Metabolic fate of the new synthetic cannabinoid 7’N‐5F‐ADB in rat,human, and pooled human S9 studied by means of hyphenated high‐resolution mass spectrometry

New psychoactive substances (NPS) are an important issue in clinical/forensic toxicology. 7’N‐5F‐ADB, a synthetic cannabinoid derived from 5F‐ADB, appeared recently on the market. Up to now, no data about its mass spectral fragmentation pattern, metabolism, and thus suitable targets for toxicological urine screenings have been available. Therefore, the aim of this study was to elucidate the metabolic fate of 7’N‐5F‐ADB in rat, human, and pooled human S9 (pS9). The main human urinary excretion products, which can be used as targets for toxicological screening procedures, were identified by Orbitrap (OT)‐based liquid chromatography–high resolution‐tandem mass spectrometry (LC–HRMS/MS). In addition, possible differentiation of 7’N‐5F‐ADB and 5F‐ADB via LC–HRMS/MS was studied. Using the in vivo and in vitro models for metabolism studies, 36 metabolites were tentatively identified. 7’N‐5F‐ABD was extensively metabolized in rat and human with minor species differences observed. The unchanged parent compound could be found in human urine but metabolites were far more abundant. The most abundant ones were the hydrolyzed ester (M5), the hydrolyzed ester in combination with hydroxylation of the tertiary butyl part (M11), and the hydrolyzed ester in addition to glucuronidation (M30). Besides the parent compound, these metabolites should be used as targets for urine‐based toxicological screening procedures. Two urine‐paired human plasma samples contained mainly the parent compound (c = 205 μg/L, 157 μg/L) and, at a higher abundance, the compound after ester hydrolysis (M5). In pS9 incubations, the parent compound, M5, and M30 were detectable among others. Furthermore, a differentiation of both compounds was possible due to different retention times and fragmentation patterns.     

Metabolic profiling of synthetic cannabinoid 5F‐ADB by human liver microsome incubations and urine samples using high‐resolution mass spectrometry

5F‐ADB (methyl 2‐{[1‐(5‐fluoropentyl)‐1H‐indazole‐3‐carbonyl] amino}‐3,3‐dimethylbutanoate) is a frequently abused new synthetic cannabinoid that has been sold since at least the end of 2014 on the drug market and has been classified as an illicit drug in most European countries, as well as Turkey, Japan, and the United States. In this study, the in vitro metabolism of 5F‐ADB was investigated by using pooled human liver microsomes (HLMs) assay and liquid chromatography‐high‐resolution mass spectrometry (LC–HRMS). 5F‐ADB (5 μmol/L) was incubated with HLMs for up to 3 hours, and the metabolites were identified using LC–HRMS and software‐assisted data mining. The in vivo metabolism was investigated by the analysis of 30 authentic urine samples and was compared to the data received from the in vitro metabolism study. Less than 3.3% of the 5F‐ADB parent compound remained after 1 hour of incubation, and no parent drug was detected after 3 hours. We identified 20 metabolites formed via ester hydrolysis, N‐dealkylation, oxidative defluorination, hydroxylation, dehydrogenation, further oxidation to N‐pentanoic acid and glucuronidation or a combination of these reactions in vitro. In 12 urine samples (n = 30), 5F‐ADB was detected as the parent drug. Three of the identified main metabolites 5F‐ADB carboxylic acid (M20), monohydroxypentyl‐5F‐ADB (M17), and carboxypentyl ADB carboxylic acid (M8) were suggested as suitable urinary markers. The screening of 8235 authentic urine samples for identified 5F‐ADB metabolites in vitro resulted in 3135 cases of confirmed 5F‐ADB consumption (38%).     

Diphenidine,a new psychoactive substance: metabolic fate elucidated with rat urine and human liver preparations and detectability in urine using GC‐MS,LC‐MSn,and LC‐HR‐MSn

Diphenidine is a new psychoactive substance (NPS) sold as a ‘legal high’ since 2013. Case reports from Sweden and Japan demonstrate its current use and the necessity of applying analytical procedures in clinical and forensic toxicology. Therefore, the phase I and II metabolites of diphenidine should be identified and based on these results, the detectability using standard urine screening approaches (SUSAs) be elucidated. Urine samples were collected after administration of diphenidine to rats and analyzed using different sample workup procedures with gas chromatography‐mass spectrometry (GC‐MS) and liquid chromatography‐(high resolution)‐mass spectrometry (LC‐(HR)‐MS). With the same approaches incubates of diphenidine with pooled human liver microsomes (pHLM) and cytosol (pHLC) were analyzed. According to the identified metabolites, the following biotransformation steps were proposed in rats: mono‐ and bis‐hydroxylation at different positions, partly followed by dehydrogenation, N,N‐bis‐dealkylation, and combinations of them followed by glucuronidation and/or methylation of one of the bis‐hydroxy‐aryl groups. Mono‐ and bis‐hydroxylation followed by dehydrogenation could also be detected in pHLM or pHLC. Cytochrome‐P450 (CYP) isozymes CYP1A2, CYP2B6, CYP2C9, and CYP3A4 were all capable of forming the three initial metabolites, namely hydroxy‐aryl, hydroxy‐piperidine, and bis‐hydroxy‐piperidine. In incubations with CYP2D6 hydroxy‐aryl and hydroxy‐piperidine metabolites were detected. After application of a common users’ dose, diphenidine metabolites could be detected in rat urine by the authors’ GC‐MS as well as LC‐MSⁿ SUSA. Copyright © 2016 John Wiley & Sons, Ltd.     

Metabolism of the tryptamine‐derived new psychoactive substances 5‐MeO‐2‐Me‐DALT, 5‐MeO‐2‐Me‐ALCHT,and 5‐MeO‐2‐Me‐DIPT and their detectability in urine studied by GC–MS,LC–MSn,and LC‐HR‐MS/MS

Many N,N‐dialkylated tryptamines show psychoactive properties and were encountered as new psychoactive substances. The aims of the presented work were to study the phase I and II metabolism and the detectability in standard urine screening approaches (SUSA) of 5‐methoxy‐2‐methyl‐N,N‐diallyltryptamine (5‐MeO‐2‐Me‐DALT), 5‐methoxy‐2‐methyl‐N‐allyl‐N‐cyclohexyltryptamine (5‐MeO‐2‐Me‐ALCHT), and 5‐methoxy‐2‐methyl‐N,N‐diisopropyltryptamine (5‐MeO‐2‐Me‐DIPT) using gas chromatography–mass spectrometry (GC–MS), liquid chromatography coupled with multistage accurate mass spectrometry (LC–MSⁿ), and liquid chromatography‐high‐resolution tandem mass spectrometry (LC‐HR‐MS/MS). For metabolism studies, urine was collected over a 24 h period after administration of the compounds to male Wistar rats at 20 mg/kg body weight (BW). Phase I and II metabolites were identified after urine precipitation with acetonitrile by LC‐HR‐MS/MS. 5‐MeO‐2‐Me‐DALT (24 phase I and 12 phase II metabolites), 5‐MeO‐2‐Me‐ALCHT (24 phase I and 14 phase II metabolites), and 5‐MeO‐2‐Me‐DIPT (20 phase I and 11 phase II metabolites) were mainly metabolized by O‐demethylation, hydroxylation, N‐dealkylation, and combinations of them as well as by glucuronidation and sulfation of phase I metabolites. Incubations with mixtures of pooled human liver microsomes and cytosols (pHLM and pHLC) confirmed that the main metabolic reactions in humans and rats might be identical. Furthermore, initial CYP activity screenings revealed that CYP1A2, CYP2C19, CYP2D6, and CYP3A4 were involved in hydroxylation, CYP2C19 and CYP2D6 in O‐demethylation, and CYP2C19, CYP2D6, and CYP3A4 in N‐dealkylation. For SUSAs, GC–MS, LC‐MSⁿ, and LC‐HR‐MS/MS were applied to rat urine samples after 1 or 0.1 mg/kg BW doses, respectively. In contrast to the GC–MS SUSA, both LC–MS SUSAs were able to detect an intake of 5‐MeO‐2‐Me‐ALCHT and 5‐MeO‐2‐Me‐DIPT via their metabolites following 1 mg/kg BW administrations and 5‐MeO‐2‐Me‐DALT following 0.1 mg/kg BW dosage. Copyright © 2017 John Wiley & Sons, Ltd.     

Rapid and sensitive screening and confirmation of thirty‐four aminocarbonyl/carboxamide (NACA) and arylindole synthetic cannabinoid drugs in human whole blood

We describe the development and validation of a method for the screening and confirmation of a range of chemically diverse synthetic cannabinoid drugs in human whole blood. The method targets the better known arylindole compounds as well as the emerging aminocarbonyl/ carboxamide (NACA) compounds. The approach consists of two separate extraction procedures designed to optimize recovery of each of these two classes, followed by analysis by liquid chromatography‐tandem mass spectrometry (LC‐MS/MS). The most significant novel compounds added were AB‐FUBINACA, ADBICA, 5 F‐ADBICA, ADB‐PINACA, ADB‐FUBINACA, ADB‐FUBINACA, 5 F‐ADB‐PINACA, 5 F‐ADB‐PINACA, AB‐PINACA, AB‐CHMINACA, and ADB‐CHMINACA. A third procedure is described for the quantitative confirmation of those compounds for which deuterated internal standards permitted quantitative analysis, including JWH‐018, JWH‐122, JWH‐081, JWH‐210, AM‐2201, XLR‐11, and UR‐144. The methods were successfully validated according to Scientific Working Group in Forensic Toxicology (SWGTOX) protocol for 34 compounds in common use in the United States in the period of 2014 and 2015, although other substances, unknown at the time may have been introduced to the market over the same time period. The method was determined to be free from carry‐over between samples, and no interference was found from other common therapeutic abused or novel psychoactive drugs. The methods were applied to the analysis of 1142 blood samples from forensic investigations, including post‐mortem examinations and driving impairment cases. The drugs most frequently detected were AB‐CHMINACA (18.6%), ADB‐CHMINACA (15%), XLR‐11 (5.5%), AB‐FUBINACA (4.5%), AB‐PINACA (3.9%), and ADB‐FUBINACA (2.3%). Copyright © 2016 John Wiley & Sons, Ltd.     

LC/MS/MS与GC/MS法分析鉴定小鼠尿中沙美特罗的代谢产物

目的:鉴定沙美特罗在小鼠尿中的主要代谢产物.方法:ig给药后,收集小鼠尿液,经固相提取,葡萄糖醛酸酶水解,进行LC/MS/MS分析和硅烷化后进行GC/MS分析同时分离鉴定沙美特罗代谢产物.结果和结论:在给药后尿样中发现沙美特罗原型和4种代谢产物M1～M4,其结构推测为19-羟基沙美特罗(M1)、2-羰基沙美特罗(M2)、19-羰基沙美特罗(M3)和19-羟基-8-甲氧基沙美特罗(M4).     

Detection of the recently emerged synthetic cannabinoid 4F‐MDMB‐BINACA in “legal high” products and human urine specimens

Synthetic cannabinoids (SCs) remain one of the largest groups of new psychoactive substances (NPS) on the European drug market. Although the number of new derivatives occurring on the market has dropped in the last two years, newly emerging NPS still represent a challenge for laboratories performing forensic drug analysis in biological matrices. The newly emerged SC 4F‐MDMB‐BINACA has been reported by several law enforcement agencies in Europe and the USA since November 2018. This work aimed at revealing urinary markers to prove uptake of 4F‐MDMB‐BINACA and differentiate from the use of structurally similar SCs. Phase‐I metabolites detected in human urine specimens were confirmed by phase‐I metabolites generated in vitro using a pooled human liver microsomes (pHLM) assay. Seized materials and test‐purchased “legal high” products were analyzed by gas chromatography–mass spectrometry (GC–MS) and liquid chromatography?quadrupole‐time‐of‐flight?mass spectrometry (LC?qToF?MS). Human urine specimens and pHLM assay extracts were measured with liquid chromatography?electrospray ionization?tandem mass spectrometry (LC?ESI?MS/MS) and confirmed by LC?qToF?MS. In January 2019, the Institute of Legal Medicine in Erlangen (Germany) identified 4F‐MDMB‐BINACA in three herbal blends. During the same time period, the described SC was identified in a research chemical purchased online. Investigation of phase‐I metabolism led to the metabolites M10 (ester hydrolysis) and M11 (ester hydrolysis and dehydrogenation) as reliable urinary markers. Widespread distribution on the German drug market was proven by analysis of urine samples from abstinence control programs and by frequent detection of 4F‐MDMB‐BINACA in “herbal blends” and “‘research chemicals” purchased via the Internet.     

Study of the in vitro and in vivo metabolism of the tryptamine 5‐MeO‐MiPT using human liver microsomes and real case samples

The synthetic tryptamine 5‐methoxy‐N‐methyl‐N‐isopropyltryptamine (5‐MeO‐MiPT) has recently been abused as a hallucinogenic drug in Germany and Switzerland. This study presents a case of 5‐MeO‐MiPT intoxication and the structural elucidation of metabolites in pooled human liver microsomes (pHLM), blood, and urine. Microsomal incubation experiments were performed using pHLM to detect and identify in vitro metabolites. In August 2016, the police encountered a naked man, agitated and with aggressive behavior on the street. Blood and urine samples were taken at the hospital and his premises were searched. The obtained blood and urine samples were analyzed for in vivo metabolites of 5‐MeO‐MiPT using liquid chromatography–high resolution tandem mass spectrometry (LC–HRMS/MS). The confiscated pills and powder samples were qualitatively analyzed using Fourier transform infrared (FTIR), gas chromatography–mass spectrometry (GC–MS), LC‐HRMS/MS, and nuclear magnetic resonance (NMR). 5‐MeO‐MiPT was identified in 2 of the seized powder samples. General unknown screening detected cocaine, cocaethylene, methylphenidate, ritalinic acid, and 5‐MeO‐MiPT in urine. Seven different in vitro phase I metabolites of 5‐MeO‐MiPT were identified. In the forensic case samples, 4 phase I metabolites could be identified in blood and 7 in urine. The 5 most abundant metabolites were formed by demethylation and hydroxylation of the parent compound. 5‐MeO‐MiPT concentrations in the blood and urine sample were found to be 160 ng/mL and 3380 ng/mL, respectively. Based on the results of this study we recommend metabolites 5‐methoxy‐N‐isopropyltryptamine (5‐MeO‐NiPT), 5‐hydroxy‐N‐methyl‐N‐isopropyltryptamine (5‐OH‐MiPT), 5‐methoxy‐N‐methyl‐N‐isopropyltryptamine‐N‐oxide (5‐MeO‐MiPT‐N‐oxide), and hydroxy‐5‐methoxy‐N‐methyl‐N‐isopropyltryptamine (OH‐5‐MeO‐MiPT) as biomarkers for the development of new methods for the detection of 5‐MeO‐MiPT consumption, as they have been present in both blood and urine samples.     

Liquid chromatography–tandem mass spectrometry screening method using information‐dependent acquisition of enhanced product ion mass spectra for synthetic cannabinoids including metabolites in urine

The total number of synthetic cannabinoids (SCs) – a group of new psychoactive substances (NPS) – is increasing every year. The rapidly changing market demands the latest analytical methods to detect the consumption of SCs in clinical or forensic toxicology. In addition, SC metabolites must also be included in a screening procedure, if detection in urine is asked for. For that purpose, an easy and fast qualitative liquid chromatography—tandem mass spectrometry (LC?MS/MS) urine screening method for the detection of 75 SCs and their metabolites was developed and validated in terms of matrix effects, recovery, and limits of identification for a selection of analytes. SC metabolites were generated using in vitro human liver microsome assays, identified by liquid chromatography?high resolution tandem mass spectrometry (LC?HRMS/MS) and finally included to the MS/MS spectra in‐house library. Sample preparation was performed using a cheap‐and‐easy salting‐out liquid–liquid extraction (SALLE) after enzymatic hydrolysis. Method validation showed good selectivity, limits of identification down to 0.05 ng/mL, recoveries above 80%, and matrix effects within ±25% for the selected analytes. Applicability of the method was demonstrated by detection of SC metabolites in authentic urine samples.     

Rapid and simple LC‐MS/MS screening of 64 novel psychoactive substances using dried blood spots

The range of novel psychoactive substances (NPS) including phenethylamines, cathinones, piperazines, tryptamines, etc. is continuously growing. Therefore, fast and reliable screening methods for these compounds are essential and needed. The use of dried blood spots (DBS) for a fast straightforward approach helps to simplify and shorten sample preparation significantly. DBS were produced from 10 µl of whole blood and extracted offline with 500 µl methanol followed by evaporation and reconstitution in mobile phase. Reversed‐phase chromatographic separation and mass spectrometric detection (RP‐LC‐MS/MS) was achieved within a run time of 10 min. The screening method was validated by evaluating the following parameters: limit of detection (LOD), matrix effect, selectivity and specificity, extraction efficiency, and short‐term and long‐term stability. Furthermore, the method was applied to authentic samples and results were compared with those obtained with a validated whole blood method used for routine analysis of NPS. LOD was between 1 and 10 ng/ml. No interference from matrix compounds was observed. The method was proven to be specific and selective for the analytes, although with limitations for 3‐FMC/flephedrone and MDDMA/MDEA. Mean extraction efficiency was 84.6 %. All substances were stable in DBS for at least a week when cooled. Cooling was essential for the stability of cathinones. Prepared samples were stable for at least 3 days. Comparison to the validated whole blood method yielded similar results. DBS were shown to be useful in developing a rapid screening method for NPS with simplified sample preparation. Copyright © 2013 John Wiley & Sons, Ltd.     

Chemical investigation on Sijunzi decoction and its two major herbs Panax ginseng and Glycyrrhiza uralensis by LC/MS/MS

Sijunzi decoction consists of Panax ginseng, Poria cocos, Atractylodes macrocephala and Glycyrrhiza uralensis. High performance liquid chromatography coupled with tandem mass spectrometry (LC/MSⁿ) was applied to identify and characterize three types of active components, ginsenoside (from P. ginseng), flavonoid and triterpenoid (from G. uralensis) in Sijunzi decoction. Spectra of MS and MS/MS from [M + Na]⁺ ions of ginsenosides were acquired and interpreted for their identification. Fragmentations with losing masses of 194 or 176 Da were the characteristic ions of triterpenoids in the MS/MS analysis. A characteristic fragment ion of the aglycon moiety at m/z 257 from source collision-induced dissociation was observed for flavonoid. LC/MS was also applied for the comparison of relative peak area of major active components between Sijunzi decoction and the single herb extracts. The concentration ratios of major active components detected in the individual herbs of P. ginseng and G. uralensis were found different from those in Sijunzi decoction. The experimental data indicated that the decocting process could result in the difference in the amount of active components.     

LC‐MS/MS detection of unaltered glucuronoconjugated metabolites of metandienone

The aim of this study was to evaluate the direct detection of glucuronoconjugated metabolites of metandienone (MTD) and their detection times. Metabolites resistant to enzymatic hydrolysis were also evaluated. Based on the common mass spectrometric behaviour of steroid glucuronides, three liquid chromatography‐tandem mass spectrometry (LC‐MS/MS) strategies were applied for the detection of unpredicted and predicted metabolites: precursor ion scan (PI), neutral loss scan (NL), and theoretical selected reaction monitoring (SRM) methods. Samples from four excretion studies of MTD were analyzed for both the detection of metabolites and the establishment of their detection times. Using PI and NL methods, seven metabolites were observed in post‐administration samples. SRM methods allowed for the detection of 13 glucuronide metabolites. The detection times, measured by analysis with an SRM method, were between 1 and 22 days. The metabolite detected for the longest time was 18‐nor‐17β‐hydroxymethyl‐17α‐methyl‐5β‐androsta‐1,4,13‐triene‐3‐one‐17‐glucuronide. One metabolite was resistant to hydrolysis with β ‐glucuronidase; however it was only detected in urine up to four days after administration. The three glucuronide metabolites with the highest retrospectivity were identified by chemical synthesis or mass spectrometric data, and although they were previously reported, this is the first time that analytical data of the intact phase II metabolites are presented for some of them. The LC‐MS/MS strategies applied have demonstrated to be useful for detecting glucuronoconjugated metabolites of MTD, including glucuronides resistant to enzymatic hydrolysis which cannot be detected by conventional approaches. Copyright © 2016 John Wiley & Sons, Ltd.     

The in vivo and in vitro phase I metabolism of FYL‐67, a novel oxazolidinone antibacterial drug,studied by LC‐MS/MS

In our previous study, FYL‐67, a novel linezolid analogue with the morpholinyl ring replaced by a 4‐(pyridin‐2‐yl)‐1H‐pyrazol‐1‐yl group, was demonstrated to own an excellent activity against Gram‐positive organisms,such as methicillin‐resistant Staphylococcus aureus (MRSA). However, metabolic biotransformation was not investigated. This study was performed to identify the phase I metabolites of FYL‐67 using liquid chromatography‐tandem mass spectrometry (LC‐MS/MS). The chemical structures were confirmed by comparison with corresponding chemical standards obtained internal. Primary elucidation of the metabolic pathway of FYL‐67 in vitro was performed using liver preparations (microsomes and hepatocytes) from rats and humans, and SD (Sprague Dawley, rat, rattus norvegicus) rats were used for the study of in vivo approach. To the end, two metabolites (M₁ and M₂) were detected after in vitro as well as in vivo experiments. Based on LC‐MS/MS analyses, the metabolites were demonstrated to be 5‐(aminomethyl)‐3‐(3‐fluoro‐4‐(4‐(pyridin‐2‐yl)‐1H‐pyrazol‐1‐yl)phenyl)oxazolidin‐2‐one (M₁) and 3‐(3‐fluoro‐4‐(4‐(pyridin‐2‐yl)‐1H‐pyrazol‐1‐yl)phenyl)‐5‐(hydroxymethyl)oxazolidin‐2‐one (M₂). Amide hydrolysis at acetyl group of FYL‐67 leading to the formation of M₁ was observed and suggested to play a major role in both in vivo and in vitro phase I metabolism of FYL‐67. M₁ was demonstrated to undergo a further oxidation to form M₂. In addition, the results indicated no species difference existing between rats and humans. The outcomes of our research can be utilized for the development and validation of the analytical method for the quantification of FYL‐67 as well as its metabolites in biological samples. Furthermore, it is helpful to conduct studies of pharmacodynamics and toxicodynamics. Copyright © 2015 John Wiley & Sons, Ltd.     

Simultaneous analysis of 29 synthetic cannabinoids and metabolites,amphetamines, and cannabinoids in human whole blood by liquid chromatography–tandem mass spectrometry – A New Zealand perspective of use in 2018

We describe the validation of a method for the simultaneous analysis of 29 synthetic cannabinoids (SCs) and metabolites, 4 amphetamines, and 2 cannabinoids in human whole blood. This method enables one analysis to cover what previously required multiple analyses for these classic and novel drugs‐of‐abuse with diverse physicochemical properties. The scope of targeted analytes was based on the most prevalent drugs‐of‐abuse and SCs encountered at the New Zealand border in 2017 and included parent compounds and metabolites belonging to the indole and indazole carboxamide, quinolinyl indole carboxylate, and naphthoylindole classifications. Samples were prepared by supported‐liquid‐extraction (SLE) followed by liquid chromatography?tandem mass spectrometry (LC?MS/MS) analysis with positive electrospray ionization (ESI). The method was validated with respect to selectivity, matrix effects, process efficiency, sensitivity, repeatability, extract stability, and carryover for qualitative confirmation. Linearity as well as accuracy and precision data at target decision concentrations were also evaluated. The limits of detection and confirmation ranged from 0.1 to 6.0 ng/mL and 1.0 to 6.0 ng/mL, respectively. The described method was successfully applied to the analysis of 564 ante‐ and post‐mortem blood samples in 2018. There were 132 cases (23%) with positive findings of at least one SC, with the five most commonly detected SCs being AMB‐FUBINACA and/or acid (61%), 5F‐ADB and/or acid (40%), ADB‐FUBINACA (11%), 5F‐MDMB‐PICA acid (6%), and MDMB‐FUBINACA acid (6%). The results also demonstrate the predominant presence of metabolites at higher levels than the unchanged parent SCs in blood, highlighting the need to maintain forensic screening methods capable of the simultaneous detection of both parent compounds and metabolites.     

Phase I metabolism of the carbazole‐derived synthetic cannabinoids EG‐018, EG‐2201, and MDMB‐CHMCZCA and detection in human urine samples

Synthetic cannabinoids (SCs) are a structurally diverse class of new psychoactive substances. Most SCs used for recreational purposes are based on indole or indazole core structures. EG‐018 (naphthalen‐1‐yl(9‐pentyl‐9H‐carbazol‐3‐yl)methanone), EG‐2201 ((9‐(5‐fluoropentyl)‐9H‐carbazol‐3‐yl)(naphthalen‐1‐yl)methanone), and MDMB‐CHMCZCA (methyl 2‐(9‐(cyclohexylmethyl)‐9H‐carbazole‐3‐carboxamido)‐3,3‐dimethylbutanoate) are 3 representatives of a structural subclass of SCs, characterized by a carbazole core system. In vitro and in vivo phase I metabolism studies were conducted to identify the most suitable metabolites for the detection of these substances in urine screening. Detection and characterization of metabolites were performed by liquid chromatography–electrospray ionization–tandem mass spectrometry (LC–ESI–MS/MS) and liquid chromatography–electrospray ionization–quadrupole time‐of‐flight–mass spectrometry (LC–ESI–QToF–MS). Eleven in vivo metabolites were detected in urine samples positive for metabolites of EG‐018 (n = 8). A hydroxypentyl metabolite, most probably the 4‐hydroxypentyl isomer, and an N‐dealkylated metabolite mono‐hydroxylated at the carbazole core system were most abundant. In vitro studies of EG‐018 and EG‐2201 indicated that oxidative defluorination of the 5‐fluoropentyl side chain of EG‐2201 as well as dealkylation led to common metabolites with EG‐018. This has to be taken into account for interpretation of analytical findings. A differentiation between EG‐018 and EG‐2201 (n = 1) uptake is possible by the detection of compound‐specific in vivo phase I metabolites evaluated in this study. Out of 30 metabolites detected in urine samples of MDMB‐CHMCZCA users (n = 20), a metabolite mono‐hydroxylated at the cyclohexyl methyl tail is considered the most suitable compound‐specific consumption marker while a biotransformation product of mono‐hydroxylation in combination with hydrolysis of the terminal methyl ester function provides best sensitivity due to its high abundance.     

Detection of the recently emerged synthetic cannabinoid 5F–MDMB‐PICA in ‘legal high’ products and human urine samples

Indole or indazole‐based synthetic cannabinoids (SCs) bearing substituents derived from valine or tert‐leucine are frequently abused new psychoactive substances (NPS). The emergence of 5F–MDMB‐PICA (methyl N‐{[1‐(5‐fluoropentyl)‐1H–indol‐3‐yl]carbonyl}‐3‐methylvalinate) on the German drug market is a further example of a substance synthesized in the context of scientific research being misused by clandestine laboratories by adding it to ‘legal high’ products. In this work, we present the detection of 5F–MDMB‐PICA in several legal high products by gas chromatography–mass spectrometry (GC–MS) analysis. To detect characteristic metabolites suitable for a proof of 5F–MDMB‐PICA consumption by urine analysis, pooled human liver microsome (pHLM) assays were performed and evaluated using liquid chromatography–tandem mass spectrometry (LC–MS/MS) and liquid chromatography quadrupole time‐of‐flight mass spectrometry (LC‐QToF‐MS) techniques to generate reference spectra of the in vitro phase I metabolites. The in vivo phase I metabolism was investigated by the analysis of more than 20 authentic human urine specimens and compared to the data received from the pHLM assay. Biotransformation of the 5‐fluoropentyl side chain and hydrolysis of the terminal methyl ester bond are main phase I biotransformation steps. Two of the identified main metabolites formed by methyl ester hydrolysis or mono‐hydroxylation at the indole ring system were evaluated as suitable urinary biomarkers and discussed regarding the interpretation of analytical findings. Exemplary analysis of one urine sample for 5F–MDMB‐PICA phase II metabolites showed that two of the main phase I metabolites are subject to extensive glucuronidation prior to renal excretion. Therefore, conjugate cleavage is reasonable for enhancing sensitivity. Commercially available immunochemical pre‐tests for urine proved to be unsuitable for the detection of 5F–MDMB‐PICA consumption. Copyright © 2017 John Wiley & Sons, Ltd.     

Metabolic patterns of JWH‐210, RCS‐4, and THC in pig urine elucidated using LC‐HR‐MS/MS: Do they reflect patterns in humans?

The knowledge of pharmacokinetic (PK) properties of synthetic cannabinoids (SCs) is important for interpretation of analytical results found for example in intoxicated individuals. In the absence of human data from controlled studies, animal models elucidating SC PK have to be established. Pigs providing large biofluid sample volumes were tested for prediction of human PK data. In this context, the metabolic fate of two model SCs, namely 4‐ethylnaphthalen‐1‐yl‐(1‐pentylindol‐3‐yl)methanone (JWH‐210) and 2‐(4‐methoxyphenyl)‐1‐(1‐pentyl‐indol‐3‐yl)methanone (RCS‐4), was elucidated in addition to Δ⁹‐tetrahydrocannabinol (THC). After intravenous administration of the compounds, hourly collected pig urine was analyzed by liquid chromatography‐high resolution mass spectrometry. The following pathways were observed: for JWH‐210, hydroxylation at the ethyl side chain or pentyl chain and combinations of them followed by glucuronidation; for RCS‐4, hydroxylation at the methoxyphenyl moiety or pentyl chain followed by glucuronidation as well as O ‐demethylation followed by glucuronidation or sulfation; for THC, THC glucuronidation, 11‐hydroxylation, followed by carboxylation and glucuronidation. For both SCs, parent compounds could not be detected in urine in contrast to THC. These results were consistent with those obtained from human hepatocyte and/or human case studies. Urinary markers for the consumption of JWH‐210 were the glucuronide of the N ‐hydroxypentyl metabolite (detectable for 3–4 h) and of RCS‐4 the glucuronides of the N ‐hydroxypentyl, hydroxy‐methoxyphenyl (detectable for at least 6 h), and the O ‐demethyl‐hydroxy metabolites (detectable for 4 h). Copyright © 2016 John Wiley & Sons, Ltd.     

LC/MS/MS evaluation of cocaine and its metabolites in different brain areas,peripheral organs and plasma in cocaine self-administering rats

BackgroundWe employed a cocaine intravenous self-administration model based on positive reinforcement of animals' instrumental reactions (i.e., lever pressing) rewarded by a dose of the drug. We also carried out simultaneous characterization of the phar-macokinetics of cocaine and its metabolites in rats during withdrawal; in this part of the experiments, we investigated the cocaine (2 mg/kg, iv)-induced changes in the distribution, rate constant, clearance and t_1/2 of the parent drug and its metabolites in different structures of the brain and in peripheral tissues.MethodsBy using liquid chromatography-tandem mass spectrometry (LC/MS/MS) we measured the levels of cocaine and its major metabolites.ResultsOur results demonstrate differences in the levels of cocaine after cocaine self-administration in the rat, with the highest concentration seen in the striatum and the lowest in the cerebellum. Cocaine metabolites determined in the rat brain remained at very low levels (benzoylecgonine), irrespectively of the brain area, whereas the norcocaine concentration varied from 1.56 μg/g (the nucleus accumbens) to 2.73 μg/g (the striatum).ConclusionAtandem LC/MS/MS is a valid method for evaluation of brain and peripheral levels ofcocaine and its metabolites. Our results demonstrate brain area-dependent differences in the levels of cocaine after its self-administration in the rat. There were also differences in pharmacokinetic parameters among the brain areas and peripheral tissues following a bolus iv injection of cocaine to rats withdrawn from cocaine; among brain structures the slowest metabolic rate was detected for the striatum.     

Elucidation of the metabolites of the novel psychoactive substance 4‐methyl‐N‐ethyl‐cathinone (4‐MEC) in human urine and pooled liver microsomes by GC‐MS and LC‐HR‐MS/MS techniques and of its detectability by GC‐MS or LC‐MSn standard screening approaches

4‐methyl‐N‐ethcathinone (4‐MEC), the N‐ethyl homologue of mephedrone, is a novel psychoactive substance of the beta‐keto amphetamine (cathinone) group. The aim of the present work was to study the phase I and phase II metabolism of 4‐MEC in human urine as well as in pooled human liver microsome (pHLM) incubations. The urine samples were worked up with and without enzymatic cleavage, the pHLM incubations by simple deproteinization. The metabolites were separated and identified by gas chromatography‐mass spectrometry (GC‐MS) and liquid chromatography‐high resolution‐tandem mass spectrometry (LC‐HR‐MS/MS). Based on the metabolites identified in urine and/or pHLM, the following metabolic pathways could be proposed: reduction of the keto group, N‐deethylation, hydroxylation of the 4‐methyl group followed by further oxidation to the corresponding 4‐carboxy metabolite, and combinations of these steps. Glucuronidation could only be observed for the hydroxy metabolite. These pathways were similar to those described for the N‐methyl homologue mephedrone and other related drugs. In pHLM, all phase I metabolites with the exception of the N‐deethyl‐dihydro isomers and the 4‐carboxy‐dihydro metabolite could be confirmed. Glucuronides could not be formed under the applied conditions. Although the taken dose was not clear, an intake of 4‐MEC should be detectable in urine by the GC‐MS and LC‐MSⁿ standard urine screening approaches at least after overdose. Copyright © 2014 John Wiley & Sons, Ltd.     

Prevalence and concentrations of new designer stimulants,synthetic opioids,benzodiazepines, and hallucinogens in postmortem hair samples: A 13-year retrospective study

Hair samples are frequently analyzed in order to characterize consumption patterns of drugs. However, the interpretation of new psychoactive substance (NPS) findings in hair remains difficult because of lacking data for comparison. In this study, selected postmortem hair samples (n = 1203) from 2008 to 2020 were reanalyzed for synthetic cathinones, piperazines, phenethylamines, hallucinogens, benzodiazepines and opioids to evaluate prevalence data and concentration ranges. Hair samples were extracted using a two-step extraction procedure and analyzed using a validated liquid chromatography–tandem mass spectrometry (LC–MS/MS) method. Overall NPSs were detected in 381 cases (31.6%). Many cases were tested positive for more than one NPS in the same time span. A variety of NPS with a large range of concentrations was observed. For better comparability and interpretation of positive cases in routine work, quantitation data for 13 NPS were calculated as percentiles. The most frequently detected NPS in this study were N-ethylamphetamine, α-pyrrolidinovalerophenone, mephedrone, benzedrone, metamfepramone, and 4-fluoroamphetamine. In conclusion, a high prevalence of these drugs was observed from postmortem hair samples. The results show a growing use of many different NPSs by mainly young drug-using adults. Consequently, NPS screening procedures should be included in forensic toxicology. Our quantitative data may support other toxicologists in their assessment of NPS hair concentrations.