Litcius/Paper detail

Fractal Pennes and Cattaneo–Vernotte bioheat equations from product-like fractal geometry and their implications on cells in the presence of tumour growth

Rami Ahmad El‐Nabulsi

2021Journal of The Royal Society Interface50 citationsDOIOpen Access PDF

Abstract

In this study, the Pennes and Cattaneo–Vernotte bioheat transfer equations in the presence of fractal spatial dimensions are derived based on the product-like fractal geometry. This approach was introduced recently, by Li and Ostoja-Starzewski, in order to explore dynamical properties of anisotropic media. The theory is characterized by a modified gradient operator which depends on two parameters: R which represents the radius of the tumour and R 0 which represents the radius of the spherical living tissue. Both the steady and unsteady states for each fractal bioheat equation were obtained and their implications on living cells in the presence of growth of a large tumour were analysed. Assuming a specific heating/cooling by a constant heat flux equivalent to the metabolic heat generation in the tissue, it was observed that the solutions of the fractal bioheat equations are robustly affected by fractal dimensions, the radius of the tumour growth and the dimensions of the living cell tissue. The ranges of both the fractal dimensions and temperature were obtained, analysed and compared with recent studies. This study confirms the importance of fractals in medicine.

Topics & Concepts

FractalFractal dimensionRADIUSBioheat transferMaterials scienceProduct (mathematics)GeometryPhysicsThermodynamicsMathematicsHeat transferMathematical analysisComputer scienceComputer securityThermoelastic and Magnetoelastic PhenomenaAdvanced Thermodynamics and Statistical MechanicsHeat Transfer Mechanisms
Fractal Pennes and Cattaneo–Vernotte bioheat equations from product-like fractal geometry and their implications on cells in the presence of tumour growth | Litcius