Abstract
This paper reports new formulations based on chitosan, citral, and diclofenac sodium salt (DCF). The central idea was to encapsulate an anionic drug into a polycationic hydrogel matrix in order to increase the intermolecular forces between them and thus to ensure slower drug release, while citral was used as a penetration enhancer to assure efficient delivery of the drug. Hydrogels without drug were also synthesized and used as a reference. The structure, morphology, and supramolecular architecture of the drug delivery systems were evaluated by FTIR spectroscopy, scanning electron microscopy, polarized optical microscopy, and wide-angle X-ray diffraction. The drug release kinetics was monitored in vitro by UV-VIS spectroscopy, in physiological conditions, while the enzymatic and hydrolytic degradability of the hydrogels were evaluated in the presence of lysozyme and phosphate buffer saline (PBS), at 37 °C. All of the data revealed that the anionic DCF was strongly anchored into the polycationic matrix and the drug was slowly released over 7 days. Moreover, the release rate can be controlled by simple variation of the molar ratio between the polycationic chitosan and lipophilic citral.
Highlights
IntroductionHydrogels are one of the most versatile classes in terms of properties and applicability [1,2]
Among biomaterials, hydrogels are one of the most versatile classes in terms of properties and applicability [1,2]
Four drug delivery systems were obtained by the self-assembling of citryl-imino-chitosan amphiphiles in the presence of an anti-inflammatory drug called diclofenac sodium salt (Scheme 1)
Summary
Hydrogels are one of the most versatile classes in terms of properties and applicability [1,2]. Considering that biocompatibility is a requirement for all of the components of drug delivery systems, hydrogels are formulated based on natural polymers or polymers from renewable resources, which have gained an increasing amount of attention during the last few years [8]. Among this class, chitosan plays an important role, due to its tremendous biological properties, and because it is very similar to the extracellular matrix, from both compositionally and mechanically points of view, which represents an important advantage regarding its bioapplicability [8,9,10,11]
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