The role of iPSC research for insight into inherited arrhythmia conditions.

Human induced pluripotent stem cells (iPSCs) have emerged as a transformative platform for modeling inherited cardiac arrhythmia syndromes and uncovering human-specific disease mechanisms. However, the promise of iPSC-derived cardiomyocytes lies beyond the recapitulation of arrhythmogenic phenotypes and channelopathies. In this review, we explore recent works which have enabled mechanistic interrogation and therapeutic insight for inherited arrhythmia syndromes, beyond the capabilities of traditional animal models. Such studies have leveraged iPSCs to elucidate the role of splice variants, transcriptional regulation, and mitochondrial stress in arrhythmogenesis. Further, iPSC systems have proven important for reclassifying variants of uncertain significance and in modeling idiopathic arrhythmias where genotype-phenotype links are elusive. Advances in directed differentiation now permit chamber-specific cardiac cell generation, allowing for atrial and ventricular disease modeling and revealing critical cell-cell interactions. iPSCs also serve as high-fidelity precursor platforms for drug testing, offering predictive insight into mutation-specific responses to pharmacologic and genetic therapies. Though limitations in maturation and scalability persist, ongoing efforts for integration with tissue engineering, multi-cellular models, and computational frameworks are evolving to improve model reliability. iPSC-based systems now occupy a critical role in arrhythmia research, bridging basic discovery with translational applications, thereby contributing to personalizing care and advancing therapeutics in inherited and idiopathic arrhythmic syndromes.