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Objective:To determine the contents of quercetin, kaempferol, total flavonoids and extracts in 52 samples of Lysimachiae Herba collected from different origins; To analyze the quality differences of Lysimachiae Herba among different producing areas. Methods:The quercetin and kaempferol contents of the Lysimachiae Herba from Guizhou Province, Sichuan Province and Chongqing were determined by HPLC, and the total flavonoids were determined by Symergy HTX microplate reader. Results:The total content of quercetin and kaempferol in 52 samples was among 0.146 2-2.517 0 mg/g, with an average content of 0.872 6 mg/g, among which the average content of Sichuan was 1.073 2 mg/g, that of Guizhou was 0.705 4 mg/g, and that of Chongqing was 0.865 1 mg/g. Among them, 20 samples reached the standard of the Chinese Pharmacopoeia. The average content of the samples that met the standard was 1.439 7 mg/g. The compliance rate of samples collected in Guizhou, Sichuan and Chongqing reached 12.5%, 62.5%, and 38.8% respectively. The total flavonoid content of 52 samples was among 0.994 2- 3.866 4 mg/g, and 52 samples were in conformity with the ethanol hot extract standard of the Chinese Pharmacopoeia. Conclusions:The total contents of quercetin and kaempferol from different sources in Sichuan, Guizhou and Chongqing are quite different, and the total contents of quercetin and kaempferol collected from the same district and county are also quite different, and the compliance rate is low. There are great differences in total flavonoids in different producing areas and different populations of Lysimachiae Herba samples collected in the field.
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A method based on ultra-high performance liquid chromatography coupled with triple quadrupole linear ion trap-tandem mass spectrometry(UHPLC-QTRAP-MS/MS) was developed for the simultaneous determination of 41 bioactive constituents of flavonoids, organic acids, nucleosides, and amino acids in Lysimachiae Herba. The content of multiple bioactive constituents was compared among the samples from different habitats. The chromatographic separation was performed in a Waters XBridge®C_(18) column(4.6 mm×100 mm, 3.5 μm) at 30 ℃. The gradient elution was performed with 0.4% methanol(A)-formic acid water(B) as the mobile phase at a flow rate of 0.8 mL·min~(-1), and the multiple-reaction monitoring(MRM) mode was adopted. According to the content of 41 constituents, hierarchical cluster analysis(HCA), orthogonal partial least squares discriminant analysis(OPLS-DA), and gray relational analysis(GRA) were perfomed to comprehensively evaluate the samples from different habitats. The results showed that the 41 constituents exhibited good linear relationship within the tested concentration ranges, with the correlation coefficients(r) greater than 0.999 4. The method featured good precision, repeatability, and stability with the relative standard deviations(RSDs) less than 5.0%. The average recoveries of the 41 constituents ranged from 98.06% to 101.9%, with the RSDs of 0.62%-4.6%. HCA and OPLS-DA separated 48 batches of Lysimachiae Herba samples from different habitats into three categories: the producing areas in Sichuan and Chongqing, the producing areas in Jiangsu, Zhejiang, and Jiangxi, and the producing areas in Guizhou. The content of 41 constituents varied among the Lysimachiae Herba samples from different habitats. The GRA results revealed that the Lysimachiae Herba sample from Nanchong City, Sichuan Province had the best comprehensive quality. The method developed in this study was accurate and reliable and thus can be used for comprehensive evaluation of Lysimachiae Herba quality and provide basic information for the selection of habitats.
Assuntos
Espectrometria de Massas em Tandem/métodos , Análise Multivariada , Cromatografia Líquida de Alta Pressão/métodos , Medicamentos de Ervas Chinesas/química , Aminoácidos/análiseRESUMO
Objective:To investigate the effect of different extracts of Lysimachiae Herba on the main toxicity induced by Tripterygii Radix et Rhizoma. Method:Ninety male SPF Kunming mice were randomly divided into 9 groups according to their body weight,control group, Lysimachiae Herba water extract group, Lysimachiae Herba 30% ethanol extract group, Tripterygii Radix et Rhizoma group, Tripterygii Radix et Rhizoma combined with Lysimachiae Herba water extract group, Tripterygii Radix et Rhizoma combined with Lysimachiae Herba 30% ethanol extract group, Tripterygii Radix et Rhizoma combined with Lysimachiae Herba 60% ethanol extract group, Tripterygii Radix et Rhizoma combined with Lysimachiae Herba 95% ethanol extract group and Tripterygii Radix et Rhizoma combined with Lysimachiae Herba ethyl acetate extract group. The dosage of Tripterygii Radix et Rhizoma and Lysimachiae Herba were 2,1 g·kg<sup>-1</sup> based on crude drugs, respectively. The control group was given an equal volume of solvent, and each group was given by gavage for 14 consecutive days. The blood and liver tissues were taken 24 hours after the last administration. The enzyme linked immunosorbent assay (ELISA) was used to detect serum biochemical indexes and liver lipid peroxidation/antioxidant indexes in mice. Meanwhile, principal component analysis was used to evaluate the attenuating effect and the mechanism of Lysimachiae Herba extract on toxicity of Tripterygii Radix et Rhizoma. Result:Compared with control group, Tripterygii Radix et Rhizoma caused the levels of alanine aminotransferase(ALT),aspartic acid amino transferase(AST),alkaline phosphatase(ALP) in serum of mice, and the levels of malondialdehyde (MDA) in liver, and comprehensive score of toxicity (Z value) produced by the above four indexes increased significantly (<italic>P</italic><0.01). The levels of total superoxide dismutase (T-SOD),glutathione-peroxidase (GPX),glutathione-S transferase (GST) decreased significantly (<italic>P</italic><0.01) in liver. Compared with Tripterygii Radix et Rhizoma group, after intervention with extracts of two solvents (water, 30% ethanol) of Lysimachiae Herba, the levels of serum ALT, AST, ALP and liver MDA were significantly decreased (<italic>P</italic><0.05, <italic>P</italic><0.01), while the levels of liver T-SOD, GPX and GST were significantly increased (<italic>P</italic><0.01). After intervention with extracts of two solvents (60% ethanol, 95% ethanol) of Lysimachiae Herba, the levels of serum ALT, AST, ALP were significantly decreased (<italic>P</italic><0.01), and liver GPX levels were significantly increased (<italic>P</italic><0.01). After the intervention with ethyl acetate extract of Lysimachiae Herba, only the level of serum AST was significantly decreased (<italic>P</italic><0.05) and the level of GPX was significantly increased (<italic>P</italic><0.05). After the intervention with extracts of different solvents (water, 30% ethanol, 60% ethanol, 95% ethanol, ethyl acetate) of Lysimachiae Herba, it can significantly reduce the comprehensive score of toxicity (<italic>P</italic><0.01). The overall decline rates of toxicity were 127.5%, 113.4%, 98.1%, 56.3% and 31.0% respectively. Among them, the toxicity reduction rate of the extracts with water as a solvent was 14.1%, 29.4%, 71.2%, 96.5% higher than those of other solvent extracts with ethanol. Conclusion:The extracts of different solvents (water, 30% ethanol, 60% ethanol, 95% ethanol and ethyl acetate) of Lysimachiae Herba can reverse the toxicity induced by Tripterygii Radix et Rhizoma in varying degrees. Among them, water and 30% ethanol are the best solvents for detoxification, especially water as the extraction solvent, and with the increase of ethanol content or fat solubility of extraction solvent, the detoxification shows a downward trend.
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Objective: To overall evaluate the mutual detoxication mechanism of Tripterygii Radix et Rhizoma(LGT) compatible with Lysimachiae Herba(JQC) in tumor-bearing state.Method: Twelve differentially characteristic components before and after compatibility were used as chemical composition spectrum,six indicators including serum alanine aminotransferase(ALT),aspartate aminotransferase(AST),creatinine(Cr) and urea nitrogen(BUN),malondialdehyde(MDA) levels in the liver and kidney tissues were used as attenuation spectrum,and twelve biological indicators including glutathione(GSH),glutathione-S-transferase(GST),glutathione peroxidase(GPx),superoxide dismutase(SOD),catalase(CAT) and interleukin(IL)-10 in the liver and kidney were used as the biological information spectrum.Mutual detoxication mechanisms of LGT compatible with JQC in tumor-bearing state were overall evaluated by principal component analysis(PCA),and the contribution of chemical components and biological indicators to mutual detoxication was further evaluated by gray correlation analysis(GCA) of "chemical composition spectrum-attenuation spectrum-biological information spectrum".Result: Compared with the model group,the attenuation spectrum scores Z values of S180(Z1 value) and H22(Z3 value) increased significantly after LGT being used alone(PZ1 value and Z3 value caused by LGT when the ratio of LGT and JQC was 4:1,2:1,1:1,1:2 and 1:4(PZ values(Z1 value and Z3 value) of LGT-JQC in the mass ratios including 4:1,1:1,1:2 and 1:4 was significantly higher than that in the ratio of 2:1(PZ values of the bioinformatics scores in the S180(Z2 value) and H22(Z4 value) tumor-bearing state,these two values were significantly increased after compatibility with JQC.The chemical components contributing the most to the attenuating effect of S180 and H22 in tumor-bearing state were 3# and 10#,respectively.The most important biological indicators were kidney GPx and renal GSH.Conclusion: LGT combined with JQC in the mass ratio of 4:1-1:4 can attenuate LGT-induced subacute toxicity in S180 and H22 tumor-bearing state,and the best ratio of such effect is 2:1.The attenuating effect reflects the thought of "there is no reason why there is no meteorology".The mechanism of attenuating action involves antioxidative damage and anti-inflammatory reaction of the liver and kidney,especially the renal GPx(S180) and renal GSH(H22) as the greatest contribution to the detoxication mechanism.