PNNL

Abstract

Near-infrared persistent luminescence nanoparticles (PLNPs) possess unique near-infrared persistent luminescence properties. They have recently been emerging as important materials for a wide variety of applications in chemistry and biology. Yet, they must endure high-temperature solid-state annealing reactions and subsequent complicated physical post-treatments. Herein, we report on a first direct aqueous-phase chemical synthesis route of NIR PLNPs and present their enhanced in vivo renewable near-infrared persistent luminescence. Our method leads to monodisperse PL nanoparticles as small as ca. 8 nm. More importantly, such sub-10 nm nanocrystals are readily dispersed, functionalized as well as form stable colloidal solutions in aqueous solution and cell culture medium for biological applications. Under bio-tissue penetrable red-light excitation, we found that such nanocrystals possess superior renewable PL photoluminescence in vitro and in vivo than current larger counterparts made by existing methods. We believe that this solid-state-reaction-free chemical approach overcomes the current key roadblock in regard to PLNP development, and thus will pave the way to broad use of these advanced miniature “luminous pearls” in photonics and biophotonics.