From single compounds to herbal extract: a strategy to systematically characterize the metabolites of licorice in rats

Metabolite identification and pharmacokinetic study of Lamiophlomis rotata in rats

An ultra-high performance liquid chromatography coupled with time-of-flight mass spectrometry technique and a subsequent LC-MS/MS method were developed for metabolite profile study of Lamiophlomis rotata extract after its oral administration.

Glycyrrhiza glabra

Liquorice foliage

Prenylation and Backbone Structure of Flavonoids and Isoflavonoids from Licorice and Hop Influence Their Phase I and II Metabolism

In vitro liver metabolism of 11 prenylated flavonoids and isoflavonoids was investigated by determining their phase I glucuronyl and sulfate metabolites using pork liver preparations. One hundred metabolites were annotated using RP-UHPLC-ESI-MS(n). A mass spectrometry-based data interpretation guideline was proposed for the tentative annotation of the position of hydroxyl groups, considering its relevance for estrogenic activity. To relate structure to metabolism, compounds were classified on the basis of three criteria: backbone structure (isoflavene, isoflavan, or flavanone), number of prenyl groups (0, 1, or 2), and prenyl configuration (chain or pyran). Glucuronidation was most extensive for isoflavenes and for unprenylated compounds (yield of 90-100%). Pyran and chain prenylation gave more complex hydroxylation patterns with 4 or more than 6 hydroxyl isomers, respectively, as compared to unprenylated compounds (only 1 hydroxyl isomer). Moreover, the number of hydroxyl isomers also increased with the number of prenyl groups.

Effects of Gancao on pharmacokinetic profiles of platycodin D and deapio-platycodin D in Jiegeng

ETHNOPHARMACOLOGICAL RELEVANCE

Jiegeng (Radix Platycodi), the dried root of Platycodon grandiflorum A. DC (Campanulaceae), has been used to treat cough, sore throat, bronchitis, and bronchial asthma for thousands of years. It is commonly prescribed with Gancao (Radix et Rhizoma Glycyrrhizae) as a herbal combination in traditional Chinese medicine (TCM) to produce synergistic effects.

AIM OF THE STUDY

To elucidate the herbaceous compatibility of Jiegeng and Gancao, we investigated the comparative pharmacokinetics, intestinal absorption, and microbial metabolism of platycodin D (PD) and deapio-platycodin D (DPD), the platycodins contained in Jiegeng.

MATERIALS AND METHODS

In the comparative pharmacokinetic study, the concentrations of PD and DPD in Jiegeng extract (JE) and the Jiegeng-Gancao herb pair (JGHP) were determined in rat plasma using liquid chromatography-tandem mass spectrometry (LC-MS/MS). In addition, the main pharmacokinetic parameters were calculated using data analysis software (DAS). Furthermore, in vitro studies using Caco-2 cells and fecal lysates were performed to contradistinguish the intestinal absorption and microbial metabolism of PD and DPD in JE from those in JGHP.

RESULTS

The peak concentration (Cmax) and area under the plasma concentration curve (AUC) of PD in rats orally administrated JGHP significantly increased compared to that in rats treated with JE. In addition, the time to reach peak concentration (Tmax) and half-life (t1/2) of PD and DPD in combination with JGHP were all prolonged compared with those of JE. There was no significant difference in the absorption of PD between JE and JGHP in Caco-2 cells. However, the hydrolysis of both PD and DPD in JGHP were weaker than that in JE after a 2-h incubation in fecal lysate which might be responsible for the different pharmacokinetic profiles of the platycodins in JE and JGHP.

CONCLUSION

In this study, we discovered that Gancao might influence the pharmacokinetic profiles of PD and DPD in Jiegeng. Furthermore, the difference in profiles may be attributable to the inequable microbial metabolism rather than intestinal absorption of the platycodins in JE and JGHP. The results of this study elucidated the pharmacokinetic compatibility and rationale for the use of JGHP.

Effects of shakuyakukanzoto and its absorbed components on twitch contractions induced by physiological Ca2+ release in rat skeletal muscle

Shakuyakukanzoto (SKT) is a kampo medicine composed of equal proportions of Glycyrrhizae radix (G. radix) and Paeoniae radix (P. radix). A double-blind study reported that SKT significantly ameliorated painful muscle cramp in cirrhosis patients without the typical severe side effects of muscle weakness and central nervous system (CNS) depression. Previous basic studies reported that SKT and its active components induced relaxation by a direct action on skeletal muscle and that SKT did not depress CNS functions; however, why SKT has a lower incidence of muscle weakness remains unknown. In the present study, we investigated which components are absorbed into the blood of rats after a single oral administration of SKT to identify the active components of SKT. We also investigated the effects of SKT and its components on the twitch contraction induced by physiological Ca²⁺ release. Our study demonstrated that SKT and five G. radix isolates, which are responsible for the antispasmodic effect of SKT, did not inhibit the twitch contraction in contrast to dantrolene sodium, a direct-acting peripheral muscle relaxant, indicating that the mechanisms of muscle contraction of SKT and dantrolene in skeletal muscle differ. These findings suggest that SKT does not reduce the contractile force in skeletal muscle under physiological conditions, i.e., SKT may have a low risk of causing muscle weakness in clinical use. Considering that most muscle relaxants and anticonvulsants cause various harmful side effects such as weakness and CNS depression, SKT appears to have a benign safety profile.

An integrated strategy based on UPLC-DAD-QTOF-MS for metabolism and pharmacokinetic studies of herbal medicines: Tibetan "Snow Lotus" herb (Saussurea laniceps), a case study

ETHNOPHARMACOLOGICAL RELEVANCE

Saussurea laniceps Hand.-Mazz. (SL) has long been used under the herbal name Tibetan "Snow Lotus" for the treatment of rheumatoid arthritis, stomachache and dysmenorrhea in Tibetan folk medicine. Since herbal medicine (HM) is a synergistical system with multiple components, both of the metabolism and pharmacokinetic studies of HM are interdependent. This study aimed to develop an integrated strategy based on the UPLC-DAD-QTOF-MS technique for metabolism and pharmacokinetic studies of HM.

MATERIAL AND METHODS

SL was used here as a test herb to verify the feasibility of the proposed strategy. SL was administered to rats, then, the blood plasma, urine and feces were analyzed to determine the metabolic profiles. Using our strategy, umbelliferone and scopoletin were evaluated to be the key bioactive components. Their pharmacokinetic parameters were measured and biotransformation pathways were elucidated.

RESULTS

After oral administration of SL to rats, 17 components in blood, 10 components in urine and 2 components in feces were identified and characterized using our UPLC-DAD-QTOF-MS method. Umbelliferone, scopoletin and their metabolites were found to be the major components involved in the metabolism process. Literature reports also suggest that umbelliferone and scopoletin are responsible for the therapeutic effects of SL, thus these two components were selected as the active markers for pharmacokinetic study. In the test of validity, the established method presented good linearity with R(2)>0.99. The relative standard deviation value was below 13.9% for precision, and recovery studies for accuracy were found to be within the range 91.8-112.5%.

CONCLUSION

The present strategy offers, simultaneously, precision in quantitative analysis (metabolism study) and accuracy in quantitative analysis (pharmacokinetic study) with greater efficiency and less costs, which is therefore reliably used for integrated metabolism and pharmacokinetic studies of HM.

Characterization of the herb-derived components in rats following oral administration of Carthamus tinctorius extract by extracting diagnostic fragment ions (DFIs) in the MSn chromatograms

An E(DFI)MSⁿCs-based strategy was proposed to rapidly detect and identify the in vivo components derived from the extract of Carthamus tinctorius using LC-IT-TOF-MSⁿ.

Identification of key licorice constituents which interact with cytochrome P450: evaluation by LC/MS/MS cocktail assay and metabolic profiling

Licorice has been shown to affect the activities of several cytochrome P450 enzymes. This study aims to identify the key constituents in licorice which may affect these activities. Bioactivity assay was combined with metabolic profiling to identify these compounds in several complex licorice extracts. Firstly, the inhibition potencies of 40 pure licorice compounds were tested using an liquid chromatography/tandem mass spectrometry cocktail method. Significant inhibitors of human P450 isozymes 1A2, 2C9, 2C19, 2D6, and 3A4 were then selected for examination of their structural features by molecular docking to determine their molecular interaction with several P450 isozymes. Based on the present in vitro inhibition findings, along with our previous in vivo metabolic studies and the prevalence of individual compounds in licorice extract, we identified several licorice constituents, viz., liquiritigenin, isoliquiritigenin, together with seven isoprenylated flavonoids and arylcoumarins, which could be key components responsible for the herb-drug interaction between cytochrome P450 and licorice. In addition, hydrophilic flavonoid glycosides and saponins may be converted into these P450 inhibitors in vivo. These studies represent a comprehensive examination of the potential effects of licorice components on the metabolic activities of P450 enzymes.

Regiospecificity of human UDP-glucuronosyltransferase isoforms in chalcone and flavanone glucuronidation determined by metal complexation and tandem mass spectrometry

The glucuronidation of a series of chalcones (2'-hydroxychalcone, 2',4'-dihydroxychalcone, 3,2'-dihydroxychalcone, 4,2'-dihydroxychalcone, and cardamonin) and their corresponding cyclized flavanones (7-hydroxyflavanone, 3'-hydroxyflavanone, 4'-hydroxyflavanone, and alpinetin) by eight human UDP-glucuronosyltransferase (UGT) 1A enzymes was evaluated. A postcolumn metal complexation LC-MS/MS strategy was used successfully to produce characteristic mass spectrometric product ions that were utilized in combination with elution order trends to identify chalcone and flavanone monoglucuronides unambiguously, thus allowing determination of the regioselectivities of the UGT1A isoforms. The presence of hydroxy groups on the A- or B-ring had a significant effect on the glucuronide product yield and the site where glucuronidation occurred. For example, for reaction with UGT1A9, formation of the 2'-O-glucuronide was increased for dihydroxychalcones with A-ring hydroxy substituents. In contrast, although UGT1A8 reacted with 3,2'-dihydroxychalcone and 4,2'-dihydroxychalcone to yield 2'-O-glucuronide products, the presence of a B-ring hydroxy group at the 4' position on cardamonin and 2',4'-dihydroxychalcone quenched the reaction at the OH-2' position. Moreover, the A-ring OH-4 group promoted glucuronidation at the 2' position for the reaction of 4,2'-dihydroxychalcone with UGT1A1 and 1A3. For UGT1A7, hydroxy group substituents on the chalcone A-ring also promoted cyclization and formation of the corresponding flavanone glucuronide.

Towards polypharmacokinetics: pharmacokinetics of multicomponent drugs and herbal medicines using a metabolomics approach

Determination of pharmacokinetics (PKs) of multicomponent pharmaceuticals and/or nutraceuticals (polypharmacokinetics, poly-PKs) is difficult due to the vast number of compounds present in natural products, their various concentrations across a wide range, complexity of their interactions, as well as their complex degradation dynamics in vivo. Metabolomics coupled with multivariate statistical tools that focus on the comprehensive analysis of small molecules in biofluids is a viable approach to address the challenges of poly-PK. This paper discusses recent advances in the characterization of poly-PK and the metabolism of multicomponent xenobiotic agents, such as compound drugs, dietary supplements, and herbal medicines, using metabolomics strategy. We propose a research framework that integrates the dynamic concentration profile of bioavailable xenobiotic molecules that result from in vivo absorption and hepatic and gut bacterial metabolism, as well as the human metabolic response profile. This framework will address the bottleneck problem in the pharmacological evaluation of multicomponent pharmaceuticals and nutraceuticals, leading to the direct elucidation of the pharmacological and molecular mechanisms of these compounds.

Prenylated isoflavonoids from plants as selective estrogen receptor modulators (phytoSERMs)

Isoflavonoids are a class of secondary metabolites, which comprise amongst others the subclasses of isoflavones, isoflavans, pterocarpans and coumestans. Isoflavonoids are abundant in Leguminosae, and many of them can bind to the human estrogen receptor (hER) with affinities similar to or lower than that of estradiol. Dietary intake of these so-called phytoestrogens has been associated with positive effects on menopausal complaints, hormone-related cancers, and osteoporosis. Therefore, phytoestrogens are used as nutraceuticals in functional foods or food supplements. Most of the isoflavonoids show agonistic activity towards both hERα and hERβ, the extent of which is modulated by the substitution pattern of their skeleton (i.e.-OH, -OCH(3)). Interestingly, substitutions consisting of a five-carbon prenyl group often seem to result in an antiestrogenic activity. There is growing evidence that the action of some of these prenylated isoflavonoids is tissue-specific, suggesting that they act like selective estrogen receptor modulators (SERMs), such as the well-known chemically synthesized raloxifene and tamoxifen. These so-called phytoSERMS might have high potential for realizing new food and pharma applications. In this review, the structural features of isoflavonoids (i.e. the kind of skeleton and prenylation (e.g. chain or pyran), position of the prenyl group on the skeleton, and the extent of prenylation (single, double)) are discussed in relation to their estrogenic activity. Anti-estrogenic and SERM activity of isoflavonoids was always associated with prenylation, but these activities did not seem to be confined to one particular kind/position of prenylation or isoflavonoid subclass. Few estrogens with agonistic activity were prenylated, but these were not tested for antagonistic activity; possibly, these molecules will turn out to be phytoSERMs as well. Furthermore, the data on the dietary occurrence, bioavailability and metabolism of prenylated isoflavonoids are discussed.

Metabolic regulatory effects of licorice: a bile acid metabonomic study by liquid chromatography coupled with tandem mass spectrometry

Licorice is one of the most popular herbal medicines worldwide, and is mainly used to moderate the characteristics of other herbs in Traditional Chinese Medicine. It is hypothesized that licorice exerts this role by regulating systemic metabolism. Bile acids play a critical role in lipid digestion and cholesterol metabolism, and are sensitive biomarkers for hepatic function. In this study, the regulatory effects of licorice on bile acid metabonome in rats were investigated using liquid chromatography coupled with tandem mass spectrometry. After oral administration of a clinical dosage of licorice water extract, the levels of 21 fully identified and 41 tentatively characterized bile acid analogs in rat plasma were determined by a fully validated method. Following partial least squares discriminant analysis, the results showed that licorice treatment led to dose-dependent up-regulation of free and glycine-conjugated bile acids excretion. Particularly, the plasma levels of cholic acid (1465.33±915.93-7156.46±3490.49 ng/mL, p=0.0027) and β-muricholic acid (228.19±163.95-1284.40±775.62 ng/mL, p=0.0045) increased significantly 48 h after administration. As licorice is widely used as a detoxifying drug, the regulation of plasma bile acids may be an important evidence to interpret its mechanism.