This study investigates the impact of dual ionic and covalent cross-links (ion-XrL and cov-XrL) on the properties of chitosan-based (CTS) hydrogels as eco-friendly drug delivery systems (DDS) for the model drug diclofenac sodium (DCNa). Citric acid and a diiodo-trehalose derivative (ITrh) were the chosen ionic and covalent cross-linker, respectively. The novel hydrogels completely disintegrated within 96 h by means of a hydrolysis process mediated by the enzyme trehalase. As far as the authors are aware, this is the first time that a trehalose derivative has been used as a covalent cross-linker in the formation of biodegradable hydrogels. The impact of CTS concentration and degree of cov-XrL on rheological parameters were examined by means of an experimental model design and marked differences were found between the materials. Hydrogels with maximum elastic properties were achieved at high CTS concentrations and high degrees of cov-XrL. DCNa-loaded formulations displayed well-controlled drug-release profiles strongly dependent on formulation composition (from 17% to 40% in 72 h). Surprisingly, higher degrees of covalent cross-linking led to a boost in drug release. The formulations presented herein provides a simple and straightforward pathway to design fully biodegradable, tailor-made controlled drug delivery systems with improved rheological properties.
Keywords: Biodegradable; Chemical cross-linking; Controlled drug release; Eco-friendly formulations; Ionic cross-linking; Viscoelastic hydrogels.
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