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ObjectiveTo identify the prototypical components and metabolites absorbed into blood and cerebrospinal fluid of Schisandrae Chinensis Fructus(SCF) based on sequential metabolism combined with liquid chromatography-mass spectrometry. MethodBlood and cerebrospinal fluid samples of integrated metabolism, intestinal metabolism and hepatic metabolism were collected from male SD rats after gavage and in situ intestinal perfusion administration, and ultra-performance liquid chromatography-quadrupole/electrostatic field orbitrap high-resolution mass spectrometry(UPLC Q-Exactive Orbitrap MS) was used to analyze and compare the differences in the spectra of SCF extract, blank plasma, administered plasma, blank cerebrospinal fluid and administered cerebrospinal fluid with ACQUITY UPLC BEH Shield RP18 column(2.1 mm×100 mm, 1.7 µm), the mobile phase was acetonitrile(A)-0.1% formic acid aqueous solution(B) for gradient elution(0-7 min, 95%B; 7-12 min, 95%-35%B; 12-17 min, 35%-15%B; 17-20 min, 15%-12%B; 20-22 min, 12%-5%B; 22-23 min, 5%B; 23-25 min, 5%-95%B; 25-28 min, 95%B). And heated electrospray ionization(HESI) was used with positive and negative ion modes, the scanning range was m/z 100-1 500. The prototypical constituents and their metabolites absorbed into blood and cerebrospinal fluid of SCF were identified according to the retention time, characteristic fragments, molecular formulae and the information of reference substances. ResultA total of 42 chemical components were identified in the extract of SCF, including lignans, flavonoids, amino acids, tannins, and others, of which lignans were the main ones. A total of 27 prototypical components and 14 metabolites were identified in plasma samples from different sites. A total of 15 prototypical components and 9 metabolites were identified in cerebrospinal fluid. The main metabolic reactions involved in the formation of metabolites were mainly demethylation, methylation, demethoxylation and hydroxylation. ConclusionThrough the systematic identification of the prototypical components and metabolites of SCF in rats, it provides data support for further better exploring the material basis of SCF in the treatment of central nervous system diseases.
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ObjectiveTo study the metabolism of chemical components from Citri Reticulatae Pericarpium(CRP)in different parts of rats by sequential metabolism and ultra performance liquid chromatography-high resolution mass spectrometry(UPLC-HRMS). MethodSD male rats were employed as experimental subjects, and blood samples of intestinal metabolism and hepatic metabolism were prepared after administration of CRP ethanol extract by in situ intestinal perfusion, and comprehensive metabolic samples were collected after intragastric administration. UPLC-HRMS was used to analyze the samples with acetonitrile(A)-0.1% formic acid aqueous solution(B)as the mobile phase for gradient elution(0-10 min, 10%-30%A; 10-30 min, 30%-95%A; 30-31 min, 95%-10%A; 31-35 min, 10%A)at a flow rate of 0.35 mL·min-1, using a heated electrospray ionization with positive and negative ion mode scanning in the range of m/z 100-1 500. Under these conditions, the differences in the profiles of CRP ethanol extract, blank plasma and drug-containing plasma under different treatment groups were compared, and the chemical components of each sample were analyzed and identified based on the retention time, accurate relative molecular mass, primary and secondary ion fragments, and the information of reference substances. ResultA total of 44 chemical components were identified in the CRP ethanol extract, including flavone-O-glycosides, flavone-C-glycosides and polymethoxyflavonoids, etc. The results of sequential metabolism showed that 22 chemical components in CRP were detected in the intestinal metabolic sample, 18 chemical components were detected in the hepatic metabolic sample, and 9 identical chemical components(narirutin, hesperidin, meranzin, 5,7,8,3ʹ,4ʹ,5ʹ-hexamethoxy-flavone, isosinensetin, sinensetin, 3,5,6,7,8,3ʹ,4ʹ-heptamethoxyflavone, nobiletin and tangeretin)could be detected in all three metabolic samples, with a total of 22 compounds entering the blood in prototype form. ConclusionThe identified 21 components with well-defined structures entering the blood as prototypes may be potential active components of CRP, and differences in the components at different metabolic parts can provide an experimental basis for elucidating the in vivo biotransformation process of the metabolic components of CRP.
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Objective To investigate dynamic metabolism in vivo of Ginkgo Folium Tablet under the guidance of sequential metabolism thoughts. Methods In situ closed-loop in rats was carried out to study sequential metabolism of Ginkgo Folium Tablet through oral digestive system, namely to investigate and compare the intestinal flora metabolism, the gut wall metabolism and hepatic metabolism, combined with chromatographic fingerprint of blood samples. Results The analysis showed that 12 peaks in Ginkgo Folium Tablet were metabolized by intestinal flora, and 7 peaks generated through the gut wall. Most components of Ginkgo Folium Tablet were metabolized in liver, and 3 original medicine components were directly into the blood. Conclusion This study conducts a qualitative description of metabolism of Ginkgo Folium Tablet in different parts of the oral route, and provides references for the quality control, mechanism explanation and secondary development for Ginkgo Folium Tablet.
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Objective To study the multicomponent in vivo dynamic process in Chuanxiong Rhizoma;To elaborate in vivo metabolic profiling. Methods HPLC was used to establish the fingerprint of aqueous extract of Chuanxiong Rhizoma, and multicomponent changes were detected at the same time. Closed-loop intestine method was used to study the multicomponent changes of oral administration of Chuanxiong Rhizoma after stomach-intestine-liver process. Results Totally 17 components were detected in the fingerprint of aqueous extract of Chuanxiong Rhizoma and they were basically stable in the digestive juice. For in vivo metabolism, 4 components were metabolized by intestinal flora;3 components were metabolized by liver;2 new components were the metabolites of intestinal flora;1 component was the metabolite of liver. Conclusion Multicomponent sequential metabolism and closed-loop intestine method were used to clarify that multicomponent metabolic profiling was feasible, and it could provide experimental basis for the metabolism of traditional Chinese medicine.
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The core of multicomponent drug metabolism is the mutual influence of the transporters and drug metabolic enzymes interaction of more ingredients, with the simultaneous determination for multiple components as the principle, and with many components changes on the environmental impact as the emphasis. Its theoretical content composes by sequential metabolism, concurrent metabolism, and multiple metabolism. On the principles of multicomponent simultaneous determination, metabolic continuous time records, metabolic continuous space records, and the combination of qualitative and quantitative research, the multicomponent drug metabolism is researched by the experimental methods of in vivo, in situ, and in vitro. In visual mode of the comparative analysis with the quantitative data evaluation, multicomponent drug metabolism can be thought of emerging research direction with solid academic foundation and advanced technical means.