Rapid screening of glutathione-trapped reactive metabolites by linear ion trap mass spectrometry with isotope pattern-dependent scanning and postacquisition data mining

The present study describes a novel integrated approach for rapid analysis of reactive metabolites with a linear ion trap mass spectrometer (LTQ). In this approach, an isotope pattern-dependent scanning method was applied to the data acquisition of glutathione (GSH)-trapped reactive metabolites. Recorded full-scan MS and MS/MS data sets were further processed with neutral loss filtering, product ion filtering, and extracted ion chromatographic analysis to search for protonated molecules and MS/MS spectra of GSH adducts. To evaluate the effectiveness and reliability of the approach, GSH adducts of carbamazepine, diclofenac, 4-ethylphenol, acetaminophen, p-cresol, and omeprazole were analyzed, which were formed in human liver microsome incubations fortified with a mixture of nonlabeled GSH and stable isotope-labeled GSH at a 1:0.8 ratio. Results demonstrate that the combination of the isotope pattern-dependent scanning with the postacquisition data mining was very effective in detecting low levels of GSH adducts, regardless of their fragmentation patterns. As compared to a neutral loss scanning method performed with a triple quadrupole mass spectrometer, the LTQ-based approach had several major advantages, including the superior selectivity and sensitivity in detecting different classes of GSH adducts and the higher throughput capability of the detection and MS/MS spectral acquisition of GSH adducts in a single LC/MS run. Overall, this analytical approach provides a simple and efficient means for screening for reactive metabolites using a linear ion trap LC/MS platform.     

Determination of exposure multiples of human metabolites for MIST assessment in preclinical safety species without using reference standards or radiolabeled compounds

A simple, reliable, and accurate method was developed for quantitative assessment of metabolite coverage in preclinical safety species by mixing equal volumes of human plasma with blank plasma of animal species and vice versa followed by an analysis using high-resolution full-scan accurate mass spectrometry. This approach provided comparable results (within (±15%) to those obtained from regulated bioanalysis and did not require synthetic standards or radiolabeled compounds. In addition, both qualitative and quantitative data were obtained from a single LC-MS analysis on all metabolites and, therefore, the coverage of any metabolite of interest can be obtained.     

高分辨质谱数据处理策略在中药体内外成分检测和表征中的应用进展

中药物质基础研究是中药现代化研究的基础。现代高分辨质谱(HRMS)已成为成分定性分析的有力手段。近年来,一些基于高分辨质谱的数据处理策略,如全信息串联质谱扫描采集策略、基于MS/MSALL的所有理论碎片离子的连续窗口采集技术、质量亏损过滤技术、特征离子过滤技术、质谱树状图过滤技术等极大地推动了中药物质基础的阐明。本文分别从中药类成分、全成分和中药体内成分三个方面综述高分辨质谱数据处理策略在中药体内外成分检测和表征中的应用进展,为中药成分和体内代谢物的快速发现和结构表征提供方法参考。     

Pentylindole/Pentylindazole Synthetic Cannabinoids and Their 5-Fluoro Analogs Produce Different Primary Metabolites: Metabolite Profiling for AB-PINACA and 5F-AB-PINACA

Whereas non-fluoropentylindole/indazole synthetic cannabinoids appear to be metabolized preferably at the pentyl chain though without clear preference for one specific position, their 5-fluoro analogs’ major metabolites usually are 5-hydroxypentyl and pentanoic acid metabolites. We determined metabolic stability and metabolites of N-(1-amino-3-methyl-1-oxobutan-2-yl)-1-pentyl-1H-indazole-3-carboxamide (AB-PINACA) and 5-fluoro-AB-PINACA (5F-AB-PINACA), two new synthetic cannabinoids, and investigated if results were similar. In silico prediction was performed with MetaSite (Molecular Discovery). For metabolic stability, 1 μmol/L of each compound was incubated with human liver microsomes for up to 1 h, and for metabolite profiling, 10 μmol/L was incubated with pooled human hepatocytes for up to 3 h. Also, authentic urine specimens from AB-PINACA cases were hydrolyzed and extracted. All samples were analyzed by liquid chromatography high-resolution mass spectrometry on a TripleTOF 5600+ (AB SCIEX) with gradient elution (0.1% formic acid in water and acetonitrile). High-resolution full-scan mass spectrometry (MS) and information-dependent acquisition MS/MS data were analyzed with MetabolitePilot (AB SCIEX) using different data processing algorithms. Both drugs had intermediate clearance. We identified 23 AB-PINACA metabolites, generated by carboxamide hydrolysis, hydroxylation, ketone formation, carboxylation, epoxide formation with subsequent hydrolysis, or reaction combinations. We identified 18 5F-AB-PINACA metabolites, generated by the same biotransformations and oxidative defluorination producing 5-hydroxypentyl and pentanoic acid metabolites shared with AB-PINACA. Authentic urine specimens documented presence of these metabolites. AB-PINACA and 5F-AB-PINACA produced suggested metabolite patterns. AB-PINACA was predominantly hydrolyzed to AB-PINACA carboxylic acid, carbonyl-AB-PINACA, and hydroxypentyl AB-PINACA, likely in 4-position. The most intense 5F-AB-PINACA metabolites were AB-PINACA pentanoic acid and 5-hydroxypentyl-AB-PINACA.

Electronic supplementary material

The online version of this article (doi:10.1208/s12248-015-9721-0) contains supplementary material, which is available to authorized users.KEY WORDS: 5-fluoro-AB-PINACA, AB-PINACA, in silico prediction, metabolism, synthetic cannabinoids     

Metabolite identification in drug discovery

Recent developments in the technologies and approaches to identify metabolites in a drug discovery environment are reviewed. Samples may be generated using either in vitro systems--typically, but not exclusively, liver subcellular fractions, such as microsomes, or whole cells, such as hepatocytes. Alternatively, metabolites are generated in vivo using excreta obtained following dosing in preclinical species. Recombinant drug metabolizing enzymes or microorganisms may offer alternate vectors. New techniques, such as the use of solid-phase microextraction, have found application in the isolation of metabolites from biological matrices. However, this is still dominated by the use of preparative chromatography, which has advanced through the use of mass-directed detection. Detection and structural elucidation by mass spectrometry have improved markedly with increases in sensitivity, allowing lower abundance metabolites to be detected, and increases in selectivity, with the use of high-resolution time-of-flight and quadrupole-time-of-flight instruments. Finally, higher field strength magnets coupled with novel probe designs and increased use of liquid chromatographic hyphenation techniques continue to drive the capabilities of nuclear magnetic resonance spectroscopy as the definitive structural elucidation tool.     

Identification of a novel in vitro metabonate from liver microsomal incubations.

In vitro drug metabolism studies during the early drug discovery stage are becoming increasingly important. With the increasing demand for high throughput and quick turnaround time for in vitro metabolism studies, however, careful examination of the results and proper design of the experiments are still crucial. In this communication, we report the identification and mechanism of formation of a novel metabonate from incubations of a diamine-containing compound with liver microsomes. The metabonate appeared to be the major product, and its formation was NADPH- and microsomal protein-dependent. Liquid chromatography/mass spectrometry and NMR analysis of the metabonate indicated an extra carbon and unusual formation of an imidazolidine ring. Further studies revealed that this metabonate was not a true biotransformation product from the diamine compound itself in the microsomal incubation, but rather a product resulting from a condensation reaction between the compound and a metabolite of the solvent (alcohol) used in the incubation. When the microsomal incubations contained a small amount of methanol or ethanol as solvent, the alcohols were metabolized to formaldehyde or acetaldehyde, which then condensed with the diamine compound through an imine intermediate to form the metabonate. The compound itself was metabolically stable in vitro when acetonitrile or dimethyl sulfoxide was used as solvent. During the study of in vitro microsomal stability and metabolite identification of amine-containing compounds, the use of alcohol as solvent should be avoided.     

In vitro metabolism of the COX-2 inhibitor DFU, including a novel glutathione adduct rearomatization.

The metabolic profile of DFU [5,5-dimethyl-3-(3-fluorophenyl)-4-(4-methylsulphonyl)phenyl-2(5H)-furanone], a potent and selective COX-2 inhibitor, was characterized using in vitro microsomal and hepatocyte incubations. A single product, corresponding to p-hydroxylation, p-OH-DFU [(5,5-dimethyl-3-(3-fluoro-4-hydroxyphenyl)-4-(4-methylsulphonyl)phenyl-2(5H)-furanone)], was produced in rat microsomal incubations of DFU. In contrast, three metabolites were produced in incubations using suspensions of freshly isolated rat hepatocytes. Microsomal production of the p-O-glucuronide metabolite of DFU from synthetic p-OH-DFU was shown to have chromatographic and mass spectrometric properties identical to the earliest eluting hepatocyte metabolite (M1). The molecular weights of the other two hepatocyte metabolites were readily obtained using capillary high-performance liquid chromatography continuous-flow liquid secondary ion mass spectrometry (HPLC/CF-LSIMS); however, the elemental composition of these metabolites was not. Unlike typical metabolic products, which produce readily identified increments in molecular weight, metabolites M2 and M3 produced molecular ions in positive- and negative-ion CF-LSIMS that were consistent with oxidation of DFU (+16 Da), followed by addition of glutathione (+306 Da) and subsequent loss of 20 and 18 Da, respectively. Capillary HPLC/high-resolution CF-LSIMS was used to generate accurate mass data for M2 and M3 that provided evidence that the losses of 20 and 18 Da, respectively, corresponded to a rearomatization through loss of HF or H(2)O. Isolation and NMR characterization provided the definitive structural proof for these metabolites. Overall, the metabolism of DFU in rat hepatocytes is proposed to proceed through an epoxide intermediate, which then either rearranges to the p-OH-DFU and is conjugated with glucuronic acid, or is trapped with glutathione, followed by rearomatization with loss of HF (M2) or H(2)O (M3).     

Atrazine metabolite screening in human microsomes: detection of novel reactive metabolites and glutathione adducts by LC-MS

Atrazine (ATZ), one of the most widely used herbicides worldwide, has been the subject of several scientific studies associated with its human and ecological risks. In order to study atrazine's toxicity, the formation of its metabolites and the result of their exposure must be assessed. This relies on our ability to detect and identify all of atrazine's metabolites; however, no previous untargeted screening method has reported the detection of all known metabolites and glutathione conjugates at once. In this study, a compound-specific, postacquisition metabolic screening method was employed following a generic HPLC separation coupled with high resolution time-of-flight mass spectrometry (TOF-MS) to detect Phase I metabolites and glutathione conjugates generated by in vitro human liver microsomal incubations. Our method was designed to be unbiased and applicable to a wide variety of compounds since methods that can detect a broad range of metabolites with high sensitivity are of great importance for many types of experiments requiring thorough metabolite screening. On the basis of incubations with atrazine and three closely related analogues (simazine, propazine, and cyanazine), we have proposed a new Phase I metabolism scheme. All known Phase I transformations of atrazine were successfully detected, as well as a new N-oxidation product. Novel reactive metabolites were also detected as well as their glutathione conjugates. These newly detected species were produced via imine formation on the N-ethyl group, a biotransformation not previously observed for atrazine or its analogues.     

Metabolite characterization in drug discovery utilizing robotic liquid-handling,quadruple time-of-flight mass spectrometry and in-silico prediction

An assay method for identification of metabolites from in vitro microsomal incubations was developed for use in the early stage of drug discovery. We have developed a practical approach which involves integrated sample generation, sample preparation, bioanalysis, and data handling to maximize sample throughput and speed up the process for identification of metabolites. The assay system consisted of a robotic liquid handler (Genesis workstation) to generate and process samples, PALLAS MetabolExpert software to predict possible metabolites, exact mass measurement via a tandem quadrupole time-of-flight mass spectrometer (QTOF-MS) coupled with liquid chromatography to analyze samples, MetaboLynx software to find potential metabolites and Advanced Chemistry Development/MS (ACD/MS) software to provide guidance to the most likely hypothetical metabolite chemical structures. For purposes of evaluating this new method, dextromethorphan, alprenolol, and propranolol were incubated separately for up to 60 minutes with rat and human hepatic microsomes. The incubation and sample preparation were carried out in 96-well plates using the Genesis workstation. The bioanalysis was performed by LC-MS/MS using QTOF with MetaboLynx software to find metabolites. Metabolic products formed in vitro by rat and human microsomes were separated using an analytical column C18 with gradient elution at flow rate of 250 micro l/min. The internal mass calibration was performed by continuous postcolumn infusion of Haloperidol. The mass spectra from incubations containing NADPH were compared to those without NADPH (control) using the MetaboLynx software to find potential metabolites. Finally, the MS/MS spectra were processed by the ACD/MS software to predict the chemical structure. MetaboLynx software successfully identified metabolites for each of the drugs studied by automatically discerning expected metabolites. Exact differences in masses between each metabolite and parent drug were measured from five replicate sample injections. All measured values are accurate to less than 0.001Da or 3.8 ppm with the standard deviation within 0.0015 Da, which allowed good prediction/confirmation of empirical formulae. Hypothetical chemical structures were achieved by the ACD/MS software and provided a useful tool to assist in prediction of the metabolic pathways of the drugs. The metabolites identified were in good agreement with previously published results for all three compounds. This new method will greatly enhance throughput, which in turn will facilitate our ability to rapidly provide this guidance to the synthetic chemist.     

High performance liquid chromatography/atmospheric pressure ionization/tandem mass spectrometry (HPLC/API/MS/MS) in drug metabolism and toxicology

Studies of the metabolic fate of drugs and other xenobiotics in living systems may be divided into three broad areas: (1) elucidation of biotransformation pathways through identification of circulatory and excretory metabolites (qualitative studies); (2) determination of pharmacokinetics of the parent drug and/or its primary metabolites (quantitative studies); and (3) identification of chemically-reactive metabolites, which play a key role as mediators of drug-induced toxicities (mechanistic studies). Mass spectrometry has been regarded as one of the most important analytical tools in studies of drug metabolism, pharmacokinetics and biochemical toxicology. With the commercial introduction of new ionization methods such as those based on atmospheric pressure ionization (API) techniques and the combination of liquid chromatography-mass spectrometry (LC-MS), it has now become a truly indispensable technique in pharmaceutical research. Triple stage quadrupole and ion trap mass spectrometers are presently used for this purpose, because of their sensitivity and selectivity. API-TOF mass spectrometry has also been very attractive due to its enhanced full-scan sensitivity, scan speed, improved resolution and ability to measure the accurate masses for protonated molecules and fragment ions. This review aims to survey the utility of mass spectrometry in drug metabolism and toxicology and to highlight novel applications and future trends in this field.     

Comparative study on the metabolism of the ergot alkaloids ergocristine,ergocryptine, ergotamine,and ergovaline in equine and human S9 fractions and equine liver preparations

Abstract

1. Ergopeptine alkaloids like ergovaline and ergotamine are suspected to be associated with fescue toxicosis and ergotism in horses. Information on the metabolism of ergot alkaloids is scarce, especially in horses, but needed for toxicological analysis of these drugs in urine/feces of affected horses. The aim of this study was to investigate the metabolism of ergovaline, ergotamine, ergocristine, and ergocryptine in horses and comparison to humans.

2. Supernatants of alkaloid incubations with equine and human liver S9 fractions were analyzed by reversed-phase liquid-chromatography coupled to high-resolution tandem mass spectrometry with full scan and MS² acquisition. Metabolite structures were postulated based on their MS² spectra in comparison to those of the parent alkaloids. All compounds were extensively metabolized yielding nor-, N-oxide, hydroxy and dihydro-diole metabolites with largely overlapping patterns in equine and human liver S9 fractions. However, some metabolic steps e.g. the formation of 8′-hydroxy metabolites were unique for human metabolism, while formation of the 13/14-hydroxy and 13,14-dihydro-diol metabolites were unique for equine metabolism. Incubations with equine whole liver preparations yielded less metabolites than the S9 fractions.

3. The acquired data can be used to develop metabolite-based screenings for these alkaloids, which will likely extend their detection windows in urine/feces from affected horses.     

Detection and characterization of metabolites in biological matrices using mass defect filtering of liquid chromatography/high resolution mass spectrometry data.

An improved mass defect filter (MDF) method employing both drug and core structure filter templates was applied to the processing of high resolution liquid chromatography/mass spectrometry (LC/MS) data for the detection and structural characterization of oxidative metabolites with mass defects similar to or significantly different from those of the parent drugs. The effectiveness of this approach was investigated using nefazodone as a model compound, which is known to undergo multiple common and uncommon oxidative reactions. Through the selective removal of all ions that fall outside of the preset filter windows, the MDF process facilitated the detection of all 14 nefazodone metabolites presented in human liver microsomes in the MDF-filtered chromatograms. The capability of the MDF approach to remove endogenous interferences from more complex biological matrices was examined by analyzing omeprazole metabolites in human plasma. The unprocessed mass chromatogram showed no distinct indication of metabolite peaks; however, after MDF processing, the metabolite peaks were easily identified in the chromatogram. Compared with precursor ion scan and neutral loss scan techniques, the MDF approach was shown to be more effective for the detection of metabolites in a complex matrix. The comprehensive metabolite detection capability of the MDF approach, together with accurate mass determination, makes high resolution LC/MS a useful tool for the screening and identification of both common and uncommon drug metabolites.     

Rapid and global detection and characterization of aconitum alkaloids in Yin Chen Si Ni Tang,a traditional Chinese medical formula,by ultra performance liquid chromatography–high resolution mass spectrometry and automated data analysis

An improved method employing Metabolynx XS with mass defect filter (MDF), a post-acquisition data processing software, was developed and applied for global detection of aconitum alkaloids in Yin Chen Si Ni Tang, a traditional Chinese medical formula (TCMF). The full-scan LC–MS/MS data sets with extra mass were acquired using ultra performance liquid chromatography coupled with quadrupole-time-of-flight mass spectrometry (UPLC/Q-TOF-MS) with the MS^E mode in a single injection. To remove the interferences, Metabolynx XS was optimized to extract the ions of aconitum alkaloids located at the lower abundance. As a result, 62 ions were assigned rapidly to aconitum alkaloids and identified tentatively by comparing the accurate mass and fragments information with that of the authentic standards or by mass spectrometry analysis and retrieving the reference literatures. Compared with the previous studies on Fuzi-containing TCMF, the report detected more aconitum alkaloids, and the analysis process was accelerated by automated data processing. It is concluded that the screening capability of Metabolynx XS with MDF, together with the utilization of MS^E in structural elucidation, can facilitate a rapid and comprehensive searching and effective structural characterization of aconitum alkaloids in TCMF.     

Metabolism study and toxicological determination of mephtetramine in biological samples by liquid chromatography coupled with high-resolution mass spectrometry

The emerging market of new psychoactive substances (NPSs) is a global-scale phenomenon, and their identification in biological samples is challenging because of the lack of information about their metabolism and pharmacokinetic. In this study, we performed in silico metabolic pathway prediction and in vivo metabolism experiments, in order to identify the main metabolites of mephtetramine (MTTA), an NPS found in seizures since 2013. MetaSite™ software was used for in silico metabolism predictions and subsequently the presence of metabolites in the blood, urine, and hair of mice after MTTA administration was verified. The biological samples were analyzed by liquid chromatography coupled with high-resolution mass spectrometry (LC–HRMS) using a benchtop Orbitrap instrument. This confirmed the concordance between software prediction and experimental results in biological samples. The metabolites were identified by their accurate masses and fragmentation patterns. LC–HRMS analysis identified the dehydrogenated and demethylated-dehydrogenated metabolites, together with unmodified MTTA in the blood samples. Besides unmodified MTTA, 10 main metabolites were detected in urine. In hair samples, only demethyl MTTA was detected along with MTTA. The combination of Metasite™ prediction and in vivo experiment was a powerful tool for studying MTTA metabolism. This approach enabled the development of the analytical method for the detection of MTTA and its main metabolites in biological samples. The development of analytical methods for the identification of new drugs and their main metabolites is extremely useful for the detection of NPS in biological specimens. Indeed, high throughput methods are precious to uncover the actual extent of use of NPS and their toxicity.     

The complex degradation and metabolism of quercetin in rat hepatocyte incubations

Abstract

1.?The current study demonstrated that there is still new information to be obtained on the chemical and biological transformation of the widely studied flavonoid quercetin.

2.?In rat hepatocytes, 35 metabolites of quercetin were observed by using high-resolution mass spectrometry. The metabolites included glucuronides, sulfates, mixed sulfate/glucuronide metabolites and methylated versions of these metabolites.

3.?Several metabolites were formed from chemical degradation products of quercetin which were found to form in Krebs–Henseleit (KH) buffer, degradants of quercetin were also formed in the buffer under the conditions used for hepatocyte incubations.

4.?The degradants and metabolites of quercetin were characterized by using high-resolution MS². It was observed that the glutathione (GSH) conjugates of quercetin formed in large amounts in ammonium bicarbonate solution although the pattern of conjugates formed was different from that observed in hepatocytes suggesting some degree on enzymatic control on GSH conjugate formation in the hepatocyte incubations.

5.?GSH conjugates were not formed when GSH was included in incubations of quercetin in KH buffer alone and only small amounts of quercetin degradation occurred. Instead, GSH was extensively converted into GSSG, thus presumably reducing the levels of oxygen in the incubation thus preventing quercetin degradation.     

Screening procedure for detection of diuretics and uricosurics and/or their metabolites in human urine using gas chromatography-mass spectrometry after extractive methylation

A gas chromatography-mass spectrometry (GC-MS)-based screening procedure was developed for the detection of diuretics, uricosurics, and/or their metabolites in human urine after extractive methylation. Phase-transfer catalyst remaining in the organic phase was removed by solid-phase extraction on a diol phase. The compounds were separated by GC and identified by MS in the full-scan mode. The possible presence of the following drugs and/or their metabolites could be indicated using mass chromatography with the given ions: m/z 267, 352, 353, 355, 386, and 392 for thiazide diuretics bemetizide, bendroflumethiazide, butizide, chlorothiazide, cyclopenthiazide, cyclothiazide, hydrochlorothiazide, metolazone, polythiazide, and for canrenoic acid and spironolactone; m/z 77, 81, 181, 261, 270, 295, 406, and 438 for loop diuretics bumetanide, ethacrynic acid, furosemide, piretanide, torasemide, as well as the uricosurics benzbromarone, probenecid, and sulfinpyrazone; m/z 84, 85, 111, 112, 135, 161, 249, 253, 289, and 363 for the other diuretics acetazolamide, carzenide, chlorthalidone, clopamide, diclofenamide, etozoline, indapamide, mefruside, tienilic acid, and xipamide. The identity of positive signals in such mass chromatograms was confirmed by comparison of the peaks underlying full mass spectra with reference spectra. This method allowed the detection of the abovementioned drugs and/or their metabolites in human urine samples, except torasemide. The limits of detection ranged from 0.001 to 5 mg/L in the full-scan mode. Recoveries of selected diuretics and uricosurics, representing the different chemical classes, ranged from 46% to 99% with coefficients of variation of less than 21%. After ingestion of the lowest therapeutic doses, furosemide was detectable in urine samples for 67 hours, hydrochlorothiazide for 48 hours, and spironolactone for 52 hours (via its target analyte canrenone). The procedure described here is part of a systematic toxicological analysis procedure for acidic drugs and poisons.     

Lacidipine metabolism in rat and dog: identification and synthesis of main metabolites.

1. The main metabolites of lacidipine were isolated from bile and plasma of rats and dogs following an oral dose of the 14C-labelled drug (10 mg/kg for rats: 2 and 1 mg/kg for dogs). They were identified by comparison of chromatographic and spectral data with authentic reference compounds synthesized ad hoc. 2. Five metabolites (I-V) were isolated and identified in dog bile by gradient h.p.l.c. with u.v. detection and h.p.l.c.-thermospray mass spectrometry. In all metabolites the heterocyclic ring has been oxidized to pyridine. Further biotransformation reactions involved hydroxylation of the methyl substituents and hydrolysis of the ethyl and t-butyl ester groups to produce carboxylic acids and a lactone. Some of these metabolites also occurred as glucuronide conjugates. 3. A metabolite retaining the intact dihydropyridine ring, the des-ethyl analogue of lacidipine (VI), was isolated from rat plasma where it accounted for 60% of the total circulating radioactivity up to 24 h after administration. To characterize this metabolite, h.p.l.c. with photodiode array u.v. detection also was employed. This compound was detected in dog plasma, but there was no evidence of its presence in dog bile samples. 4. Profiles of circulating metabolites were qualitatively similar in rats and dogs. Identified metabolites accounted for the large majority of total radioactivity in all the analysed samples.     

Lacidipine metabolism in rat and dog: identification and synthesis of main metabolites

1. The main metabolites of lacidipine were isolated from bile and plasma of rats and dogs following an oral dose of the ¹⁴C-labelled drug (10?mg/kg for rats: 2 and 1?mg/kg for dogs). They were identified by comparison of chromatographic and spectral data with authentic reference compounds synthesized ad hoc.

2. Five metabolites (I-V) were isolated and identified in dog bile by gradient?h.p.l.c. with u.v. detection and?h.p.l.c.-thermospray mass spectrometry. In all metabolites the heterocyclic ring has been oxidized to pyridine. Further biotransformation reactions involved hydroxylation of the methyl substituents and hydrolysis of the ethyl and t-butyl ester groups to produce carboxylic acids and a lactone. Some of these metabolites also occurred as glucuronide conjugates.

3. A metabolite retaining the intact dihydropyridine ring, the des-ethyl analogue of lacidipine (VI), was isolated from rat plasma where it accounted for 60% of the total circulating radioactivity up to 24?h after administration. To characterize this metabolite,?h.p.l.c. with photodiode array u.v. detection also was employed. This compound was detected in dog plasma, but there was no evidence of its presence in dog bile samples.

4. Profiles of circulating metabolites were qualitatively similar in rats and dogs. Identified metabolites accounted for the large majority of total radioactivity in all the analysed samples.     

The use of in vitro technologies and high-resolution/accurate-mass LC-MS to screen for metabolites of 'designer' steroids in the equine

Detection of androgenic-anabolic steroid abuse in equine sports requires knowledge of the drug's metabolism in order to target appropriate metabolites, especially where urine is the matrix of choice. Studying 'designer' steroid metabolism is problematic since it is difficult to obtain ethical approval for in vivo metabolism studies due to a lack of toxicological data. In this study, the equine in vitro metabolism of eight steroids available for purchase on the Internet is reported; including androsta-1,4,6-triene-3,17-dione, 4-chloro,17α-methyl-androsta-1,4-diene-3,17β-diol, estra-4,9-diene-3,17-dione, 4-hydroxyandrostenedione, 20-hydroxyecdysone, 11-keto-androstenedione, 17α-methyldrostanolone, and tetrahydrogestrinone. In order to allow for retrospective analysis of sample testing data, the use of a high-resolution (HR) accurate-mass Thermo LTQ-Orbitrap liquid chromatography-mass spectrometry (LC-MS) instrument was employed for metabolite identification of underivatized sample extracts. The full scan LC-HRMS Orbitrap data were complimented by LC-HRMS/MS and gas-chromatography-mass spectrometry (GC-MS) experiments in order to provide fragmentation information and to ascertain whether GC-MS was capable of detecting any metabolite not detected by LC-HRMS. With the exception of 20-hydroxyecdysone, all compounds were found to be metabolized by equine liver S9 and/or microsomes. With the exception of 17α-methyldrostanolone, which produced metabolites that could only be detected by GC-MS, the metabolites of all other compounds could be identified using LC-HRMS, thus allowing retrospective analysis of previously acquired full-scan data resulting from routine equine drug testing screens. In summary, while in vitro techniques do not serve as a replacement for more definitive in vivo studies in all situations, their use does offer an alternative in situations where it would not be ethical to administer untested drugs to animals.     

Screening and identification of GSH-trapped reactive metabolites using hybrid triple quadruple linear ion trap mass spectrometry

The present study describes a new analytical approach for the detection and characterization of GSH-trapped reactive metabolites using multiple reaction monitoring (MRM) as the survey scan to trigger the acquisition of enhanced product ion (EPI) spectra on a triple quadrupole linear ion mass spectrometer. The MRM scan step was carried out following up to 114 MRM transitions from the protonated molecules of potential GSH adducts to their product ions derived from a neutral loss of 129 or 307 Da. MRM transition protocols were constructed on the basis of common bioactivation reactions predicted to occur in human liver microsomes (HLM). The effectiveness and reliability of the approach were evaluated using acetaminophen, diclofenac, and carbamazepine as model compounds. The total ion chromatograms of the MRM for the HLM incubations with these compounds and GSH clearly displayed a number of GSH adducts, including acetaminophen-GSH adducts and carbamazepine-GSH adducts that were not previously observed in HLM incubations. In addition, clomipramine and mefenamic acid that have the frame structures susceptible to P450-mediated bioactivation were investigated. As a result, the MRM-EPI analysis revealed multiple GSH adducts of clomipramine and mefenamic acid in HLM incubations possibly mediated by epoxide and/or quinone imine intermediates. Compared with the neutral loss (NL) and precursor ion (PI) scanning analysis, the MRM-based approach provided superior sensitivity and selectivity for GSH adducts. It also enabled the sensitive acquisition of EPI spectra with rich fragmentation in the same LC/MS run, which were useful for the rapid structure elucidation of GSH adducts and the elimination of false positives. The MRM-EPI experiment can be employed for high throughput screening of reactive metabolites and should be especially applicable to compounds of the same chemotype. Also, it can be applied in conjunction with the PI or NL scan as a comprehensive method for the analysis of reactive metabolites in a drug discovery setting.