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ObjectiveHigh performance liquid chromatography (HPLC) was used to establish the specific chromatograms of Aurantii Fructus from different origins, and the quality variability of Aurantii Fructus from Sichuan was analyzed and evaluated by combining entropy weighting method and grey correlation method. MethodHPLC was performed on an Agilent Eclipse Plus C18 column (4.6 mm×250 mm, 5 μm) with a gradient elution of methanol (A)-0.1% phosphoric acid aqueous solution as the mobile phase (0-12 min, 25%-33%A; 12-21 min, 33%-41%A; 21-30 min, 41%-42%A; 30-40 min, 42%-59%A; 40-53 min, 59%-72%A; 53-60 min, 72%A; 60-65 min, 72%-100%A; 65-70 min, 100%A; 70~71 min, 100%-25%A; 71-80 min, 25% A) at a flow rate of 1.0 mL·min-1, the injection volume was 10 μL and the detection wavelength was 330 nm. Fifty batches of Aurantii Fructus samples from different origins (Sichuan, Chongqing, Jiangxi and Hunan) were tested, and the similarity evaluation software is used to generate characteristic profiles and compare them with control profile for peak identification, and then to evaluate the similarity of the samples. IBM SPSS 19.0 and SIMCA 14.1 were used to perform multivariate statistical analysis on the results of the samples, and then the entropy weighting method and grey correlation were used to calculate the overall quality score of samples from Sichuan. ResultHPLC specific chromatogram of Aurantii Fructus was established, and 14 common peaks were identified as eriocitrin, neoeriocitrin, narirutin, naringin, hesperidin, neohesperidin, meranzin hydrate, poncirin, meranzin, marmin, nobiletin, 3,3′,4′,5,6,7,8-heptamethoxyflavone, tangeretin and auraptene. And the similarities between the samples from Sichuan and the control chromatogram were all above 0.980. The samples could be classified into four categories according to their main origins by chemical pattern recognition, and the results of cluster analysis, principal component analysis and orthogonal partial least squares-discriminant analysis were all able to discriminate the samples of different main origins effectively. The comprehensive evaluation results of entropy weighting method combined with grey correlation showed that the quality of Aurantii Fructus from Sichuan varied greatly among different origins, and the quality of Aurantii Fructus from Sichuan was ranked as Bazhong>Luzhou>Chongqing>Neijiang. ConclusionIn this study, the characteristic mapping of Aurantii Fructus from Sichuan is established, and combined with the analytical methods of chemometrics and grey correlation, the quality of samples from different origins can be effectively differentiated, which can provide a reference for the comprehensive evaluation and control of the quality of Aurantii Fructus from Sichuan.
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Strengthening the standard formulation and quality management of traditional Chinese medicine(TCM) dispensing granules is an important part of the strategic planning for the development of TCM in China. In order to examine the clinical application and overall quality control of the existing national standards for TCM dispensing granules, this study classified and summarized the varieties in the existing standards, analyzed their clinical applicability, and discussed the characteristics of the test methods for identification, content determination and specific chromatogram/fingerprint. It was found that the coverage of the existing standards was inadequate in terms of quantity, and it was even weaker in the aspects of therapeutic efficacy, herb family, processing method and preparation method of TCM dispensing granules. It was concluded that the characteristics of national standards in test methods were summarized as follows:guided by clinical application, based on the reference system, taking specific chromatogram as a breakthrough, so as to improve the overall quality control of TCM dispensing granules. It is suggested that the coverage of national standards should be subsequently expanded to meet the needs of market development. In order to enhance clinical applicability, the content of national quality standards should be increased, including increasing variety diversity to meet the needs of clinical application, raising the standard requirements to improve the clinical medication experience, and strengthening effectiveness research to highlight clinical efficacy. At the same time, the accessibility of regulatory inspection is enhanced, the rules for the management of varieties without national standards are promulgated to lay the foundation for the healthy and orderly development of TCM dispening granule industry.
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ObjectiveTo establish the specific chromatogram and thin layer chromatography(TLC) of Qingxin Lianziyin(QXLZY) benchmark samples, in order to clarify the key quality attributes and provide a reference for the quality evaluation of QXLZY. MethodHigh performance liquid chromatography(HPLC) specific chromatogram of QXLZY benchmark samples was developed by using a YMC Hydrosphere C18 column(4.6 mm×250 mm, 5 μm) with the mobile phase of acetonitrile(A)-0.2% formic acid aqueous solution(B) for gradient elution(0-10 min, 5%-20%A; 10-20 min, 20%A; 20-25 min, 20%-24%A; 25-40 min, 24%-30%A; 40-55 min, 30%-50%A; 55-65 min, 50%-100%A; 65-75 min, 100%A; 75-75.1 min, 100%-5%A; 75.1-90 min, 5%A), and the detection wavelength was 360 nm. Ultra-high performance liquid chromatography-linear ion trap/orbitrap mass spectrometry(UHPLC-LTQ-Orbitrap MS) with electrospray ionization(ESI) was used to identify the components of QXLZY benchmark samples by accurate relative molecular weight and multilevel MS fragment ion information, the detection conditions were positive and negative ion modes and data dependency scanning mode. TLC identification methods for Ophiopogonis Radix, Lycii Cortex, Nelumbinis Semen, Poria, Astragali Radix and Ginseng Radix et Rhizoma in QXLZY were established. ResultA total of 15 characteristic peaks were identified from Glycyrrhizae Radix et Rhizoma, Plantaginis Semen and Scutellariae Radix, and the relative standard deviations of the retention times of 15 characteristic peaks in 15 batches of QXLZY benchmark samples were≤3% with peak 8(baicalin) as the reference peak. A total of 100 compounds, including flavonoids, organic acids, saponins, amino acids and others, were identified in the benchmark samples by UHPLC-LTQ-Orbitrap MS. The established TLC had good separation and was suitable for the identification of Ophiopogonis Radix, Lycii Cortex, Nelumbinis Semen, Poria, Astragali Radix and Ginseng Radix et Rhizoma in QXLZY. ConclusionThe material basis of QXLZY benchmark samples is basically determined by MS designation and source attribution. The established specific chromatogram and TLC of QXLZY are simple, stable and reproducible, which can provide a reference for the development and quality control of QXLZY.
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We prepared 15 batches of Kaixin Powder benchmark samples with the decoction pieces of different batches. Further, we established the specific chromatograms and index component content determination method of Kaixin Powder benchmark samples and analyzed the peaks and similarity of the chromatograms. With sibiricose A5, sibiricose A6, polygalaxanthone Ⅲ, 3,6'-disinapoyl sucrose, ginsenoside Rb_1, β-asarone, α-asarone, and dehydropachymic acid as index components, the index component content determination method was established and 70%-130% of the mean content of each component was set as the range. The chromatograms of 15 batches of Kaixin Powder benchmark samples had a total of 22 characteristic peaks, among which 8 peaks were identified, which represented sibiricose A5, sibiricose A6, polygalaxanthone Ⅲ, 3,6'-disinapoyl sucrose, ginsenoside Rb_1, β-asarone, α-asarone, and dehydropachymic acid, respectively. The chromatograms shared the similarity of 0.992-0.999. The 15 batches of benchmark samples had sibiricose A5 of 0.34-0.55 mg·g~(-1), sibiricose A6 of 0.43-0.57 mg·g~(-1), polygalaxanthone Ⅲ of 0.12-0.19 mg·g~(-1), 3,6'-disinapoyl sucrose of 1.08-1.78 mg·g~(-1), ginsenoside Rb_1 of 0.33-0.62 mg·g~(-1), β-asarone of 2.34-3.72 mg·g~(-1), α-asarone of 0.11-0.22 mg·g~(-1), and dehydropachymic acid of 0.053-0.079 mg·g~(-1). This study established the specific chromatograms and index component content determination method of Kaixin Powder benchmark samples, and the method was simple, feasible, reproducible, and stable. This study provides a scientific basis for further research on the key chemical properties of the benchmark samples and preparations of Kaixin Powder.
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Powders , Ginsenosides , Benchmarking , Drugs, Chinese Herbal/chemistry , Sucrose , Chromatography, High Pressure Liquid/methodsABSTRACT
ObjectiveTo establish the specific chromatogram and thin layer chromatography(TLC) identification method of Kaixinsan(KXS) samples, in order to clarify the key quality attributes and provide reference for the quality evaluation of KXS. MethodHigh performance liquid chromatography(HPLC) specific chromatogram of KXS was developed with YMC Hydrosphere C18 column(4.6 mm×250 mm, 5 μm), the mobile phase was acetonitrile(A)-0.2% formic acid aqueous solution(B) for gradient elution(0-15 min, 2%-20%A; 15-25 min, 20%-25%A; 25-30 min, 25%-30%A; 30-45 min, 30%-31%A; 45-50 min, 31%-44%A; 50-65 min, 44%-45%A; 65-73 min, 45%-75%A; 73-95 min, 75%-100%A; 95-105 min, 100%A; 105-105.1 min, 100%-2%A; 105.1-120 min, 2%A), the detection wavelength was 320 nm. Ultra high performance liquid chromatography-linear ion trap-electrostatic field orbitrap mass spectrometry(UHPLC-LTQ-Orbitrap MS) was used to identify the chemical components of KXS with electrospray ionization(ESI), negative ion mode and scanning range of m/z 50-2 000. TLC identification methods for Poria and Ginseng Radix et Rhizoma in KXS were established. ResultThere were 11 common peaks in the specific chromatogram of KXS, attributed to Polygalae Radix, Poria and Acori Tatarinowii Rhizoma. Taking peak 9(α-asarone) as the reference peak, the relative standard deviations of the retention times of 15 batches of KXS samples were<0.2%. A total of 34 compounds were identified by UHPLC-LTQ-Orbitrap MS, including terpenoids, phenylpropanoids, oligosaccharides and ketones. The established TLC had good separation and was rapid, reliable, simple, feasible, suitable for the identification of Poria and Ginseng Radix et Rhizoma in KXS. ConclusionThe specific chromatogram and TLC of KXS are stable and reproducible. The material basis of KXS is basically clarified by MS, which can provide a reference for the development and quality control of KXS.
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Da Chaihu decoction is a classic prescription for the treatment of cholecystitis that is widely used in clinical practice, and has a definite curative effect. However, due to its diverse components and complex functions, the traditional indexes fail to capture its overall efficacy. Therefore, this study analyzed and predicted the quality markers (Q-markers) of Da Chaihu decoction based on specific chromatogram and network pharmacology to provide a reference for the comprehensive control of the quality. The study obtained 35 potential practical components of Da Chaihu decoction through virtual screening. The specific chromatogram of 15 batches of Da Chaihu decoction was established by HPLC-DAD with neohesperidin as a reference. Compared with the chromatographic peaks and the reference substance, the chemical components were assigned to predict the nine components of albiflorin, paeoniflorin, naringin, hesperidin, neohesperidin, baicalin, wogonoside, saikosaponin b2, saikosaponin b1 as Q-markers of Da Chaihu decoction. Finally, the network of the "components-key targets-signal pathways-biological processes" was constructed by network pharmacology to explore the mechanism of Da Chaihu decoction in treating cholecystitis to clarify the accuracy of Q-markers. The results indicated that potential Q-markers could act on multiple targets to regulate inflammatory and metabolism, and then combine to treat cholecystitis. Q-markers could combine with the pharmacologic action of Da Chaihu decoction, which could elucidate the overall efficacy of Da Chaihu decoction. This study explored the Q-markers of Da Chaihu decoction combined with the specific chromatogram and network pharmacology, which provided a basis for the quality control and evaluation of Da Chaihu decoction.
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The Chinese Pharmacopoeia began to apply fingerprints (specific chromatogram) to quality control of traditional Chinese medicine in its 2010 edition, and in its 2015 and 2020 editions, new fingerprints (specific chromatogram) were added for improvement of the Pharmacopoeia-based national standards for drugs. This review analyzes the traditional Chinese medicine fingerprints (specific chromatogram) in Chinese Pharmacopoeia (2010-2020) in terms of the number of varieties listed, application of fingerprints (specific chromatogram), selection of evaluation method, determination method, the selection of extraction or preparation solvents of the test samples. With the expansion of the application of fingerprints (specific chromatogram), the evaluation indicators are constantly improving. The future development of the fingerprints (specific chromatogram) is also discussed in light of the selection of appropriate extraction or preparation solvents to obtain effective substances, which is the basis for the establishment of the fingerprints; multiple fingerprints for one drug based on different functional indications or basic sources, which expands the application of the fingerprints; addition of technical guidelines for traditional Chinese medicine fingerprints to standardize the use of the fingerprints; and the regular revision, update and application expansion of the fingerprints to ensure its essential role in quality control of traditional Chinese medicine.
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China , Chromatography, High Pressure Liquid/methods , Drugs, Chinese Herbal , Medicine, Chinese Traditional , Quality Control , SolventsABSTRACT
Objective:To control the quality of the reference sample of Wenjingtang by establishing the specific chromatograms. Method:On the basis of analyzing 15 batches of Wenjingtang freeze-dried powder samples, a high performance liquid chromatography (HPLC) specific chromatogram analysis method of Wenjingtang was established. The system adaptability was investigated and the retention time, relative retention value and deviation caused by different chromatographic columns and instruments were calculated by using the same brand of chromatographic columns, four different brands of chromatographic columns and instruments from three different manufacturers. The precision, repeatability and stability of this method was further completed. The possible chemical components of the freeze-dried powders were speculated and identified by ultra-performance liquid chromatography-quadrupole-time-of-flight mass spectrometry (UPLC-Q-TOF-MS<italic><sup>n</sup></italic>). Chromatographic separation was performed on ACQUITY UPLC BEH C<sub>18</sub> column (2.1 mm×100 mm, 1.7 μm) with acetonitrile (A)-0.1% formic acid aqueous solution (B) as mobile phase for gradient elution (0-2.8 min, 10%A; 2.8-8.0 min, 10%-18%A; 8.0-12.2 min, 18%-25%A; 12.2-15.3 min, 25%-40%A; 15.3-17.4 min, 40%A; 17.4-20.5 min, 40%-90%A), and column temperature was set at 30 ℃ with flow rate of 0.4 mL·min<sup>-1</sup>. Mass spectrometry was performed on electrospray ionization, data were collected under positive and negative ion modes, and the detection range was <italic>m</italic>/<italic>z</italic> 50-1 600. Result:Ten characteristic peaks were selected as the distinguishing features in this specific chromatograms, and eight of them were identified by comparing with the reference standards, including paeoniflorin (peak 1), liquiritin apioside (peak 2), liquiritin (peak 3), ferulic acid (peak 4), iquiritigenin (peak 6), cinnamaldehyde (peak 8), paeonol (peak 9)and glycyrrhizic acid (peak 10). By mass spectrometry analysis, 30 compounds were identified, and the source of medicinal materials were assigned. It mainly contained triterpenoid saponins and flavonoids from Glycyrrhizae Radix et Rhizoma, ginsenosides from Ginseng Radix et Rhizoma, monoterpenoid glycosides and tannins from Paeoniae Radix Alba, steroids in Achyranthis Bidentatae Radix, phenolic acids in Angelicae Sinensis Radix. Conclusion:The established characteristic chromatographic analysis method of Wenjingtang is simple, stable and repeatable. The chemical composition of the freeze-dried powder of Wenjingtang is basically defined by mass spectrometry identification and source attribution, which can provide reference for the development and quality control of Wenjingtang in the future.
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This work aims to establish an HPLC specific chromatogram and determine six components of Vernonia anthelmintica with chlorogenic acid, isochlorogenic acid B, isochlorogenic acid A, isochlorogenic acid C, scutellarein and luteolin as index components. HPLC analysis was performed on a Waters Xbridge C_(18) column(4.6 mm×250 mm, 5 μm) with gradient elution of acetonitrile-0.05% trifluoroacetic acid solution at a flow rate of 1.0 mL·min~(-1). The detection wave length was 360 nm and the column temperature was 30 ℃. Chemometrics software Chempattern was employed to analyze the data. HPLC specific chromatogram of V. anthelmintica was established and six characteristic peaks were marked. Six characteristic peaks were simultaneously determined by HPLC within 50 min. The contents of the six components in 13 batch samples of V. anthelmintica were 0.14%-0.68%, 0.44%-0.74%, 0.63%-1.01%, 0.14%-0.71%, 0.15%-0.26% and 0.010%-0.030%, respectively. The HPLC specific chromatogram of V. anthelmintica, together with determination of six components showed strong specificity, and it can be used for the quality control of the crude drug.
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Chromatography, High Pressure Liquid , Drugs, Chinese Herbal/chemistry , Phytochemicals/analysis , Quality Control , Vernonia/chemistryABSTRACT
In this experiment, the decoction process of famous classical formula Xiebai San was determined by optimizing the particle size of "Cuo san" and investigating the decoction process parameters, such as boiling container, water volume and duration. Xiebai San was taken as an example to explore the study method of the "Cuo san" in the famous classical formulas. The specific chromatogram of Xiebai San and the determination method of glycyrrhizin and glycyrrhizic acid in Xiebai San were established. Different particle sizes of "Cuo san" and decoction parameters were optimized based on the similarity of specific chromatogram, the specific chromatogram's peak area, the content of glycyrrhizin, the content of glycyrrhizic acid and extract yield rate.The particle size of Xiebai San powder was determined to be 2.00-4.75 mm(by four-mesh sieves). The decoction process was determined as follows: put the prescription amount into a ceramic pot, add 420 mL of water, and boil and simmer until the volume is 300 mL.The similarity of specific chromatogram was above 0.9, the specific chromatogram's peak area was larger, the content of glycyrrhizin was 0.12%, the content of glycyrrhizic acid was 0.21%,and the extract yield rate was 15.05%. The finally determined particle size of "Cuo san" can better represent the quality of Xiebai San, and is easy to prepare and suitable for industrial production.This experimental research method can comprehensively investigate the quality of Xiebai San as a whole, the content of active ingredients, and the situation of extract yield.It is a more comprehensive and objective evaluation method, and can provide experimental basis and reference for the study of other "Cuo san" famous classical formulas.
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Drugs, Chinese Herbal/chemistry , Glycyrrhizic Acid/analysis , Particle Size , Powders , Technology, PharmaceuticalABSTRACT
Objective: To establish the UPLC specific chromatogram and HPLC content determination methods of multi-index components about the material reference of classical Huaganjian and build its quality control system. Methods: According to the ancient books and combining with the previously inspected process, 18 batches of Huaganjian material reference from different origins were prepared. The specific chromatogram was established by using UPLC. Similarity was calculated by using TCM Chromatographic Fingerprint Similarity Evaluation Software (2012). Combining with orthogonal partial least squares discriminant analysis, we excavated the main components that affected the quality of Huaganjian material reference from different batches and origins. Three of these index components (paeoniflorin, hesperidin, paeonol) from prescription sovereign drug, minister drug, and assistant drug were selected and used as indicators for content determination of Huaganjian material reference. HPLC content determination methods were established and the content of 18 batches of samples was determined respectively. Results: The similarity of the specific chromatogram was ≥ 0.989. Thirty-three common peaks were calibrated, and eight common peaks were identified by chemical composition (gallic acid, geniposide, paeoniflorin, hesperidin, didymin, paeonol, sinensetin, and 3,5,6,7,8,3',4'- heptamethoxyflavone). Nine index components that affected the stability between batches were found out (Peak 31, 20, 11, 13, 22, 33, 21, 29, 1). Paeoniflorin, hesperidin, and paeonol were selected as content determination indicators. The content range of these components in material reference was 1.28%-1.95% paeoniflorin, 0.91%-1.02% hesperidin, 0.48%-0.57% paeonol. Conclusion: The quality control method of the material reference of classic prescription Huaganjian was established preliminarily through the UPLC specific chromatogram and HPLC content determination of index components. This method was rapid, simple, feasible, reproducible, stable and could provide a theoretical basis for the subsequent development and quality control of Huaganjian preparations.
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OBJECTIVE: To establish the HPLC specific chromatogram of licorice flavonoids based on chemometric analysis method, and search for differentiated components of Glycyrrhiza uralensis Fisch. cultivated for different years. METHODS: The analysis was performed on a Shiseido Capcell Pak C18 column(4.6 mm×250 mm,5 μm) by gradient elution with acetonitrile-0.1% formic acid solution as mobile phase at a flow rate of 1.0 mL•min-1. The column temperature was maintained at 40℃ and the detection wavelength was set at 280 nm. The HPLC specific chromatograms of Glycyrrhiza uralensis Fisch. cultivated for different years were further evaluated by chemometric methods including similarity analysis (SA),hierarchical clustering analysis (HCA) and principal component analysis (PCA). RESULTS: Four-years-old licorice was confirmed as the best one. Liquiritin, liquiritin apioside, liquiritigenin and isoliquiritin had significant differences, which can be used as key indicators to distinguish Glycyrrhiza uralensis Fisch. cultivated for different years. CONCLUSION: This method can provide reference for standardized cultivation and quality standard improvement of licorice.
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OBJECTIVEP: To evaluate comprehensively the quality of Glycyrrhiza uralensis Fisch. in different harvest periods by chemometric analysis based on the HPLC specific chromatogram and multi-component assay. METHODS: The similarity was analyzed with "Similarity Evaluation System for Chromatographic Fingerprint of Chinese Materia Medica 2012". t-test, correlation analysis, clustering analysis(HCA), principal component analysis (PCA) and partial least-squares discriminant analysis (PLS-DA) were used for data analysis. RESULTS: Twenty-one peaks were selected as common peaks of the fingerprint. The similarity of the samples were above 0.9. The contents of liquiritin, glycyrrhizic acid, liquiritin apioside, isoliquiritin apioside, isoliquiritin, neoisoliquiritin, echinatin, and liquiritigenin were determined.There were some differences in the quality of Glycyrrhiza uralensis Fisch. in different harvest periods, with liquiritin apioside, neoisoliquiritin and echinatin as the main compounds of difference. CONCLUSION: Autumn is confirmed as the best harvesting period of Glycyrrhiza uralensis Fisch. by chemometric analysis. It is suggested that liquiritin apioside should be used as the key quality control indicator for evaluating Glycyrrhiza uralensis Fisch.in different harvest periods.
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Objective: To extract, separate and purify homogeneous polysaccharides from Rubus sachalinensis and study on monosaccharide component and immunomodulatory activity. Methods: The crude polysaccharides of Rubus sachalinensis (RSP) were extracted by hot water. The Cellulose DE-52 and Sephadex G-100 columns were used to separate and purify homogeneous polysaccharides. The relative molecular mass was analyzed by high-performance gel permeation chromatography, and the monosaccharide composition and structure were preliminarily identified by GC, IR and NMR. The effects on proliferation function of mice spleen lymphocyte proliferation were determined by CCK-8, and the effects on the release capacity of IL-2, IFN-γ and TNF-α were determined by the ELISA kit. Results: Two homogeneous polysaccharides, RSP1-1 and RSP1-2, were separated and purified, with molecular weights of 13 227 and 9 343 determined by HPGPC. They mainly contained arabinose, mannose, glucose and galactose, with the mole ratios at 9.5:7.0:10.3:18.6 and 5.7:11.1:10.3:14.2, respectively. The structure of RSP1-1and RSP1-2 was analyzed by IR and NMR, and RSP1-1 might mainly contain α-1,3-Ara, β-1,4Gal, β-1,6-Glc, β-1,3-Man, and RSP1-2 might mainly contain β-1,4-Gal, β-1,6-Glc, β-1,3-Man. At 5-200 μg/mL, RSP1-1and RSP1-2 stimulated proliferation of spleen lymphocytes (P < 0.05) and promoted lymphocytes to secrete IFN-γ and TNF-α. At 5 μg/mL, RSP1-1and RSP1-2 promoted lymphocytes to secrete IL-2. Conclusion: RSP1-1and RSP1-2 are natural homogeneous polysaccharides that are obtained from this plants for the first time. Its purity and structure were further characterized by IR and NMR. These two homogeneous polysaccharides promoted the proliferation of splenic lymphocyte in different degrees and promoted lymphocytes to secrete IL-2, IFN-γ and TNF-α that all possessing immunomodulating activity.
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Based on UPLC specific chromatogram and determination of seven main components,this study aimed at evaluating the quality of Cistanche deserticola,C. tubulosa and C. sinensis. Echinacoside,cistanoside A,verbascoside,tubuloside A,isoacteoside,2'-acetylacteoside,tubuloside B were used as reference substances. UPLC analysis was performed on a Waters ACQUITY UPLC HSS T3 column( 2. 1 mm×100 mm,1. 8 μm). The mobile phase was acetonitrile-0. 08% trifluoroacetic acid solution. The flow rate was0. 3 mL·min-1,and the injection amount was 10 μL. The column temperature was 40 ℃,and the detection wavelength was 330 nm.The UPLC specific chromatograms were processed with ChemPattern software. UPLC specific chromatograms of C. deserticola and C.tubulosa from different samples were of high similarity,but the similarities of their counterfeit C. sinensis were less than 0. 06. Both of cluster and principal component analysis can distinguish certified products and counterfeits. The content ratios of echinacoside/verbascoside and verbascoside/isoacteoside were quite different between C. deserticola and C. tubulosa,which had distinct significance.The UPLC specific chromatogram and contents of seven main components can provide a basis for quality evaluation of Cistanches Herba.
Subject(s)
Chromatography, High Pressure Liquid , Cistanche , Chemistry , Classification , Drugs, Chinese Herbal , Reference Standards , Phytochemicals , Principal Component AnalysisABSTRACT
DNA barcoding and HPLC specific chromatogram were used to identify three kinds of Plumeria flowers respectively. DNAs extracted from the three Plumeria species were amplified by PCR with universal primers, and the psbA-trnH region was selected. All the amplified products were sequenced and the results were analyzed by MEGA 5.0. Chemometric methods including principal components analysis and hierarchical clustering analysis were conducted on the SAS 9.0 software to demonstrate the variability among samples. In conclusion, the psbA-trnH of all samples were successfully amplified from total DNA and sequenced. These three varieties of Plumeria can be differentiated by the psbA-trnH region and clustered into three groups respectively through building neighbor joining tree, which conformed to their germplasm origins. However, it was hard to distinguish them by HPLC specific chromatograms combined with chemometrics analysis. These indicated that DNA barcoding was a promising and reliable tool for the identification of three kinds of Plumeria flowers compared to HPLC specific chromatogram generally used. It could be treated as a powerful complementary method for traditional authentication, especially for those varieties which are difficult to be identified by conventional chromatography.
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High price and difficult to get of reference substance have become obstacles to HPLC assay of ethnic medicine. A new method based on quantitative reference herb (QRH) was proposed. Specific chromatograms in fruits of Capsicum frutescens were employed to determine peak positions, and HPLC quantitative reference herb was prepared from fruits of C. frutescens. The content of capsaicin and dihydrocapsaicin in the quantitative control herb was determined by HPLC. Eleven batches of fruits of C. frutescens were analyzed with quantitative reference herb and reference substance respectively. The results showed no difference. The present method is feasible for quality control of ethnic medicines and quantitative reference herb is suitable to replace reference substances in assay.
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Objective: To establish a new standard for the quality evaluation of Schisandrae chinensis Fructus. Methods: On the basis of the 2015 edition pharmacopoeia standard of Schisandrae chinensis Fructus, some testing items including the characteristic chro-matogram (HPLC) and total lignans content (UV) were established. Results: With schizandrin as the reference material, the HPLC specific chromatograms of Schisandrae chinensis Fructus including 7 characteristic peaks were established. The content of total lignans in Schisandrae chinensis Fructus was not less than 1. 8% with schizandrin as the standard. Conclusion: The proposed quality evalua-tion standard is more comprehensive and reproducible. It can provide a more scientific evaluation tool for the quality evaluation of Schisandrae chinensis Fructus and its related preparations.
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Objective:To establish the HPLC specific chromatogram and provide comprehensive evaluation of Xanthii fructus from different regions.Methods:The HPLC analysis was performed on an Alltima C18 column (250 mm ×4.6 mm,5μm) with acetonitrile-0.1%phosphoric acid solution as the mobile phase with gradient elution at a flow rate of 0.8 ml· min-1 .The detection wavelength was 278 nm.The column temperature was 25℃.The software"Similarity Evaluation System for Chromatographic Fingerprint of TCMs"was employed to carry out the similarity analysis of the samples from Henan , Jilin, Anhui and the other regions .Results:The specific chromatogram was preliminarily constructed and 5 common peaks with chlorogenic acid as the reference were identified .Conclusion:The method is scientific basis of the quality assessment of Xanthii fructus with convenient and reliable properties .
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OBJECTIVE: To establish the HPLC specific chromatogram of Oldenlandia corymbosa Linn. and Oldenlan diadiffusa (Willd.) Roxb. in different regions so as to distinguish these two traditional Chinese medicinal materials. METHODS: HPLC was performed on an Agilent Eclipse XDB-C18(4.6 mm×250 mm,5 μm) column with mobile phase consisting of methanol-water at a flow rate of 1 mL·min-1, column temperature at 30℃ and detection wavelength at 254 nm. Similarity evaluation system for chromatographic fingerprint of TCM was used to conduct similarity evaluation and Matlab7.0 software was used for principal component and cluster analysis. RESULTS: Oldenlandia corymbosa Linn. and Oldenlan diadiffusa (Willd.) Roxb. had eight common peaks, namely, a-h; the characteristic peaks of O. corymbosa were 7 to 12, while the characteristic peaks of O. diffusa were 1 to 6. The similarity values of O. corymbosa and O. diffusa collected from different sources were 0.733-0.984 and 0.873-0.951, respectively. According to the principal components analysis and cluster analysis, the tested samples were classified into three categories: O. corymbosa collected from wild, O. diffusa collected from wild and purchased O. diffusa. CONCLUSION: The established method is reliable and rapid to distinguish the two kinds of easily confused traditional Chinese medicinal materials and also can offer reference for their quality control and clinical use.