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Control of the fluorescence lifetime in dye based nanoparticles

Stine G. Stenspil, Junsheng Chen, Mikkel Baldtzer Liisberg, Amar H. Flood, Bo W. Laursen

2024Chemical Science27 citationsDOIOpen Access PDF

Abstract

Fluorescent dye based nanoparticles (NPs) have received increased interest due to their high brightness and stability. In fluorescence microscopy and assays, high signal to background ratios and multiple channels of detection are highly coveted. To this end, time-resolved imaging offers suppression of background and temporal separation of spectrally overlapping signals. Although dye based NPs and time-resolved imaging are widely used individually, the combination of the two is uncommon. This is likely due to that dye based NPs in general display shortened and non-mono-exponential lifetimes. The lower quality of the lifetime signal from dyes in NPs is caused by aggregation caused quenching (ACQ) and energy migration to dark states in NPs. Here, we report a solution to this problem by the use of the small-molecule ionic isolation lattices (SMILES) concept to prevent ACQ. Additionally, incorporation of FRET pairs of dyes locks the exciton on the FRET acceptor providing control of the fluorescence lifetime. We demonstrate how SMILES NPs with a few percent rhodamine and diazaoxatriangulenium FRET acceptors imbedded with a cyanine donor dye give identical emission spectra and high quantum yields but very different fluorescence lifetimes of 3 ns and 26 ns, respectively. The two spectrally identical NPs are easily distinguished at the single particle level in fluorescence lifetime imaging. The doping approach for dye based NPs provides predictable fluorescence lifetimes and allows for these bright imaging reagents to be used in time-resolved imaging detection modalities.

Topics & Concepts

FluorescenceFörster resonance energy transferCyaninePhotochemistryFluorescence in the life sciencesRhodamineQuenching (fluorescence)Fluorescence-lifetime imaging microscopyRhodamine BNanoparticleChemistryFluorophoreExcitonTime-resolved spectroscopyMaterials scienceNanotechnologyOpticsPhotocatalysisQuantum mechanicsCatalysisPhysicsBiochemistryLuminescence and Fluorescent MaterialsLanthanide and Transition Metal ComplexesMolecular Sensors and Ion Detection
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