单线态氧
光动力疗法
光敏剂
伤口愈合
纳米纤维
化学
双层
杰纳斯
氧气
活性氧
纳米技术
体内
生物医学工程
渗透(战争)
吸收(声学)
材料科学
脂质双层
生物物理学
缺氧(环境)
作者
Xiaoyong Huang,Bo Tian,Zhaojie Sun,Yuze Zhou,Jun Zeng,Huilin Liu,Shuai Shi,Tong Chen,Shang Yunfei,Huili Tong,Shuwei Hao,Shuang Li,Chunhui Yang
标识
DOI:10.1002/adhm.202503706
摘要
Abstract Impaired wound healing poses life‐threatening risks due to uncontrolled multidrug‐resistant bacterial infections. Although photodynamic therapy (PDT) represents a promising non‐antibiotic strategy to combat antibiotic‐resistant pathogens, its efficacy in wound dressings faces two fundamental limitations: inadequate light penetration depth hindering photosensitizer activation and hypoxia suppressing reactive oxygen species generation. To address these limitations, a near‐infrared (NIR)‐activated multifunctional bilayer Janus nanofibrous dressing featuring asymmetric hydrophobicity/hydrophilicity is engineered. This bilayer architecture integrates three synergistic functions: i) A hydrophilic CaO 2 ‐doped inner layer enabling quick blood absorption and oxygen release, promoting cell proliferation and tissue regeneration. ii) A hydrophobic outer layer with embedded NaYF 4 :Yb,Er@mSiO 2 @Ce6 achieving NIR‐triggered singlet oxygen ( 1 O 2 ) to eradicate bacteria. iii) Continuous oxygen supply from the hydrophilic layer, sustaining the photosensitization for the PDT process and thus overcoming the hypoxic‐induced limitations. In vitro and in vivo studies demonstrate the designed Janus nanofibrous dressing's excellent biocompatibility, rapid hemostasis, and near‐complete bacterial eradication (>99.99%). By synchronizing hemostasis, oxygenation, and hypoxia‐alleviated PDT, this platform significantly accelerates the healing of infected wounds through sequential hemostasis‐proliferation‐remodeling phases within 12 days, achieving near‐complete recovery compared to only 47.6% in the control group. This work provides a promising strategy for designing new dressings for infected wounds.
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