Fast Absorbent and Highly Bioorthogonal Hydrogels Developed by IEDDA Click Reaction for Drug Delivery Application.

In this work, we engineered highly biocompatible and fast absorbent injectable hydrogels derived from norbornene (Nb)-functionalized hyaluronic acid (HA-Nb) and a water-soluble cross-linker possessing tetrazine (Tz) functional groups on both ends of polyethylene glycol (PEG-DTz). The by-product (nitrogen gas) of the inverse electron demand Diels−Alder (IEDDA) cross-linking reaction carved porosity in the resulting hydrogels. By varying the molar ratio of HA-Nb and PEG-DTz (Nb:Tz = 10:10, 10:5, 10:2.5), we were able to formulate hydrogels with tunable porosity, gelation time, mechanical strength, and swelling ratios. The hydrogels formed quickly (gelation time < 100 s), offering a possibility to use them as an injectable drug delivery system. The experimental data showed rapid swelling and a high swelling ratio thanks to the existence of PEG chains and highly porous architectures of the hydrogels. The hydrogels were able to encapsulate a high amount of curcumin (~99%) and released the encapsulated curcumin in a temporal pattern. The PEG-DTz cross-linker, HA-Nb, and the resulting hydrogels showed no cytotoxicity in HEK-293 cells. These fast absorbent hydrogels with excellent biocompatibility fabricated from HA-Nb and the IEDDA click-able cross-linker could be promising drug carriers for injectable drug delivery applications.

Dual cross-linked chitosan/alginate hydrogels prepared by Nb-Tz 'click' reaction for pH responsive drug delivery.

A novel physically and chemically double-crosslinked hydrogel derived from chitosan oligosaccharide/alginate (COS/Alg) was developed by using norbornene (Nb)-tetrazine (Tz) click reaction for ketoprofen delivery. The properties of the hydrogel were evaluated by rheological, FTIR, TGA, XRD, SEM, swelling and drug release studies. The Nb-Tz chemical cross-linking facilitated outstanding hydrophobic drug loading (44% wt/wt of ketoprofen) and sustained release through a hydrophobic interaction mechanism between the drug and the used polysaccharides. The COS/Alg electrostatics network (10/10 of NH2/COOH molar ratio) generated the pH responsiveness, suppressing the release in simulated gastric fluid (below 10% for 2 h) and enhancing the release in simulated intestinal fluids (up to 84% for 24 h). The prepared hydrogel was non-toxic to human HEK-293 cells (95% cell viability). This work opens up a potential approach for preparing hydrophilic hydrogels from natural polysaccharides that can be used in the delivery of hydrophobic drugs.

Multi-stimuli responsive hydrogels derived from hyaluronic acid for cancer therapy application.

One of the most promising strategies for the controlled release of therapeutic molecules is stimuli-responsive and biodegradable hydrogels developed from natural polymers. However, current strategies to development stimuli-responsive hydrogels lack precise control over drug release profile and use cytotoxic materials during preparation. To address these issues, multi-stimuli responsive hydrogels derived from hyaluronic acid and diselenide based cross-linker were developed for the controlled release of doxorubicin (DOX). Hydrogels were rapidly formed via an inverse electron demand Diels-Alder click chemistry and encapsulated DOX/indocyanine green (ICG) in their porous networks. The hydrogels showed a rapid release of DOX in acidic (pH 5), reducing (10 mmol DTT), and oxidizing medium (0.5% H2O2), and after NIR irradiation. The in vitro experiments demonstrated that hydrogels were highly cytocompatible and the DOX-loaded hydrogels induced similar anti-tumor effect as compared to that of the free-DOX. Furthermore, DOX + ICG loaded hydrogels increased the antitumor efficacy of DOX after NIR irradiation.