Preservation of Cell Structure, Metabolism, and Biotransformation Activity of Liver-On-Chip Organ Models by Hypothermic Storage.

The liver is a central organ in the metabolization of nutrition, endogenous and exogenous substances, and xenobiotic drugs. The emerging organ-on-chip technology has paved the way to model essential liver functions as well as certain aspects of liver disease in vitro in liver-on-chip models. However, a broader use of this technology in biomedical research is limited by a lack of protocols that enable the short-term preservation of preassembled liver-on-chip models for stocking or delivery to researchers outside the bioengineering community. For the first time, this study tested the ability of hypothermic storage of liver-on-chip models to preserve cell viability, tissue morphology, metabolism and biotransformation activity. In a systematic study with different preservation solutions, liver-on-chip function can be preserved for up to 2 d using a derivative of the tissue preservation solution TiProtec, containing high chloride ion concentrations and the iron chelators LK614 and deferoxamine, supplemented with polyethylene glycol (PEG). Hypothermic storage in this solution represents a promising method to preserve liver-on-chip function for at least 2 d and allows an easier access to liver-on-chip technology and its versatile and flexible use in biomedical research.

In vitro approaches to studying the metabolism of new psychoactive compounds.

In the last two decades, a large number of new drugs from several drug classes have appeared on the illicit drug market. While some of these compounds have meanwhile been scheduled as controlled substances, the majority of them are (still) sold as so-called 'legal highs', mostly via the Internet. At the time they appear on the market the metabolism of these drugs is generally unknown. Therefore, it must be studied in order to obtain data necessary for analytical method development as well as toxicological risk assessment. In vitro metabolism studies of new designer drugs can be performed for identification and structure elucidation of new designer drug metabolites or to assess the qualitative and quantitative involvement of certain enzymes in the metabolism of a particular drug. In this review, the value of the following enzyme preparations for in vitro metabolism studies of new designer drugs will be discussed: liver microsomes, recombinant cDNA-expressed enzymes, liver cytosol, S9 mix, and hepatocytes. This will cover the major metabolic enzymes: cytochrome P450 monooxygenases, flavin-monooxygenases, monoamine oxidases, UDP-glucuronyltransferases, sulfotransferases, and catechol-O-methyltransferases. Important analytical aspects such as the value of mass spectrometric techniques will also be covered.

Automated mass spectral deconvolution and identification system for GC-MS screening for drugs, poisons, and metabolites in urine.

BACKGROUND: The challenge in systematic toxicological analysis using gas chromatography and/or liquid chromatography coupled to mass spectrometry is to identify compounds of interest from background noise. The large amount of spectral information collected in one full-scan MS run demands the use of automated evaluation of recorded data files. We evaluated the applicability of the freeware deconvolution software AMDIS (Automated Mass Spectral Deconvolution and Identification System) for GC-MS-based systematic toxicological analysis in urine for increasing the speed of evaluation and automating the daily routine workload. METHODS: We prepared a set of 111 urine samples for GC-MS analysis by acidic hydrolysis, liquid-liquid extraction, and acetylation. After analysis, the resulting data files were evaluated manually by an experienced toxicologist and automatically using AMDIS with deconvolution and identification settings previously optimized for this type of analysis. The results by manual and AMDIS evaluation were then compared. RESULTS: The deconvolution settings for the AMDIS evaluation were successfully optimized to obtain the highest possible number of components. Identification settings were evaluated and chosen for a compromise between most identified targets and general number of hits. With the use of these optimized settings, AMDIS-based data analysis was comparable or even superior to manual evaluation and reduced by half the overall analysis time. CONCLUSIONS: AMDIS proved to be a reliable and powerful tool for daily routine and emergency toxicology. Nevertheless, AMDIS can identify only targets present in the user-defined target library and may therefore not indicate unknown compounds that might be relevant in clinical and forensic toxicology.

Identification of cytochrome P450 enzymes involved in the metabolism of the designer drugs N-(1-phenylcyclohexyl)-3-ethoxypropanamine and N-(1-phenylcyclohexyl)-3-methoxypropanamine.

The involvement of human hepatic cytochrome P450 isoenzymes (P450s) in the metabolism of the designer drugs N-(1-phenylcyclohexyl)-3-ethoxypropanamine (PCEPA) and N-(1-phenylcyclohexyl)-3-methoxypropanamine (PCMPA) to the common metabolite N-(1-phenylcyclohexyl)-3-hydroxypropanamine (PCHPA) was studied using insect cell microsomes with cDNA-expressed human P450s and human liver microsomes (HLMs). Incubation samples were analyzed by gas chromatography-mass spectrometry or liquid chromatography-mass spectrometry. Among the tested isoenzymes, P450 2B6, P450 2C19, P450 2D6, and P450 3A4 catalyzed PCEPA O-deethylation, and P450 2B6, P450 2C19, and P450 2D6 catalyzed PCMPA O-demethylation. According to the relative activity factor approach, these enzymes accounted for 22, 3, 30, and 45% of the net clearance for PCEPA and 51, 8, and 40% of the net clearance for PCMPA, respectively. At 1 microM PCEPA, the chemical inhibitors 4-(4-chlorobenzyl)pyridine for P450 2B6 and quinidine for P450 2D6 reduced metabolite formation in pooled HLMs by 37 and 73%, respectively, and at 10 microM PCEPA, they reduced metabolite formation by 57 and 26%, respectively. At 1 microM PCMPA, 4-(4-chlorobenzyl)pyridine and quinidine reduced metabolite formation in pooled HLMs by 25 and 39%, respectively, and at 10 microM PCMPA, they reduced metabolite formation by 62 and 27%, respectively. The experiments with the MAB inhibitory to P450 3A4 and the chemical inhibitor ketoconazole for P450 3A4 showed no inhibitory effect concerning PCEPA O-dealkylation. Experiments with HLMs from P450 2D6 poor metabolizers showed a reduction of metabolite formation as compared to pooled HLM of 73 and 25% (1 microM and 10 microM PCEPA) and 40 and 38% (1 microM and 10 microM PCMPA), respectively. In conclusion, the main metabolic step was catalyzed by different P450s.

Detection and validated quantification of nine herbal phenalkylamines and methcathinone in human blood plasma by LC-MS/MS with electrospray ionization.

The herbal stimulants Ephedra species, Catha edulis (khat), and Lophophora williamsii (peyote) have been abused for a long time. In recent years, the herbal drug market has grown owing to publicity on the Internet. Some ingredients of these plants are also ingredients of cold remedies. The aim of the presented study is to develop a multianalyte procedure for detection and validated quantification of the phenalkylamines ephedrine, pseudoephedrine, norephedrine, norpseudoephedrine, methylephedrine, methylpseudoephedrine, cathinone, mescaline, synephrine (oxedrine), and methcathinone in plasma. After mixed-mode solid-phase extraction of 1 ml of plasma, the analytes were separated using a strong cation exchange separation column and gradient elution. They were detected using a Q-Trap LC-ESI-MS/MS system (MRM mode). Calibration curves were used for quantification using norephedrine-d3, ephedrine-d3, and mescaline-d9 as internal standards. The method was validated according to international guidelines. The assay was selective for the tested compounds. It was linear from 10 to 1000 ng/ml for all analytes. The recoveries were generally higher than 70%. Accuracy ranged from - 0.8 to 20.0%, repeatability from 2.5 to 12.3%, and intermediate precision from 4.6 to 20.0%. The lower limit of quantification was 10 ng/ml for all analytes. No instability was observed after repeated freezing and thawing or in processed samples. The applicability of the assay was tested by analysis of authentic plasma samples after ingestion of different cold medications containing ephedrine or pseudoephedrine, and after ingestion of an aqueous extract of Herba Ephedra. After ingestion of the cold medications, only the corresponding single alkaloids were detected in human plasma, whereas after ingestion of the herb extract, all six ephedrines contained in the plant were detected. The presented LC-MS/MS assay was found applicable for sensitive detection and accurate and precise quantification of all studied analytes in plasma.

Screening procedure for detection of stimulant laxatives and/or their metabolites in human urine using gas chromatography-mass spectrometry after enzymatic cleavage of conjugates and extractive methylation.

A gas chromatography-mass spectrometry (GC-MS)-based screening procedure was developed for the detection of stimulant laxatives and/or their metabolites in human urine after enzymatic cleavage of conjugates followed by extractive methylation. The part of the phase-transfer catalyst remaining in the organic phase was removed by solid-phase extraction on a diol phase. The compounds were separated by capillary GC and identified by computerized MS in the full scan mode. By use of mass chromatography with the ions m/z 305, 290, 335, 320, 365, 350, 311, 326, 271, and 346, the possible presence of stimulant laxatives and/or their metabolites could be indicated. The identity of positive signals in such mass chromatograms was confirmed by comparison of the peaks underlying full mass spectra with the reference spectra. This method allowed the detection of the diphenol laxatives bisacodyl, picosulfate, and phenolphthalein and of the anthraquinone laxatives contained in plant extracts and/or their metabolites in human urine samples. The overall recoveries of the stimulant laxatives and/or their metabolites ranged between 33% and 89% with a coefficient of variation of less than 15%, and the limits of detection ranged between 10 and 25 ng/mL (S/N 3) in the full scan mode. After ingestion of the lowest therapeutic dose of sodium picosulfate, its main metabolite, bisacodyl diphenol, was detectable in urine samples for 72 hours. After ingestion of the lowest therapeutic dose of a senna extract, the main metabolite of sennosides, rhein, was detectable in urine samples for 24 hours. This procedure is part of a systematic toxicological analysis procedure for acidic drugs and poisons with the modification of enzymatic cleavage of conjugates.

Toward high-throughput drug screening using mass spectrometry.

A critical overview on the potential of mass spectrometry-based methods regarding high-throughput screening analysis is presented. Within this scope, screening procedures will be discussed for simultaneous detection of several drug classes relevant to clinical and forensic toxicology or doping control in urine or blood using gas chromatography-mass spectrometry or liquid chromatography-mass spectrometry.