The Kv1.1 null mouse is a potential model for SUDEP in patients who experience ictal and postictal bradycardia. It offers the opportunity for evaluation of the combination of factors, in addition to vagal activation, necessary to produce a terminal asystole following seizure. It is notable that long-term studies that evaluate electroencephalography (EEG) and cardiorespiratory events surrounding nonfatal seizures may provide indices predictive of terminal seizure.
Background/Aims: The zebrafish is an emerging model system for the study of cardiac electrophysiology and human arrhythmias. High resolution imaging techniques are powerful tools for the study of zebrafish cardiac electrophysiology, but these methods require the complete absence of cardiac contraction. Many pharmacological agents that uncouple cardiac contraction also markedly alter the cardiac action potential (AP). In this study, we compared the effects two uncoupling agents, 2,3-Butanedione monoxime (BDM) and blebbistatin, on contractility and AP parameters in embryonic zebrafish heart. Methods: Zebrafish hearts were explanted (48 hpf) and superfused with either BDM (15 mM) or blebbistatin (1, 5 or 10 µM), while recording atrial or ventricular APs with the disrupted patch technique. Calcium transients were recorded with a high-speed confocal scanning microscope in hearts loaded intracellularly with 10 µM fluo-4 and superfused with 10 µM blebbistatin. Results: Despite abolishing cardiac contractility, BDM altered ventricular AP morphology and inhibited spontaneous APs. In contrast, blebbistatin (10 µM) abolished contractility without significantly altering AP morphology or generation of spontaneous APs. Blebbistatin allowed for high fidelity measurements of atrial and ventricular calcium transients. Conclusion: Blebbistatin is a potent and effective excitation-contraction uncoupling agent in embryonic zebrafish heart.
SummaryAdvances in induced pluripotent stem cell (iPSC) technology have set the stage for routine derivation of patient- and disease-specific human iPSC-cardiomyocyte (CM) models for preclinical drug screening and personalized medicine approaches. Peripheral blood mononuclear cells (PBMCs) are an advantageous source of somatic cells because they are easily obtained and readily amenable to transduction. Here, we report that the electrophysiological properties and pharmacological responses of PBMC-derived iPSC CM are generally similar to those of iPSC CM derived from other somatic cells, using patch-clamp, calcium transient, and multielectrode array (MEA) analyses. Distinct iPSC lines derived from a single patient display similar electrophysiological features and pharmacological responses. Finally, we demonstrate that human iPSC CMs undergo acute changes in calcium-handling properties and gene expression in response to rapid electrical stimulation, laying the foundation for an in-vitro-tachypacing model system for the study of human tachyarrhythmias.
SummaryGenome editing in induced pluripotent stem cells is currently hampered by the laborious and expensive nature of identifying homology-directed repair (HDR)-modified cells. We present an approach where isolation of cells bearing a selectable, HDR-mediated editing event at one locus enriches for HDR-mediated edits at additional loci. This strategy, called co-targeting with selection, improves the probability of isolating cells bearing HDR-mediated variants and accelerates the production of disease models.
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