Correlation study on non-volatile ingredients of Menthae Haplocalycis Herba formula granules and traditional herbal pieces by UPLC-MS/MS / 中国中药杂志

To establish the method for determining non-volatile ingredients of neochlorogenic acid, chlorogenic acid, cryptochlorogenic acid, caffeic acid, isochlorogenic acid A, rosmarinic acid, ferulic acid, rutin, luteoloside, isoquercitrin, hesperidin, diosmin, diosmetin, luteolin, acacetin and linarin in Menthae Haplocalycis Herba formula granules and traditional herbal pieces by UPLC-MS/MS, and analyze the correlation of non-volatile ingredients in Menthae Haplocalycis Herba formula granules and traditional herbal pieces. Shim-pack GIST C_(18) column(2.1 mm×100 mm, 2 μm) was adopted with acetonitrile-0.1% formic acid aqueous solution as the mobile phase for gradient elution at the flow rate of 0.4 mL·min~(-1). The column temperature was set at 35 ℃. The quantitative analysis was performed using the electrospray ionization source and the multiple reaction monitoring. The linear relationship, resolution, repeatability and recovery of the 16 chemical components all met the requirements. The 16 non-volatile ingredients in traditional herbal pieces of Menthae Haplocalycis Herba could be tracked in formula granules. There were certain differences of the 16 chemical components among Menthae Haplocalycis Herba formula granules of different manufacturers and traditional herbal pieces of different producing areas. The UPLC-MS/MS method was simple, rapid and accurate, and could be used for the quality control of non-volatile ingredients in Menthae Haplocalycis Herba formula granules and traditional herbal pieces.

Wavelength switching of UPLC fingerprint and chemical pattern recognition of different medical parts of Lonicera japonica / 中草药

Objective: To study Lonicerae Japonicae Flos, Lonicerae Japonicae Caulis, and Lonicerae Japonicae Leaves by UPLC method, and study the different parts of Lonicera japonica by the fingerprint similarity evaluation, cluster analysis, principal component analysis, and other chemical pattern recognition technologies, in order to provide scientific basis for the comprehensive utilization of L. japonica. Methods: The method was carried out on an ACQUITY UPLC BEH C18 column (100 mm × 2.1 mm, 1.7 μm) by a gradient elution using acetonitrile and 0.1% phosphoric acid. The flow rate was 0.3 mL/min, The column temperature was 30 ℃. The sample room temperature was 8 ℃. The detection wavelengths were 326, 238, and 250 nm, and the injection volume was 1 μL. Results: The UPLC fingerprint of 28 batches of samples from different parts of Lonicerae Japonicae were set up and 14 common peaks were obtained. They were new chlorogenic acid, chlorogenic acid, cryptochlorogenic acid, caffeic acid, loganin, rutinum, luteoloside, isochlorogenic acid B, isochlorogenic acid A and isochlorogenic acid C. There were some differences in chemical composition and quantity of Lonicerae Japonicae Flos, Lonicerae Japonicae leaves, and Lonicerae Japonicae Caulis. PCA and cluster analysis revealed the similarity and difference of 28 batches of samples from different parts of L. japonica. Conclusion: The combination of clustering analysis and principle component analysis could be used to confirm that the chemical constituents of Lonicerae Japonicae Flos and Lonicerae Japonicae leaves were similar, but there was a difference between Lonicerae Japonicae Flos and Lonicerae Japonicae Caulis. The established fingerprint method can provide a reference for the quality control of Lonicerae Japonicae Flos, Lonicerae Japonicae leaves, and Lonicerae Japonicae Caulis.

Comparison of eleven active components in Lonicerae Japonicae Flos,Lonicerae Japonicae Caulis and leaves of Lonicero japonica by UPLC / 中国中药杂志

This present study aims to establish a UPLC method for simultaneously determining eleven components such as new chlorogenic acid,chlorogenic acid,caffeic acid,cryptochlorogenic acid,artichoke,isochlorogenic acid A,isochlorogenic acid B,isochlorogenic acid C,rutin,hibisin and loganin in Lonicerae Japonicae Flos,Lonicerae Japonicae Caulis and leaves of Lonicera japonica and comparing the differences in the contents of phenolic acids,flavonoids and iridoid glycosides of Lonicerae Japonicae Flos,Lonicerae Japonicae Caulis and leaves of Lonicera japonica.The method was carried out on an ACQUITY UPLC BEH C18column(2.1 mm×100 mm,1.7 μm) by a gradient elution using acetonitrile and 0.1% phosphoric acid.The flow rate was 0.3 mL·min-1.The column temperature was maintained at 30 ℃.The sample room temperature was 8 ℃.The wavelength was set at 326 nm for new chlorogenic acid,chlorogenic acid,caffeic acid,cryptochlorogenic acid,artichoke,isochlorogenic acid A,isochlorogenic acid B and isochlorogenic acid C,352 nm for rutin and lignin,and 238 nm for loganin.The injection volume was 1 μL.The eleven components has good resolution and was separated to baseline.Each component had a wide linear range and a good linear relationship(r≥0.999 6),the average recovery rate(n=9) was 98.96%,100.7%,97.24%,97.06%,99.53%,96.78%,98.12%,95.20%,95.12%,100.2%,98.61%and with RSD was 2.5%,1.4%,1.9%,2.1%,1.7%,1.9%,1.6%,2.0%,1.4%,2.2%,2.0%,respectively.Based on the results of the content determination,the chemometric methods such as cluster analysis and principal component analysis were used to compare the Lonicerae Japonicae Flos,Lonicerae Japonicae Caulis and leaves of Lonicera japonica.The results showed that Lonicerae Japonicae Flos and leaves of Lonicera japonica were similar in the chemical constituents,but both showed chemical constituents difference compored to Lonicerae Japonicae Caulis.The established multi-component quantitative analysis method can provide a reference for the quality control of Lonicerae Japonicae Flos,Lonicerae Japonicae Caulis and leaves of Lonicera japonica.

Applicability Study on QAMS for Multi-component Content Determination of Lonicerae Japonicae Caulis / 中国中医药信息杂志

Objective To establish a QAMS method for content determination of six compositions (chlorogenic acid, caffeic acid, cryptochlorogenin acid, isochlorogenic acid A, isochlorogenic acid C and loganin) from Lonicerae Japonicae Caulis; To verify the feasibility and applicability of this method in quality control of Lonicerae Japonicae Caulis. Methods Chlorogenic acid was set as internal reference substance. The HPLC analysis was performed on a Waters Symmetry C18 column (4.6 mm × 250 mm, 5 μm) with a mobile phase consisted of acetonitrile and 0.4% phosphoric acid solution in gradient elution manner at a flow rate of 1 mL/min. The column temperature was maintained at 35 ℃, and the detection wavelength was set at 327 nm for chlorogenic acid, caffeic acid, cryptochlorogenin acid, isochlorogenic acid A, isochlorogenic acid C and 236 nm for loganin. Results The relative correction factors of caffeic acid, cryptochlorogenin acid, isochlorogenic acid A, isochlorogenic acid C and loganin were established; there was no obvious difference between calculated value of QAMS and measured value of external standard method. Conclusion The quality control mode of QAMS can be used for multi-index synchronization quality evaluation of the six compositions from Lonicerae Japonicae Caulis.

An overview of effects of traditional medicine on pharmacokinetics of western medicine / 药学学报

Traditional medicine (herb medicine) began to prevail again over last two decades, and it is about 70% of the world population taking herb medicine as supplement or alternative medicine according to a recent survey. The consumption of herb medicine increased exponentially in Canada, Australia and Europe during last 10 years. Since concomitant administration of herbal and western medicine has become a trend, it requires paying close attention to the problem. Herb-drug interactions have been extensively investigated worldwide, and there is an increasing concern about the clinical herb-drug interaction. In this review we introduced the current progress in the herb-drug interactions including evidence-based clinical studies and establishment of levels of evidence for herb-drug interaction; and in the related mechanisms including the induction and inhibition of metabolic enzymes, inhibition and induction of transport and efflux proteins, alteration of gastrointestinal functions, and alteration in renal elimination. We also analyzed both the achievements and the challenges faced in the concomitant administration of traditional Chinese medicine and western medicine.

Determination of doxazosin enantiomers in rat plasma and investigation of their chiral inversion / 药学学报

The study is to establish an HPLC method using fluorescence detector for the determination of doxazosin enantiomers and investigate their chiral inversion in vitro and in vivo. Ultron ES-OVM was taken as the chiral chromatographic column, and the column temperature was 30 degrees C. Isocratic elution using a mobile phase of phosphate buffer-acetonitrile (85 : 15, v/v) at a flow rate of 0.8 mL x min(-1) was done. The fluorescence detection was set at lambda(Ex) = 255 nm and lambda(Em) = 385 nm. Prazosin was used as the internal standard. (-) Doxazosin or (+) doxazosin added into rat plasma in vitro was determined after incubating in 37 degrees C water bath for 2, 5 and 10 days. (-) Doxazosin or (+) doxazosin was administered orally to the rats for one months. Plasma samples were taken at 8 h after the last administration. A good linear relationship was achieved when the concentration of doxazosin enantiomers was within the range of 4 - 2 000 ng x mL(-1). The average recovery for (-) doxazosin was 99.5% with RSD 3.6%, and for (+) doxazosin was 99.3% with RSD 4.3%. Chiral inversion was observed neither in vitro nor in vivo studies. The method is selective, accurate and reproducible, which is suitable for the detection of doxazosin enantiomers in rat plasma. The in vitro and in vivo studies indicate that chiral inversion occurs uneasily between (-) doxazosin and (+) doxazosin in the rat.