Litcius/Paper detail

Fractional Modeling Applied to the Dynamics of the Action Potential in Cardiac Tissue

Sérgio Adriani David, Carlos Alberto Valentim, Amar Debbouche

2022Fractal and Fractional19 citationsDOIOpen Access PDF

Abstract

We investigate a class of fractional time-partial differential equations describing the dynamics of the fast action potential process in contractile myocytes. The system is explored in both one and two dimensional cases. Homogeneous and nonhomogeneous solutions are derived. We also numerically simulate some of the proposed fractional solutions to provide a different modeling perspective on distinct phases of cardiac membrane potential. Results indicate that the fractional diffusion-wave equation may be employed to model membrane potential dynamics with the fractional order working as an extra asset to modulate electricity conduction, particularly for lower fractional order values.

Topics & Concepts

Action (physics)Dynamics (music)Thermal conductionFractional calculusMathematicsApplied mathematicsOrder (exchange)Mathematical analysisPartial differential equationCardiac action potentialPhysicsThermodynamicsRepolarizationMedicineElectrophysiologyInternal medicineFinanceEconomicsQuantum mechanicsAcousticsFractional Differential Equations Solutionsstochastic dynamics and bifurcationLipid Membrane Structure and Behavior
Fractional Modeling Applied to the Dynamics of the Action Potential in Cardiac Tissue | Litcius