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Paper detail

Light-emitting diode excitation for upconversion microscopy: a quantitative assessment

Lanthanide-based upconversion nanoparticles (UCNPs) generally require high power laser excitation. Here we report wide-field upconversion microscopy at single-nanoparticle sensitivity using incoherent excitation of a 970-nm light-emitting diode (LED). We show that due to its broad emission spectrum, LED excitation is about 3 times less effective for UCNPs and generates high background compared to laser illumination. To counter this, we use time-gated luminescence detection to eliminate the residual background from the LED source, so that individual UCNPs with high sensitizer (Yb3+) doping and inert shell protection become clearly identified under LED excitation at 1.18 W cm-2, as confirmed by correlated electron microscopy images. Hydrophilic UCNPs are obtained by polysaccharide coating via a facile ligand exchange protocol to demonstrate imaging of cellular uptake using LED excitation. These results suggest a viable approach to bypassing the limitations associated with high-power lasers when applying UCNPs and upconversion microscopy to life science research.

preprint2020arXivOpen access
Yueying CaoXianlin ZhengSimone De CamillisBingyang ShiJames A. PiperNicolle H. PackerYiqing Lu
physics.app-phBiological Physicsphysics.optics
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Yueying CaoXianlin ZhengSimone De CamillisBingyang ShiJames A. PiperNicolle H. PackerYiqing Lu

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