Comparison of sensitivity between gas chromatography–low-resolution mass spectrometry and gas chromatography–high-resolution mass spectrometry for determining metandienone metabolites in urine

In doping control laboratories the misuse of anabolic androgenic steroids is commonly investigated in urine by gas chromatography–low-resolution mass spectrometry with selected ion monitoring (GC–LRMS–SIM). By using high-resolution mass spectrometry (HRMS) detection sensitivity is improved due to reduction of biological background. In our study HRMS and LRMS methods were compared to each other. Two different sets were measured both with HRMS and LRMS. In the first set metandienone (I) metabolites 17α-methyl-5β-androstan-3α,17β-diol (II), 17-epimetandienone (III), 17β-methyl-5β-androst-1-ene-3α,17α-diol (IV) and 6β-hydroxymetandienone (V) were spiked in urine extract prepared by solid-phase extraction, hydrolysis with β-glucuronidase from Escherichia coli and liquid–liquid extraction. In the second set the metabolites were first spiked in blank urine samples of four male persons before pretreatment. Concentration range of the spiked metabolites was 0.1–10 ng/ml in both sets. With HRMS (resolution of 5000) detection limits were 2–10 times lower than with LRMS. However, also with the HRMS method the biological background hampered detection and compounds from matrix were coeluted with some metabolites. For this reason the S/N values of the metabolites spiked had to be first compared to S/N values of coeluted matrix compounds to get any idea of detection limits. At trace concentrations selective isolation procedures should be implemented in order to confirm a positive result. The results suggest that metandienone misuse can be detected by HRMS for a prolonged period after stopping the intake of metandienone.     

Measurement of dexfenfluramine metabolism in rat liver microsomes by gas chromatography–mass spectrometry

A specific and useful method was developed for the determination of dexfenfluramine metabolism by microsomal systems utilising GC–MS. The synthesis of two metabolites 1-(3-trifluoromethylphenyl)propan-2-ol (‘alcohol') and 1-(3-trifluoromethylphenyl)-1,2-propanediol (‘diol') via straightforward routes, were confirmed by MS and NMR spectra. The conditions for extraction from alkalinised microsomal mixtures of the metabolites nordexfenfluramine, 1-(3-trifluoromethylphenyl)propan-2-one (‘ketone'), alcohol and diol, their conversion to trifluoroacetate derivatives and analysis by GC–MS–SIM are described. Calibration curves were constructed between 48 and 9662 nM and fitted to quadratic equations (r²>0.999). The method precision was good over low (121 nM) medium (2415 nM) and above medium (9662 nM) concentrations for all metabolites; the within- and day-to-day coefficients of variation ranged between 2.5–12.4% and 6.7–17.5%, respectively. The accuracy, measured as bias, was very good both within- and day-to-day (range: −0.4–12.6%, 0.8–18.9%). For most metabolites, the C.V. for the assay and bias increased at 121 nM. Dexfenfluramine metabolism by rat liver microsomes was investigated using the assay method and showed a concentration dependent increase in nordexfenfluramine and ketone metabolites over the substrate range of 5–200 μM.     

Identification of quercetin glucuronides in human plasma by high-performance liquid chromatography–tandem mass spectrometry

After intake of food or herbal medicinal products containing quercetin glycosides, the systemic availability of the genuine glycoside, as well as the systemic occurrence of the aglycone or conjugates of this polyphenol has been a matter of dispute. Consequently, we designed this study to develop a reliable method for determination of quercetin and its metabolites. Following consumption of fried onions five different glucuronides of quercetin could be identified in human plasma samples by means of HPLC–UV–MS/MS. Selective determination of the target compounds was achieved by simultaneous UV (254 nm) and MS/MS detection with selected reaction monitoring experiments using positive mode electrospray ionisation. In contrast, neither the free flavonol nor the genuine glycoside could be detected in plasma. Identification of the quercetin glucuronides detected in vivo was confirmed by comparison with authentic reference compounds synthesised enzymatically using glucuronyl transferase from rabbit liver.     

Analysis of benzphetamine and its metabolites in rat urine by liquid chromatography–electrospray ionization mass spectrometry

An analytical method to identify and determine benzphetamine (BMA) and its five metabolites in urine was developed by liquid chromatography–electrospray ionization mass spectrometry (LC–ESI–MS) using the solid-phase extraction column Bond Elut SCX. Deuterium-labeled compounds, used as internal standards, were separated chromatographically from each corresponding unlabeled compound in the alkaline mobile phase with an alkaline-resistant ODS column. This method was applied to the identification and determination of BMA and its metabolites in rat urine collected after oral administration of BMA. Under the selected ion monitoring mode, the limit of quantitation (signal-to-noise ratio 10) for BMA, N-benzylamphetamine (BAM), p-hydroxybenzphetamine (p-HBMA), p-hydroxy-N-benzylamphetamine (p-HBAM), methamphetamine (MA) and amphetamine (AM) was 700 pg, 300 pg, 500 pg, 1.4 ng, 6 ng and 10 ng in 1 ml of urine, respectively. This analytical method for p-HBMA, structurally closer to the unchanged drug of all the metabolites, was very sensitive, making this a viable metabolite for discriminating the ingestion of BMA longer than the parent drug or other metabolites in rat.     

Liquid chromatography–electrospray tandem mass spectrometry of acidic monoamine metabolites

A new method based on liquid chromatography–tandem mass spectrometry has been developed for the determination of monoamine metabolites, i.e., homovanillic acid (HVA), vanilmandelic acid (VMA), 3,4-dihydroxyphenylacetic acid (DOPAC) and 5-hydroxyindoleacetic acid (5-HIAA) in human urine. Analytes were separated on a C₁₆ amide (5 cm, 5 μm) column and ionized by negative ion electrospray. Operating in the selected-reaction monitoring mode, linearity was established over three-orders of magnitude and limits of detection were in the range 30–70 μg/l. Precision calculated as RSD was within 0.8–5.2% for all intra- and inter-day determinations. The method was applied to the quantitative analysis of monoamine metabolites in 700 urine samples from occupationally (adults) and environmentally (both children and adults) exposed people living in areas with different soil contamination from lead. The urinary excretion of monoamine metabolites was significantly higher (P<0.001) in the subgroup of children living in polluted areas as compared to the control group (HVA, 6.03 vs. 4.57 mg/g creatinine; VMA, 5.33 vs. 4.37 mg/g creatinine; 5-HIAA 3.24 vs. 2.45 mg/g creatinine). In adults belonging to both groups of subjects occupationally and environmentally exposed, no differences were detected in the urinary concentration of monoamine metabolites. However, adults showed lower values of HVA (2.57 mg/g creatinine), VMA (2.17 mg/g creatinine) and 5-HIAA (2.09 mg/g creatinine) as compared to children groups.     

Identification and confirmation of 3-hydroxy metabolite of ketoprofen in camels by gas chromatography–mass spectrometry and nuclear magnetic resonance spectroscopy

The metabolites of ketoprofen were investigated in five camels following intravenous administration of a dose of 2.0 mg/kg body weight. Two metabolites were identified. The first one was purified with thin-layer chromatography. It was identified by gas chromatography–mass spectrometry (GC–MS) in comparison with authenticated reference standard and was found to be hydroxyketoprofen due to reduction of the ketone group of ketoprofen. The second metabolite was purified by high-performance liquid chromatography. It was identified with GC–MS and nuclear magnetic resonance spectroscopy as 3-hydroxybenzolketoprofen resulting from oxidation of the aromatic ring.     

Analysis of hydroxylated and N-dealkylated metabolites of terfenadine in microsomal incubates by liquid chromatography–mass spectrometry

This report describes an assay for the H₁-receptor antagonist, terfenadine, and its two primary metabolites, terfenadine alcohol (TOH) and azacyclonol (AZ), using positive-ion, electrospray ionization–liquid chromatography–mass spectrometry. The assay was developed in support of kinetic studies of terfenadine oxidative metabolism in human liver and intestinal microsomes, which required quantification of incubate metabolites at low nanomolar concentrations. Terfenadine metabolites were extracted from basified microsomal incubates into methylene chloride. Reconstituted extracts were subject to liquid chromatographic separation on a cyano-reverse phase column. The [M+H]⁺ ions of terfenadine, terfenadine metabolites, and internal standard were monitored in the effluent by quadrupole mass spectrometry. The assay demonstrated linearity over an incubate concentration range of 5–250 and 12.5–1250 ng/ml for the metabolites and the parent drug, respectively. The respective limits of detection and quantitation for all three analytes were 1.5 and 5 ng/ml of microsomal incubate. Replicate analysis of quality control samples exhibited intra-day coefficients of variation ranging from 3.3% to 7.8% for the three analytes. The corresponding inter-day coefficients of variation ranged from 4.2% to 8.6%. The reproducibility and sensitivity of the assay, combined with the selectivity of mass spectrometric detection, should allow an accurate kinetic characterization of terfenadine oxidation mediated by the high affinity CYP3A enzymes in human liver and intestinal microsomes.     

Simultaneous determination of dimethylamphetamine and its metabolites in rat hair by gas chromatography–mass spectrometry

In order to study the disposition of dimethylamphetamine (DMAP) and its metabolites, DMAP N-oxide, methamphetamine (MA) and amphetamine (AP), from plasma to hair in rats, a simultaneous determination method for these compounds in biological samples using gas chromatography–mass spectrometry with selected ion monitoring (GC–MS-SIM) was developed. As DMAP N-oxide partially degrades to DMAP and MA during GC–MS analysis, it was necessary to avoid conditions which co-extract the N-oxide in the sample preparation so as to assure no contribution of artifactual products from DMAP N-oxide in the detection of the other compounds. For confirmation of the satisfactory separation of DMAP N-oxide from the others, the internal standards used for quantification were labeled with different numbers of deuterium atoms. Determination of unchanged DMAP was performed without any derivatization, that of DMAP N-oxide was carried out after conversion into trifluoroacetyl-MA by reaction with trifluoroacetic anhydride, and MA and AP were quantified after trifluoroacetyl-derivatization.After intraperitoneal administration of DMAP HCl to pigmented hairy rats (5 mg kg⁻¹ day⁻¹, 10 days, n=3), concentrations of DMAP and its metabolites in urine, plasma and hair were measured by GC–MS-SIM. The area under the concentration versus time curves (AUCs) of DMAP, DMAP N-oxide, MA and AP in the plasma were 397.2±97.5, 279.7±68.3, 18.4±1.2 and 15.9±2.2 μg min ml⁻¹, while their concentrations in the hair newly grown for 4 weeks after administration were 4.82±0.67. 0.45±0.09, 3.25±0.36 and 0.89±0.05 ng mg⁻¹, respectively. This fact suggested that the incorporation tendency of DMAP N-oxide from plasma into hair was distinctly low in comparison with the other compounds.     

Separation and identification of corticosterone metabolites by liquid chromatography–electrospray ionization mass spectrometry

High-performance liquid chromatography coupled to atmospheric pressure ionization–electrospray ionization mass spectrometry (API–ESI–MS) was investigated for the analysis of corticosterone metabolites; their characterization was obtained by combining the separation on Zorbax Eclipse XDB C₁₈ column (eluted with a methanol–water–acetic acid gradient) with identification using positive ion mode API–ESI–MS and selected ion analysis. The applicability of this method was verified by monitoring the activity of steroid converting enzymes (20β-hydroxysteroid dehydrogenase and 11β-hydroxysteroid dehydrogenase) in avian intestines.     

Simultaneous determination of ivabradine and its metabolites in human plasma by liquid chromatography–tandem mass spectrometry

A rapid, selective, sensitive and reproducible liquid chromatographic method with tandem mass spectrometric detection has been developed and validated for the analysis of a new specific bradycardic agent, ivabradine (S 16257) and six potentially active metabolites in human plasma. Isolation of these compounds and of the internal standard was performed by an automated solid-phase extraction system using Oasis cartridges. Separation and detection of ivabradine and its metabolites were achieved using a C₁₈ column and a MS–MS detector with a positive electrospray ionization source. Ivabradine and its metabolites gave a linear response ranging from 0.1 or 0.2 to 20 ng/ml and the limits of quantitation ranged from 0.1 to 0.2 ng/ml using a 0.5 ml plasma sample size. A complete validation demonstrated the method to be accurate, precise and specific for the simultaneous quantification of ivabradine and its metabolites in human plasma. The method was subsequently applied to the quantitative determination of ivabradine and its metabolites in human plasma samples from healthy volunteers participating in a clinical study to provide pharmacokinetic data.     

Simultaneous determination of anabolic and catabolic steroid hormones in meat by gas chromatography–mass spectrometry

A rapid and economical method for the determination in meat of androgens, estrogens, progestogens and corticoids, including some precursors and metabolites, has been developed. The extracted steroids are separated in a polar, a neutral, and a phenolic fraction by C₈-SPE followed by a liquid–liquid extraction of the phenolates. Each fraction is separately purified by normal-phase SPE. The different steroid fractions can be analysed either together to obtain a comprehensive hormone pattern in one step or separately to enhance detection selectivity and sensitivity. Using a universally applicable silylation of the hydroxyl and keto groups, detection limits of 0.02–0.1 μg/kg are reached by GC–MS (EI) in the selected ion monitoring mode.     

Simultaneous determination of four anthracyclines and three metabolites in human serum by liquid chromatography–electrospray mass spectrometry

A sensitive and very specific method, using liquid chromatography–electrospray mass spectrometry (LC–ES-MS), was developed for the determination of epirubicin, doxorubicin, daunorubicin, idarubicin and the respective active metabolites of the last three, namely doxorubicinol, daunorubicinol and idarubicinol in human serum, using aclarubicin as internal standard. Once thawed, 0.5-ml serum samples underwent an automated solid-phase extraction, using C₁₈ Bond Elut cartridges (Varian) and a Zymark Rapid-Trace robot. After elution of the compounds with chloroform–2-propanol (4:1, v/v) and evaporation, the residue was reconstituted with a mixture of 5 mM ammonium formate buffer (pH 4.5)–acetonitrile (60:40, v/v). The chromatographic separation was performed using a Symmetry C₁₈, 3.5 μm (150×1 mm I.D.) reversed-phase column, and a mixture of 5 mM ammonium formate buffer (pH 3)–acetonitrile (70:30, v/v) as mobile phase, delivered at 50 μl/min. The compounds were detected in the selected ion monitoring mode using, as quantitation ions, m/z 291 for idarubicin and idarubicinol, m/z 321 for daunorubicin and daunorubicinol, m/z 361 for epirubicin and doxorubicin, m/z 363 for doxorubicinol and m/z 812 for aclarubicin (I.S.). Extraction recovery was between 71 and 105% depending on compounds and concentration. The limit of detection was 0.5 ng/ml for daunorubicin and idarubicinol, 1 ng/ml for doxorubicin, epirubicin and idarubicin, 2 ng/ml for daunorubicinol and 2.5 ng/ml for doxorubicinol. The limit of quantitation (LOQ) was 2.5 ng/ml for doxorubicin, epirubicin and daunorubicinol, and 5 ng/ml for daunorubicin, idarubicin, doxorubicinol and idarubicinol. Linearity was verified from these LOQs up to 2000 ng/ml for the parent drugs (r≥0.992) and 200 ng/ml for the active metabolites (r≥0.985). Above LOQ, the within-day and between-day precision relative standard deviation values were all less than 15%. This assay was applied successfully to the analysis of human serum samples collected in patients administered doxorubicin or daunorubicin intravenously. This method is rapid, reliable, allows an easy sample preparation owing to the automated extraction and a high selectivity owing to MS detection.     

Stereoselective measurement of E- and Z-doxepin and its N-desmethyl and hydroxylated metabolites by gas chromatography–mass spectrometry

A stereoselective method of analysis of the antidepressant drug doxepin (DOX, an 85:15% mixture of E–Z stereoisomers), its principal metabolites E- and Z-N-desmethyldoxepin (desDOX) and ring-hydroxylated metabolites in microsomal incubation mixtures is described. DOX and its metabolites were extracted from alkalinised incubation mixtures by either: 9:1 hexane–propan-2-ol (method 1) or 1:1 hexane–dichloromethane (method 2), derivatised with trifluoroacetic anhydride and analysed by GC–MS with selected ion monitoring. Both methods were suitable for the analysis of individual desDOX isomers as indicated by correlation coefficients of ≥0.999 for calibration curves constructed between 50 and 2500 nM, and good within-day precision at 125 nM (C.V. ≤14%) and 1000 nM (C.V. ≤8%). Method 1, however, was unsuitable for the analysis of ring-hydroxylated metabolites of DOX, whereas the hydroxylated metabolites of E-DOX and E-desDOX (generated in situ) were extracted by method 2 with a C.V. of ca. 13%. This is the first assay method that permits the simultaneous measurement of desDOX and hydroxylated metabolites of DOX in microsomal mixtures.     

Monitoring of olanzapine in serum by liquid chromatography–atmospheric pressure chemical ionization mass spectrometry

A selective assay of olanzapine with liquid chromatography atmospheric pressure chemical ionization (LC–APCI–MS, positive ions) is described. The drug and internal standard (ethyl derivative of olanzapine) were isolated from serum using a solid-phase extraction procedure (C₁₈ cartridges). The separation was performed on ODS column in acetonitrile–50 mM ammonium formate buffer, pH 3.0 (25:75). After analysis of mass spectra taken in full scan mode, a selected-ion monitoring detection (SIM) was applied with the following ions: m/z 313 and 256 for olanzapine and m/z 327 and 270 for the internal standard for quantitation. The limit of quantitation was 1 μg/l, the absolute recovery was above 80% at concentration level of 10 to 100 μg/l. The method tested linear in the range from 1 to 1000 μg/l and was applied for therapeutic monitoring of olanzapine in the serum of patients receiving (Zyprexa™) and in one case of olanzapine overdose. Olanzapine in frozen serum samples and in frozen extracts was stable over at least four weeks. The examinations of urine extracts from patients receiving olanzapine revealed peaks of postulated metabolites (glucuronide and N-desmethylolanzapine).     

Metabolic profiling of valproic acid by cDNA-expressed human cytochrome P450 enzymes using negative-ion chemical ionization gas chromatography–mass spectrometry

A sensitive negative ion chemical ionization (NCI) gas chromatographic–mass spectrometric (GC–MS) method was modified for the quantitation of valproic acid (VPA) metabolites generated from in vitro cDNA-expressed human microsomal cytochrome P450 incubations. The use of the inherent soft ionization nature of electron-capture NCI to achieve high sensitivity enabled us to conduct kinetic studies using small amounts of recombinant human P450 enzymes. The assay is based on the selective ion monitoring of the intense [M−181] fragments of pentafluorobenzyl (PFB) esters in the NCI mode, and has the following features: (1) a micro-extraction procedure to isolate VPA metabolites from small incubation volumes (100 μl); (2) a second step derivatization with tert.-butyldimethylsilylating reagents to enhance sensitivity for hydroxylated metabolites; (3) a short run-time (<30 min) while maintaining full separation of 15 VPA metabolites by using a narrow-bore non-polar DB-1 column plus a new temperature gradient; and (4) good reproducibility and accuracy (intra- and inter-assay RSDs <15%, bias <15%) by using seven deuterated derivatives of analytes as internal standards. The derivatives of mono- and diunsaturated metabolites, like the parent drug, produced abundant [M−181]⁻ ions while the hydroxylated metabolites gave an ion at m/z of 273, corresponding to the [M−181]⁻ ion of the tert.-butyldimethylsilyl ethers. In conclusion, the GC–NCI-MS analysis of valproate metabolites provided us with a high resolution and sensitivity necessary to conduct metabolic and kinetic studies of valproic acid in small volume samples typical of the in vitro cDNA-expressed micro-incubation enzymatic systems.     

Automated in-tube solid-phase microextraction–liquid chromatography–electrospray ionization mass spectrometry for the determination of ranitidine

The technique of automated in-tube solid-phase microextraction (SPME) coupled with liquid chromatography–electrospray ionization mass spectrometry (LC–ESI-MS) was evaluated for the determination of ranitidine. In-tube SPME is an extraction technique for organic compounds in aqueous samples, in which analytes are extracted from the sample directly into an open tubular capillary column by repeated aspirate/dispense steps. In order to optimize the extraction of ranitidine, several in-tube SPME parameters such as capillary column stationary phase, extraction pH and number and volume of aspirate/dispense steps were investigated. The optimum extraction conditions for ranitidine from aqueous samples were 10 aspirate/dispense steps of 30 μl of sample in 25 mM Tris–HCl (pH 8.5) with an Omegawax 250 capillary column (60 cm×0.25 mm I.D., 0.25 μm film thickness). The ranitidine extracted on the capillary column was easily desorbed with methanol, and then transported to the Supelcosil LC-CN column with the mobile phase methanol–2-propanol–5 M ammonium acetate (50:50:1). The ranitidine eluted from the column was determined by ESI-MS in selected ion monitoring mode. In-tube SPME followed by LC–ESI-MS was performed automatically using the HP 1100 autosampler. Each analysis required 16 min, and carryover of ranitidine in this system was below 1%. The calibration curve of ranitidine in the range of 5–1000 ng/ml was linear with a correlation coefficient of 0.9997 (n=24), and a detection limit at a signal-to-noise ratio of three was ca. 1.4 ng/ml. The within-day and between-day variations in ranitidine analysis were 2.5 and 6.2% (n=5), respectively. This method was also applied for the analyses of tablet and urine samples.     

Determination of lorazepam in plasma and urine as trimethylsilyl derivative using gas chromatography–tandem mass spectrometry

A procedure based on gas chromatography–tandem mass spectrometry for identification and quantitation of lorazepam in plasma and urine is presented. The analyte was extracted from biological fluids under alkaline conditions using solid-phase extraction with an Extrelut-1 column in the presence of oxazepam-d₅ as the internal standard. Both compounds were then converted to their trimethylsilyl derivatives and the reaction products were identified and quantitated by gas chromatography–tandem mass spectrometry using the product ions of the two compounds (m/z 341, 306 and 267 for lorazepam derivative and m/z 346, 309 and 271 for oxazepam-d₅ derivative) formed from the parent ions by collision-induced dissociation in the ion trap spectrometer. Limit of quantitation was 0.1 ng/ml. This method was validated for urine and plasma samples of individuals in treatment with the drug.     

Determination of ephedrines in urine by gas chromatography–mass spectrometry

A selective gas–liquid chromatographic method with mass spectrometry (GC–MS) for the simultaneous confirmation and quantification of ephedrine, pseudo-ephedrine, nor-ephedrine, nor-pseudoephedrine, which are pairs of diastereoisomeric sympathomimetic amines, and methyl-ephedrine was developed for doping control analysis in urine samples. O-Trimethylsilylated and N-mono-trifluoroacetylated derivatives of ephedrines — one derivative was formed for each ephedrine — were prepared and analyzed by GC–MS, after alkaline extraction of urine and evaporation of the organic phase, using d₃-ephedrine as internal standard. Calibration curves, with r²>0.98, ranged from 3.0 to 50 μg/ml depending on the analyte. Validation data (specificity, % RSD, accuracy, and recovery) are also presented.     

Identification and quantification of five macrolide antibiotics in several tissues, eggs and milk by liquid chromatography–electrospray tandem mass spectrometry

We present an electrospray high-performance liquid chromatographic tandem mass spectrometric (HPLC–MS–MS) method capable of determining in several tissues (muscle, kidney, liver), eggs and milk the following five macrolides: tylosin, tilmicosin, spiramycin, josamycin, erythromycin. Roxithromycin was used as an internal standard. The method uses extraction in a Tris buffer at pH 10.5, followed by protein precipitation with sodium tungstate and clean-up on an Oasis solid-phase extraction column. The HPLC separation was performed on a Purospher C₁₈ column (125×3 mm I.D.) protected by a guard column, with a gradient of aqueous 0.1 M ammonium acetate–acetonitrile as the mobile phase at a flow-rate of 0.7 ml min⁻¹. Protonated molecules served as precursor ions for electrospray ionisation in the positive ion mode and four product ions were chosen for each analyte for multiple reaction monitoring (MRM). A validation study was conducted to confirm the five macrolides by MRM HPLC–MS–MS analysis of a negative control and fortified samples. All of the samples analysed were confirmed with four ions. The ion ratio reproducibility limit ranged from 2.4 to 15%. All compounds could be detected and quantified at half-maximum residue limits (MRLs). The method is specific, quantitative and reproducible enough to conform to European Union recommendations within the concentration range 0.5 MRL–2 MRL (accuracy: 80 to 110%, relative standard deviation: 2 to 13%). This whole method allows extraction and analysis of up to 50 samples per day.     

High-performance liquid chromatography–tandem electrospray mass spectrometry for the determination of lidocaine and its metabolites in human plasma and urine

A sensitive, selective and accurate high-performance liquid chromatographic–tandem mass spectrometric assay was developed and validated for the determination of lidocaine and its metabolites 2,6-dimethylaniline (2,6-xylidine), monoethylglycinexylidide and glycinexylidide in human plasma and urine. A simple sample preparation technique was used for plasma samples. The plasma samples were ultrafiltered after acidification with phosphoric acid and the ultrafiltrate was directly injected into the LC system. For urine samples, solid-phase extraction discs (C₁₈) were used as sample preparation. The limit of quantification (LOQ) was improved by at least 10 times compared to the methods described in the literature. The LOQ was in the range 1.6–5 nmol/l for the studied compounds in plasma samples.