Quantitative and qualitative investigations of pharmacopoeial plant material polygoni avicularis herba by UHPLC-CAD and UHPLC-ESI-MS methods.

INTRODUCTION: Polygonum aviculare L. also known as common knotgrass is an annual herbaceous weed occurring all over the world in the temperate regions. Recent studies report that flavonol glucuronides are major constituents of common knotgrass. There is no comprehensive analytical procedure for the standardisation of Polygoni Avicularis Herba available on the European market. OBJECTIVE: To develop a method for the proper authentication and standardisation of Polygoni Avicularis Herba and to preliminary evaluate variability in qualitative and quantitative composition among commercial samples and samples from wild harvesting defined as Polygonum aviculare sensu lato. METHODOLOGY: The UHPLC-ESI(+)-MS method was used for the qualitative screening of nine independent samples of Polygonum aviculare herb. The UHPLC-CAD method was developed for the quantitation of the major compounds in an extract using quercetin-3-O-glucuronide as a standard. RESULTS: Twenty-five major constituents were detected and characterised. Among them three new natural products were tentatively identified. Twelve compounds were quantitated using a validated UHPLC-CAD method. In all nine samples flavonol glucuronides were confirmed as major compounds. The total flavonoid content was estimated for all samples and varied from 0.70 to 2.20%. CONCLUSION: The developed procedure may be used for the routine standardisation of common knotgrass. The results indicate that the pharmacopoeial approach to the authentication and standardisation of Polygonum aviculare herb should be revised.

Effect of hydrolysis on identifying prenatal cannabis exposure.

Identification of prenatal cannabis exposure is important due to potential cognitive and behavioral consequences. A two-dimensional gas chromatography-mass spectrometry method for cannabinol, Delta(9)-tetrahydrocannabinol (THC), 11-hydroxy-THC (11-OH-THC), 8beta,11-dihydroxy-THC, and 11-nor-9-carboxy-THC (THCCOOH) quantification in human meconium was developed and validated. Alkaline, enzymatic, and enzyme-alkaline tandem hydrolysis conditions were optimized with THC- and THCCOOH-glucuronide reference standards. Limits of quantification ranged from 10 to 15 ng/g, and calibration curves were linear to 500 ng/g. Bias and intra-day and inter-day imprecision were <12.3%. Hydrolysis efficiencies were analyte-dependent; THC-glucuronide was effectively cleaved by enzyme, but not base. Conversely, THCCOOH-glucuronide was most sensitive to alkaline hydrolysis. Enzyme-alkaline tandem hydrolysis maximized efficiency for both glucuronides. Identification of cannabinoid-positive meconium specimens nearly doubled following alkaline and enzyme-alkaline hydrolysis. Although no 11-OH-THC glucuronide standard is available, enzymatic hydrolysis improved 11-OH-THC detection in authentic specimens. Maximal identification of cannabis-exposed neonates and the widest range of cannabis biomarkers are achieved with enzyme-alkaline tandem hydrolysis.

Enzymatic production of bile Acid glucuronides used as analytical standards for liquid chromatography-mass spectrometry analyses.

The present study reports a novel method for the production and purification of analytical standards of glucuronide conjugates of bile acids, chenodeoxycholic (CDCA), lithocholic, (LCA) and hyodeoxycholic (HDCA) acids. CDCA-3G (CDCA-3-glucuronide) and -24G, LCA-3G and -24G, and HDCA-6G and -24G were enzymatically formed by using microsomes from human liver, purified by liquid chromatography, digested with recombinant beta-glucuronidase, and quantified by liquid chromatography/electrospray ionization coupled to mass spectrometry (LC-ESI/MS). The position of the glucuronosyl moiety on the bile acids was determined by analyzing the susceptibility to hydrolysis under elevated pH and temperature conditions of the standards. By using the purified analytical standards, a LC-ESI/MS/MS method was developed for the determination of these glucuronide conjugates in in vitro assays. The linearity of the assay ranged from 0.5 to 40 ng/mL for the six glucuronides, and the limit of quantification (LOQ) was 0.5 ng/mL. Intra- and interday precisions and accuracy values were all lower than 10.2%. Furthermore, processed sample stability analyses revealed that the six standards were stable at 4 degrees C for more than 24 h. This method was successfully used for the quantification of CDCA, LCA, and HDCA glucuronides formed by human liver or hepatoma HepG2 cells. In conclusion, such a method allows the purification of high-quality analytical standards of glucuronide derivatives and may easily be used for the quantification of other endo- and xenobiotics that are glucuronidated.

Preparation of pyridine-N-glucuronides of tobacco-specific nitrosamines.

Nicotine and cotinine are metabolized to pyridine-N-glucuronides in humans. This suggests that the analogous metabolites of the carcinogenic nicotine-related nitrosamines N'-nitrosonornicotine (NNN), 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK), and 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanol (NNAL) should also be formed in people exposed to these compounds via tobacco products. We describe the synthesis of the appropriate pyridine-N-glucuronides: pyridyl-N-beta-D-glucopyranuronosyl-N'-nitrosonornicotinium inner salt (NNN-N-Gluc, 8), 4-(methylnitrosamino)-1-(3-pyridyl-N-beta-D-glucopyranuronosyl)-1-butanonium inner salt (NNK-N-Gluc, 9), and 4-(methylnitrosamino)-1-(3-pyridyl-N-beta-D-glucopyranuronosyl)-1-butanolonium inner salt (NNAL-N-Gluc, 10). The starting material, methyl 2,3,4-tri-O-acetyl-1-bromo-1-deoxy-alpha-D-glucopyranuronate (1), is prepared in two steps from glucuronolactone. Reactions of 1 with racemic NNN (2), NNK (3), or racemic NNAL (4) are carried out with no solvent and the crude products are deprotected by treatment with base, giving the desired N-glucuronides 8-10 in 5-7% overall yield after HPLC purification. The N-glucuronides were characterized by (1)H NMR, including COSY and NOESY spectra, and by MS and MS/MS. NNN-N-Gluc exists as a 52:48 ratio of (E)- and (Z)-rotamers, which were partially separated by HPLC. This ratio was surprisingly similar to the (E):(Z) ratio for NNN itself suggesting hydrogen bonding of the (Z)-nitroso oxygen atom to the 2' '-hydroxyl group of the glucuronide moiety. Partial HPLC separations of the (E)- and (Z)-rotamers of NNK-N-Gluc and the (E)- and (Z)-rotamers as well as the (R)- and (S)-diastereomers of NNAL-N-Gluc were also achieved. The standards prepared in this study as well as the HPLC conditions developed for their separation will be important for analysis of these compounds in human urine.