Analysis of chemical constituents of Ginseng-Douchi compound fermentation products based on UPLC-Q-TOF-MS / 中国中药杂志

In this experiment, ultra high performance liquid chromatography-quadrupole time-of-flight mass spectrometry(UPLC-Q-TOF-MS) was used to analyze and identify chemical constituents of Ginseng-Douchi(GD) compound fermentation, and explore the conversion rules of ginsenosides and soybean isoflavones after compound fermentation. Waters Acquity UPLC BEH C_(18) column(2.1 mm×100 mm, 1.7 μm) was adopted, with 0.1% formic acid aqueous solution(A)-0.1% formic acid acetonitrile solution(B) as mobile phase for gradient elution; electrospray ion source(ESI) was used to collect data in positive and negative ion modes; according to the exact mass number, the secondary spectrum comparison of the database and the existing literature reports, Peakview 2.0/masterview 1.0 software was used to determine the common ion structure formula. Finally, a total of 133 chemical constituents were analyzed and identified from the GD. Ginseng saponins and isoflavone glycosides were significantly converted after fermentation. Among them, peak areas of prototype ginsenosides Rk_3, Rh_1, Rh_2, Rh_3, daidzin, glycitin and genistin decreased significantly; whereas peak areas of se-condary ginsenoside Rb_1, Rb_2, Rk_1, glycitein, genistein and daidzein increased significantly. In this experiment, liquid-mass spectrometry technique was used to investigate the conversion of active ingredients of GD compound fermented products after co-fermentation, so as to provide a scientific basis for elucidating pharmacodynamics material basis and quality control.

Analysis and evaluation of chemically induced artificial agarwood / 中国中药杂志

In this study,the content of ethanol extraction of agarwood were performed following the method of Chinese Pharmacopoeia(ChP 2015 edition). The chromatographic fingerprints were established by GC-MS. Similarity Evaluation System for Chromatographic Fingerprint of traditional Chinese medicine（TCM）(version 2012) was employed to calculate the similarity of each chromatogram of agarwood. The ratios of sum peak area in the range of 170-270 min and 0-100 min of individual chromatogram were calculated using square peaks to normalization. AMDIS and RI were employed to identify the common and different peaks. Correlation coefficient P(corr) combined with Variable important in projection(VIP) value was employed to screen the different representative components based on OPLS-DA analysis. Grey related degree and TOPSIS were used to evaluate the quality of artificial agarwoods. The results showed that more than 10.0% of the ethanol extract content was found in 15 batches of artificial agarwoods among the total 18. The similarity of 18 batches artificial agarwoods was 0.439-0.779. The peak area ratios of two intervals were in the range of 0.307-13.254. The 9 common components and 8 different components were identified. Meanwhile, 2% salicylic acid is the best inducer based on grey related degree and TOPSIS. Grey related degree and TOPSIS can be used to evaluate the quality of artificial agarwoods rapidly. These results provide a reference data to evaluate the qualityof artificial agarwood.

Protective effect of SNMC on mice with fulminant liver failure / 中华肝脏病杂志

<p><b>OBJECTIVE</b>To investigate the protective effect of stronger neo-minophagen C (SNMC) on fulminant liver failure (FLF).</p><p><b>METHODS</b>D-Gal N and LPS were injected once into the abdominal cavity of rats to establish an experimental model of FLF. The level of plasma ALT, Alb, TBil, TNFalpha, NO, ET-1, IL-6 and liver histopathology of the rats were examined.</p><p><b>RESULTS</b>In the D-Gal N and LPS model of FLF, there was an obvious decline of plasma TNFalpha (F = 52.84), NO (F = 15.81), ET-1 (F = 15.68), IL-6 (F = 15.32) and there was less hepatic tissue damage in SNMC-treated groups using different doses (high dose, medium dose, low dose) and at different times (pre-protection, simultaneous protection, post-protection) compared with those not treated with SNMC. These results indicated that SNMC could be used to treat FLF. It was better to use a low dose of SNMC and use it at the same time as inducing the FLF. There were no differences in the results of those treated with SNMC of different dosages and treated at different times.</p><p><b>CONCLUSION</b>SNMC can decrease the mortality of FLF by preventing hepatocyte apoptosis induced by D-Gal N and LPS and inhibit liver inflammation caused by all kinds of factors.</p>