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Autori principali: Onofri, Elia, Cristiani, Emiliano, Martelli, Andrea, Gentile, Piergiorgio, Hernández, Joel Girón, Pontrelli, Giuseppe
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2506.17078
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author Onofri, Elia
Cristiani, Emiliano
Martelli, Andrea
Gentile, Piergiorgio
Hernández, Joel Girón
Pontrelli, Giuseppe
author_facet Onofri, Elia
Cristiani, Emiliano
Martelli, Andrea
Gentile, Piergiorgio
Hernández, Joel Girón
Pontrelli, Giuseppe
contents Releasing capsules are widely employed in biomedical applications as smart carriers of therapeutic agents, including drugs and bioactive compounds. Such delivery vehicles typically consist of a loaded core, enclosed by one or multiple concentric coating strata. In this work, we extend over existing mechanistic models to account for such multi-strata structures, and we characterise the release kinetics of the active substance into the surrounding medium. We present a computational study of drug release from a multi-stratum spherical microcapsule, modelled through a non-linear diffusion equation incorporating radial anisotropy and space- and time-discontinuous coefficients. The problem is solved numerically using a finite volume scheme on a grid with adaptive spatial and temporal resolution. Analytical expressions for concentration and cumulative release are derived for all strata, enabling the exploration of parameter sensitivity -- such as coating permeability and internal diffusivity -- on the overall release profile. The resulting release curves provide mechanistic insight into the transport processes and offer design criteria for achieving controlled release. Model predictions are benchmarked against in vitro experimental data obtained under physiologically relevant conditions, showing good agreement and validating the key features of the model. The proposed model thus serves as a practical tool for predicting the behaviour of composite coated particles, supporting performance evaluation and the rational design of next-generation drug delivery systems with reduced experimental effort.
format Preprint
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institution arXiv
publishDate 2025
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spellingShingle A general multi-stratum model for a nanofunctionalized releasing capsule: a computational study
Onofri, Elia
Cristiani, Emiliano
Martelli, Andrea
Gentile, Piergiorgio
Hernández, Joel Girón
Pontrelli, Giuseppe
Dynamical Systems
Releasing capsules are widely employed in biomedical applications as smart carriers of therapeutic agents, including drugs and bioactive compounds. Such delivery vehicles typically consist of a loaded core, enclosed by one or multiple concentric coating strata. In this work, we extend over existing mechanistic models to account for such multi-strata structures, and we characterise the release kinetics of the active substance into the surrounding medium. We present a computational study of drug release from a multi-stratum spherical microcapsule, modelled through a non-linear diffusion equation incorporating radial anisotropy and space- and time-discontinuous coefficients. The problem is solved numerically using a finite volume scheme on a grid with adaptive spatial and temporal resolution. Analytical expressions for concentration and cumulative release are derived for all strata, enabling the exploration of parameter sensitivity -- such as coating permeability and internal diffusivity -- on the overall release profile. The resulting release curves provide mechanistic insight into the transport processes and offer design criteria for achieving controlled release. Model predictions are benchmarked against in vitro experimental data obtained under physiologically relevant conditions, showing good agreement and validating the key features of the model. The proposed model thus serves as a practical tool for predicting the behaviour of composite coated particles, supporting performance evaluation and the rational design of next-generation drug delivery systems with reduced experimental effort.
title A general multi-stratum model for a nanofunctionalized releasing capsule: a computational study
topic Dynamical Systems
url https://arxiv.org/abs/2506.17078