Abstract
Sonodynamic therapy (SDT) has good feasibility to deeply seated infections, but SDT alone is insufficient being highly effective against multidrug-resistant (MDR) bacteria. SDT combined with triphenylphosphanium bromide (P(+)Ph(3)Br(-)) is expected to solve this problem. This work develops a pseudo-conjugated polymer P(FCPS-P) containing cationic P(+)Ph(3)Br(-)-modified sonosensitizer FCPS (FCPS-P) and ROS-sensitive thioketal bonds. P(FCPS-P) is assembled with DSPE-mPEG(2000) to generate nanoparticle NP(FCPS-P). FCPS has SDT effect and generates ROS under ultrasound (US) stimulation. ROS triggers the degradation of NP(FCPS-P) and release of FCPS-P, endowing highly favored biosafety. FCPS-P targets to bacterial surface through electrostatic interaction and achieves bacterial killing under a synergistic action of SDT and P(+)Ph(3)Br(-). In vitro, NP(FCPS-P)+US gives >90% inhibition rates against MDR ESKAPE pathogens, moreover, it causes bacterial metabolic disorders including inhibited nucleic acid synthesis, disordered energy metabolism, excessive oxidative stress, and suppressed biofilm formation and virulence. In mice, NP(FCPS-P)+US exhibits a 99.3% bactericidal rate in Pseudomonas aeruginosa-induced sublethal pneumonia and renders a 90% animal survival rate in lethal pneumonia, and additionally immunological staining and transcriptomics analyses reveal that NP(FCPS-P)+US induces inhibited inflammatory response and accelerated lung injury repair. Taken together, NP(FCPS-P)+US is a promising antibiotics-alternative strategy for treating deeply seated bacterial infections.