Photoactive Red Fluorescent SiO 2 Nanoparticles Based on Controlled Methylene Blue Aggregation in Reverse Microemulsions.

We present a reverse microemulsion synthesis procedure for incorporating methylene blue (MB), a known FDA-approved type-II red-absorbing photosensitizer and 1 O 2 generator, into the matrix of hydrophobic-core/hydrophilic-shell SiO 2 nanoparticles. Different synthesis conditions were explored with the aim of controlling the entrapped-dye aggregation at high dye loadings in the hydrophobic protective core; minimizing dye aggregation ensured highly efficient photoactive nanoentities for 1 O 2 production. Monitoring the synthesis in real time using UV-vis absorption allowed tracking of the dye aggregation process. In particular, silica nanoparticles (MB@SiO 2 NPs) of ∼50 nm diameter size with a high local entrapped-MB concentration (∼10 -2 M, 1000 MB molecules per NP) and a moderate proportion of dye aggregation were obtained. The as-prepared MB@SiO 2 NPs showed a high singlet oxygen photogeneration efficiency (Φ Δ = 0.30 ± 0.05), and they can be also considered as red fluorescent probes (Φ F ∼ 0.02, λ max ∼ 650 nm). The distinctive photophysical and photochemical characteristics of the synthesized NPs reveal that the reverse microemulsion synthesis procedure offers an interesting strategy for the development of complex theranostic nano-objects for photodynamic therapy.