透明质酸
二甲双胍
光热治疗
药理学
药物输送
光热效应
化学
控制释放
再生(生物学)
糖尿病
自愈水凝胶
抗氧化剂
伤口愈合
联合疗法
双胍
抗菌活性
细胞内
药品
生物化学
生物物理学
止血
防腐剂
作者
Zexiang Zheng,Xing Yang,Xinshuo Liu,Li Xu,Lihua Li,Jinhuan Tian,Changren Zhou
标识
DOI:10.1016/j.mtbio.2025.102755
摘要
Diabetic wounds remain a global public-health threat due to simultaneous bleeding, bacterial colonization and persistent inflammation. We hypothesized that a dynamic metal-polyphenol hydrogel that instantly seals bleeding vessels, acid-triggered releases metformin and synergistically photothermal antibacterial would break this deadlock. Therefore, we developed a multifunctional hyaluronic acid hydrogel (ODF-Met) by conjugating metformin to dopamine-grafted oxidized hyaluronic acid via dynamic imine bonds, followed by coordination with Fe 3+ to form a dynamic metal-polyphenol network. This unique structure endows ODF-Met with remarkable photothermal antibacterial efficacy (≈ 100%), self-healing ability, biodegradability and robust tissue adhesion (30 kPa). Importantly, ODF-Met exhibits smart pH-responsive release behavior, with cumulative release rates of 87.9 ± 6.8% (pH = 5.5) within 3 h and 85.0 ± 4.0% (pH = 7.4) within 60 h. The acid-triggered metformin release significantly enhanced intracellular ROS scavenging and promoted endothelial cell angiogenesis, thereby amplifying the therapeutic effects of metformin. Unlike traditional sustained-release systems based on covalent conjugation, microspheres, or micelles, the combination of dynamic imine and metal–polyphenol bonds ensures controlled, pH-triggered drug release while preserving metformin bioactivity. The experiments validated that ODF-Met achieved rapid hemostasis (< 10 s), exerted potent photothermal antibacterial action and synergistically provided anti-inflammatory, antioxidant and angiogenic effects. It successfully promoted scarless healing of diabetic infected wounds. In conclusion, ODF-Met represents an integrated and innovative strategy for diabetic wound repair, offering a new design paradigm for metformin delivery systems aimed at achieving tissue regeneration without scarring.
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