Bis-imidazolium ionic liquid and silver nanoparticles mediated synthesis of alginate hydrogels for bacterial skin infection and wound healing applications.

To advance biomedical engineering and enhance its therapeutic and diagnostic capabilities, the development of novel materials that can mimic the complexity of biological tissues is crucial. Hydrogels, with their high water content and biocompatibility, are particularly suitable for a wide range of medical applications. This research explores the synthesis and bioactivity of alginate hydrogels and their crosslinked derivatives within the biomedical field. We synthesized a series of alginate and p-phthaloyl crosslinked alginate films, which were further modified with imidazolium-based bi-ionic liquids and green-synthesized silver nanoparticles (AgNPs). The successful synthesis of these materials was confirmed using techniques such as FTIR, XRD, EDX, UV-Vis, H NMR, and SEM. Additionally, their mechanical and thermal properties were assessed under various conditions. The polymers were tested for antibacterial activity against five different bacterial strains, including both gram-negative and gram-positive bacteria. The findings demonstrated that the hydrogel film with ionic liquid and the cross-linked film with AgNPs exhibited significant antibacterial properties with 23 mm and 10 mm zones of inhibition (ZOI) respectively. In vivo, testing on mice models revealed that the alginate cross-linked film incorporated with AgNPs (APC + 10 % AgNPs) film achieved 97 % wound closure by day 7, while the sodium alginate film embedded with bis-imidazolium ionic liquid (SA + 10 % BIL) achieved 93.25 % wound healing by day 9. These results suggest that the p-phthaloyl crosslinked alginate film incorporated with AgNPs holds the potential for effective and rapid wound recovery.