ABSTRACT
Objective:To observe the metabolic characteristics of effective components from Polygonum orientale inflorescences in intestinal flora of rats. Method:The incubating samples of effective components from P. orientale inflorescences in rat intestinal flora in vitro were detected by UPLC-ESI-Q-TOF-MS/MS, the mobile phase was consisted of 0.1%formic acid solution-0.1%formic acid acetonitrile solution and eluted in gradient mode at a flow rate of 0.3 mL·min-1.The mass spectral analysis was detected with electrospray ionization under positive ion mode and negative ion mode.The metabolites and possible biotransformation pathways of effective components form P. orientale inflorescences in rat intestinal flora in vitro was analyzed by Metabolite ToolsTM, mass defect filtration(MDF) and other metabolite analysis techniques and combined with the accurate relative molecular weight of the compounds, the fragment ion information and the literature data. Result:Eighteen metabolites were detected after incubation of effective components from P. orientale inflorescences in rat intestinal flora.The main biotransformation pathways were reduction, oxidation, hydrolysis in Ⅰ phase reaction and methylation in Ⅱ phase reaction. Conclusion:The effective components of P. orientale inflorescences can be transformed into a variety of metabolites under the action of intestinal flora in rats.It is suggested that whether the metabolites are bioactive components should be considered when P. orientale inflorescences is used as medicine.
ABSTRACT
To investigate the metabolism of quercitrin in rat intestinal flora and possible biological pathways, laying the foundation for the metabolic mechanism of traditional Chinese medicine glycosides ingredients. UPLC-Q-TOF-MS/MS method was established to detect the quercitrin and its metabolites with 0.1% formic acid solution(A)-0.1% formic acid acetonitrile(B) as the mobile phase for gradient elution at a flow rate of 0.3 mL•min⁻¹. Electrospray negative ion mode was applied to analyze the metabolites of quercitrin in rat intestinal flora. Metabolite ToolsTM, mass defect filter(MDF) and other technologies were used to screen, analyze the metabolites and infer the chemical formula of the metabolites. The results showed that quercitrin would have degalactoside, deoxygenation and acetylation reactions, and the aglycone quercetin resulted from degalactoside would have further reactions such as hydroxylation, deoxygenation, reduction, and ring opening to achieve deoxygenation metabolite kaempferol, C2-C3 double bonds hydrogenation and reduction product taxifolin, and degalactoside product quercetin. The research results showed that quercitrin can be metabolized by rat intestinal flora, which could increase their hydrophobicity and chemical diversity.