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Main Authors: Carwood, Obi A., Carr, Elliot J.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.19510
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author Carwood, Obi A.
Carr, Elliot J.
author_facet Carwood, Obi A.
Carr, Elliot J.
contents Mathematical modelling and computer simulation are increasingly being used alongside experiments to help optimise and guide the design of drug delivery systems. Recent drug delivery research has (i) highlighted the advantages of drug delivery systems constructed using functionally graded materials to achieve target release rates and desired dosage levels over time; and (ii) revealed how it is possible for drug to bind to the carrier material and become irreversibly immobilised within the system, reducing the amount of drug delivered. In this paper, we consider the effect of functionally graded materials and binding reactions on drug release from common slab, cylinder and sphere devices. In particular, two key contributions are presented. First, we outline a deterministic-continuum approach that develops exact analytical expressions for calculating the total fraction of drug released from the device based on a partial differential equation model of the release process. Second, we develop a stochastic-discrete approach for calculating the fraction of drug released over time based on a random-walk model that captures the randomness of the release process and resulting variability in the total fraction of drug released. Both approaches are numerically validated and provide tools for exploring how the fraction of drug released depends on system parameters (e.g. diffusivity and reaction rate functions induced by the functionally graded material and binding reactions), insight which may be useful for designers of drug delivery systems.
format Preprint
id arxiv_https___arxiv_org_abs_2508_19510
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Functionally-graded drug delivery systems with binding reactions: analytical and stochastic approaches for the fraction of drug released
Carwood, Obi A.
Carr, Elliot J.
Medical Physics
Mathematical modelling and computer simulation are increasingly being used alongside experiments to help optimise and guide the design of drug delivery systems. Recent drug delivery research has (i) highlighted the advantages of drug delivery systems constructed using functionally graded materials to achieve target release rates and desired dosage levels over time; and (ii) revealed how it is possible for drug to bind to the carrier material and become irreversibly immobilised within the system, reducing the amount of drug delivered. In this paper, we consider the effect of functionally graded materials and binding reactions on drug release from common slab, cylinder and sphere devices. In particular, two key contributions are presented. First, we outline a deterministic-continuum approach that develops exact analytical expressions for calculating the total fraction of drug released from the device based on a partial differential equation model of the release process. Second, we develop a stochastic-discrete approach for calculating the fraction of drug released over time based on a random-walk model that captures the randomness of the release process and resulting variability in the total fraction of drug released. Both approaches are numerically validated and provide tools for exploring how the fraction of drug released depends on system parameters (e.g. diffusivity and reaction rate functions induced by the functionally graded material and binding reactions), insight which may be useful for designers of drug delivery systems.
title Functionally-graded drug delivery systems with binding reactions: analytical and stochastic approaches for the fraction of drug released
topic Medical Physics
url https://arxiv.org/abs/2508.19510