Hybrid Nanoparticle Platform for Nanoscale Scintillation Proximity Assay.

Reference
Janczak CM, Calderon IAC, Noviana E, Hadvani P, Lee JR, Aspinwall CA. 2019. Hybrid Nanoparticle Platform for Nanoscale Scintillation Proximity Assay. ACS Appl Nano Mater. 2:1259–1266. doi:10.1021/acsanm.8b02136.
Abstract

β-particle emitting radionuclides, such as H, C, P, P, and S, are important molecular labels due to their small size and the prevalence of these atoms in biomolecules but are challenging to selectively detect and quantify within aqueous biological samples and systems. Here, we present a core-shell nanoparticle-based scintillation proximity assay platform (nanoSPA) for the separation-free, selective detection of radiolabeled analytes. nanoSPA is prepared by incorporating scintillant fluorophores into polystyrene core particles and encapsulating the scintillant-doped cores within functionalized silica shells. The functionalized surface enables covalent attachment of specific binding moieties such as small molecules, proteins, or DNA that can be used for analyte-specific detection. nanoSPA was demonstrated for detection of H-labeled analytes, the most difficult biologically relevant β-emitter to measure due to the low energy β-particle emission, using three model assays that represent covalent and non-covalent binding systems that necessitate selectivity over competing H-labeled species. In each model, nmol quantities of target were detected directly in aqueous solution without separation from unbound H-labeled analyte. The nanoSPA platform facilitated measurement of H-labeled analytes directly in bulk aqueous samples without surfactants or other agents used to aid particle dispersal. Selectivity for bound H-analytes over unbound H analytes was enhanced up to 30-fold when the labeled species was covalently bound to nanoSPA, and 4- and 8-fold for two non-covalent binding assays using nanoSPA. The small size and enhanced selectivity of nanoSPA should enable new applications compared to the commonly used microSPA platform, including the potential for separation-free, analyte-specific cellular or intracellular detection.