Effects of Porous Media Properties and Flow Environment on Drug Release from Porous Implants

TL;DR

This study uses numerical simulations to analyze how flow conditions and porous media properties affect drug release from porous implants, aiming to optimize their performance in physiological environments.

Contribution

It introduces a detailed numerical model incorporating flow dynamics and drug diffusion to predict drug release profiles from porous implants.

Findings

Flow conditions significantly influence drug release rates.

High Reynolds numbers can increase the release rate during later stages.

The model suggests potential for designing adaptive drug delivery implants.

Abstract

Drug-Filled Porous Implants (DFPIs) are an innovative solution for delivering drugs in a controlled and sustained manner to target sites. To optimize their performance across various physiological conditions, it is essential to understand how fluid flow and porous media properties influence the drug release process. In this work, we numerically investigate a wide range of flow conditions and their effects on drug release from DFPI. The DFPI is modeled as a homogeneous, saturated porous medium, with flow through the porous structure modeled using the Forchheimer-extended Darcy law. Drug diffusion within the DFPI and its transport through the surrounding channel are simulated using a diluted species transport approach. The results reveal the impact of flow conditions and porous media characteristics on the drug release profile of the implant and drug availability within the channel. The variations in drug release behavior are analyzed by modeling the release as an apparent first-order process with a time-dependent rate constant. Notably, the results highlight specific conditions under which the rate constant increases during the later stages of drug release from the DFPI, particularly at high Reynolds numbers, while also ensuring a prolonged operational time period of the implant. These findings suggest the potential for developing intelligent DFPI designs capable of delivering drugs in a manner more attuned to the specific needs of the application.