subsequently, it was validated in the left ventricle with fibrosis obtained from a patient with nonischemic cardiomyopathy. The method successfully determined the location and extent of fibrosis in 204 segments of the left ventricle model with an average error of 0.0±4.3% (N = 204). Moreover, the method effectively detected fibrotic scars in the mid-myocardial region, a region known to present challenges in accurate detection using electrogram amplitude as the primary criterion.

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“…For all five meshes, we replicated the sinus rhythm by simultaneously stimulating the endocardium of the LV [ 27 ]. These measurements were utilized to test our algorithm.…”

Section: Methodsmentioning

confidence: 99%

Computer based method for identification of fibrotic scars from electrograms and local activation times on the epi- and endocardial surfaces of the ventricles

Okenov,

Nezlobinsky,

Zeppenfeld

et al. 2024

PLoS ONE

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“…A recent paper utilizing computational simulation pointed out that GtACR1 may be used to defibrillate human hearts (Ochs et al, 2021). Majumder et al (2020) developed a theoretical ion channel called the Biologically Integrated Cardiac Defibrillator (BioICD), whose activation can lead to a rapid and repeated restoration of normal rhythm for arrhythmia in the human atrium and ventricle (Majumder et al, 2020). It is believed that this theoretical simulation may soon be developed.…”

Section: Cardiac Optogeneticsmentioning

confidence: 99%

Applications and challenges of rhodopsin-based optogenetics in biomedicine

et al. 2022

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Optogenetics is an emerging bioengineering technology that has been rapidly developed in recent years by cross-integrating optics, genetic engineering, electrophysiology, software control, and other disciplines. Since the first demonstration of the millisecond neuromodulation ability of the channelrhodopsin-2 (ChR2), the application of optogenetic technology in basic life science research has been rapidly progressed, especially in neurobiology, which has driven the development of the discipline. As the optogenetic tool protein, microbial rhodopsins have been continuously explored, modified, and optimized, with many variants becoming available, with structural characteristics and functions that are highly diversified. Their applicability has been broadened, encouraging more researchers and clinicians to utilize optogenetics technology in research. In this review, we summarize the species and variant types of the most important class of tool proteins in optogenetic techniques, the microbial rhodopsins, and review the current applications of optogenetics based on rhodopsin qualitative light in biology and other fields. We also review the challenges facing this technology, to ultimately provide an in-depth technical reference to support the application of optogenetics in translational and clinical research.

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“…Given that the heart itself is a source of electricity, De Coster is interested in intrinsic strategies that can reset cardiac rhythmicity. To achieve this, the group has taken advantage of the fact that most ion channels in the heart are voltage gated, that is, they open and close to allow the flow of ions across the cell membrane in response to the transmembrane voltage 81 …”

Section: Engineering An Arrythmia‐gated Ion Channelmentioning

confidence: 99%

“…Upon activation, opening of the channel prolongs the action potential and restores a normal cardiac rhythm. Introducing a nonlinearity into the closing rate allows the channel to close rapidly once the rhythm has been reset 81 …”

Section: Engineering An Arrythmia‐gated Ion Channelmentioning

confidence: 99%

Synthetic biology: at the crossroads of genetic engineering and human therapeutics—a Keystone Symposia report

Cable¹,

Leonard

et al. 2021

Annals of the New York Academy of Sciences

Self Cite

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Synthetic biology has the potential to transform cell‐ and gene‐based therapies for a variety of diseases. Sophisticated tools are now available for both eukaryotic and prokaryotic cells to engineer cells to selectively achieve therapeutic effects in response to one or more disease‐related signals, thus sparing healthy tissue from potentially cytotoxic effects. This report summarizes the Keystone eSymposium “Synthetic Biology: At the Crossroads of Genetic Engineering and Human Therapeutics,” which took place on May 3 and 4, 2021. Given that several therapies engineered using synthetic biology have entered clinical trials, there was a clear need for a synthetic biology symposium that emphasizes the therapeutic applications of synthetic biology as opposed to the technical aspects. Presenters discussed the use of synthetic biology to improve T cell, gene, and viral therapies, to engineer probiotics, and to expand upon existing modalities and functions of cell‐based therapies.

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

Cited by 15 publications

References 64 publications

Computer based method for identification of fibrotic scars from electrograms and local activation times on the epi- and endocardial surfaces of the ventricles

Computer based method for identification of fibrotic scars from electrograms and local activation times on the epi- and endocardial surfaces of the ventricles

Applications and challenges of rhodopsin-based optogenetics in biomedicine

Synthetic biology: at the crossroads of genetic engineering and human therapeutics—a Keystone Symposia report

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