Mathematical model of the neonatal mouse ventricular action potential

Keyphrases

• Myocytes 100%
• Mathematical Model 100%
• Neonatal Mice 100%
• Ventricular Action Potential 100%
• Ca2+ 66%
• Ca2+ Entry 66%
• K+ Current 66%
• Action Potential Shape 66%
• Cell Function 33%
• Molecular Interactions 33%
• Myocardium 33%
• Heart Disease 33%
• Na + 33%
• Hypothesis Testing 33%
• Repolarization 33%
• Transmembrane 33%
• Novel Prediction 33%
• Sarcoplasmic Reticulum 33%
• Heart Cell 33%
• L-type Ca2+ Channel 33%
• Interaction between Components 33%
• Ca2+ Influx 33%
• Action Potential Duration 33%
• Adult Cardiac Myocytes 33%
• Adult Cells 33%
• Computational Modeling 33%
• System Behavior 33%
• Delayed Rectifier 33%
• Plateau Phase 33%
• T-type 33%
• Intracellular Na+ Concentration 33%
• Sarcoplasmic Reticulum Ca2+ Leak 33%
• Synthesizing Data 33%
• Neonatal Heart 33%
• Ion Transport Mechanism 33%

Medicine and Dentistry

• Calcium Ion 100%
• Action Potential 100%
• Sodium Ion 33%
• Sarcoplasmic reticulum 33%
• Potassium Current 33%
• Neonatal Infant 16%
• Heart Disease 16%
• Myocardium 16%
• Cell Function 16%
• Repolarization 16%
• Cardiac Muscle Cell 16%
• Calcium Channel 16%
• Action Potential Duration 16%
• Ion Transport Mechanism 16%

Biochemistry, Genetics and Molecular Biology

• Action Potential 100%
• Potassium Current 66%
• Cell Function 33%
• Cardiac Muscle Cell 33%
• Molecular Interaction 33%
• Calcium Channel 33%
• Ion Transport 33%
• Repolarization 33%
• Action Potential Duration 33%