Physicochemical Characterization of Injectable Genipin-Crosslinked Gelatin-Kelulut Honey Hydrogels for Future Cutaneous Tissue Loss.

Chronic wounds, particularly those associated with conditions like diabetes, present significant challenges in healthcare due to prolonged healing and high susceptibility to infections. This study investigates the development of injectable hydrogels composed of genipin-crosslinked gelatin and Kelulut honey (KH) as novel biomaterials for wound healing applications. Hydrogels were prepared with varying concentrations (/) of gelatin (9% and 10%) and KH (0.1% and 0.5%), with genipin (0.1%) acting as a crosslinker. The physicochemical properties were extensively evaluated, including the swelling ratio, water vapor transmission rate (WVTR), contact angle, porosity, enzymatic degradation, and surface roughness. The results showed that KH incorporation significantly enhanced the swelling properties of the hydrogels, with the 9GE_0.1KH formulation demonstrating a swelling ratio of 742.07 ± 89.61% compared to 500% for the control 9GE formulation. The WVTR values for KH-incorporated hydrogels ranged from 1670.60 ± 236.87 g/mh to 2438.92 ± 190.90 g/mh, which were within the ideal range (1500-2500 g/mh) for wound healing. Contact angle measurements indicated improved hydrophilicity, with 9GE_0.1KH showing a contact angle of 42.14° ± 7.52° compared to 60° ± 11.66° for the 10GE formulation. Biodegradation rates were slightly higher for KH-modified hydrogels (0.079 ± 0.006 mg/h for 9GE_0.1KH), but all remained within acceptable limits. These findings suggest that genipin-crosslinked gelatin-KH hydrogels offer a promising scaffold for enhanced wound healing and potential applications in tissue engineering and three-dimensional (3D) bioprinting technologies.