Sequential detection of inflammation-related hypochlorite ions and viscosity with a relay fluorescent probe.

Based on the correlation between inflammation and reactive oxygen species and viscosity, a fluorescent probe (SWJT-19) was designed for a relay detection of hypochlorite ions and viscosity. The synthesized probe could quickly and selectively detect hypochlorite ions, as well as viscosity of the system effectively. Moreover, the probe had been successfully applied to sequentially detect hypochlorite ions and viscosity in organisms, as well as imaging in mouse inflammation.

A lysosome-targetable fluorescent probe for the ratiometric detection of formaldehyde in living cells and in vivo.

Inspired by the synthetic method of benzoxazine derivatives and our previous research, a fluorescent probe (SWJT-6) was designed for formaldehyde (FA) detection based on the cyclization reaction. The synthetic SWJT-6 showed excellent colorimetric and ratiometric response to formaldehyde, and could be perfectly used as test strips to detect formaldehyde. It also showed a fast detection time (3 min), low detection limit (5.65 µM) and high selectivity for formaldehyde within various interfering analytes. In addition, SWJT-6 has been successfully applied in bioimaging of intracellular and lysosomal formaldehyde in both HeLa cells and zebrafish.

A Near-Infrared Colorimetric Fluorescent Probe for Ferrous Ion Detection and Imaging.

Based on the N-redox mechanism, a turn-on near-infrared fluorescence probe (SWJT-15) with cyano isophorone as skeleton was designed and synthesized for the detection of ferrous ions (Fe2+). The probe has a lower detection limit (83 nM) and fast response (200 s) to Fe2+ ions. And the probe has unique selectivity and good anti-interference performance against Fe2+ ions compared to other metal ions. Moreover, the probe has been successfully applied to imaging Fe2+ ions in HeLa cells.

A red-NIR fluorescent probe for rapid and visual detection of acrolein.

A novel red-NIR probe (SWJT-8) for detecting acrolein by utilizing the Michael addition reaction was developed. SWJT-8 exhibits a series of unique advantages, such as colorimetric discrimination, high selectivity and the fastest response. And this probe has been successfully applied to the detection of intracellular acrolein.