This article describes the design and synthesis of donor-bridge-acceptor-based semiconducting polymer dots (Pdots) that exhibit narrow-band emissions, ultrahigh brightness, and large Stokes shifts in the near-infrared (NIR) region. We systematically investigated the effect of π-bridges on the fluorescence quantum yields of the donor-bridge-acceptor-based Pdots. The Pdots could be excited by a 488 or 532 nm laser and have a high fluorescence quantum yield of 33% with a Stokes shift of more than 200 nm. The emission full width at half-maximum of the Pdots can be as narrow as 29 nm, about 2.5 times narrower than that of inorganic quantum dots at the same emission wavelength region. The average per-particle brightness of the Pdots is at least 3 times larger than that of the commercially available quantum dots. The excellent biocompatibility of these Pdots was demonstrated in vivo, and their specific cellular labeling capability was also approved by different cell lines. By taking advantage of the durable brightness and remarkable stability of these NIR fluorescent Pdots, we performed in vivo microangiography imaging on living zebrafish embryos and long-term tumor monitoring on mice. We anticipate these donor-bridge-acceptor-based NIR-fluorescent Pdots with narrow-band emissions to find broad use in a variety of multiplexed biological applications.
Photoluminescence (PL) of organolead
halide perovskites (OHPs)
is sensitive to OHPs’ surface conditions and is an effective
way to report surface states. Literature has reported that at the
ensemble level, the PL of photoexcited OHP nanorods declines under
an inert nitrogen (N2) atmosphere and recovers under subsequent
exposure to oxygen (O2). At the single-particle level,
we observed that OHP nanorods photoblink at rates dependent on both
the excitation intensity and the O2 concentration. Combining
the two sets of information with the charge-trapping/detrapping mechanism,
we are able to quantitatively evaluate the interaction between a single
surface defect and a single O2 molecule using a new kinetic
model. The model predicts that the photodarkening of OHP nanorods
in the N2 atmosphere has a different mechanism than conventional
PL quenching, which we call photo-knockout. This model provides fundamental
insights into the interactions of molecular O2 with OHP
materials and helps design a suitable OHP interface for a variety
of applications in photovoltaics and optoelectronics.
Super-resolution imaging of single DNA molecules via point accumulation for imaging in nanoscale topography (PAINT) has great potential to visualize fine DNA structures with nanometer resolution. In a typical PAINT video acquisition, dye molecules (YOYO-1) in solution sparsely bind to the target surfaces (DNA) whose locations can be mathematically determined by fitting their fluorescent point spread function. Many YOYO-1 molecules intercalate into DNA and remain there during imaging, and most of them have to be temporarily or permanently fluorescently bleached, often stochastically, to allow for the visualization of a few fluorescent events per DNA per frame of the video. Thus, controlling the fluorescence on–off rate is important in PAINT. In this paper, we study the photobleaching of YOYO-1 and its correlation with the quality of the PAINT images. At a low excitation laser power density, the photobleaching of YOYO-1 is too slow and a minimum required power density was identified, which can be theoretically predicted with the proposed method in this report.
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