%0 Journal Article
%T High-sensitivity imaging of time-domain near-infrared light transducer
%J -
%D 2019
%R https://doi.org/10.1038/s41566-019-0437-z
%X The optically transparent biological window in the near-infrared (NIR) spectral range allows deep-tissue excitation and the detection of fluorescence signals1,2. Spectrum-domain discrimination of NIR contrast agents via an upconversion or downshifting scheme requires sufficient (anti-) Stokes shift to separate excitation and fluorescence emission. Here, we report a time-domain (¦Ó) scheme in which >5,000 ytterbium signal transducers are condensed within an optically inert and biocompatible CaF2 shell (2.3£¿nm), which forms a 14.5£¿nm ¦Ó-dot. Because of the long-lived and spectrally narrowly defined excited state of pure ytterbium ions, the NIR ¦Ó-dot can convert the NIR pulsed excitation into long-decaying luminescence with an efficiency approaching 100%. Within a safe injection dosage of 13£¿¦Ìg£¿g£¿1, an excitation power density of 1.1£¿mW£¿cm£¿2 was sufficient to image organs with a signal-to-noise ratio of >9. The high brightness of ¦Ó-dots further allows long-term in vivo passive targeting and dynamic tracking in a tumour-bearing mouse model
%U https://www.nature.com/articles/s41566-019-0437-z