Your search keyword '"Huber, I."' showing total 6 results

1. Optogenetic modulation of cardiac action potential properties may prevent arrhythmogenesis in short and long QT syndromes.

Author

Gruber A, Edri O, Huber I, Arbel G, Gepstein A, Shiti A, Shaheen N, Chorna S, Landesberg M, and Gepstein L

Subjects

Channelrhodopsins genetics, Humans, Induced Pluripotent Stem Cells metabolism, Induced Pluripotent Stem Cells physiology, Microscopy, Confocal, Myocytes, Cardiac metabolism, Opsins genetics, Optical Imaging, Optogenetics, Patch-Clamp Techniques, Action Potentials physiology, Arrhythmias, Cardiac physiopathology, Long QT Syndrome physiopathology, Myocytes, Cardiac physiology

Abstract

Abnormal action potential (AP) properties, as occurs in long or short QT syndromes (LQTS and SQTS, respectively), can cause life-threatening arrhythmias. Optogenetics strategies, utilizing light-sensitive proteins, have emerged as experimental platforms for cardiac pacing, resynchronization, and defibrillation. We tested the hypothesis that similar optogenetic tools can modulate the cardiomyocyte's AP properties, as a potentially novel antiarrhythmic strategy. Healthy control and LQTS/SQTS patient-specific human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) were transduced to express the light-sensitive cationic channel channelrhodopsin-2 (ChR2) or the anionic-selective opsin, ACR2. Detailed patch-clamp, confocal-microscopy, and optical mapping studies evaluated the ability of spatiotemporally defined optogenetic protocols to modulate AP properties and prevent arrhythmogenesis in the hiPSC-CMs cell/tissue models. Depending on illumination timing, light-induced ChR2 activation induced robust prolongation or mild shortening of AP duration (APD), while ACR2 activation allowed effective APD shortening. Fine-tuning these approaches allowed for the normalization of pathological AP properties and suppression of arrhythmogenicity in the LQTS/SQTS hiPSC-CM cellular models. We next established a SQTS-hiPSC-CMs-based tissue model of reentrant-arrhythmias using optogenetic cross-field stimulation. An APD-modulating optogenetic protocol was then designed to dynamically prolong APD of the propagating wavefront, completely preventing arrhythmogenesis in this model. This work highlights the potential of optogenetics in studying repolarization abnormalities and in developing novel antiarrhythmic therapies.

Published

2021

2. Engineered heart tissue models from hiPSC-derived cardiomyocytes and cardiac ECM for disease modeling and drug testing applications.

Author

Goldfracht I, Efraim Y, Shinnawi R, Kovalev E, Huber I, Gepstein A, Arbel G, Shaheen N, Tiburcy M, Zimmermann WH, Machluf M, and Gepstein L

Subjects

Action Potentials drug effects, Animals, Arrhythmias, Cardiac pathology, Calcium metabolism, Cardiovascular Agents pharmacology, Disease Models, Animal, Extracellular Matrix drug effects, Humans, Hydrogels pharmacology, Induced Pluripotent Stem Cells drug effects, Myocardial Contraction drug effects, Myocytes, Cardiac drug effects, Organ Specificity, Swine, Arrhythmias, Cardiac drug therapy, Drug Evaluation, Preclinical, Extracellular Matrix metabolism, Heart physiology, Induced Pluripotent Stem Cells cytology, Models, Cardiovascular, Myocytes, Cardiac cytology, Tissue Engineering methods

Abstract

Cardiac tissue engineering provides unique opportunities for cardiovascular disease modeling, drug testing, and regenerative medicine applications. To recapitulate human heart tissue, we combined human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) with a chitosan-enhanced extracellular-matrix (ECM) hydrogel, derived from decellularized pig hearts. Ultrastructural characterization of the ECM-derived engineered heart tissues (ECM-EHTs) revealed an anisotropic muscle structure, with embedded cardiomyocytes showing more mature properties than 2D-cultured hiPSC-CMs. Force measurements confirmed typical force-length relationships, sensitivity to extracellular calcium, and adequate ionotropic responses to contractility modulators. By combining genetically-encoded calcium and voltage indicators with laser-confocal microscopy and optical mapping, the electrophysiological and calcium-handling properties of the ECM-EHTs could be studied at the cellular and tissue resolutions. This allowed to detect drug-induced changes in contraction rate (isoproterenol, carbamylcholine), optical signal morphology (E-4031, ATX2, isoproterenol, ouabin and quinidine), cellular arrhythmogenicity (E-4031 and ouabin) and alterations in tissue conduction properties (lidocaine, carbenoxolone and quinidine). Similar assays in ECM-EHTs derived from patient-specific hiPSC-CMs recapitulated the abnormal phenotype of the long QT syndrome and catecholaminergic polymorphic ventricular tachycardia. Finally, programmed electrical stimulation and drug-induced pro-arrhythmia led to the development of reentrant arrhythmias in the ECM-EHTs. In conclusion, a novel ECM-EHT model was established, which can be subjected to high-resolution long-term serial functional phenotyping, with important implications for cardiac disease modeling, drug testing and precision medicine. STATEMENT OF SIGNIFICANCE: One of the main objectives of cardiac tissue engineering is to create an in-vitro muscle tissue surrogate of human heart tissue. To this end, we combined a chitosan-enforced cardiac-specific ECM hydrogel derived from decellularized pig hearts with human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) from healthy-controls and patients with inherited cardiac disorders. We then utilized genetically-encoded calcium and voltage fluorescent indicators coupled with unique optical imaging techniques and force-measurements to study the functional properties of the generated engineered heart tissues (EHTs). These studies demonstrate the unique potential of the new model for physiological and pathophysiological studies (assessing contractility, conduction and reentrant arrhythmias), novel disease modeling strategies ("disease-in-a-dish" approach) for studying inherited arrhythmogenic disorders, and for drug testing applications (safety pharmacology)., (Copyright © 2019 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.)

Published

2019

3. Modeling Reentry in the Short QT Syndrome With Human-Induced Pluripotent Stem Cell-Derived Cardiac Cell Sheets.

Author

Shinnawi R, Shaheen N, Huber I, Shiti A, Arbel G, Gepstein A, Ballan N, Setter N, Tijsen AJ, Borggrefe M, and Gepstein L

Subjects

Action Potentials, Anti-Arrhythmia Agents pharmacology, Cells, Cultured, ERG1 Potassium Channel genetics, Humans, Induced Pluripotent Stem Cells, Mutation, Patch-Clamp Techniques, Patient-Specific Modeling, Arrhythmias, Cardiac diagnosis, Arrhythmias, Cardiac genetics, Arrhythmias, Cardiac metabolism, Arrhythmias, Cardiac prevention & control, Myocytes, Cardiac metabolism

Abstract

Background: The short QT syndrome (SQTS) is an inherited arrhythmogenic syndrome characterized by abnormal ion channel function, life-threatening arrhythmias, and sudden cardiac death., Objectives: The purpose of this study was to establish a patient-specific human-induced pluripotent stem cell (hiPSC) model of the SQTS, and to provide mechanistic insights into its pathophysiology and therapy., Methods: Patient-specific hiPSCs were generated from a symptomatic SQTS patient carrying the N588K mutation in the KCNH2 gene, differentiated into cardiomyocytes, and compared with healthy and isogenic (established by CRISPR/Cas9-based mutation correction) control hiPSC-derived cardiomyocytes (hiPSC-CMs). Patch-clamp was used to evaluate action-potential (AP) and I Kr current properties at the cellular level. Conduction and arrhythmogenesis were studied at the tissue level using confluent 2-dimensional hiPSC-derived cardiac cell sheets (hiPSC-CCSs) and optical mapping., Results: Intracellular recordings demonstrated shortened action-potential duration (APD) and abbreviated refractory period in the SQTS-hiPSC-CMs. Similarly, voltage- and AP-clamp recordings revealed increased I Kr current density due to attenuated inactivation, primarily in the AP plateau phase. Optical mapping of the SQTS-hiPSC-CCSs revealed shortened APD, impaired APD-rate adaptation, abbreviated wavelength of excitation, and increased inducibility of sustained spiral waves. Phase-mapping analysis revealed accelerated and stabilized rotors manifested by increased rotor rotation frequency, increased rotor curvature, decreased core meandering, and increased rotor complexity. Application of quinidine and disopyramide, but not sotalol, normalized APD and suppressed arrhythmia induction., Conclusions: A novel hiPSC-based model of the SQTS was established at both the cellular and tissue levels. This model recapitulated the disease phenotype in the culture dish and provided important mechanistic insights into arrhythmia mechanisms in the SQTS and its treatment., (Copyright © 2019. Published by Elsevier Inc.)

Published

2019

4. In vivo assessment of the electrophysiological integration and arrhythmogenic risk of myocardial cell transplantation strategies.

Author

Gepstein L, Ding C, Rahmutula D, Wilson EE, Yankelson L, Caspi O, Gepstein A, Huber I, and Olgin JE

Subjects

Animals, Electric Conductivity, Embryonic Stem Cells cytology, Humans, In Vitro Techniques, Myoblasts cytology, Myocytes, Cardiac cytology, Rats, Rats, Sprague-Dawley, Risk Factors, Stem Cell Transplantation, Arrhythmias, Cardiac physiopathology, Electrophysiological Phenomena, Myoblasts transplantation, Myocardium cytology, Myocytes, Cardiac transplantation

Abstract

Cell replacement strategies are promising interventions aiming to improve myocardial performance. Yet, the electrophysiological impact of these approaches has not been elucidated. We assessed the electrophysiological consequences of grafting of two candidate cell types, that is, skeletal myoblasts and human embryonic stem cell-derived cardiomyocytes (hESC-CMs). The fluorescently labeled (DiO) candidate cells were grafted into the rat's left ventricular myocardium. Two weeks later, optical mapping was performed using the Langendorff-perfused rat heart preparation. Images were obtained with appropriate filters to delineate the heart's anatomy, to identify the DiO-labeled cells, and to associate this information with the voltage-mapping data (using the voltage-sensitive dye PGH-I). Histological examination revealed the lack of gap junctions between grafted skeletal myotubes and host cardiomyocytes. In contrast, positive Cx43 immunostaining was observed between donor and host cardiomyocytes in the hESC-CMs-transplanted hearts. Optical mapping demonstrated either normal conduction (four of six) or minimal conduction slowing (two of six) at the hESC-CMs engraftment sites. In contrast, marked slowing of conduction or conduction block was seen (seven of eight) at the myoblast transplantation sites. Ventricular arrhythmias could not be induced in the hESC-CM hearts following programmed electrical stimulation but were inducible in 50% of the myoblast-engrafted hearts. In summary, a unique method for assessment of the electrophysiological impact of myocardial cell therapy is presented. Our results demonstrate the ability of hESC-CMs to functionally integrate with host tissue. In contrast, transplantation of cells that do not form gap junctions (skeletal myoblats) led to localized conduction disturbances and to the generation of a proarrhythmogenic substrate.

Published

2010

5. Cell therapy for modification of the myocardial electrophysiological substrate.

Author

Yankelson L, Feld Y, Bressler-Stramer T, Itzhaki I, Huber I, Gepstein A, Aronson D, Marom S, and Gepstein L

Subjects

Action Potentials, Analysis of Variance, Animals, Animals, Newborn, Arrhythmias, Cardiac physiopathology, Cells, Cultured, Computer Simulation, Fibroblasts cytology, Genetic Therapy, Male, Potassium Channels, Voltage-Gated genetics, Rats, Rats, Sprague-Dawley, Transfection, Arrhythmias, Cardiac therapy, Electrophysiology, Fibroblasts physiology, Myocytes, Cardiac physiology, Potassium Channels, Voltage-Gated metabolism

Abstract

Background: Traditional antiarrhythmic pharmacological therapies are limited by their global cardiac action, low efficacy, and significant proarrhythmic effects. We present a novel approach for the modification of the myocardial electrophysiological substrate using cell grafts genetically engineered to express specific ionic channels., Methods and Results: To test the aforementioned concept, we performed ex vivo, in vivo, and computer simulation studies to determine the ability of fibroblasts transfected to express the voltage-sensitive potassium channel Kv1.3 to modify the local myocardial excitable properties. Coculturing of the transfected fibroblasts with neonatal rat ventricular myocyte cultures resulted in a significant reduction (68%) in the spontaneous beating frequency of the cultures compared with baseline values and cocultures seeded with naive fibroblasts. In vivo grafting of the transfected fibroblasts in the rat ventricular myocardium significantly prolonged the local effective refractory period from an initial value of 84+/-8 ms (cycle length, 200 ms) to 154+/-13 ms (P<0.01). Margatoxin partially reversed this effect (effective refractory period, 117+/-8 ms; P<0.01). In contrast, effective refractory period did not change in nontransplanted sites (86+/-7 ms) and was only mildly increased in the animals injected with wild-type fibroblasts (73+/-5 to 88+/-4 ms; P<0.05). Similar effective refractory period prolongation also was found during slower pacing drives (cycle length, 350 to 500 ms) after transplantation of the potassium channels expressing fibroblasts (Kv1.3 and Kir2.1) in pigs. Computer modeling studies confirmed the in vivo results., Conclusions: Genetically engineered cell grafts, transfected to express potassium channels, can couple with host cardiomyocytes and alter the local myocardial electrophysiological properties by reducing cardiac automaticity and prolonging refractoriness.

Published

2008

6. Pharmacodynamic interaction between mibefradil and other calcium channel blockers.

Author

Matthes J, Huber I, Haaf O, Antepohl W, Striessnig J, and Herzig S

Subjects

Amlodipine pharmacology, Animals, Calcium Channel Blockers metabolism, Calcium Channels, L-Type genetics, Cell Line, Cell Membrane metabolism, Dihydropyridines metabolism, Drug Interactions, Ethosuximide pharmacology, Female, Gallopamil pharmacology, Humans, In Vitro Techniques, Isradipine metabolism, Male, Mibefradil metabolism, Perfusion, Radioligand Assay, Rats, Rats, Wistar, Arrhythmias, Cardiac chemically induced, Calcium Channel Blockers pharmacology, Calcium Channels, L-Type drug effects, Dihydropyridines pharmacology, Mibefradil pharmacology, Myocardial Contraction drug effects, Ventricular Pressure drug effects

Abstract

Briefly after withdrawal of the (T-type) calcium channel blocker mibefradil from the market, four cases of life-threatening interaction of mibefradil with dihydropyridines were reported. We investigated in vitro whether mibefradil interacts with a dihydropyridine, as described for other non-dihydropyridine compounds. Rat working hearts were used to examine functional interactions between amlodipine and mibefradil. Gallopamil and another T-type-channel blocker, ethosuximide, were included for comparison. Effects of mibefradil, (+)- and (-)-gallopamil on [3H](+)-isradipine binding were studied in membranes from tsA201-cells transfected with alpha(1c)-, alpha(2)delta-, and beta(1a)- or beta(2a)-calcium channel subunits. Mibefradil increased negative inotropic effect of amlodipine, but not of gallopamil. Gallopamil and ethosuximide showed no influence on contractile effects of amlodipine. Furthermore, mibefradil concentration-dependently caused bradycardic rhythm disturbance. The same type of arrhythmia was observed combining low concentrations of mibefradil with amlodipine, or with gallopamil, respectively. Amlodipine alone, or the combination of gallopamil or ethosuximide with amlodipine did not cause any arrhythmia. Binding studies showed a concentration-dependent positive allosteric interaction between [3H](+)-isradipine and mibefradil, but not with [3H](+)-isradipine and gallopamil enantiomers. Molecular and functional evidence points to an interaction between a dihydropyridine and mibefradil. Mibefradil caused rhythm disturbances and potentiation of negative inotropy when combined with amlodipine.

Published

2000