Silkworm cocoon bionic design in wound dressings: A novel hydrogel with self-healing and antimicrobial properties

Hydrogels with rapid wound-healing capabilities and antimicrobial effects are gaining significant interest in related fields. Nonetheless, developing a multifunctional hydrogel wound dressing with injectable self-assembling, self-healing, antimicrobial properties, and efficient skin wound-healing capabilities remained a formidable challenge. In this experiment, we drew inspiration from silkworm cocoons' natural formation and protective mechanisms, employing a novel physical cross-linking method to create an injectable and self-healing quaternary hydrogel successfully. The hydrogel is based on a matrix of silk fibroin/silk sericin (SF/SS), with 1,2-dimyristoyl-sn-glycero-3-phosphate sodium salt (DMPG) serving as a physical cross-linking agent to form the hydrogel network structure, and the incorporation of silver nanoparticles (AgNPs) further enhances its antimicrobial capabilities. Our biomimetic hydrogel, which replicated the chemical properties of silkworm cocoons, demonstrated excellent hydrophilicity with a water contact angle that ranged from 37 to 52°. Its tensile and compressive resistance was approximately four times greater than that of a pure SF hydrogel, and its swelling performance was about three times higher than that of a pure SF hydrogel. Furthermore, the hydrogel exhibited an impressive bacterial inhibition rate of over 98 % in bacterial growth and inhibition experiments, which provided a solid foundation for accelerating wound healing. Likewise, experiments with mice and histological analyses revealed that on day 7, the expression of TNF-α and IL-1β in the wound tissues treated with the SF/SS/AgNPs hydrogel was significantly reduced by >25 % compared to the blank control group. This reduction indicates that the hydrogel could decrease the production of inflammatory cytokines, potentially aiding in the acceleration of wound healing and mitigation of inflammation-related adverse reactions. By day 14, the wounds were healed mainly, with the wound area reduced by 17 % compared to that of the blank group. This demonstrates the significant potential of this cocoon-mimetic hydrogel in accelerating wound healing and providing wound protection.