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OBJECTIVE To explore the protective mechanism of amifostine on acute radiation injury mice. METHODS Thirty C57BL/6J mice were randomly divided into normal control group, model group and amifostine group (150 mg/kg), with 10 mice in each group. Thirty minutes before irradiation, the mice in the amifostine group were intraperitoneally injected with amifostine; normal control group and model group were given constant volume of normal saline intraperitoneally; then acute radiation injury was induced by 4 Gy X-ray radiation in both model group and amifostine group. The white blood cell count (WBC), platelet count and red blood cell (RBC) count in mice were detected 2 hours before irradiation and on days 1, 4, 7, 10 and 14 after irradiation; the changes in the proportion of WBC (neutrophils, lymphocytes and monocytes) on the 7th day after irradiation were analyzed. The 16S rRNA high-throughput sequencing was used to analyze the structure of gut microbiota in mice feces on the 7th day after irradiation, then its correlation with WBC was analyzed. RESULTS The counts of WBC on the 1st, 4th, 7th and 10th day after irradiation, platelet count on the 10th day after irradiation and RBC count on the 1st day after irradiation in the amifostine group were significantly higher than those in model group (P<0.05). Compared with normal control group,β diversity of gut microbiome showed significant change, relative abundance of Firmicutes increased and that of Bacteroidetes decreased in model group. Amifostine could reverse the change in β diversity of gut microbiome, and the relative abundance of Bacteroidetes and Firmicutes. The model group consisted of four distinct species, namely Allobaculum, Erysipelotrichia, Erysipelotrichales and Erysipelotrichaceae, which were significantly negatively correlated with the proportion of peripheral blood lymphocytes (P<0.01); amifostine group consisted of two distinct species, namely Lactobacillus murinus and L. crispatus, which were significantly negatively correlated with the proportion of neutrophils (P<0.05). CONCLUSIONS Amifostine significantly improves irradiation-induced injury by regulating dysbiosis of LY201816) gut microbiota.
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OBJECTIVE To explore the mechanism of Kuaisong yin in the prevention and treatment of constipation. METHODS Slow transit constipation (STC) model was established with Compound difenoxylate tablet in mice and rats. Two batches of mice were divided into blank group, model group, positive control group (Maren soft capsule, 0.64 g/kg), Kuaisong yin low-dose, medium-dose and high-dose groups (3.2, 6.4, 12.8 g/kg), with 10 mice in each group. The effect of Kuaisong yin on constipation in mice was evaluated by intestinal propulsion experiment and defecation experiment. Rats were divided into blank group, model group, positive control group (Maren soft capsule,0.36 g/kg), Kuaisong yin low-dose and high-dose groups (2.4, 4.8 g/kg), with 7 or 8 rats in each group. They were given relevant medicine once a day for 1 week. The metabonomics of serum and urine of rats were analyzed by UPLC-Q-TOF-MS/MS technology. RESULTS Compared with model group, the ink propulsion rate and 5 h defecation volume of mice in Kuaisong yin high-dose group were significantly increased (P<0.05); the first defecation time of mice in Kuaisong yin medium-dose and high-dose groups was significantly shortened, and the quality of defecation was significantly reduced within 5 h (P<0.05 or P<0.01). Serum metabonomics screened 16 compounds (such as proline, propionylcarnitine, hemolytic phosphatidylcholine, etc.) and 6 metabolic pathways (such as sphingomyelin metabolism, arginine and proline metabolism, sphingolipid biosynthesis-lactose and neolactone series). Urine metabonomics screened 20 different metabolites (such as prostaglandin A2, L-valine, phosphatidylcholine, sphingomyelin, etc.) and 8 metabolic pathways (such as valine, leucine and isoleucine biosynthesis, sphingomyelin metabolism, pyruvate metabolism, etc.). CONCLUSIONS Kuaisong yin can play a role in improving constipation by regulating different metabolites such as hemolytic phosphatidylcholine, phosphatidylcholine, prostaglandin A2, L-valine, proline, and regulating metabolic pathways such as multiple amino acid metabolism, sphingomyelin metabolism, etc.
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OBJECTIVE To study the mechanism of Compound zaoren granule in improving insomnia. METHODS Forty-nine mice were divided into blank group, model group, positive control group 1 (Estazolam tablets 0.5 mg/kg),control group 2 (Shumian capsule 0.6 g/kg), Compound zaoren granule low-dose, medium-dose and high-dose groups (2.5, 5, 10 g/kg), with 7 mice in each group. The insomnia model was established by chronic unpredictable mild stress combined with 4-chloro-DL- phenylacetic acid. The behavioral changes of mice were investigated through open field test and pentobarbital sodium synergistic hypnosis experiment, as well as the pathomorphology of mice hypothalamus tissue was observed by HE staining. The metabonomics analysis and multivariate statistical analysis of serum in mice were performed by UHPLC-Q-TOF-MS/MS, and the differential metabolites were screened out; the metabolic pathway analysis was conducted based on MetaboAnalyst 5.0 database. RESULTS Compared with blank group, the total travelling distance, the number of entering the central region and the moving distance in the central region of the model group were significantly reduced (P<0.05), the proportion of total rest time was significantly increased (P<0.05), the sleep duration of mice was significantly shortened (P<0.05), and hypothalamic nerve cells damaged and severely vacuolated. Compared with model group, the total travelling distance of Compound zaoren granule low-dose and medium-dose groups were increased significantly and the proportions of total rest time of those groups were decreased significantly (P<0.05), and the sleep duration of mice in Compound zaoren granule high-dose group was prolonged significantly (P<0.05); the hypothalamic nerve cells of mice in each administration group recovered to varying degrees, and the hypothalamus histiocytes of mice in the Compound zaoren granules high-dose group were closer to those in the blank group. A total of 18 differential metabolites (such as phenylalanine, taurine, norvaline, methionine) and 4 important amino acid metabolic pathways (L-phenylalanine, tyrosine and tryptophan biosynthesis; taurine and hypotaurine metabolism; L-phenylalanine metabolism; cysteine and methionine metabolism) were identified through metabolomics analysis. CONCLUSIONS Compound zaoren granules can normalize the disordered metabolism in vivo by regulating differential metabolites such as phenylalanine, taurine, and four amino acid metabolic pathways, so as to improve insomnia.
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OBJECTIVE:To establish a method for content determination of steroidal saponin in Allium sativum. METHODS:Pre-column derivatization of steroidal saponin was performed by using the derivatization agent of nitro-benzoic acid-chlorine. And HPLC was conducted to determine the content of steroidal saponin. The column was Shimadzu VP-ODS with mobile phase of aceto-nitrile-water mixed solution(80:20,V/V)at a flow rate of 1.0 ml/min,the detection wavelength was 254 nm,the column temper-ature was 25 ℃,and the injection volume of 20 μl. RESULTS:The linear rang of sarsasapogenin was 0-1.25 mg/ml(r=0.999 0);RSDs of precision,stability and reproducibility tests were lower than 2%;recovery was 93.1%-96.8%(RSD=1.56%,n=6). CON-CLUSIONS:The method is simple,stable with good separation,and can be use for the content determination of steroidal saponin in A. sativum.