AI Article Synopsis
- Phototherapy techniques like photothermal therapy (PTT) and photodynamic therapy (PDT) are effective against bacterial infections, but drug-resistant bacteria have tough membranes that reduce their effectiveness.
- A new MXene/CaO bio-heterojunction (MC bio-HJ) is developed to enhance disinfection and tissue regeneration by encouraging pathogenic bacteria to adopt a competent cell-like state, improving their membrane permeability.
- In mouse models, the MC bio-HJ not only speeds up healing of MRSA-infected skin but also improves bone integration in infected bone defects when used with orthopedic implants.
Article Abstract
Phototherapy, such as photothermal therapy (PTT) and photodynamic therapy (PDT) has been a powerful strategy to combat bacterial infection. However, the compact cell membranes of pathogenic bacteria, especially drug-resistant bacteria, significantly diminish the efficiency of heat conduction and impede the entrance of reactive oxygen species (ROS) into cells, resulting in unsatisfactory sterilization. Enlightened by the membrane feature of competent bacteria, herein a MXene/CaO bio-heterojunction (MC bio-HJ) is elaborated to achieve rapid disinfection and promote infected tissue regeneration through activating competent cell-like antibacterial tactics. The bio-HJ first compels pathogenic bacteria to become a competent cell-like stage through the coordination of Ca and membrane phospholipid, and potentiates the membrane permeability. Assisted by near infrared (NIR) irradiation, the heat and ROS generated from PTT and PDT of bio-HJ easily pass through bacterial membrane and drastically perturb bacterial metabolism, leading to rapid disinfection. More importantly, employing two in vivo infected model of mice, it have corroborated that the MC bio-HJs not only effectively accelerate MRSA-infected cutaneous regeneration, but also considerably boost osseointegration in an infected bone defect after coating on orthopedic implants. As envisaged, this work demonstrates a novel therapeutic tactic with robust antibacterial effect to remedy infected tissue regeneration through activating competent cell-like stage.
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| http://dx.doi.org/10.1002/adma.202414111 | DOI Listing |
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