posted on 2016-01-23, 00:00authored byJing-Ya Zhao, Gang Chen, Yi-Ping Gu, Ran Cui, Zhi-Ling Zhang, Zi-Li Yu, Bo Tang, Yi-Fang Zhao, Dai-Wen Pang
Cell-derived
microvesicles (MVs) are natural carriers that can
transport biological molecules between cells, which are expected to
be promising delivery vehicles for therapeutic purposes. Strategies
to label MVs are very important for investigation and application
of MVs. Herein, ultrasmall Mn-magnetofunctionalized Ag2Se quantum dots (Ag2Se@Mn QDs) integrated with excellent
near-infrared (NIR) fluorescence and magnetic resonance (MR) imaging
capabilities have been developed for instant efficient labeling of
MVs for their in vivo high-resolution dual-mode tracking. The Ag2Se@Mn QDs were fabricated by controlling the reaction of Mn2+ with the Ag2Se nanocrystals having been pretreated
in 80 °C NaOH solution, with an ultrasmall size of ca. 1.8 nm,
water dispersibility, high NIR fluorescence quantum yield of 13.2%,
and high longitudinal relaxivity of 12.87 mM–1 s–1 (almost four times that of the commercial contrast
agent Gd-DTPA). The ultrasmall size of the Ag2Se@Mn QDs
enables them to be directly and efficiently loaded into MVs by electroporation,
instantly and reliably conferring both NIR fluorescence and MR traceability
on MVs. Our method for labeling MVs of different origins is universal
and free of unfavorable influence on intrinsic behaviors of MVs. The
complementary imaging capabilities of the Ag2Se@Mn QDs
have made the long-term noninvasive whole-body high-resolution dual-mode
tracking of MVs in vivo realized, by which the dynamic biodistribution
of MVs has been revealed in a real-time and in situ quantitative manner.
This work not only opens a new window for labeling with QDs, but also
facilitates greatly the investigation and application of MVs.