Abstract

Plasmonic nanoparticles can strongly interact with adjacent photosensitizer molecules, resulting in a significant alteration of their singlet oxygen (¹O₂) production. In this work, we report the next generation of metal-enhanced ¹O₂ nanoplatforms exploiting the lightning rod effect, or plasmon hot spots, in anisotropic (nonspherical) metal nanoparticles. We describe the synthesis of Rose Bengal-decorated silica-coated silver nanocubes (Ag@SiO₂-RB NCs) with silica shell thicknesses ranging from 5 to 50 nm based on an optimized protocol yielding highly homogeneous Ag NCs. Steady-state and time-resolved ¹O₂ measurements demonstrate not only the silica shell thickness dependence on the metal-enhanced ¹O₂ production phenomenon but also the superiority of this next generation of nanoplatforms. A maximum enhancement of ¹O₂ of approximately 12-fold is observed with a 10 nm silica shell, which is among the largest ¹O₂ production metal enhancement factors ever reported for a colloidal suspension of nanoparticles. Finally, the Ag@SiO₂-RB NCs were benchmarked against the Ag@SiO₂-RB nanospheres previously reported by our group, and the superior ¹O₂ production of Ag@SiO₂-RB NCs resulted in improved antimicrobial activities in photodynamic inactivation experiments using both Gram-positive and -negative bacteria model strains.