[Quality control method for phenolic acid components in abandoned stems and leaves of Artemisia selengensis based on UPLC fingerprint combined with quantitative analysis of multi-components by single marker (QAMS)].

This study established an ultra-performance liquid chromatography(UPLC) fingerprint of abandoned stems and leaves of Artemisia selengensis and quantitative analysis of multi-components by single marker(QAMS) for five phenolic acid components. Waters Acquity UPLC BEH C_(18) chromatography column(2.1 mm×100 mm, 1.7 µm) was used. The gradient elution was carried out with the mobile phase composed of 0.1% phosphoric acid water and acetonitrile at a flow rate of 0.3 mL·min~(-1) and a column temperature at 30 ℃. The detection wavelength was 330 nm, and the injection volume was 2 µL. Similarity evaluation and cluster analysis were conducted on the fingerprint data, and 15 common components in 13 batches of abandoned stems and leaves of A. selengensis were identified. The relative correction factors of ferulic acid, isochlorogenic acid A, isochlorogenic acid B, and isochlorogenic acid C were calculated using chlorogenic acid as the internal reference. The QAMS for determining five components in the abandoned stems and leaves of A. selengensis was established. At the same time, the content of these five components was determined using the external standard method(ESM), and the results showed that there were no significant differences in their content determined by the QAMS and the ESM. The results indicated that the content of phenolic acid components in the abandoned stems and leaves of A. selengensis from different varieties and different origins had obvious differences. In addition, the content of phenolic acid components in the abandoned stems and leaves of lignified A. selengensis was significantly higher than that of non-lignified A. selengensis. In summary, QAMS established in this study can be quickly, accurately, and economically used to determine the content of five phenolic acid components in abandoned stems and leaves of A. selengensis, laying a foundation for the resource development and utilization of abandoned stems and leaves of A. selengensis.

Contribution of phenolamides to the quality evaluation in Lycium spp.

ETHNOPHARMACOLOGICAL RELEVANCE: Goji berry is a general term for various plant species in the genus Lycium. Goji has long been historically used in traditional Chinese medicines. Goji is a representative tonic medicine that has the effects of nourishing the liver and kidney and benefiting the essence and eyesight. It has been widely used in the treatment of various diseases, including tinnitus, impotence, spermatorrhea and blood deficiency, since ancient times. AIM OF THE REVIEW: This study aims to comprehensively summarize the quality evaluation methods of the main compounds in goji, as well as the current research status of the phenolamides in goji and their pharmacological effects, to explore the feasibility of using phenolamides as quality control markers and thus improve the quality and efficacy in goji. MATERIALS AND METHODS: Relevant literature from PubMed, Web of Science, Science Direct, CNKI and other databases was comprehensively collected, screened and summarized. RESULTS: According to the collected literature, the quality evaluation markers of goji in the Pharmacopoeia of the People's Republic of China are Lycium barbarum polysaccharide (LBP) and betaine. As a result of its structure complexity, only the total level of LBP can be determined, while betaine is not prominent in the pharmacological action of goji and lacks species distinctiveness. Neither of them can well explain the quality of goji. KuA and KuB are commonly used as quality evaluation markers of the Lycii cortex because of their high levels and suitable pharmacological activity. Goji is rich in polyphenols, carotenoids and alkaloids. Many studies have used the above compounds to establish quality evaluation methods but the results have not been satisfactory. Phenolamides have often been neglected in previous studies because of their low single compound levels and high separation difficulty. However, in recent years, the favorable pharmacological activities of phenolamides have been gradually recognized, and studies on goji phenolamides are greatly increasing. In addition, phenolamides have higher species distinctiveness than other compounds and can be combined with other compounds to better evaluate the quality of goji to improve its average quality. CONCLUSIONS: The phenolamides in the goji are rich and play a key role in antioxidation, anti-inflammation, neuroprotection and immunomodulation. As a result of their characteristics, it is suitable to evaluate the quality by quantitative analysis of multi-components by single-marker and fingerprint. This method can be combined with other techniques to improve the quality evaluation system of goji, which lays a foundation for their effectiveness and provides a reference for new quality evaluation methods of similar herbal medicines.

Extraction，isolation，identification and content determination of four chemical components in Yao medicine Ventilago leiocarpa / 中国药房

OBJECTIVE To extract and isolate the four chemical components of Yao medicine Ventilago leiocarpa， and to conduct identification and content determination for them. METHODS The chemical components of V. leiocarpa were separated and purified by solvent extraction， extraction， silica gel column chromatography and preparative liquid chromatography； then the chemical structures of four isolated compounds were identified based on their spectral data. The contents of four components were determined by high performance liquid chromatography（HPLC）-quantitative analysis of multi-components by single-marker （QAMS） method， with the following chromatographic conditions： chromatographic column was Echway GowonTM C18 （250 mm× 4.6 mm， 5 μm）. The mobile phase was acetonitrile-0.1% phosphoric acid for gradient elution； the detection wavelength was 269 nm， and the column temperature was 25 ℃ . Using emodin as internal reference， the relative correction factors （fi/s） between emodin and the other 3 components were established and used to calculate the content. At the same time， the content of each component was calculated with the external standard method （ESM）， and the differences between these two methods were compared. RESULTS Four compounds were isolated from V. leiocarpa， and they were identified as emodin， frangulin A， pleuropyrone A， emodin-8-O-β-D-glucoside. The result of HPLC-QAMS showed that the fi/s of pleuropyrone A， emodin-8-O-β-D- glucoside and frangulin A were 1.147 2， 0.874 7 and 0.644 4， respectively. The content of these four components was measured as a good linearity （r≥0.999 6）； relative standard deviation （RSD） of precision， stability and reproducibility tests were all lower than 2.00%， and average recoveries were E-mail：dearhuangjianyou@126.com 99.41%-100.46%（RSD≤2.05%）. There was no significant difference between QAMS method and ESM （RSD＜3.00%）. CONCLUSIONS Emodin， frangulin A， pleuropyrone A and emodin- 8-O-β-D-glucoside are isolated from V. leiocarpa； among them， the last three components are all isolated from for the first time. The established HPLC-QAMS method is accurate and reliable for the determination of 4 components in V. leiocarpa， and can used for quality control of V. leiocarpa.

Establishment of the fingerprints of soaking Euodiae fructus with water decoction of Radix glycyrrhizae by Zhangbang method and content determination of alkaloid / 中国药师

Objective To establish HPLC fingerprints of soaking Euodiae fructus with water decoction of Radix glycyrrhizae by Zhangbang method(hereinafter referred to as"soaking Euodiae fructus"),and to determine the content of evodiamine,rutaecarpine and evocarpine,so as to provide the basis for the quality control and standard improvement of soaking Euodiae fructus.Methods The fingerprint of soaking Euodiae fructus was established based on wavelength switching technology,and the similarity evaluation was conducted.Taking the rutaecarpine as the internal reference,the relative correction factors of evodiamine and evocarpine were calculated by slope correction method,and the differences in measurement results between quantitative analysis of multi-components by single-marker(QAMS)method and external standard method were compared.Results The established fingerprint of soaking Euodiae fructus had a total of 20 common peaks,the similarity between it and the control fingerprint spectrum was 0.970 to 0.998,and 7 common peaks of them were identified.The contents of evodiamine and evocarpine determined by QAMS method were 1.754-7.542 mg/g and 1.281-2.455 mg/g in 10 batches of samples,and the results obtained by QAMS method and external standard method were similar.Conclusion The established HPLC method is simple,reliable,with good separation and repeatability,and can be used for quality evaluation of processed Euodiae fructus.

Simultaneous content determination of ten constituents in Tianma Toufengling Capsules by QAMS / 中成药

AIM To establish a quantitative analysis of multi-components by single-marker(QAMS)method for the simultaneous content determination of gastrodin,parishin E,syringin,parishin B,parishin C,ferulic acid,parishin A,buddleoside,harpagoside and cinnamic acid in Tianma Toufengling Capsules.METHODS The analysis was performed on a 30℃thermostatic GL Science InertsilTM ODS-3 column(150 mm×4.6 mm,5 μm),with the mobile phase comprising of acetonitrile-0.1%phosphoric acid flowing at 1.0 mL/min in a gradient elution manner,and the detection wavelengths were set at 220,280 nm.Syringin was used as an internal standard to calculate the relative correction factors of the other nine constituents,after which the content determination was made.RESULTS Ten constituents showed good linear relationships within their own ranges(r≥0.999 7),whose average recoveries were 98.53%-102.22%with the RSDs of 1.26%-2.68%.The result obtained by QAMS approximated those obtained by external standard method.CONCLUSION This accurate and specific method can be used for the quality control of Tianma Toufengling Capsules.

Exploring Effect of Concentration on Quantitative Accuracy of QAMS by Taking Ginsenosides as an Example / 中国实验方剂学杂志

ObjectiveTo investigate the influence of concentration ratio（CR） between the internal reference and target components on the quantitative accuracy of quantitative analysis of multi-components by single marker（QAMS） by taking ginsenosides as an example. MethodUltra performance liquid chromatography（UPLC） was employed， the contents of nine components in Ginseng Radix et Rhizoma（ginsenosides Rg1， Re， Rf， Rh1， Rb1， Rc， Rb2， Rb3， Rd） were determined by external standard method（ES）. Using ginsenoside Rg1 as the internal reference， the contents of the remaining 8 ginsenosides were determined by QAMS， and the quantitative results were compared with those of ES to evaluate the quantitative accuracy of the established QAMS. According to the contents of these 9 ginsenosides， the simulated sample solutions with different CRs of ginsenoside Rg1 to ginsenosides Rf， Rb2， Rd were prepared with the reference substance（CR=100∶1， 10∶1， 5∶1， 2∶1， 1∶1， 0.5∶1， 0.25∶1）， in order to validate the effect of the CRs between the internal reference and other components on the quantitative accuracy of the QAMS. ResultThe results of ginsenosides Re， Rf， Rb1， Rc， Rb2 calculated by the two methods were the same with the relative standard deviation（RSD）<3%， however， the results of ginsenosides Rh1， Rb3 and Rd calculated by the two methods were different with RSDs of 7.06%-9.61%. According to the result of the simulated sample solution， the difference between the calculated results of ES and QAMS was large when the CR between the internal reference（ginsenoside Rg1） and other components was 5 or 10 or even higher. ConclusionThe quantitative error of QAMS will increase when the CR between the quantitative component and the internal reference is too large， so it is suggested that when establishing the QAMS， the components with close concentration to the internal reference should be selected for quantification.

[Quality evaluation of Compound Cheqian Tablets based on UPLC-Q-TOF-MS/MS, network pharmacology and "double external standards" QAMS].

The Compound Cheqian Tablets are derived from Cheqian Power in Comprehensive Recording of Divine Assistance, and they are made by modern technology with the combination of Plantago asiatica and Coptis chinensis. To investigate the material basis of Compound Cheqian Tablets in the treatment of diabetic nephropathy, in this study, the chemical components of Compound Cheqian Tablets were characterized and analyzed by UPLC-Q-TOF-MS/MS, and a total of 48 chemical components were identified. The identified chemical compounds were analyzed by network pharmacology. By validating with previous literature, six bioactive compounds including acteoside, isoacteoside, coptisine, magnoflorine, palmatine, and berberine were confirmed as the index components for qua-lity evaluation. Furthermore, the content of the six components in the Compound Cheqian Tablets was determined by the "double external standards" quantitative analysis of multi-components by single marker(QAMS), and the relative correction factor of isoacteoside was calculated as 1.118 by using acteoside as the control; the relative correction factors of magnoflorine, palmatine, and berberine were calculated as 0.729, 1.065, and 1.126, respectively, by using coptisine as the control, indicating that the established method had excellent stability under different conditions. The results obtained by the "double external standards" QAMS approximated those obtained by the external standard method. This study qualitatively characterized the chemical components in the Compound Cheqian Tablets by applying UPLC-Q-TOF-MS/MS and screened the pharmacodynamic substance basis for the treatment of diabetic nephropathy via network pharmacology, and primary pharmacodynamic substance groups were quantitatively analyzed by the "double external stan-dards" QAMS method, which provided a scientific basis for clarifying the pharmacodynamic substance basis and quality control of Compound Cheqian Tablets.

Establishment of quantitative analysis of multi-components by single marker for content determination of 10 ganoderic acids in Ganoderma lucidum / 中国药房

OBJECTIVE To establish a quantitative analysis of multi-components by single marker （QAMS） method for simultaneous determination of 10 ganoderic acids in Ganoderma lucidum. METHODS Using ganoderic acid A as internal reference， high-performance liquid chromatography （HPLC） method was adopted to calculate relative correction factors of the other 9 components， such as ganoderic acid B， ganoderic acid C2， ganoderic acid D， ganoderic acid F， ganoderic acid H， ganoderenic acid A， ganoderenic acid B， ganoderenic acid C， ganoderenic acid D； the contents of above ganoderic acids were calculated with relative correction factors， and compared with the results of external standard method. RESULTS The linear relationship of ganoderic acid A， ganoderic acid B， ganoderic acid C2， ganoderic acid D， ganoderic acid F， ganoderic acid H， ganoderenic acid A， ganoderenic acid B， ganoderenic acid C and ganoderenic acid D were 0.032-3.996， 0.040-4.971， 0.037-4.568， 0.028-3.558， 0.033-4.177， 0.044-5.440， 0.032-3.944， 0.040-4.994， 0.045-5.593 and 0.035-4.342 mg/mL （all R 2≥0.999 2）， respectively. RSDs of precision， stability （24 h） and reproducibility tests were all lower than 2%. Their average recovery rates were 99.43%， 100.25%， 98.50%， 99.88%， 100.59%， 99.64%， 98.50%， 99.40%， 99.64% and 99.76%， respectively （RSD＜2%， n＝6）. Relative correction factors of ganoderic acid B， ganoderic acid C2， ganoderic acid D， ganoderic acid F， ganoderic acid H， ganoderenic acid A， ganoderenic acid B， ganoderenic acid C and ganoderenic acid D were 1.788 5， 1.288 2， 1.126 4， 1.698 5， 0.885 4， 5.468 1， 4.210 9， 5.780 8， 4.290 3， respectively. Relative errors between the content obtained by QAMS method and external standard method for G. lucidum from different origins were within ±12%. CONCLUSIONS It is feasible that the contents of 10 ganoderic acids are determined simultaneously by QAMS method， using ganoderic acid A as internal reference. This method shows good precision and reproducibility and can be used for the quality control of G. lucidum.

Simultaneous determination of five components in Forsythia suspensa flower with UPLC-QAMS / 中国药房

OBJECTIVE To establish the methods for simultaneous determination of rutin， forsythiaside A， （+）-pinoresinol-4- O-β-D-glucopyranoside， forsythin and forsythigenin in Forsythia suspensa flower. METHODS UPLC method was adopted. The determination was performed on ACQUITY UPLC HSS T3 C18 column with mobile phase consisted of acetonitrile-0.1% phosphoric acid solution （gradient elution） at the flow rate of 0.3 mL/min. The detection wavelengths were set at 275 nm （0-8 min），330 nm （8-10.5 min），275 nm （10.5-32 min）， respectively. The column temperature was 25 ℃， and sample size was 1 μL. Taking rutin as reference， the content of each component was determined by quantitative analysis of multi-components by single-marker （QAMS） method， and then compared with external standard method. RESULTS The contents of forsythiaside A， （+）-pinoresinol-4-O-β-D- glucopyranoside， forsythin and forsythigenin by QAMS were 7.472-7.671， 2.919-2.986， 1.439-1.486， 1.523-1.566 mg/g； the results obtained by the external standard method were 7.454-7.664， 2.913-2.996， 1.444-1.484， 1.519-1.562 mg/g， respectively. There was no significant difference in the measurement results between the two methods， with a relative deviation less than 1.0%. CONCLUSIONS This study successfully establishes the UPLC-QAMS method for simultaneous determination of five components in F. suspensa flower， and the results obtained by this method are not significantly different from those obtained by the external standard method. It can be used for quality control of F. suspensa flower.

Study on quality control method of Qiguiling mixture / 中国药房

OBJECTIVE To establish the fingerprint of Qiguiling mixture and the method for the content determination of 4 kinds of active components such as calycosin-7-glucoside， so as to control the quality of Qiguiling mixture. METHODS The fingerprints of 12 batches of Qiguiling mixture were established by HPLC. SPSS 25.0 software was used for cluster analysis and principal component analysis， and SIMCA 14.1 software was used for orthogonal partial least squares-discriminant analysis. The variable importance in projection （VIP） value greater than 1.0 was used as the index to screen the differential components. The contents of calycosin-7-glucoside， glycyrrhizin and glycyrrhizic acid were calculated by the quantitative analysis of multi- components by single marker （QAMS） with hesperidin as the internal reference， and the results were compared with external standard method. RESULTS In the fingerprints of 12 batches of samples， 17 common peaks were identified， and the similarities were more than 0.940. A total of 4 common peaks were identified， which were calycosin-7-glucoside （peak 6）， glycyrrhizin （peak 8）， hesperidin （peak 12）， and glycyrrhizic acid （peak 17）. The 12 batches of samples could be clustered into two categories， S4， S7-S9 and S11-S12 were clustered into one category， and the other batches of samples were clustered into one category. The cumulative variance contribution rate of the six principal components was 85.840%， and VIP values of peaks 15， 14， 4， 8 （glycyrrhizin） and 9 were all greater than 1.0. The relative error between the results of QAMS and external standard method was less than 5% （n＝3） for the contents of calycosin-7-glucoside， glycyrrhizin and glycyrrhizic acid. CONCLUSIONS Established HPLC fingerprint and content determination method in this study can be used for quality control of Qigiling mixture. Five components such as glycyrrhizin are the differential components.

Analysis on Quality Standard of Fraxini Cortex（Fraxinus chinensis） Dispensing Granules Based on Standard Decoction / 中国实验方剂学杂志

ObjectiveTo establish the quality standard for Fraxini Cortex（Fraxinus chinensis） dispensing granules based on standard decoction， and to provide a basis for the quality control of this dispensing granules. MethodHigh performance liquid chromatography（HPLC） specific chromatograms of 15 batches of Fraxini Cortex（F. chinensis） standard decoctions and 3 batches of Fraxini Cortex（F. chinensis） dispensing granules were established with the mobile phase of 0.1% phosphoric acid aqueous solution（A）-acetonitrile（B） for gradient elution（0-10 min， 12%-15%B； 10-30 min， 15%-32%B） and the detection wavelength of 220 nm. And similarity evaluation， cluster analysis and principal component analysis（PCA） were also carried out. HPLC quantitative analysis of multi-components by single marker（QAMS） was established to determine the contents of the main components in the standard decoctions and dispensing granules. The contents of the corresponding components in Fraxini Cortex（F. chinensis） decoction pieces were also detected， and the transfer rates from decoction pieces to standard decoctions and dispensing granules were calculated. ResultThe similarities between specific chromatograms of 15 batches of Fraxini Cortex（F. chinensis） standard decoctions and 3 batches of Fraxini Cortex（F. chinensis） dispensing granules were all>0.9， and 7 common peaks were identified. The results of cluster analysis and PCA showed that there was some differences in the composition of different batches of standard decoctions， but did not show aggregation of origin. As the standard decoctions， the extract rate was 6.18%-11.62%， the contents of esculin， syringin， fraxin， esculetin， fraxetin， calceolarioside B were 44.92-103.51， 1.36-11.87， 33.26-90.73， 4.63-29.75， 2.40-16.86， 2.49-17.35 mg·g-1， and the transfer rates from decoction pieces to standard decoction were 25.21%-42.54%， 52.57%-88.84%， 43.43%-79.45%， 49.15%-88.27%， 49.22%-72.69%， 27.66%-47.67%， respectively. The extract rates of Fraxini Cortex（F. chinensis） dispensing granules were 10.4%-10.7%， the transfer rates of the above six components from decoction pieces to dispensing granules were 42.76%-43.17%， 80.01%-80.90%， 59.59%-59.88%， 51.35%-52.67%， 60.50%-60.93%， 37.98%-38.37%， respectively， which were generally consistent with the transfer rates from decoction pieces to standard decoctions. ConclusionThe established quality control standard of Fraxini Cortex（F. chinensis） dispensing granules based on standard decoctions is reasonable and reliable， which can provide reference for the quality control and process research of this dispensing granules.

Quality evaluation of Crataegus pinnatifida leaves by fingerprint combined with quantitative analysis of multi-components by single-marker / 中国药房

OBJECTIVE To establish the fingerprint and multi-component content determination method of Crataegus pinnatifida leaves from different producing areas， and to evaluate the quality of C. pinnatifida leaves and screen the differential markers. METHODS Seventy-eight batches of C. pinnatifida leaves were collected from Chengde of Hebei Province， Huludao of Liaoning Province， Yuncheng of Shanxi Province and Linyi of Shandong Province. High-performance liquid chromatography （HPLC） and Similarity Evaluation System for Traditional Chinese Medicine Chromatographic Fingerprints （2012 edition） were used to draw the fingerprints and conduct similarity evaluation. Grey correlation analysis， cluster analysis （CA）， principal component analysis （PCA） and orthogonal partial least squares-discriminant analysis （OPLS-DA） were performed by using SPSS 19.0， MetaboAnalyst 5.0 and SIMCA 14.1 software. The differential markers affecting the quality of C. pinnatifida leaves were screened with variable importance in the projection （VIP） value greater than 1 and the error line not exceeding the origin as the criterion. Using vitexin rhamnoside as an internal reference， the contents of chlorogenic acid， glucosylvitexin， hypericin and isoquercetin in 78 batches of C. pinnatifida leaves were determined by the same HPLC combined with quantitative analysis of multi- components by single-marker （QAMS）， and the results were compared with external standard method. RESULTS Eight common peaks were calibrated in the fingerprints for 78 batches of C. pinnatifida leaves from 4 producing areas. Five known components were identified， including chlorogenic acid （peak 1）， glucosylvitexin （peak 3）， vitexin rhamnoside （peak 4）， hypericin （peak 7） and isoquercetin （peak 8）； their similarities ranged from 0.871 to 0.998. Average relative correlations of samples from Chengde of Hebei Province， Huludao of Liaoning Province， Yuncheng of Shanxi Province and Linyi of Shandong Province were 0.538， 0.528， 0.462 and 0.435， respectively. CA and PCA showed that the samples from Chengde of Hebei Province and Huludao of Liaoning Province were roughly classified into one category， while the samples from Linyi of Shandong Province and Yuncheng of Shanxi Province were roughly classified into one category； VIP values of peak 1， 2， 3 and 5 were all greater than 1. By QAMS， the relative correction factors of chlorogenic acid， glucosylvitexin， hypericin and isoquercetin were 0.401， 0.993， 1.670 and 1.615 （RSD＜2%）. Compared with external standard method， except for isoquercetin in the two batches of samples （S39 and S41）， there was no significant difference in the content of each component in other batches of samples （the relative deviations≤ 5%）. CONCLUSIONS The established fingerprint and QAMS method are simple to operate and can be used to evaluate the quality of C. pinnatifida leaves. The sample from Chengde of Hebei Province is relatively good in quality. Chlorogenic acid （peak 1）， glucosylvitexin （peak 3）， and the corresponding components of peaks 2 and 5 may be differential markers affecting the quality of C. pinnatifida leaves.

Quality evaluation of Compound Cheqian Tablets based on UPLC-Q-TOF-MS/MS, network pharmacology and "double external standards" QAMS / 中国中药杂志

The Compound Cheqian Tablets are derived from Cheqian Power in Comprehensive Recording of Divine Assistance, and they are made by modern technology with the combination of Plantago asiatica and Coptis chinensis. To investigate the material basis of Compound Cheqian Tablets in the treatment of diabetic nephropathy, in this study, the chemical components of Compound Cheqian Tablets were characterized and analyzed by UPLC-Q-TOF-MS/MS, and a total of 48 chemical components were identified. The identified chemical compounds were analyzed by network pharmacology. By validating with previous literature, six bioactive compounds including acteoside, isoacteoside, coptisine, magnoflorine, palmatine, and berberine were confirmed as the index components for qua-lity evaluation. Furthermore, the content of the six components in the Compound Cheqian Tablets was determined by the "double external standards" quantitative analysis of multi-components by single marker(QAMS), and the relative correction factor of isoacteoside was calculated as 1.118 by using acteoside as the control; the relative correction factors of magnoflorine, palmatine, and berberine were calculated as 0.729, 1.065, and 1.126, respectively, by using coptisine as the control, indicating that the established method had excellent stability under different conditions. The results obtained by the "double external standards" QAMS approximated those obtained by the external standard method. This study qualitatively characterized the chemical components in the Compound Cheqian Tablets by applying UPLC-Q-TOF-MS/MS and screened the pharmacodynamic substance basis for the treatment of diabetic nephropathy via network pharmacology, and primary pharmacodynamic substance groups were quantitatively analyzed by the "double external stan-dards" QAMS method, which provided a scientific basis for clarifying the pharmacodynamic substance basis and quality control of Compound Cheqian Tablets.

[Determination of content of nine components in Xinnaojian preparations from different manufacturers by QAMS].

This study established the ultra-performance liquid chromatography(UPLC) fingerprint of Xinnaojian preparations. With epicatechin gallate as the internal reference substance, a quantitative analysis of multi-components by single marker(QAMS) method for determining the content of nine components(gallic acid, epigallocatechin, catechin, caffeine, epicatechin, epigallocatechin gallate, gallocatechin gallate, epicatechin gallate, and catechin gallate) in Xinnaojian preparations was established. The content determined by the external standard method(ESM) and QAMS method was compared to evaluate the feasibility and accuracy of QAMS method. The results showed that the standard curves of nine components had good linear relationship within the test concentration ranges. The average recoveries were 87.57%-107.4%, and the RSD was 1.5%-2.9%. Except epigallocatechin, the other components showed good repeatability under different experimental conditions. Epigallocatechin could meet the requirements in the same instrument and at the same wavelength. The results generally showed no significant difference between QAMS and ESM. The content of 9 components varied between the samples from different manufacturers, while it showed no significant difference between the samples from the same manufacturer. In summary, the UPLC fingerprint combined with QAMS method is feasible and accurate for determining the content of the nine components, which can be used for rapid quality evaluation of Xinnaojian preparations.

Chromatographic fingerprint combined with quantitative analysis of multi-components by single-marker for quality control of total lignans from Fructus arctii by high-performance liquid chromatography.

INTRODUCTION: The total lignans from Fructus arctii (TLFA) is a mixture of a series of lignans isolated from dried ripe fruit of Arctium lappa L. We previously reported on the pharmacological activity of TLFA that is related to diabetes. An accurate and practical TLFA quantitative analysis method for utilising it needs to be established. OBJECTIVE: This study aimed to develop an effective quantitative analysis method for assessing the TLFA quality. METHODS: A total of 11 marker components were confirmed by analysing the high-performance liquid chromatography fingerprints of 24 batches of TLFA samples. The samples were prepared from TLFA and structurally identified as lappaol H, lappaol C, arctiin, arctignan D, arctignan E, matairesinol, arctignan G, isolappaol A, lappaol A, arctigenin, and lappaol F. In the quantitative analysis of multi-components by the single-marker (QAMS) method and with arctiin as an internal reference substance, the content of these lignans in TLFA was simultaneously determined according to their relative correction factors with arctiin. RESULTS: There was no significant difference between results measured by the QAMS and traditional external standard methods. Hierarchical cluster and principal component analyses were performed to evaluate 24 TLFA batches based on the contents of 10 marker components. The results revealed that QAMS method combined with chemometric analyses could accurately measure and clearly distinguish the different quality samples of TLFA. CONCLUSION: The QAMS method is a reliable and promising quality control method for TLFA. It can provide a reference for promoting quality control of complex multi-component systems, especially for traditional Chinese medicine.

[Chemical pattern recognition of Atractylodes chinensis from different producing areas and establishment of quantitative analysis of multi-components by single marker (QAMS) method for four components].

This study established the fingerprint and combined it with chemical pattern recognition to evaluate the quality of Atractylodes chinensis samples from different producing areas and then employed the quantitative analysis of multi-components by single marker(QAMS) method to verify the feasibility and applicability of the established method in the quality evaluation of A. chinensis. The fingerprints of A. chinensis samples were constructed via high performance liquid chromatography(HPLC) to evaluate the inter-batch consistency. With the quality control component atractylodin as the internal reference, the relative correction factors(RCFs) were established for atractylenolide Ⅰ, atractylenolide Ⅲ, and ß-eudesmol and the content of the four components was calculated. The external standard method was used to verify the accuracy of QAMS method. The quality of A. chinensis was further evaluated by similarity analysis, clustering analysis, and principal component analysis. The fingerprints of 13 batches of samples were calibrated with 21 common peaks, and 4 common peaks were identified with the similarities all above 0.9. The RCFs established with atractylodin as the internal reference represented good reproducibility under different experimental conditions. Specifically, the RCFs of atractylenolide Ⅰ, atractylenolide Ⅲ, and ß-eudesmol in A. chinensis were 2.091, 4.253, and 6.010, respectively. QAMS and ESM showed no significant difference in the results, indicating that the QAMS method established in this study was stable and reliable. Thus, HPLC fingerprint combined with QAMS can be used for the quality evaluation of A. chinensis, providing a basis for comprehensive and rapid quality evaluation of A. chinensis.

[Quality evaluation of Psoraleae Fructus based on QAMS method and TLC identification].

The present study established a determination method of Psoraleae Fructus by quantitative analysis of multi-components by the single marker(QAMS) and further improved the thin-layer chromatography(TLC) method. The QAMS method was established by UPLC with psoralen as the internal marker, and the content of psoralenoside, isopsoralenoside, psoralen, and isopsoralen was simultaneously determined. As revealed by the comparison with results of the external standard method, the QAMS method was accurate and feasible. According to the current quality standards of Psoraleae Fructus, the TLC method was further optimized and improved, and bakuchiol was added for identification based on the original TLC method with psoralen and isopsoralen as indicators. This study provides a reference for improving the quality control method of Psoraleae Fructus.

[Quality evaluation of Ginseng Radix et Rhizoma based on UPLC characteristic chromatogram and quantitative analysis of multi-components by single marker (QAMS)].

Based on UPLC characteristic chromatogram and quantitative analysis of multi-components by single marker(QAMS), the content of seven types of ginsenosides in Ginseng Radix et Rhizoma was simultaneously determined, and the quality of Ginseng Radix et Rhizoma was evaluated by the principal component analysis(PCA). The chromatographic separation was performed on the Acquity UPLC BEH C_(18) column(2.1 mm×100 mm, 1.7 µm) with the mobile phase of acetonitrile-water for gradient elution at the flow rate of 0.3 mL·min~(-1), the column temperature of 30 ℃, the detection wavelength of 203 nm, and the injection volume of 2 µL. The UPLC chromatogram was established with 19 batches of Ginseng Radix et Rhizoma samples from three producing areas by Similarity Evaluation System for Chromatographic Fingerprint of Traditional Chinese Medicine(version 2012). Thirteen characteristic peaks were determined and seven components were identified. SPSS 26.0 was used to conduct PCA on the characteristic peak areas. With the peak of ginsenoside Rb_1 as reference peak S, ginsenoside Rb_1 showed good durability of relative correction factor as compared with other ginsenosides. The QAMS method for the determination of seven ginsenosides in Ginseng Radix et Rhizoma was established. There was no significant difference in results between the QAMS method and the external standard method. As revealed by the results of PCA and the determination of the total content of seven ginsenosides, the four batches of Ginseng Radix et Rhizoma numbered S19, S18, S1, and S2 were of superior quality. The characteristic chromatogram and QAMS method for the determination of seven ginsenosides in this study were convenient and accurate, which greatly shortened the analysis time and improved the analysis efficiency. The findings of this study are expected to provide a basis for the overall quality evaluation of Ginseng Radix et Rhizoma.

[Simultaneous determination of glucosinolates and flavonoids in leaves of Moringa oleifera by quantitative analysis of multi-components by single-marker (QAMS)].

To establish a method for simultaneously determining the content of four glucosinolates and five flavonoids in leaves of Moringa oleifera via quantitative analysis of multi-components by single-marker(QAMS) and verify the feasibility and applicability of the established method. The glucosinolates and flavonoids were analyzed via Waters Acquity UPLC HSS T_3 column(2.1 mm × 100 mm, 1.8 µm). The gradient elution was carried out with the mobile phase composed of 0.1% formic acid-acetonitrile and 0.3% formic acid at the flow rate of 0.4 mL·min~(-1) and the column temperature of 40 ℃. The wavelengths for the detection of glucosinolates and flavonoids were 225 nm and 260 nm, respectively. With 4-O-(α-L-rhamnoyloxy)-benzyl glucosinolate and vecenin-2 as internal reference substances, the relative correction factors of four glucosinolates and five flavonoids were respectively calculated for determining the content of the 9 ingredients in leaves of M. oleifera. To verify the accuracy and feasibility of QAMS, we used internal standard method(ISM) and external standard method(ESM) to determine the content of glucosinolates and flavonoids, respectively. The t-test results showed that there was no significant difference in the content of glucosinolates obtained by ISM and QAMS methods or in the content of flavonoids obtained by ESM and QAMS methods. The content of glucosinolates and flavonoids varied among M. oleifera of different varieties and from different producing areas. The total glucosinolates and total flavonoids had the highest content in the Indian variety while the lowest content in the variety ■Honghe No. 1'. The established QAMS method is rapid, simple and accurate and can be used for simultaneous determination of glucosinolates and flavonoids in the leaves of M. oleifera. This study provides experimental data for the quality control and utilization of M. oleifera leaves.

[Establishment and verification of quality evaluation method of Jizhi Syrup based on quantitative analysis of multi-components by single marker].

A quantitative analysis of multi-components by single marker(QAMS) method was established for the simultaneous determination of ephedrine hydrochloride, protocatechuic acid, 5-caffeoylquinic acid, 4-hydroxybenzoic acid, naringin, neohesperidin, glycyrrhizic acid, and praeruptorin A in Jizhi Syrup by high performance liquid chromatography(HPLC) with ultraviolet multi-wavelength detection system, and its feasibility in quality evaluation of Jizhi syrup was verified. With naringin as the internal reference substance, the relative correction factors and chromatographic peak localization methods of other seven components were respectively established at 210, 254, 280, and 320 nm. The method reproducibility was validated, and the result of QAMS were compared with those obtained by the external standard method(ESM) to verify the accuracy and feasibility of the method. The relative correction factors of ephedrine hydrochloride, protocatechuic acid, 5-caffeoylquinic acid, 4-hydroxybenzoic acid, neohesperidin, glycyrrhizic acid, and praeruptorin A with naringin as reference were 0.846, 0.582, 0.608, 0.293, 0.913, 2.207, and 0.940, respectively, which presented excellent reproducibility under different experimental conditions. Furthermore, QAMS and ESM showed no significant difference in the results for 15 batches of samples. Except protocatechuic acid and 5-caffeoylquinic acid, other six compounds were the exclusive components of single medicinal materials. In addition, glycyrrhizic acid and praeruptorin A were identified in the Jizhi Syrup for the first time, filling up the blank of no component detected in Glycyrrhizae Radix et Rhizoma and Peucedani Radix. The method established in this study is convenient, efficient, specific, accurate, and reliable, which can comprehensively and effectively evaluate the quality of Jizhi Syrup to ensure the safety and efficacy of this drug in clinical application.