Phytochemical nanozymes reprogram redox for balanced antimicrobial and regenerative therapy in acute and chronic diabetic wounds

氧化应激 化学 活性氧 再生(生物学) 抗氧化剂 伤口愈合 药理学 抗菌剂 细胞生物学 生物化学 医学 免疫学 生物 有机化学
作者
Yipeng Pang,Fructueux Modeste Amona,Xiaohan Chen,Yuxin You,Ziqi Sha,Zilu Liu,Jiamin Li,Yi Liu,Xingtang Fang,Xi Chen
出处
期刊:Redox biology [Elsevier BV]
卷期号:85: 103718-103718 被引量:1
标识
DOI:10.1016/j.redox.2025.103718
摘要

Chronic diabetic wounds are characterized by persistent oxidative stress and microbial infections, leading to delayed healing and tissue repair. While elevated reactive oxygen species (ROS) levels can provide bactericidal effects, uncontrolled oxidative stress simultaneously impairs tissue regeneration. Thus, precise redox modulation that balances antimicrobial efficacy with tissue regeneration is critical for effective wound therapy. Herein, we developed a phytochemical nanozymes system by integrating ferulic acid (FA) with cerium oxide nanoparticles (CeO2), enabling precise redox modulation to balance antimicrobial efficacy with tissue regeneration. Structural analysis confirmed the uniform dispersion and pH-responsive release of FA and Ce ions, facilitating targeted redox modulation. The FA-CeO2 nanozymes exhibited potent antioxidant activity through Ce3+/Ce4+ cycling and FA-mediated radical scavenging, effectively mitigating oxidative stress while promoting bacterial clearance against S. aureus and E. coli. Furthermore, FA-CeO2 significantly enhanced Nrf2/HO-1 pathway activation, leading to upregulated VEGF/CD31 expression, accelerated cell proliferation, and enhanced collagen deposition in vitro. In vivo, FA-CeO2 facilitated wound closure, reduced bacterial burden, and improved tissue regeneration in acute and diabetic wound models, with minimal cytotoxicity and excellent biocompatibility. These findings highlight the critical role of precise redox modulation in balancing antibacterial and regenerative therapy, positioning phytochemical nanozymes as a dual-modality platform for effective wound therapy and advancing nanomedicine strategies targeting oxidative stress and tissue repair.
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