High-throughput quantification of drugs and their metabolites in biosamples by LC-MS/MS and CE-MS/MS: possibilities and limitations.

Off-line solid phase extraction with C18 disk plates and turbulent flow chromatography were evaluated versus on-line solid phase extraction using column-switching HPLC as sample preparation techniques for high-throughput analysis of pharmaceutical compounds and their metabolites by LC-MS/MS. Turbulent flow chromatography was found to be very straightforward in its applicaton, but the LOQs were more than fivefold higher compared with off-line or other on-line solid phase extraction methods. Solid phase extraction (SPE) on disk was found to be fast and sufficient efficient to minimize matrix effects and therefore an apprach to provide sensitive and reliable LC-MS/MS methods. Column-switching HPLC with microbore columns (0.5 mm i.d.) were used for fast analysis of a parent drug and four of its metabolites utilizing steep gradients in 1 minute. The application of CZE-MS/MS for bionalysis of pharamaceutical compounds is also discussed.     

Reliable on-line sample preparation of basic compounds from plasma using a reversed phase restricted access media in column-switching LC

We investigated on-line sample preparation of basic compounds from plasma using a methylcellulose-immobilized reversed-phase restricted-access media in column-switching liquid chromatography (LC). Dilution of the plasma sample with phosphate buffered saline prevented or delayed the formation of fibrin clots at 4 °C and resulted in reproducible on-line sample preparation over a 30-h period. The use of an ion-pair reagent in the extraction LC enhanced recoveries of hydrophilic basic compounds. The ability of the methods to quantify compounds in plasma were validated and the method was successfully applied to the pharmacokinetic study of a hydrophilic basic compound injected into the bloodstream of rats.     

Blood plasma level determination using an automated LC–MSn screening system and electronically stored calibrations exemplified for 22 drugs and two active metabolites often requested in emergency toxicology

Fast and comprehensive qualitative and quantitative methods preferably by gas chromatography–mass spectrometry (GC–MS) and/or liquid chromatography–mass spectrometry (LC–MS) are needed to support the (differential) diagnosis of acute poisonings in emergency toxicology. One option is a commercially available qualitative screening solution based on LC–MSⁿ (Bruker Daltonik Toxtyper?, TT). Identified and toxicologically relevant compounds should be quantified to assess severity of poisonings. The aim of the present study was to test the TT system for quantification simultaneous with the screening process in blood plasma exemplified for 22 relevant drugs and two active metabolites. A standard liquid–liquid extraction was used for sample work‐up followed by 1:5 dilution of the final extracts. They were analyzed using the TT system consisting of a Bruker amaZon speed ion trap and a Thermo Fisher Dionex Ultimate 3000 LC system. Plasma levels were assessed using full‐scan data and an electronically stored five‐point calibration. The calibration model was linear for the studied ranges and could be used for at least two months. The method was validated according to international guidelines. The acceptance criteria recommended for emergency toxicology for accuracy and precision were fulfilled for all tested compounds, but bromazepam, lorazepam, oxycodone, and prothipendyl could reliably be determined only above the therapeutic range. In conclusion, the presented procedure allowed the combination of a comprehensive LC–MSⁿ screening with fast automated assessment of plasma levels for emergency toxicology of tested compounds.     

Urinary detection of conjugated and unconjugated anabolic steroids by dilute‐and‐shoot liquid chromatography‐high resolution mass spectrometry

Anabolic androgenic steroids (AAS) are an important class of doping agents. The metabolism of these substances is generally very extensive and includes phase‐I and phase‐II pathways. In this work, a comprehensive detection of these metabolites is described using a 2‐fold dilution of urine and subsequent analysis by liquid chromatography‐high resolution mass spectrometry (LC‐HRMS). The method was applied to study 32 different metabolites, excreted free or conjugated (glucuronide or sulfate), which permit the detection of misuse of at least 21 anabolic steroids. The method has been fully validated for 21 target compounds (8 glucuronide, 1 sulfate and 12 free steroids) and 18 out of 21 compounds had detection limits in the range of 1–10 ng mL^?1 in urine. For the conjugated compounds, for which no reference standards are available, metabolites were synthesized in vitro or excretion studies were investigated. The detection limits for these compounds ranged between 0.5 and 18 ng mL^?1 in urine. The simple and straightforward methodology complements the traditional methods based on hydrolysis, liquid‐liquid extraction, derivatization and analysis by gas chromatography–mass spectrometry (GC‐MS) and liquid chromatography‐mass spectrometry (LC‐MS). Copyright © 2014 John Wiley & Sons, Ltd.     

LC/ESI-MS allows simultaneous and specific quantification of SDZ RAD and cyclosporine, including groups of their metabolites in human blood

An analytic technique using liquid chromatography (LC) coupled with electrospray-mass spectrometry (ESI-MS) has been developed for the simultaneous determination of the new immunosuppressant SDZ RAD (40-O-[2-hydroxy)ethylrapamycin) and cyclosporine (Cs), including their metabolites in blood. With the time-sparing, automated on-line extraction technique, the recovery of SDZ RAD averaged 95% and that of Cs, 94%. The calibration lines were linear from 0.5 to 100 microg/L (r2 = 0.99) for SDZ RAD and from 10 to 1,000 microg/L (r2 = 0.99) for Cs. The method has been tested on blood samples from renal transplant recipients taken between 1 and 5 hours after oral SDZ RAD and Cs administration. In blood, we found the following metabolites: Hydroxy-SDZ RAD, dihydroxy-SDZ RAD, demethyl-SDZ RAD, and the ring-opened form of SDZ RAD. The main metabolite of SDZ RAD in blood was hydroxy-SDZ RAD. This novel LC/ESI-MS technique provided an excellent method for simultaneous quantitative monitoring of SDZ RAD and Cs, including their relevant groups of metabolites in patients treated simultaneously with these immunosuppressants.     

Power of Orbitrap‐based LC‐high resolution‐MS/MS for comprehensive drug testing in urine with or without conjugate cleavage or using dried urine spots after on‐spot cleavage in comparison to established LC–MSn or GC–MS procedures

Reliable, sensitive, and comprehensive urine screening procedures by gas chromatography–mass spectrometry (GC–MS) or liquid chromatography–mass spectrometry (LC–MS) with low or high resolution (HR) are of high importance for drug testing, adherence monitoring, or detection of toxic compounds. Besides conventional urine sampling, dried urine spots are of increasing interest. In the present study, the power of LC–HR–MS/MS was investigated for comprehensive drug testing in urine with or without conjugate cleavage or using dried urine spots after on‐spot cleavage in comparison to established LC–MSⁿ or GC–MS procedures. Authentic human urine samples (n = 103) were split in 4 parts. One aliquot was prepared by precipitation (UP), one by UP with conjugate cleavage (UglucP), one spot on filter paper cards and prepared by on‐spot cleavage followed by liquid extraction (DUSglucE), and one worked‐up by acid hydrolysis, liquid–liquid extraction, and acetylation for GC–MS analysis. The 3 series of LC–HR–MS/MS results were compared among themselves, to corresponding published LC–MSⁿ data, and to screening results obtained by conventional GC–MS. The reference libraries used for the 3 techniques contained over 4500 spectra of parent compounds and their metabolites. The number of all detected hits (770 drug intakes) was set to 100%. The LC–HR–MS/MS approach detected 80% of the hits after UP, 89% after UglucP, and 77% after DUSglucE, which meant over one‐third more hits in comparison to the corresponding published LC–MSⁿ results with ≤49% detected hits. The GC–MS approach identified 56% of all detected hits. In conclusion, LC–HR–MS/MS provided the best screening results after conjugate cleavage and precipitation.     

On-line radiometric determination of [14C]-urapidil and its main metabolises in rat plasma, using post-column ion-pair extraction and solvent segmentation techniques

Post-column ion-pair extraction has been applied to the on-line radiometric determination of [¹⁴C]-urapidil and its main metabolises in reversed-phase liquid chromatography (LC). [¹⁴C]-remoxipride was used as internal standard. Chromatography was performed isocratically, using acetonitrile—water (pH = 2.2) as eluent on a cyanobonded column. Various ion-pair reagents were tested for their extraction efficiency of the analytes mentioned from the eluent into chloroform. Quantitative extraction was possible using sodium dodecylbenzenesulphonate as ion-pair reagent. The influence of the extraction solvent composition, the percentage organic modifier in the eluent and the flow-rates of eluent and scintillator on the extraction percentage and the ¹⁴C-counting efficiency has been studied. In addition, the enhancement of sensitivity is possible using an on-line radiometric procedure. Finally, the method has been applied to the analysis of rat plasma for [¹⁴C] -labelled urapidil and its metabolises.     

On-line immunoaffinity extraction and HPLC analysis of flunitrazepam and its main metabolites in serum

A sensitive, simple, and rapid method for the determination of flunitrazepam and its major metabolites (7-aminoflunitrazepam, 7-acetamidoflunitrazepam, and norflunitrazepam) in serum and plasma is presented. The on-line procedure uses an immobilized, highly reusable antibody against benzodiazepines for selective extraction from serum followed by analysis by high-performance liquid chromatography with ultraviolet detection. This reliable method provides a limit of detection of 1 ng/mL serum, and results are obtained in less than 40 min.     

The investigation and the use of high flow column-switching LC/MS/MS as a high-throughput approach for direct plasma sample analysis of single and multiple components in pharmacokinetic studies

Recently direct plasma injection LC/MS/MS technique has been increasingly used in pharmaceutical research and development due to the demand for higher throughput of sample analyses. In this work, two on-line extraction methods including high flow LC/MS/MS and high flow column switching LC/MS/MS were investigated. The evaluations were conducted and focused on their performances with respect to peak responses, separation efficiency, and signal to-noise ratio in a multiple-component LC/MS/MS assay. Two HPLC pumps were used-with one for high flow delivery and one for gradient elution. A CTC autosampler was used to inject plasma samples. High flow LC was achieved by the use of 4 ml/min flow rate on a 1×50 mm Waters Oasis column. A 2×100 mm YMC column was coupled via a column-switching valve. The extracted analytes were analyzed in multiple-reaction-monitoring (MRM) mode using a triple quadrupole MS/MS. As a rapid and simple procedure, vortex-mixing plasma and internal standard directly in sample vials completed sample preparation. The high flow column switching method (two-column system) provided sharper peak shape than the conventional high flow method. This effect increased analyte signal-to-noise ratio and sensitivity. Narrower peak width resulted in much better separation efficiency, which was required for multiple compound (N-in-1) analysis. A 2 mm I.D. column resulted in better peak shape and resolution than using a smaller I.D. column. The selected method achieved acceptable recoveries for most of the compounds tested, and it was successfully applied to a 10-in-1 pharmacokinetic (PK) study. The results showed that the dynamic range, lower limit of quantitation, assay accuracy and precision were acceptable for all compounds. Rapid sample preparation eliminated labor intensive and time consuming processes and improved productivity. This high throughput on-line extraction high flow column switching method has been proven particularly useful for multiple component analysis in PK studies.     

On-line SPE-RP-LC for the determination of insulin derivatives in biological matrices

An automated and on-line solid-phase extraction (SPE)-liquid chromatography (LC) procedure is described for the determination of insulin in biological matrices. The total procedure consists of two SPEs in series, followed by RP-LC separation. During the first SPE a strong anion-exchange (SAX) cartridge (ISOLUTE, 40-90 microm, 10 x 4 mm i.d.) is used, followed by a RP-cartridge (Luna C(8), 4 x 2.0 mm i.d.). The second SPE cartridge contains the same material as the LC column and is used to transfer the sample from the SAX cartridge to the LC column. The developed system can detect 100 nmol/l insulin in aqueous samples and 200 nmol/l insulin in spiked plasma samples using UV. When electrospray ionization (ESI)-mass spectrometry (MS), was coupled with the developed system, the LODs were lowered by a factor two to 50 and 100 nmol/l for aqueous and spiked plasma samples, respectively.     

Column-switching liquid chromatographic determination of ML-1035 sulphoxide and its sulphone and sulphide metabolites in rat urine.

A fully automated column-switching LC assay has been developed for the simultaneous determination of a gastroprokinetic agent, ML-1035 sulphoxide, and its sulphone and sulphide metabolites in rat urine. ML-1035 Sulphoxide is a metoclopramide analogue. The method involved direct injection of a diluted urine sample into a CN extraction column for sample clean-up. Polar urine components, including proteins, were flushed to waste. The retained compounds were then eluted onto a C8 analytical column for further separation and analysis by fluorescence detection. After the subsequent washing and re-equilibration with a sequence of three solvent mixtures, the extraction column was ready for the next injection. The recovery of the compounds from the extraction column was 85-90%. The limit of quantitation for all compounds of interest was 25 ng ml-1 or lower, using a 100 microliters specimen of urine. Good inter-day precision (2.1-10.0%), accuracy (0.3-18.0%), and linearity were obtained for all compounds over a range of 25-1000 ng ml-1. The applicability of the LC method was validated with urine samples from rats that had received ML-1035 sulphoxide.     

Sample work-up by column techniques

A review is given of the extraction and purification of biological samples by filtration through lipophilic neutral and ion-exchange dextran gels and their derivatives. Liquid-gel extraction, reversed-phase liquid chromatography and ligand-exchange chromatography are also discussed. The applications of Sephadex and Lipidex gels are reviewed, with special reference to extractions from biological fluids and solid samples and the extraction of metabolites. A number of selective isolation procedures are reviewed for estrogens, lignans, isoflavanes, isoflavones, catechol estrogens, ketonic compounds and ethynyl steroids.     

Isolation and identification of clozapine metabolites in patient urine.

Biotransformation products of the atypical neuroleptic clozapine were isolated from urine samples of three schizophrenic patients by solid-phase extraction, liquid-liquid extraction for the separation of unpolar and polar metabolites, and thin-layer chromatography followed by final purification by high-performance liquid chromatography. Their structures were elucidated by mass spectrometry and (1)H NMR spectroscopy and in some cases by enzymatic deconjugation. Besides the known metabolites desmethylclozapine, clozapine N-oxide, 8-deschloro-8-hydroxyclozapine, and 8-deschloro-8-hydroxydesmethylclozapine, the unpolar fraction contained 7-hydroxyclozapine and a compound in which the piperazine ring of clozapine was partially degraded to an ethylenediamine derivative. Novel metabolites identified in the polar fraction were the sulfate and glucuronide conjugates of 7-hydroxyclozapine N-oxide, 8-deschloro-8-hydroxyclozapine-O-glucuronide, and the O-glucuronide of N-hydroxydesmethylclozapine; further conjugates were tentatively identified as 9-hydroxydesmethylclozapine-O-sulfate and 6-hydroxyclozapine-O-sulfate. In addition, the previously described conjugates 7-hydroxydesmethylclozapine-O-sulfate, 7-hydroxyclozapine-O-glucuronide and -O-sulfate, 8-deschloro-8-hydroxydesmethylclozapine-O-glucuronide, and the quaternary ammonium glucuronide of clozapine were detected.     

Effective on-line extraction of drugs from plasma using a restricted-access media column in column-switching HPLC equipped with a dilution system: Application to the simultaneous determination of ER-118585 and its metabolites in canine plasma

The present paper describes the on-line extraction of drugs in plasma using a restricted-access media (RAM) column in a column-switching high performance liquid chromatography (HPLC) apparatus that was equipped with an on-line dilution system. The use of a six- to eightfold on-line dilution ratio for plasma samples resulted in almost 100% recovery of both acidic and basic drugs from plasma. It was found that the relationship between the on-line dilution times and drug recovery efficiencies from plasma was explained in terms of the binding constant between the drug and albumin. The applicability of column-switching HPLC with an on-line dilution system and the effectiveness of the extraction procedure were confirmed by a simultaneous determination of the basic compound, ER-118585, and its metabolites in canine plasma.     

On-line desorption of dried blood spot: A novel approach for the direct LC/MS analysis of μ-whole blood samples

The aim of this work is to present a new concept, called on-line desorption of dried blood spots (on-line DBS), allowing the direct analysis of a dried blood spot coupled to liquid chromatography mass spectrometry device (LC/MS). The system is based on an inox cell which can receive a blood sample (10 μL) previously spotted on a filter paper. The cell is then integrated into LC/MS system where the analytes are desorbed out of the paper towards a column switching system ensuring the purification and separation of the compounds before their detection on a single quadrupole MS coupled to atmospheric pressure chemical ionisation (APCI) source. The described procedure implies that no pretreatment is necessary in spite the analysis is based on whole blood sample.     

Method for the quantitative analysis of cilostazol and its metabolites in human plasma using LC/MS/MS

An LC/MS/MS method for the simultaneous determination of cilostazol, a quinolinone derivative, and three active metabolites, OPC-13015, OPC-13213, and OPC-13217, in human plasma was developed and validated. Cilostazol, its metabolites, and the internal standard, OPC-3930 were extracted from human plasma by liquid-liquid partitioning followed by solid-phase extraction (SPE) on a Sep-Pak silica column. The eluent from the SPE column was then evaporated and the residue reconstituted in a mixture of methanol/ammonium acetate buffer (pH 6.5) (2:8 v/v). The analytes in the reconstituted solution were resolved using reversed-phase chromatography on a Supelcosil LC-18-DB HPLC column by an 17.5-min gradient elution. Cilostazol, its metabolites, and the internal standard were detected by tandem mass spectrometry with a Turbo Ionspray interface in the positive ion mode. The method was validated over a linear range of 5.0-1200.0 ng/ml for all the analytes. This method was demonstrated to be specific for the analytes of interest with no interference from endogenous substances in human plasma or from several potential concomitant medications. For cilostazol and its metabolites, the accuracy (relative recovery) of this method was between 92.1 and 106.4%, and the precision (%CV) was between 4.6 and 6.5%. During the validation, standard curve correlation coefficients equalled or exceeded 0.999 for cilostazol and its metabolites. These data demonstrate the reliability and precision of the method. The method was successfully cross-validated with an established HPLC method.     

Measurement of methylglyoxal in rat tissues by electrospray ionization mass spectrometry and liquid chromatography

INTRODUCTION: Increased methylglyoxal formation due to insulin resistance has been implicated in the development of essential hypertension and in type-2 diabetic complications in animal models. Methylglyoxal is a highly reactive aldehyde, which binds sulfhydryl and amino groups of membrane proteins forming conjugates, advanced glycation end products (AGEs), which alter membrane function, leading to increased blood pressure and oxidative stress. We have shown elevated aldehyde conjugates in tissues of hypertensive rats which may be formed primarily from methylglyoxal. Our objective was to develop a specific method to measure methylglyoxal in rat tissues. METHOD: This method involves preparation of plasma, blood and tissue homogenates, solid phase extraction of methylglyoxal, derivitization using o-phenylenediamine, further purification of derivatized products by solid phase extraction and quantification by electrospray ionization liquid chromatography mass spectrometry (ESI/LC/MS). RESULTS: Methylglyoxal was highest in aorta followed by heart, liver, kidney and blood in that order in Sprague-Dawley rats. Levels of methylglyoxal in plasma were about an order of magnitude lower than that in tissues, but above the concentration used for the lowest calibration standard. DISCUSSION: We have successfully developed an ESI/LC/MS method for quantification of methylglyoxal in rat tissues. The high selectivity of this method offers an advantage over other methods based on fluorescence. This method will allow the evaluation of methylglyoxal in essential hypertension and type-2 diabetes.     

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.     

Metabolic profiling of endocrine-disrupting compounds by on-line cytochrome p450 bioreaction coupled to on-line receptor affinity screening

We present a fully automated and hyphenated bioanalytical method for metabolic profiling of potentially harmful xenoestrogens. The system consists of an on-line cytochrome P450 bioreactor coupled to a reversed-phase, gradient high-performance liquid chromatograph. A C18 solid-phase extraction (SPE) unit is used as an interface between the P450 bioreactor and the HPLC column. The HPLC column is linked on-line to a high-resolution screening (HRS)-estrogen receptor alpha affinity detection (ERAD) assay. In effect, the P450 bioreactor produces metabolites that are subsequently trapped on-line by SPE and separated by HPLC. The separated metabolites are then screened on-line, at the moment of elution, for affinity toward estrogen receptor alpha (ERalpha) using the HRS-ERAD assay. The SPE method was optimized with methoxychlor (MXC) and its metabolites mono- and bis-OH-MXC. After optimization, the P450-bioreactor-SPE-HPLC system was made generally applicable to the biocatalysis and trapping of polar to highly apolar compounds. The precision of the P450-bioreactor-SPE-HPLC system is high (relative standard deviation相似文献   

Chromatography and computational chemical analysis for drug discovery

Analytical chemists have increasingly turned their attention to drug discovery and drug analysis and to solve fundamental questions of biological significance in physiology and genetics. New technologies have been developed, and a variety of instruments have been redesigned for biomedical applications. The development of high-performance liquid chromatography (HPLC) opened a new era in biorelated fields and allowed faster separations of fragile macromolecules. Capillary column gas chromatography (GC)/mass spectrometry (MS) have been used to achieve more powerful separation and to perform structural analysis of molecules, and laboratory automation including robotics has become a powerful trend in both analysis and synthesis. Liquid chromatography (LC)/MS is more suitable for biomedical applications than GC/MS because almost all biomolecules are heat sensitive. Furthermore, a combination of various mass spectrometers has been used even for proteins directly. Improving the sensitivity of nuclear magnetic resonance spectrometry (NMR) has permitted a direct connection with LC. Purification of biomolecules on-line by LC has been performed since the development of chip-electrophoresis, On the other hand, computational chemical analysis is a promising technique given the advancing the hardware and software for use in chemical fields. In this review, a combination of chromatography and computational chemistry for use in drug discovery studies is described. Fast LC analysis using a column switching technique was introduced for aromatic amino acid metabolites and guanidino compounds. Recent developments in related technologies are also included from review papers.