Simultaneous quantification of multiple components in rat plasma by UPLC-MS/MS and pharmacokinetic study after oral administration of Huangqi decoction.

A rapid, sensitive and accurate UPLC-MS/MS method was developed for the simultaneous quantification of components of Huangqi decoction (HQD), such as calycosin-7-O-ß-d-glucoside, calycosin-glucuronide, liquiritin, formononetin-glucuronide, isoliquiritin, liquiritigenin, ononin, calycosin, isoliquiritigenin, formononetin, glycyrrhizic acid, astragaloside IV, cycloastragenol, and glycyrrhetinic acid, in rat plasma. After plasma samples were extracted by protein precipitation, chromatographic separation was performed with a C18 column, using a gradient of methanol and 0.05% acetic acid containing 4mm ammonium acetate as the mobile phase. Multiple reaction monitoring scanning was performed to quantify the analytes, and the electrospray ion source polarity was switched between positive and negative modes in a single run of 10 min. Method validation showed that specificity, linearity, accuracy, precision, extraction recovery, matrix effect and stability for 14 components met the requirements for their quantitation in biological samples. The established method was successfully applied to the pharmacokinetic study of multiple components in rats after intragastric administration of HQD. The results clarified the pharmacokinetic characteristics of multiple components found in HQD. This research provides useful information for understanding the relation between the chemical components of HQD and their therapeutic effects.

[Effect of Huangqi decoction on entecavir pharmacokinetics in rat plasma].

Entecavir (ETV), a guanosine nucleotide antiviral agent with activity against hepatitis B virus (HBV) and Huangqi decoction (HQD) that exerts significant therapeutic effects in liver cirrhosis are used as an effective drug combination in the treatment of liver cirrhosis with HBV. Therefore, this study was designed to assess the effect of HQD on ETV pharmacokinetics in rat plasma. Spraque-Dawley (SD) rats were randomized into single- and 7-day-dose experimental groups. The ETV and ETV-HQD groups were administered ETV and a simultaneous combination of ETV and HQD, respectively while the ETV-HQD-2h group received HQD 2 h after ETV treatment, all administered via intragastric (i.g.) gavage. A rapid, sensitive, and efficient ultra-high- performance liquid chromatography-linear trap quadrupole (UHPLC-LTQ)-Orbitrap method was developed and validated to determine ETV in rat plasma from blood samples collected at different time points following treatment. The linearity, accuracy, precision, recovery, matrix effects and stability of ETV were all satisfactory. The ETV-HQD group exhibited a decrease in the maximum plasma concentration (Cmax), and a delay in time to achieve Cmax (tmax) following single- and multi-dose administrations, and decreased area under the concentration- time curve (AUC0­t) following single dosing. ETV pharmacokinetics did not change significantly between the ETV and ETV-HQD-2h groups. In vitro everted intestinal sac models experiments indicated that HQD decreased the absorption of ETV. HQD prevented ETV from accessing the intestinal mucosa epithelial surface, thereby decreasing its absorption in rats.

Chicken bile powder protects against α-naphthylisothiocyanate-induced cholestatic liver injury in mice.

This study explored the effects of chicken bile powder (CBP), a 2000-year-old Chinese medicine, on α-naphthyl isothiocyanate (ANIT)-induced intrahepatic cholestasis in mice. CBP treatment for 14 days significantly ameliorated ANIT-induced changes in serum alanine aminotransferase, aspartate aminotransferase, bile acids, bilirubin, γ-glutamyl transpeptidase, alkaline phosphatase, and liver tissue morphology. Serum metabolomics showed changes in 24 metabolites in ANIT-exposed mice; 16 of these metabolites were reversed by CBP treatment via two main pathways (bile acid biosynthesis and arachidonic acid metabolism). Additionally, CBP administration markedly increased fecal and biliary bile acid excretion, and reduced total and hydrophobic bile acid levels in the livers of cholestatic mice. Moreover, CBP increased liver expression of bile acid efflux transporters and metabolic enzymes. It also attenuated ANIT-induced increases in hepatic nuclear factor-κB-mediated inflammatory signaling, and increased liver expression of the nuclear farnesoid X receptor (FXR) in cholestatic mice. CBP also activated FXR in vitro in HEK293T cells expressing mouse Na+-taurocholate cotransporting polypeptide. It did not ameliorate the ANIT-induced liver injuries in FXR-knockout mice. These results suggested that CBP provided protection from cholestatic liver injury by restoring bile acid homeostasis and reducing inflammation in a FXR-dependent manner.