Abstract
Bimetallic silver-copper nanoparticles (AgCu NPs) exhibit enhanced antibacterial properties compared to their monometallic counterparts; however, their clinical translation is limited by poor stability and biocompatibility. Here, we unveil a bacterial incubation-driven synthesis (bacterial-enabled dynamic nanoreactor) of ultra-small AgCu NPs with dual antimicrobial-antitumor functionality. Remarkably, conventional 15 nm AgCu NPs undergo spontaneous size reduction to 2 nm upon interaction with E. coli or S. aureus, accompanied by a complete loss of surface plasmon resonance (SPR) and formation of protein-capped stable dispersions. Mechanistic studies reveal this bacterially triggered transformation involves Ag(+) release via oxidative dissolution in saline environments, followed by PVP/PVA and bacterial biomolecule-mediated re-nucleation. The US-AgCu NPs demonstrate synergistic therapeutic advantages: Enhanced antibacterial potency compared to parent NPs; pH-selective cytotoxicity; Reusable antimicrobial performance over multiple cycles with minimal resistance development; Long-term stability. This bio-derived strategy achieves kilogram-scale production of therapeutic NPs via continuous fermentation, addressing critical challenges in nanomaterial manufacturing for combating antimicrobial resistance and malignancies.