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Pseudocatalytic Hydrogels with Intrinsic Antibacterial and Photothermal Activities for Local Treatment of Subcutaneous Abscesses and Breast Tumors

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The intimate relationship between bacteria and tumors has triggered a lot of activities in the development and design of bioactive materials to concurrently respond to antitumor and antibacterial demands. Herein,… Click to show full abstract

The intimate relationship between bacteria and tumors has triggered a lot of activities in the development and design of bioactive materials to concurrently respond to antitumor and antibacterial demands. Herein, a pseudocatalytic hydrogel (AM‐I@Agar) with intrinsic antibacterial and photothermal activities, synthesized by incorporating prefabricated amylose‐iodine nanoparticles into low‐melting‐point agarose hydrogel, is explored as a bioactive agent for local treatment of subcutaneous abscesses and breast tumors. The AM‐I@Agar hydrogel depicts the ability of pseudocatalytic O2 generation from H2O2 to alleviate hypoxia. Meanwhile, the AM‐I@Agar hydrogel exhibits temperature self‐regulation features, beneficial for avoiding thermal injury during photothermal therapy owing to thermochromic properties. Upon local injection into a subcutaneous abscess, methicillin‐resistant Staphylococcus aureus is effectively eliminated by the AM‐I@Agar hydrogel, and complete skin recovery is achieved in 8 d, demonstrating much better antibacterial effects compared with penicillin, a small‐molecule antibiotic. AM‐I/5‐FU@Agar hydrogel, obtained after loading 5‐fluorouracil (5‐FU), significantly inhibits tumors in both normal 4T1 tumor‐bearing mice and MRSA‐infected 4T1 tumor‐bearing mice models via a synergistic photothermal‐chemo effect, and shows treatment efficiency superior to that achieved with photothermal therapy or 5‐FU alone. This work provides a concept for the design and development of bioactive agents for potential management of bacteria‐associated cancer.

Keywords: local treatment; antibacterial photothermal; photothermal activities; treatment subcutaneous; treatment; intrinsic antibacterial

Journal Title: Advanced Healthcare Materials
Year Published: 2022

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