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BACKGROUND & AIMS: Excess sucrose intake induces metabolic syndrome. In human, abnormal lipids metabolism like obesity, hyperlipidemia and fatty liver are induced. However, excess sucrose causes different phenotypes in different species. Based on our previous study, excess sucrose induced fatty liver and hyperlipidemia in rats. The phenotypes and mechanism of abnormal lipid metabolism in mice is unclear. We investigated the different phenotypes in 5 strains of mice and the relationship between gut microbiome and abnormal lipid metabolism in C57BL/6N mice. METHODS: We examined the effect of a high sucrose diet in 5 different strains of mice. Besides, to find out the relationship between gut microbiome and metabolic disorder induced by excess sucrose, C57BL/6N mice were fed with a high sucrose diet with or without antibiotics cocktail. RESULTS: A high sucrose diet induced obesity and fatty liver in inbred mice, whereas did not induce hyperlipidemia in all strains of mice. Moreover, a high sucrose diet changed the composition of gut microbiota in C57BL/6N mice. Antibiotics treatment alleviated the abnormal lipid metabolism induced by high sucrose diet by changing the composition of gut short chain fatty acids. CONCLUSIONS: These results indicates that the phenotypes of metabolic syndrome are influenced by genetic factors. Furthermore, the dysbiosis of gut microbiome caused by excess sucrose may contribute to the development of abnormal lipid metabolism via its metabolites.
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Nanoprecipitation, which is achieved through the diffusion and precipitation of drug molecules in blended solvent and antisolvent phases, is a classic route for constructing nanodrugs (NDs) and previously directed by diffusion-controlled theory. However, the diffusion-controlled mechanism is out of date in the recent preparation of self-delivery supramolecular NDs (SDSNDs), characterized by the construction of drug nanoparticles through supramolecular interactions in the absence of carriers and surfactants. Herein, a "reaction"-like complement, contributed from supramolecular interactions, is proposed for the preparation of naphthoquinone SDSNDs. Different from the diffusion-controlled process, the formation rate of SDSNDs via the "reaction"-like process is almost constant and highly dependent on the supramolecular interaction-determined Gibbs free energy of molecular binding. Thus, the formation rate and drug availability of SDSNDs are greatly improved by engineering the supramolecular interactions, which facilitates the preparation of SDSNDs with expected sizes, components, and therapeutic functions. As a deep understanding of supramolecular-interaction-involved nanoprecipitation, the current "reaction"-like protocol not only provides a theoretical supplement for classic nanoprecipitation but also highlights the potential of nanoprecipitation in shaping self-assembled, coassembled, and metal-ion-associated SDSNDs.
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In this study, a novel ratiometric fluorescent nanoprobe for pH monitoring has been developed by synthesizing red fluorescent Ag2S quantum dots (Ag2S QDs) and green fluorescent carbon dots (CDs) nanohybrids (Ag2S CDs) in one pot using CDs as templates. The nanoprobe exhibits dual-emission peaks at 500 and 670 nm under a single-excitation wavelength of 450 nm. The red fluorescence can be selectively quenched by increasing pH, while the green fluorescence is an internal reference. Therefore, the change of the relative fluorescence intensity (I500/I670) in the ratiometric Ag2S CDs probes can be used for pH sensing. The results revealed that I500/I670 of Ag2S CDs probes was linearly related to pH variation between pH 5.4 and 6.8. Meanwhile, the Ag2S CDs probes possessed a good reversibility along with pH changing between 5.0 and 7.0 without any interruption from common metal ions, proteins and other interferences.
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Development of novel antiviral reagents is of great importance for the control of virus spread. Here, Ag2S nanoclusters (NCs) were proved for the first time to possess highly efficient antiviral activity by using porcine epidemic diarrhea virus (PEDV) as a model of coronavirus. Analyses of virus titers showed that Ag2S NCs significantly suppressed the infection of PEDV by about 3 orders of magnitude at the noncytotoxic concentration at 12 h postinfection, which was further confirmed by the expression of viral proteins. Mechanism investigations indicated that Ag2S NCs treatment inhibits the synthesis of viral negative-strand RNA and viral budding. Ag2S NCs treatment was also found to positively regulate the generation of IFN-stimulating genes (ISGs) and the expression of proinflammation cytokines, which might prevent PEDV infection. This study suggest the novel underlying of Ag2S NCs as a promising therapeutic drug for coronavirus.