Your search keyword '"Y. Efimov"' showing total 7 results

1. Opsin spectral sensitivity determines the effectiveness of optogenetic termination of ventricular fibrillation in the human heart: a simulation study.

Author

Karathanos, Thomas V., Bayer, Jason D., Wang, Dafang, Boyle, Patrick M., and Trayanova, Natalia A.

Subjects

OPSINS, SPECTRAL sensitivity, OPTOGENETICS, VENTRICULAR fibrillation, HEART physiology

Abstract

Key points Optogenetics-based defibrillation, a theoretical alternative to electrotherapy, involves expression of light-sensitive ion channels in the heart (via gene or cell therapy) and illumination of the cardiac surfaces (via implanted LED arrays) to elicit light-induced activations., We used a biophysically detailed human ventricular model to determine whether such a therapy could terminate fibrillation (VF) and identify which combinations of light-sensitive ion channel properties and illumination configurations would be effective., Defibrillation was successful when a large proportion (> 16.6%) of ventricular tissue was directly stimulated by light that was bright enough to induce an action potential in an uncoupled cell., While illumination with blue light never successfully terminated VF, illumination of red light-sensitive ion channels with dense arrays of implanted red light sources resulted in successful defibrillation., Our results suggest that cardiac expression of red light-sensitive ion channels is necessary for the development of effective optogenetics-based defibrillation therapy using LED arrays., Abstract Optogenetics-based defibrillation has been proposed as a novel and potentially pain-free approach to enable cardiomyocyte-selective defibrillation in humans, but the feasibility of such a therapy remains unknown. This study aimed to (1) assess the feasibility of terminating sustained ventricular fibrillation (VF) via light-induced excitation of opsins expressed throughout the myocardium and (2) identify the ideal (theoretically possible) opsin properties and light source configurations that would maximise therapeutic efficacy. We conducted electrophysiological simulations in an MRI-based human ventricular model with VF induced by rapid pacing; light sensitisation via systemic, cardiac-specific gene transfer of channelrhodopsin-2 (ChR2) was simulated. In addition to the widely used blue light-sensitive ChR2-H134R, we also modelled theoretical ChR2 variants with augmented light sensitivity (ChR2+), red-shifted spectral sensitivity (ChR2-RED) or both (ChR2-RED+). Light sources were modelled as synchronously activating LED arrays (LED radius: 1 mm; optical power: 10 mW mm-2; array density: 1.15-4.61 cm-2). For each unique optogenetic configuration, defibrillation was attempted with two different optical pulse durations (25 and 500 ms). VF termination was only successful for configurations involving ChR2-RED and ChR2-RED+ (for LED arrays with density ≥ 2.30 cm-2), suggesting that opsin spectral sensitivity was the most important determinant of optogenetic defibrillation efficacy. This was due to the deeper penetration of red light in cardiac tissue compared with blue light, which resulted in more widespread light-induced propagating wavefronts. Longer pulse duration and higher LED array density were associated with increased optogenetic defibrillation efficacy. In all cases observed, the defibrillation mechanism was light-induced depolarisation of the excitable gap, which led to block of reentrant wavefronts. [ABSTRACT FROM AUTHOR]

Published

2016

2. Pivotal role of α2 Na+ pumps and their high affinity ouabain binding site in cardiovascular health and disease.

Author

Blaustein, Mordecai P., Chen, Ling, Hamlyn, John M., Leenen, Frans H. H., Lingrel, Jerry B., Wier, W. Gil, and Zhang, Jin

Subjects

CARDIOVASCULAR diseases, OUABAIN, SMOOTH muscle, SODIUM/POTASSIUM ATPase, BLOOD pressure, ANGIOTENSIN II

Abstract

Reduced smooth muscle (SM)-specific α2 Na+ pump expression elevates basal blood pressure (BP) and increases BP sensitivity to angiotensin II (Ang II) and dietary NaCl, whilst SM-α2 overexpression lowers basal BP and decreases Ang II/salt sensitivity. Prolonged ouabain infusion induces hypertension in rodents, and ouabain-resistant mutation of the α2 ouabain binding site (α2R/R mice) confers resistance to several forms of hypertension. Pressure overload-induced heart hypertrophy and failure are attenuated in cardio-specific α2 knockout, cardio-specific α2 overexpression and α2R/R mice. We propose a unifying hypothesis that reconciles these apparently disparate findings: brain mechanisms, activated by Ang II and high NaCl, regulate sympathetic drive and a novel neurohumoral pathway mediated by both brain and circulating endogenous ouabain (EO). Circulating EO modulates ouabain-sensitive α2 Na+ pump activity and Ca2+ transporter expression and, via Na+/Ca2+ exchange, Ca2+ homeostasis. This regulates sensitivity to sympathetic activity, Ca2+ signalling and arterial and cardiac contraction. [ABSTRACT FROM AUTHOR]

Published

2016

3. Arrhythmogenic and metabolic remodelling of failing human heart.

Author

Gloschat, C. R., Koppel, A. C., Aras, K. K., Brennan, J. A., Holzem, K. M., and Efimov, I. R.

Subjects

HEART failure, HEART disease related mortality, DISEASE prevalence, PATHOLOGICAL physiology, ELECTROPHYSIOLOGY, DRUG therapy, METABOLIC regulation

Abstract

Heart failure (HF) is a major cause of morbidity and mortality worldwide. The global burden of HF continues to rise, with prevalence rates estimated at 1-2% and incidence approaching 5-10 per 1000 persons annually. The complex pathophysiology of HF impacts virtually all aspects of normal cardiac function - from structure and mechanics to metabolism and electrophysiology - leading to impaired mechanical contraction and sudden cardiac death. Pharmacotherapy and device therapy are the primary methods of treating HF, but neither is able to stop or reverse disease progression. Thus, there is an acute need to translate basic research into improved HF therapy. Animal model investigations are a critical component of HF research. However, the translation fromcellular and animal models to the bedside ishampered by significant differences between species and among physiological scales. Our studies over the last 8 years show that hypotheses generated in animal models need to be validated in human in vitro models. Importantly, however, human heart investigations can establish translational platforms for safety and efficacy studies before embarking on costly and risky clinical trials. This review summarizes recent developments in human HF investigations of electrophysiology remodelling, metabolic remodelling, and β-adrenergic remodelling and discusses promising new technologies for HF research. [ABSTRACT FROM AUTHOR]

Published

2016

4. Molecular and cellular neurocardiology: development, and cellular and molecular adaptations to heart disease.

Author

Habecker, Beth A., Anderson, Mark E., Birren, Susan J., Fukuda, Keiichi, Herring, Neil, Hoover, Donald B., Kanazawa, Hideaki, Paterson, David J., and Ripplinger, Crystal M.

Subjects

CARDIOVASCULAR diseases, HEART diseases -- Molecular aspects, NERVOUS system, CARDIOVASCULAR system, EMBRYOLOGY, LABORATORY rodents

Abstract

The nervous system and cardiovascular system develop in concert and are functionally interconnected in both health and disease. This white paper focuses on the cellular andmolecular mechanisms that underlie neural-cardiac interactions during development, during normal physiological function in the mature system, and during pathological remodelling in cardiovascular disease. The content on each subject was contributed by experts, and we hope that this will provide a useful resource for newcomers to neurocardiology as well as aficionados. [ABSTRACT FROM AUTHOR]

Published

2016

5. Lessons from computer simulations of ablation of atrial fibrillation.

Author

Jacquemet, Vincent

Subjects

HEART atrium, CATHETER ablation, ATRIAL fibrillation treatment, COMPUTER simulation, ELECTROCARDIOGRAPHY, MATHEMATICAL models

Abstract

This paper reviews the simulations of catheter ablation in computer models of the atria, from the first attempts to the most recent anatomical models. It describes how postulated substrates of atrial fibrillation can be incorporated into mathematical models, how modelling studies can be designed to test ablation strategies, what their current trade-offs and limitations are, and what clinically relevant lessons can be learnt from these simulations. Drawing a parallel between clinical and modelling studies, six ablation targets are considered: pulmonary vein isolation, linear ablation, ectopic foci, complex fractionated atrial electrogram, rotors and ganglionated plexi. The examples presented for each ablation target illustrate a major advantage of computer models, the ability to identify why a therapy is successful or not in a given atrial fibrillation substrate. The integration of pathophysiological data to create detailed models of arrhythmogenic substrates is expected to solidify the understanding of ablation mechanisms and to provide theoretical arguments supporting substrate-specific ablation strategies. [ABSTRACT FROM AUTHOR]

Published

2016

6. All-optical control of cardiac excitation: combined high-resolution optogenetic actuation and optical mapping.

Author

Entcheva, Emilia and Bub, Gil

Subjects

HEART physiology, ELECTROPHYSIOLOGY, ARRHYTHMIA, HEART cells, MEMBRANE potential

Abstract

Cardiac tissue is an excitable system that can support complex spatiotemporal dynamics, including instabilities (arrhythmias) with lethal consequences. While over the last two decades optical mapping of excitation (voltage and calcium dynamics) has facilitated the detailed characterization of such arrhythmia events, until recently, no precise tools existed to actively interrogate cardiac dynamics in space and time. In this work, we discuss the combined use of new methods for space- and time-resolved optogenetic actuation and simultaneous fast, high resolution optical imaging of cardiac excitation waves. First, the mechanisms, limitations and unique features of optically induced responses in cardiomyocytes are outlined. These include the ability to bidirectionally control the membrane potential using depolarizing and hyperpolarizing opsins; the ability to induce prolonged sustained voltage changes; and the ability to control refractoriness and the shape of the cardiac action potential. At the syncytial tissue level, we discuss optogenetically enabled experimentation on cell-cell coupling, alteration of conduction properties and termination of propagating waves by light. Specific attention is given to space- and time-resolved application of optical stimulation using dynamic light patterns to perturb ongoing activation and to probe electrophysiological properties at desired tissue locations. The combined use of optical methods to perturb and to observe the system can offer new tools for precise feedback control of cardiac electrical activity, not available previously with pharmacological and electrical stimulation. These new experimental tools for all-optical electrophysiology allow for a level of precise manipulation and quantification of cardiac dynamics comparable in robustness to the computational setting, and can provide new insights into pacemaking, arrhythmogenesis and suppression or cardioversion. [ABSTRACT FROM AUTHOR]

Published

2016

7. Local calcium gradients during excitation-contraction coupling and alternans in atrial myocytes.

Author

Blatter, Lothar A., Kockskämper, Jens, Sheehan, Katherine A., Zima, Aleksey V., Hüser, Jörg, and Lipsius, Stephen L.

Published

2003