New synthetic approaches toward OCF3-containing compounds.

Fluorinated organic compounds are an important class of organic molecules and play a key role in both academic and industrial communities due to the unique nature of fluorine. Among the fluorine-containing functional groups, the OCF3 group is of vital importance because of its favorable physicochemical properties, so it frequently acts as the pivotal skeletal motif in a broad spectrum of pharmaceutical molecules, agrochemicals, natural products, and materials. Over the past few decades, a wider range of strategies for the efficient, versatile, and practical synthesis of trifluoromethoxylated compounds have been the focus of a number of research initiatives. These synthesis approaches are especially fascinating in the context of the design of agrochemicals and new drugs as established pathways for installing the OCF3 moiety. In this review, the state of the art of the synthesis of OCF3-containing compounds is summarized. It can be segmented into six categories: (1) de novo formation of the OCF3 group; (2) construction of trifluoromethoxylated compounds via trifluoromethylation of the corresponding alcohol or phenol; (3) construction of trifluoromethoxylated compounds via installing the entire OCF3 group straightaway onto a complex molecule; (4) visible-light-induced trifluoromethoxylation; (5) transition metal-catalyzed trifluoromethoxylation; and (6) construction of the trifluoromethoxylated compounds via rearrangement reactions.

Biodistribution and Toxicological Effects of Ultra-Small Pt Nanoparticles Deposited on Au Nanorods (Au@Pt NRs) in Mice with Intravenous Injection.

Purpose: Pt-based nanostructures are one of the promising nanomaterials for being used in catalysts, sensors, and therapeutics. However, their impacts on the health and biological systems are not adequately understood yet. Methods: In this work, nanorods composed of ultrasmall platinum (Pt) nanoparticles deposited on the surface and gold nanorod as the core (Au@Pt NRs) were synthesized, and the distribution and toxic effects of Au@Pt NRs were investigated in C57BL/6 mice with intravenous injection by using atomic absorption spectroscopy (AAS), transmission electron microscope (TEM), hematoxylin-eosin (HE) staining and blood cell analyzer. Results: At the time point of Day 1, Day 8 and Day 16 post injection of Au@Pt NRs (6 mg/kg of Pt atom), Au@Pt NRs were mainly accumulated in the liver and spleen. The energy dispersive spectrometer mapping images showed Au@Pt NRs experienced quick corrosion and Au released faster than Pt in the physiological environments. The catalase (CAT) activity in tissues increased slightly in the early stage of the Au@Pt NRs exposure and went down to the normal level. With HE staining, inflammatory cells infiltration could be seen in the tissues, while no significant influences were detected on the blood biochemistry and the function of liver and kidney. Conclusion: In conclusion, intravenously injected Au@Pt NRs mainly distributed in the liver and spleen with comparable levels, and did not exert any significant toxic effects on the organs' function within two weeks; meanwhile, Au@Pt NRs were able to degrade, which indicated acceptable safety to the mice and potentials of biomedical application.

Enhancing the kinetics of vanadium oxides via conducting polymer and metal ions co-intercalation for high-performance aqueous zinc-ions batteries.

Aqueous zinc-ions batteries with low cost, reliable safety, high theoretical specific capacity and eco-friendliness have captured conspicuous attention in large-scale energy storage. However, the developed cathodes often suffer from low electrical conductivity and sluggish Zn2+ diffusion kinetics, which severely hampers the development of aqueous zinc-ions batteries. Herein, we successfully prepare Mg/PANI/V2O5•nH2O (MPVO) nanosheets through conducting polymers (polyaniline) and metal ions (Mg2+) co-intercalated strategy and systematically explore its electrochemical performance as cathode materials for aqueous zinc-ion batteries. Benefitting from the synergistic effect of polyaniline and Mg2+ co-intercalated, the MPVO exhibits larger interlayer spacing and higher electrical conductivity than the single guest intercalation, which significantly enhances the electrochemical kinetics. As a consequence, the MPVO cathodes deliver superior specific capacity, rate capability and long-term cycling performance. Moreover, multiple characterizations and theoretical calculations are executed to expound the relevant mechanism.Therefore, this work provides a novel thought for the design of high-performance cathode materials for aqueous ZIBs.

Effective RNAi in leukemia cells is enhanced by spermine-modified pullulan combined with desloratadine.

RNA interference is a very useful tool for clinical treatment as well as mechanistic studies of leukemia. However, leukemia cells are known as hard-to-transfected by non-virus carriers. The low capacity of endocytosis and lysosomal escape of synthetic carriers are two obstacles for successful RNAi in leukemia cells. In this work, we established a universal powerful strategy for mediating effective RNAi in different types of leukemia cells by sequentially using spermine-modified pullulan (PS) as siRNA carrier and desloratadine (DL) to promote the lysosomal escape. It was shown that the complex of PS and siRNA could be largely internalized by human T-cell acute lymphoblastic leukemia cells, acute myeloid leukemia cells and chronic myeloid leukemia cells in serum-containing media, and the internalized complex was able to escape from the lysosomes by the aid of DL, resulting in effective RNAi against the key genes for the different leukemia cells.