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This study aims to establish a method for the simultaneous determination of 7 active components in Dracocephalum tanguticum and to evaluate the quality of medicinal materials from different habitats. The method was established with high performance liquid chromatography(HPLC) and the gradient elution was performed with the mobile phase of acetonitrile-methanol-0.2% phosphoric acid solution at a column temperature of 35 ℃, an injection volume of 15 μL, and a flow rate of 0.6 mL·min~(-1). The detection wavelength was set as 215 nm. With rosmarinic acid as the internal reference, the relative correction factors and the content of other 6 components were calculated. The results were compared with those obtained with the external standard method. The results showed that the samples from Huangzhong county, Qinghai province had the best quality, with the highest content of p-hydroxybenzoic acid, cosmosiin, rosmarinic acid, oleanolic acid, and ursolic acid(9.29, 12.14, 6.02, 3.11, 17.67 mg·g~(-1) respectively). The samples from Chaya county, Tibet autonomous region ranked the second, with the highest content of betulin and betulinic acid(15.53, 7.17 mg·g~(-1), respectively). The method is accurate, reliable, and repeatable and suitable for the simultaneous determination of multiple components in D. tanguticum. The content of functional components varied in the samples from different producing areas and can be used as the indicator for the quality evaluation of medicinal materials.
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Cinamatos , Medicamentos de Ervas Chinesas/análise , Lamiaceae , Cromatografia Líquida de Alta Pressão/métodos , Ácido RosmarínicoRESUMO
The stability of volatile oil quality of traditional Chinese medicine is an important prerequisite for its clinical efficacy and safety. The quality of volatile oil of traditional Chinese medicine is affected by many factors, such as location, producing area, harvest time, extraction process, processing process and so on, which leads to the difference of oil yield or chemical composition of volatile oil, affects the uniformity of volatile oil quality of traditional Chinese medicine, and then affects the curative effect of volatile oil. Therefore, how to control the quality of volatile oil is the key to the role of volatile oil in traditional Chinese medicine. In this paper, the effects of different parts of medicinal materials, different producing areas and different harvest periods on the quality of volatile oil of traditional Chinese medicine were analyzed, and the 2015 edition of Chinese Pharmacopoeia containing volatile oil was classified according to medicinal parts, and the differences of volatile oil components of traditional Chinese medicine were discussed in order to provide reference for the development of volatile oil of traditional Chinese medicine and the establishment of quality standard of volatile oil of traditional Chinese medicine.
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OBJECTIVE: To establish a method for simultaneous determination of 10 isoflavones in Belamcanda chinensis, and to evaluate the differences of active ingredient content of B. chinensis from different areas. METHODS: UPLC method was adopted. The determination was performed on Waters ACQUITY UPLC BEH C18 column with mobile phase consisted of 0.5 % methyl-β-cyclodextrin and 0.1% phosphate as water phase, acetonitrile as organic phase (gradient elution) at the flow rate of 0.2 mL/min. The column temperature was set at 35 ℃, and the detection wavelength was set at 265 nm. The sample size was 2 μL, and analysis time was 20 min. The contents of 10 isoflavones in 26 samples from 8 provinces, including tectoridin, iristectorin A, iristectorin B, iridin, tectorigenin, iristectorigenin B, iristectorigenin A, irigenin, irisflorentin, dichotomitin, were determined. RESULTS: The linear ranges of tectoridin, iristectorin A, iristectorin B, iridin, tectorigenin, iristectorigenin B, iristectorigenin A, irigenin, irisflorentin, dichotomitin were 8.569 5-342.78, 0.643-25.72, 1.119 8-44.79, 2.187 8-87.51, 0.770 3-30.81, 0.421 3- 16.85, 0.288 5-11.54, 1.795 3-71.81, 0.560 8-22.43, 0.086-3.44 μg/mL(all r≥0.999 6). The limits of quantitation were 0.015, 0.102, 0.096, 0.013, 0.036, 0.088, 0.102, 0.019, 0.067, 0.092 μg/mL. RSDs of precision, stability(24 h)and reproducibility tests were lower than 2.00% (n=6). The recoveries ranged 95.30%-103.30% (all RSD≤2.33%, n=6). Among 26 samples of B. chinensis, the content of tectoridin was the highest (3.66%-57.79%), and the content of dichotomitin was the lowest (0.09%- 0.59%), the contents of irisflorentin were 0.29-2.80 mg/g. The contents of isoflavones in B. chinensis from different areas were different greatly. CONCLUSIONS: The established method is sensitive, with short analysis time and good repeatability, and can be used to determine the content of 10 isoflavones and evaluate the content difference of each component.
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Objective To evaluate the quality of Hedysari Radix from different producing areas in Gansu Province by setting Hedysari Radix from different producing areas in Gansu Province as study subjects and trace elements in Hedysari Radix as evaluation indexes; To provide the references for establishment of the quality standards of Hedysari Radix.Methods The content of Fe, Cu, Ca, Mn, Zn, Mg, Cr, Co, Na, Li, Ni and K in Hedysari Radix were detected by using flame atomic absorbption method. Data were analyzed by the factor analysis conducted by SPSS21.0 software. The common factors were extracted by principal component and analytic function for quality comprehensive ranking was established.ResultsThree common factors were extracted, namely F1, F2, and F3. The quality function was Y=0.657F1+0.119F2+0.089F3. Cr, Li, Co, Cu, Zn, Fe and Mg were the characteristic trace elements of Hedysari Radix that could affect the quality of Hedysari Radix. When the quality of Hedysari Radix was evaluated by the contents of trace elements, the quality of wild Hedysari Radix were better than cultivated Hedysari Radix and the quality rank was consistent with the idea that Longnan is the main producing area of Hedysari Radix. The quality of samples from Dingxi area was better.Conclusion The quality evaluation of Hedysari Radix based on trace elements shows the differences in Hedysari Radix from different producing areas in Gansu Province and the results are relatively reasonable.
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OBJECTIVE:To detect the contents of chlorogenic acid and rutoside in Saussurea involucrate,and to optimize the decoction and extraction technology of S. involucrate from different producing areas. METHODS:The contents of chlorogenic acid and rutoside in 10 batches of S. involucrate from different producing areas were determined by HPLC. L9(34)orthogonal experiment was used to optimize the water amount,decoction times and decoction time using comprehensive score of extraction transport rate of chlorogenic acid and rutoside as index. The verification test was also conducted. RESULTS:The contents of chlorogenic acid and rutoside in 10 batches of S. involucrate were 0.380%-0.546% and 0.334%-0.617%;the optimal decoction technology was as follows as the amout of crude material of S. involucrate 100 g,soaking for 20 min,decocting for 3 times,12,10 and 10 fold of water,decocting 45,30 and 30 min,respectively. The extraction transfer rates of chlorogenic acid and rutoside were 96.2%(RSD=2.66%,n=3)and 89.3%(RSD=3.31%,n=3)in verification test. CONCLUSIONS:For S. involucrate from different producing areas,the contents of effective components are different;optimized decoction and extraction technology is stable and feasible.
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AIM: To get the IR spectrums of chrysanthemums from the different producing areas,and to find out the characters of IR spectrums,and the data of IR spectroscopy of chrysanthemums from the different producing areas. METHODS: Using Fourier transform infrared spectroscopy. RESULTS: The FTIR spectrums、Second-order derivative spectrums、Two-dimensional spectrums of chrysanthemums from the different producing areas have their obvious IR characters. CONCLUSION: We can discriminate chrysanthemums from the different producing areas macroscopically and holistically by IR spectroscopy.IR spectroscopy can give us the digital descriptions of TCM,so it is a new analytical method to discriminate TCM.