A natural bioadhesive derived from Eucommia ulmoides gum for enhanced wound repair
Zemin Ou, Yichun Yang, Chenxiaoning Meng, Qingxia Li, Hong Yi, Chun Li, Lingyu Jia, Zhimin Wang, Xiaoqian Liu
Journal:INTERNATIONAL JOURNAL OF BIOLOGICAL MACROMOLECULES
IF:8.5
DOI:10.1016/j.ijbiomac.2026.150834
PMID:
Published:2026-02-09
research field:抗菌材料生物材料生物医学工程天然高分子伤口愈合
Abstract
The repair of full-thickness skin defects remains a critical biomedical challenge owing to the high risks of infection, persistent inflammation, and irreversible tissue loss, highlighting the urgent need for bioadhesive materials that integrate strong adhesion, biocompatibility, and antibacterial functionality. In this study, a natural bioadhesive termed Eucommia ulmoides gum natural bioadhesive (EUGNBA) was developed through a thermally induced conformational reorganization of Eucommia ulmoides gum, enabling robust wet-tissue adhesion without chemical crosslinkers. EUGNBA demonstrated outstanding mechanical performance, exceeding porcine fibrin adhesives in shear strength, tensile strength, and interfacial toughness by 2.06-, 2.64-, and 3.49-fold, respectively. Raman mapping and spectroscopic characterization confirmed that these superior adhesive properties originated from its conformational adaptability and multiscale interfacial interactions. Beyond mechanical superiority, EUGNBA displayed broad-spectrum antibacterial efficacy exceeding 99.9% against Staphylococcus aureus , Escherichia coli , and Pseudomonas aeruginosa , along with excellent cytocompatibility, negligible hemolysis, and tunable biodegradability in vivo. In rat wound models, EUGNBA markedly enhanced the healing of incisional and full-thickness wounds by promoting re-epithelialization, collagen maturation, and neovascularization, accompanied by activation and coordination of NF-κB-mediated inflammation resolution, Wnt-driven epithelial regeneration, and tight-junction-associated barrier restoration. Compared with commercial adhesives and sutures, EUGNBA achieved superior tissue integration and facilitated the regeneration of dermal appendages. Collectively, this study establishes a scalable approach for engineering conformationally adaptive natural bioadhesives with integrated antibacterial an
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