With
the booming antimicrobial drug resistance worldwide,
traditional
antibacterial agents (e.g., antibiotics) are usually powerless against
superbug. Targeting antibacterial pathways different from traditional
antibiotics could be an effective approach to treating wounds with
a resistant bacterial infection. In this work, an antibacterial polymersome
was developed to physically induce bacterial membrane damage and
interfere with bacterial metabolism. First, we synthesized an antibacterial
poly(ε-caprolactone)-block-poly(glutamic acid)-block-poly(Lys-stat-Phe) copolymer, which
was then self-assembled into polypeptosome with the amplification
of surface positive charges to disrupt bacterial membranes. In addition,
the polypeptosome was further decorated with photocatalytic bismuth
sulfide (Bi2S3) nanoparticles as a photocatalyst
to interfere with reduced nicotinamide adenine dinucleotide (NADH)
conversion. Specifically, near-infrared light generated free electrons
from Bi2S3 nanoparticles could effectively interfere
with NADH homeostasis to induce antibiotic-resistant bacteria death,
as verified by transcriptome sequence analysis. Moreover, effective
healing of antibiotic-resistant bacteria-infected wounds of mice was
achieved with a spray of polypeptosome dispersion. Overall, we provided
a fresh strategy to integrate bacterial membrane damage and metabolism
interference functions within antibacterial polymersomes for healing
antibiotic-resistant bacteria-infected wound.