A water-soluble fluorescent organic nano-photosensitizer for the ratiometric detection of mitochondrial G-quadruplexes with photodynamic therapy potential.

We report a water-soluble AIEgen (TPAL) that can self-assemble into fluorescent organic nanoparticles for the ratiometric detection of mitochondrial DNA (mtDNA) parallel G-quadruplexes (G4s) with high selectivity, a low detection limit and photodynamic therapy (PDT) potential.

Design and assembly of AIE-active fluorescent organic nanoparticles for anti-counterfeiting fluorescent hydrogels and inks.

Two kinds of AIE-active fluorescent organic nanoparticles were designed and constructed as anti-counterfeiting photoresponsive materials. One is fluorescent organic nanoparticles (TPELs) based on a self-assembly strategy, which were self-assembled from novel amphiphilic tetraphenylethylene (TPE) molecules decorated with a lactose moiety and different photoresponsive tags. The other is polymeric fluorescent organic nanoparticles (F-TPEs) derived from the nanoprecipitation strategy, which utilized pluronic copolymer F127 to encapsulate hydrophobic TPEs without lactosyl modifications. Upon UV light irradiation, these AIE-active materials exhibit different photooxidation behaviors in an aqueous solution to give cyan, orange and green fluorescence emissions, and they were successfully used as an anti-counterfeiting fluorescent hydrogel and ink.

Dual functional amphiphilic sugar-coated AIE-active fluorescent organic nanoparticles for the monitoring and inhibition of insulin amyloid fibrillation based on carbohydrate-protein interactions.

Amyloid-related diseases, such as Alzheimer's disease, are all considered to be related to the deposition of amyloid fibrils in the body. Insulin is a protein hormone that easily undergoes aggregation and fibrillation to form more toxic amyloid-like fibrils. So far, it is still challenging to develop a new protocol to study the ex situ detection and in situ inhibition of amyloid fibrillation. Here, we reported a modular synthetic strategy to construct nine amphiphilic sugar-coated AIE-active fluorescent organic nanoparticles (FONs, TPE2/3/4X, X = G, M or S) with glucosamine (G), mannose (M) or sialic acid (S) as a hydrophilic moiety and tetraphenylethylene (TPE) as a hydrophobic AIE core. The carbohydrate-protein interactions between insulin and TPE2/3/4X were investigated by fluorescence spectroscopy, circular dichroism spectroscopy and transmission electron microscopy. Among the nine FON AIEgens, TPE2G was screened out as the best dual functional FON for the ex situ detection and in situ inhibition of the insulin fibrillation process, indicating that the glycosyl moiety exhibited a crucial effect on the detection/inhibition of insulin fibrillation. The molecular dynamics simulation results showed that the binding mechanism between TPE2G and native insulin was through weak interactions dominated by van der Waals interactions and supplemented by hydrogen bonding interactions to stabilize an α-helix of the insulin A chain, thereby inhibiting the insulin fibrillation process. This work provides a powerful protocol for the further research of amyloid-related diseases based on carbohydrate-protein interactions.

Water-soluble AIE-active fluorescent organic nanoparticles for ratiometric detection of SO2 in the mitochondria of living cells.

We report a water-soluble AIEgen (TYDL) to be self-assembled into fluorescent organic nanoparticles (TYDLs) for specific sensing of SO2 in living hepatoma cells. It is demonstrated that the TYDLs were suitable for ratiometrically detecting endogenous and exogenous SO2 in mitochondria with good selectivity, low detection limit (75 nM) and excellent photostability (>30 min). These findings imply the great potential applications of TYDLs for the diagnosis of SO2-related diseases in cell biology.

[Laser ablation and fast pulse discharge plasma spectroscopy analysis of Sn in soil].

A developing technique, laser ablation and fast pulse discharge plasma spectroscopy technique (LA-FPDPS), was used for the first time to analyze the Sn concentration in soil. The peak intensity of Sn (284.0 nm) line from soil plasma emission was greatly enhanced in comparison with using the traditional single pulse (SP) LIBS system. Using the technique, calibration curve of Sn in soil was derived. The limit of detection (LOD) for Sn in soil was reduced to be 0.16 microg x g(-1). The value is significantly improved compared with the results reported in literature when using LIBS technique, which usually was between 8.2 to 54 microg x g(-1) depending on the experimental condition, indicating that this technique possibly will be useful for rapid quantitative elemental analysis in soil.