FRET-Modulated Multihybrid Nanoparticles for Brightness-Equalized Single-Wavelength Barcoding
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Chen, Chi
Corry, Ben
Huang, Liang
Hildebrandt, Niko
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American Chemical Society
Abstract
Semiconductor quantum dots (QDs) are the
most versatile fluorophores for Förster resonance energy
transfer (FRET) because they can function as both donors and
acceptors for a multitude of fluorophores. However, a
complete understanding of multidonor−multiacceptor FRET
networks on QDs and their full employment into advanced
fluorescence sensing and imaging have not been accomplished.
Here, we provide a holistic photophysical analysis of such
multidonor-QD-multiacceptor FRET systems using timeresolved
and steady-state photoluminescence (PL) spectroscopy
and Monte Carlo simulations. Multiple terbium complex
(Tb) donors (1−191 units) and Cy5.5 dye acceptors (1−60 units) were attached to a central QD, and the entire range of
combinations of FRET pathways was investigated by Tb, QD, and Cy5.5 PL. Experimental and simulation results were in
excellent agreement and could disentangle the distinct contributions of hetero-FRET, homo-FRET, and dye dimerization. The
FRET efficiency was independent of the number of Tb donors and dependent on the number of Cy5.5 acceptors, which could
be used to independently adapt the PL intensity by the number of Tb donors and the PL lifetime by the number of Cy5.5
acceptors. We used this unique tuning capability to prepare Tb-QD-Cy5.5 conjugates with distinct QD PL lifetimes but similar
QD PL intensities. These brightness-equalized multihybrid FRET nanoparticles were applied to optical barcoding via three
time-gated PL intensity detection windows, which resulted in simple RGB ratios. Direct applicability was demonstrated by an
efficient RGB distinction of different nanoparticle-encoded microbeads within the same field of view with both singlewavelength
excitation and detection on a standard fluorescence microscope.
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Journal of the American Chemical Society
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2037-12-31
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