Your search keyword '"arrhythmia mechanism"' showing total 3 results

1. Mechanisms of torsades de pointes: an update

Author

Yukiomi Tsuji, Masatoshi Yamazaki, Masafumi Shimojo, Satoshi Yanagisawa, Yasuya Inden, and Toyoaki Murohara

Subjects

arrhythmia mechanism, animal model of long QT syndrome, torsades de pointes, ventricular fibrillation, electrical storm, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Torsades de Pointes (TdP) refers to a polymorphic ventricular tachycardia (VT) with undulating QRS axis that occurs in long QT syndrome (LQTS), although the term has been used to describe polymorphic ventricular tachyarrhythmias in which QT intervals are not prolonged, such as short-coupled variant of TdP currently known as short-coupled ventricular fibrillation (VF) and Brugada syndrome. Extensive works on LQTS-related TdP over more than 50 years since it was first recognized by Dessertennes who coined the French term meaning “twisting of the points”, have led to current understanding of the electrophysiological mechanism that TdP is initiated by triggered activity due to early afterdepolarization (EAD) and maintained by reentry within a substrate of inhomogeneous repolarization. While a recently emerging notion that steep voltage gradients rather than EADs are crucial to generate premature ventricular contractions provides additions to the initiation mode, the research to elucidate the maintenance mechanism hasn't made much progress. The reentrant activity that produces the specific form of VT is not well characterized. We have conducted optical mapping in a rabbit model of electrical storm by electrical remodeling (QT prolongation) due to chronic complete atrioventricular block and demonstrated that a tissue-island with prolonged refractoriness due to enhanced late Na+ current (INa−L) contributes to the generation of drifting rotors in a unique manner, which may explain the ECG characteristic of TdP. Moreover, we have proposed that the neural Na+ channel NaV1.8-mediated INa−L may be a new player to form the substrate for TdP. Here we discuss TdP mechanisms by comparing the findings in electrical storm rabbits with recently published studies by others in simulation models and human and animal models of LQTS.

Published

2024

2. Calmodulinopathy: Functional Effects of CALM Mutations and Their Relationship With Clinical Phenotypes

Author

Badone, B, Ronchi, C, Kotta, M, Sala, L, Ghidoni, A, Crotti, L, Zaza, A, Badone, Beatrice, Ronchi, Carlotta, Kotta, Maria-Christina, Sala, Luca, Ghidoni, Alice, Crotti, Lia, Zaza, Antonio, Badone, B, Ronchi, C, Kotta, M, Sala, L, Ghidoni, A, Crotti, L, Zaza, A, Badone, Beatrice, Ronchi, Carlotta, Kotta, Maria-Christina, Sala, Luca, Ghidoni, Alice, Crotti, Lia, and Zaza, Antonio

Abstract

In spite of the widespread role of calmodulin (CaM) in cellular signaling, CaM mutations lead specifically to cardiac manifestations, characterized by remarkable electrical instability and a high incidence of sudden death at young age. Penetrance of the mutations is surprisingly high, thus postulating a high degree of functional dominance. According to the clinical patterns, arrhythmogenesis in CaM mutations can be attributed, in the majority of cases, to either prolonged repolarization (as in long-QT syndrome, LQTS phenotype), or to instability of the intracellular Ca2+ store (as in catecholamine-induced tachycardias, CPVT phenotype). This review discusses how mutations affect CaM signaling function and how this may relate to the distinct arrhythmia phenotypes/mechanisms observed in patients; this involves mechanistic interpretation of negative dominance and mutation-specific CaM-target interactions. Knowledge of the mechanisms involved may allow critical approach to clinical manifestations and aid in the development of therapeutic strategies for “calmodulinopathies,” a recently identified nosological entity.

Published

2018

3. Calmodulinopathy: Functional Effects of CALM Mutations and Their Relationship With Clinical Phenotypes

Author

Beatrice Badone, Carlotta Ronchi, Maria-Christina Kotta, Luca Sala, Alice Ghidoni, Lia Crotti, Antonio Zaza, Badone, B, Ronchi, C, Kotta, M, Sala, L, Ghidoni, A, Crotti, L, and Zaza, A

Subjects

0301 basic medicine, Cell signaling, calmodulin mutations, lcsh:Diseases of the circulatory (Cardiovascular) system, Ca, Ca2+ handling, 2+, Review, 030204 cardiovascular system & hematology, Biology, Cardiovascular Medicine, Bioinformatics, Sudden death, 03 medical and health sciences, 0302 clinical medicine, Repolarization, In patient, calmodulin mutation, Dominance (genetics), arrhythmia mechanism, repolarization, ion channels, Penetrance, Phenotype, Young age, 030104 developmental biology, lcsh:RC666-701, ion channel, Cardiology and Cardiovascular Medicine, arrhythmia mechanisms, handling

Abstract

In spite of the widespread role of calmodulin (CaM) in cellular signaling, CaM mutations lead specifically to cardiac manifestations, characterized by remarkable electrical instability and a high incidence of sudden death at young age. Penetrance of the mutations is surprisingly high, thus postulating a high degree of functional dominance. According to the clinical patterns, arrhythmogenesis in CaM mutations can be attributed, in the majority of cases, to either prolonged repolarization (as in long-QT syndrome, LQTS phenotype), or to instability of the intracellular Ca2+ store (as in catecholamine-induced tachycardias, CPVT phenotype). This review discusses how mutations affect CaM signaling function and how this may relate to the distinct arrhythmia phenotypes/mechanisms observed in patients; this involves mechanistic interpretation of negative dominance and mutation-specific CaM-target interactions. Knowledge of the mechanisms involved may allow critical approach to clinical manifestations and aid in the development of therapeutic strategies for “calmodulinopathies”, a recently identified nosological entity.

Published

2018