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Computational Study to Identify the Effects of the KCNJ2 E299V Mutation in Cardiac Pumping Capacity
- Source :
- Computational and Mathematical Methods in Medicine, Computational and Mathematical Methods in Medicine, Vol 2020 (2020)
- Publication Year :
- 2019
-
Abstract
- The KCNJ2 gene mutations induce short QT syndrome (SQT3) by directly increasing the IK1 current. There have been many studies on the electrophysiological effects of mutations such as the KCNJ2 D172N that cause the SQT3. However, the KCNJ2 E299V mutation is distinguished from other representative gene mutations that can induce the short QT syndrome (SQT3) in that it increased IK1 current by impairing the inward rectification of K+ channels. The studies of the electromechanical effects on myocardial cells and mechanisms of E299V mutations are limited. Therefore, we investigated the electrophysiological changes and the concomitant mechanical responses according to the expression levels of the KCNJ2 E299V mutation during sinus rhythm and ventricular fibrillation. We performed excitation-contraction coupling simulations using a human ventricular model with both electrophysiological and mechanical properties. In order to observe the electromechanical changes due to the expression of KCNJ2 E299V mutation, the simulations were performed under normal condition (WT), heterogeneous mutation condition (WT/E299V), and pure mutation condition (E299V). First, a single-cell simulation was performed in three types of ventricular cells (endocardial cell, midmyocardial cell, and epicardial cell) to confirm the electrophysiological changes and arrhythmogenesis caused by the KCNJ2 E299V mutation. In three-dimensional sinus rhythm simulations, we compared electrical changes and the corresponding changes in mechanical performance caused by the expression level of E299V mutation. Then, we observed the electromechanical properties of the E299V mutation during ventricular fibrillation using the three-dimensional reentry simulation. The KCNJ2 E299V mutation accelerated the opening of the IK1 channel and increased IK1 current, resulting in a decrease in action potential duration. Accordingly, the QT interval was reduced by 48% and 60% compared to the WT condition, for the WT/E299V and E299V conditions, respectively. During sustained reentry, the wavelength was reduced due to the KCNJ2 E299V mutation. Furthermore, there was almost no ventricular contraction in both WT/E299V and E299V conditions. We concluded that in both sinus rhythm and fibrillation, the KCNJ2 E299V mutation results in very low contractility regardless of the expression level of mutation and increases the risk of cardiac arrest and cardiac death.
- Subjects :
- medicine.medical_specialty
Article Subject
Heart Ventricles
Computer applications to medicine. Medical informatics
Finite Element Analysis
R858-859.7
030204 cardiovascular system & hematology
Gene mutation
QT interval
General Biochemistry, Genetics and Molecular Biology
Contractility
03 medical and health sciences
0302 clinical medicine
Internal medicine
medicine
Humans
Sinus rhythm
Computer Simulation
Potassium Channels, Inwardly Rectifying
030304 developmental biology
Fibrillation
0303 health sciences
General Immunology and Microbiology
Chemistry
Applied Mathematics
Models, Cardiovascular
Computational Biology
Short QT syndrome
Arrhythmias, Cardiac
General Medicine
medicine.disease
Myocardial Contraction
Biomechanical Phenomena
Electrophysiological Phenomena
Modeling and Simulation
Mutation (genetic algorithm)
Ventricular fibrillation
Mutation
Cardiology
medicine.symptom
Research Article
Subjects
Details
- ISSN :
- 17486718
- Volume :
- 2020
- Database :
- OpenAIRE
- Journal :
- Computational and mathematical methods in medicine
- Accession number :
- edsair.doi.dedup.....13b56601851e4225e697d15ab577d0c1