Archive/Synergistic Hydrogels Enabled by Dual-Regulatory Mussel Foot Protein for Advancing Wound Healing
Synergistic Hydrogels Enabled by Dual-Regulatory Mussel Foot Protein for Advancing Wound Healing
Jiren Xu, Na Li, Chen Wang et al.
July 14, 2026
en

Abstract

Impaired wound healing is often caused by persistent inflammation, bacterial infection, and insufficient extracellular matrix remodeling. Natural polymer-based hydrogels represent ideal wound dressings but often struggle to balance structural stability and biological activity. Herein, we report a dual-functional network regulation strategy enabled by highly soluble mussel foot protein (HMFP) that acts simultaneously as a structural crosslinking regulator and bioactive effector to fabricate synergistic hydrogels (CS-SH-H) from β-chitosan (CS) and sodium hyaluronate (SH). HMFP homogenizes the porous microstructure, strengthens intermolecular interactions, and significantly improves thermal and structural stability via multivalent non-covalent bonding. In vitro, CS-SH-H shows excellent cytocompatibility, significantly promotes fibroblast proliferation and migration, and exerts potent antibacterial activity against Escherichia coli (E. coli) and Staphylococcus aureus (S. aureus). In a mouse full-thickness skin defect model, the hydrogel dramatically accelerates wound closure, reducing the residual wound area to 25% on day 7, outperforming the control groups. Immunohistochemistry confirms that HMFP suppresses TNF-α-mediated inflammation and enhances Ki-67-positive cell proliferation, leading to accelerated re-epithelialization and collagen deposition. This study establishes HMFP as a promising marine-derived dual-functional network regulator for designing high-performance hydrogel dressings. This strategy is scalable and translatable for treating infected and inflammatory wounds.

IPC Classification

G06H04C07A01

Keywords

synergistichydrogelsenableddual-regulatorymusselfootproteinadvancingwoundhealinggelsimpairedoftencausedpersistentinflammationbacterialinfectioninsufficientextracellularmatrixremodelingnaturalpolymer-based
Reference this publication

€ 4.00