Litcius/Paper detail

Numerical evaluation of heat-triggered drug release via thermo-sensitive liposomes: A comparison between image-based vascularized tumor and volume-averaged porous media models

Gabriele Adabbo, Assunta Andreozzi, Marcello Iasiello, Giuseppe Peter Vanoli

2023International Journal of Heat and Mass Transfer22 citationsDOIOpen Access PDF

Abstract

In this study, two numerical models for controlled drug delivery through thermo-sensitive liposomes under mild microwave hyperthermia are compared. The first model simulates blood flow directly in a realistic tumor vascular network. The second one, at the volume-averaged macro scale, employs the porous media model. Using the vascular-scale approach is helpful for these kind of applications since the porous media assumption does not allow to account for local vascular blood flow, which is a crucial variable to quantify outputs like local drug accumulations. In the present study, the vascularized tumor model is obtained from a photo-acoustic scan and used as computational domain. The vascular-scale model considers heat and drug transfer in vascular and intracellular spaces, employing energy equations for heat transfer and a three-compartment convection-diffusion model for drug diffusion. Blood flow is simulated using the momentum equation for non-Newtonian fluids. The volume-averaged model shows good agreement with the vascular-scale model even if provides less precise information about temperature field distribution and drug localization within the tumor tissue. Also, the volume-averaged model underestimates Fraction of Killed Cells by 3 % post-treatment, presenting a more uniform temperature field and drug distribution compared to the vascular-scale one. Despite these small limitations, the porous media model is reliable for obtaining average results, while the vascular-scale model is suitable when more accurate results are needed. This study's findings aid those who aim to predict hyperthermia-driven drug delivery, suggesting the vascular-scale approach for precision and accuracy and the volume-averaged approach for average outcomes.

Topics & Concepts

Heat transferPorous mediumDiffusionMaterials scienceMechanicsBlood flowScale (ratio)Finite volume methodVolume fractionVolume (thermodynamics)Control volumeBiomedical engineeringThermodynamicsPorosityPhysicsMedicineRadiologyComposite materialQuantum mechanicsNanofluid Flow and Heat TransferNanoparticle-Based Drug DeliveryPhotoacoustic and Ultrasonic Imaging