Your search keyword '"Elise Catlin"' showing total 2 results

1. Bioadhesive eutectogels supporting drug nanocrystals for long-acting delivery to mucosal tissues

Author

María Beatrice Bianchi, Chunyang Zhang, Elise Catlin, Giuseppina Sandri, Marcelo Calderón, Eneko Larrañeta, Ryan F. Donnelly, Matías L. Picchio, and Alejandro J. Paredes

Subjects

Nanocrystals, Eutectogels, Bioadhesion, Drug delivery, 3D printing, Curcumin, Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

Eutectogels (Egels) are an emerging class of soft ionic materials outperforming traditional temperature-intolerant hydrogels and costly ionogels. Due to their excellent elasticity, non-volatile nature, and adhesion properties, Egels are attracting a great deal of interest in the biomedical space. Herein, we report the first example of adhesive Egels loading drug nanocrystals (Egel-NCs) for controlled delivery to mucosal tissues. These soft materials were prepared using gelatin, glycerine, a deep eutectic solvent (DES) based on choline hydrochloride and glycerol, and nanocrystallised curcumin, a model drug with potent antimicrobial and anti-inflammatory activities. We first explored the impact of the biopolymer concentration on the viscoelastic and mechanical properties of the networks. Thanks to the dynamic interactions between gelatin and the DES, the Egel showed excellent stretchability and elasticity (up to ≈160%), reversible gel-sol phase transition at mild temperature (≈50 ​°C), 3D-printing ability, and good adhesion to mucin protein (stickiness ≈40 ​kPa). In vitro release profiles demonstrated the ability of the NCs-based Egel to deliver curcumin for up to four weeks and deposit significantly higher drug amounts in excised porcine mucosa compared to the control cohort. All in all, this study opens new prospects in designing soft adhesive materials for long-acting drug delivery and paves the way to explore novel eutectic systems with multiple therapeutic applications.

Published

2022

2. On a highway to the brain: A review on nose-to-brain drug delivery using nanoparticles

Author

María L. Formica, Daniel A. Real, Matías L. Picchio, Elise Catlin, Ryan F. Donnelly, and Alejandro J. Paredes

Subjects

General Materials Science

Abstract

The administration of drugs to the central nervous system (CNS) is primarily controlled by the blood-brain barrier (BBB), a structure that prevents the passage of foreign compounds from the blood to the brain's extracellular fluid. Although currently available treatments for brain diseases that affect millions of people globally are partially effective, they are associated with severe side effects of systemic drug distribution. On the other hand, the ability of certain drugs to permeate through the BBB is impeded by their physicochemical properties, achieving sub-therapeutic concentrations in their target tissues. In this sense, the intranasal route with its unique anatomical features provides a promising passage for the delivery of drugs to the brain. Nanoparticle-based systems, in particular, have demonstrated an outstanding capacity to overcome the challenges presented by the intranasal route and produce drug accumulation in the brain while avoiding systemic distribution. This review covers recent developments in the use of polymer, lipid, and inorganic nanoparticles, as well as drug nanocrystals, to deliver drugs to the brain via intranasal administration. A general discussion including favourable aspects and limitations of this approach is also provided.

Published

2022