Identification of phenothiazine antihistamines and their metabolites in urine

Identification of the phenothiazine antihistamines alimemazine, dimetotiazine, isothipendyl, mequitazine, oxomemazine, promethazine, thiethylperazine, triflupromazine and their metabolites in urine is described. After acid hydrolysis of the conjugates, extraction and acetylation the urine samples were analysed by computerized gas chromatography-mass spectrometry. Using ion chromatography with the selective ions m/z 58, 72, 100, 114, 124, 128, 141, and 199 the possible presence of phenothiazine antihistamines and/or their metabolites was indicated. The identity of positive signals in the reconstructed ion chromatograms was confirmed by a visual or computerized comparison of the stored full mass spectra with the reference spectra. The ion chromatograms, reference mass spectra and gas chromatographic retention indices (OV-101) are documented. The procedure presented is integrated in a general screening procedure (general unknown analysis) for several groups of drugs.Some of these results were reported at the Symposium Klinisch-Toxikologische Analytik of the Austrian and German Societies of Clinical Chemistry, Salzburg, Austria, September 14–16 1987 (Maurer et al. 1987).     

Detection of anticonvulsants and their metabolites in urine within a “general unknown” analysis procedure using computerized gas chromatography-mass spectrometry

Detection of the anticonvulsants carbamazepine, clonazepam, diazepam, ethosuximide, mephenytoin, mesuximide, methylphenobarbital, phenobarbital, phenytoin, primidone, propylhexedrine, sultiame, trimethadion and their metabolites in urine is described. The method presented is integrated in a general screening procedure (general unknown analysis) for several groups of drugs, detecting several hundred drugs and over 1000 metabolites. It includes cleavage of conjugates by acid hydrolysis, isolation by liquid-liquid extraction, derivatization by acetylation, separation by capillary gas chromatography and identification by computerized mass spectrometry. Using mass chromatography with the selective ions m/z 58, 104, 113, 117, 165, 193, 204 and 246, the possible presence of anticonvulsants and/or their metabolites was indicated. The identity of positive signals in the reconstructed mass chromatograms was confirmed by a visual or computerized comparison of the stored full mass spectra with the reference spectra. The sample preparation, mass chromatograms, reference mass spectra and gas chromatographic retention indices are documented.Part of these results was reported at the 1st German-German Symposium of theGesellschaft für Toxikologische und Forensische Chemie (GTFCh) and theArbeitsgemeinschaft Toxikologische Chemie der DDR, Leipzig (GDR), July 3–5, 1990 (Maurer 1990d).     

Screening procedure for detection of non-steroidal anti-inflammatory drugs and their metabolites in urine as part of a systematic toxicological analysis procedure for acidic drugs and poisons by gas chromatography-mass spectrometry after extractive methylation

Non-steroidal anti-inflammatory drugs (NSAIDs) are widely used as analgesic and anti-rheumatic drugs, and they are often misused. A gas chromatographic-mass spectrometric (GC-MS) screening procedure was developed for their detection in urine as part of a systematic toxicological analysis procedure for acidic drugs and poisons after extractive methylation. The compounds were separated by capillary GC and identified by computerized MS in the full-scan mode. Using mass chromatography with the ions m/z 119, 135, 139, 152, 165, 229, 244, 266, 272, and 326, the possible presence of NSAIDs and 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 recorded during this study. This method allowed the detection of therapeutic concentrations of acemetacin, acetaminophen (paracetamol), acetylsalicylic acid, diclofenac, diflunisal, etodolac, fenbufen, fenoprofen, flufenamic acid, flurbiprofen, ibuprofen, indometacin, kebuzone, ketoprofen, lonazolac, meclofenamic acid, mefenamic acid, mofebutazone, naproxen, niflumic acid, phenylbutazone, suxibuzone, tiaprofenic acid, tolfenamic acid, and tolmetin in urine samples. The overall recoveries of the different NSAIDs ranged between 50 and 80% with coefficients of variation of less than 15% (n = 5), and the limits of detection of the different NSAIDs were between 10 and 50 ng/mL (S/N = 3) in the full-scan mode. Extractive methylation has proved to be a versatile method for STA of various acidic drugs, poisons, and their metabolites in urine. It has also successfully been used for plasma analysis.     

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.     

Screening procedure for detection of dihydropyridine calcium channel blocker metabolites in urine as part of a systematic toxicological analysis procedure for acidic compounds by gas chromatography-mass spectrometry after extractive methylation

A gas chromatographic-mass spectrometric (GC-MS) screening procedure was developed for the detection of dihydropyridine calcium channel blocker ("calcium antagonist") metabolites in urine as part of a systematic toxicological analysis procedure for acidic drugs and poisons after 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. Using mass chromatography with the ions m/z 139, 284, 297, 298, 310, 312, 313, 318, 324, and 332, the possible presence of calcium channel blocker 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 recorded during this study. This method allowed the detection of therapeutic concentrations of amlodipine, felodipine, isradipine, nifedipine, nilvadipine, nimodipine, nisoldipine, and nitrendipine in human urine samples. Because urine samples from patients treated with nicardipine were not available, the detection of nicardipine in rat urine was studied. The overall recovery ranged between 67 and 77% with a coefficient of variation of less than 10%, and the limit of detection was at least 10 ng/mL (signal-to-noise ratio = 3) in the full-scan mode.     

Identification of phase I and phase II metabolites of Guanfu base A hydrochloride in human urine.

Guanfu base A is a novel arrhythmic drug candidate isolated from the tuber of a traditional Chinese herb. Phase I and Phase II metabolites of Guanfu base A (GFA) Hydrochloride were studied in human urine by means of liquid chromatography mass spectrometry (LC/MSD) and tandem mass spectrometry (MS/MS). For phase I metabolites, Guanfu base I (GFI) was separated by HPLC and identified by comparison with authentic reference for their retention times, molecular ion peaks, fragment ions, and UV spectra. GFA oxide was also indicated to exist in human urine. For phase II metabolites, after human urine was treated either with glucuronidase or sulfatase, GFA occured in the chromatograms. It was suggested that there were GFA glucuronide and GFA sulfate in human urine. Further more, positive molecular ions, m/z 606 and m/z 510, of the two conjugates were detected in human urine by LC/MSD. In addition, characteristic ion of m/z 606 was identified as the precursor ion of m/z 177 [Glucuronic acid+H]+ by using MS/MS. Characteristic ion of m/z 430 [GFA+H]+ was also identified as a product ion of m/z 606 [GFA glucuronide+H]+. It was concluded that there were GFI. GFA oxide, GFA glucuronide and GFA sulfate in human urine.     

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

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

Screening for detection of new antidepressants, neuroleptics, hypnotics, and their metabolites in urine by GC-MS developed using rat liver microsomes

A gas chromatography-mass spectrometry (GC-MS) procedure for the detection of new antidepressants, neuroleptics, hypnotics, and their metabolites in urine is presented. The metabolites were first identified in rat liver microsome preparations by GC-MS after isolation and derivatization. Using these GC-MS data, a GC-MS screening was developed for urine as part of the authors' modified systematic toxicologic analysis procedure. After acid hydrolysis of a 2.5-mL aliquot of urine, a further aliquot was added. The mixture was then liquid-liquid extracted at pH 8-9, acetylated, and GC separated. Using mass chromatography with the ions m/z 58, 100, 120, 182, 195, 235, 261, 276, 284. and 293, the presence of new antidepressants, neuroleptics, hypnotics, and their metabolites could be indicated. Positive peaks could be identified by library search using the reference mass spectra recorded during the microsome studies. The intake of therapeutic doses of the following drugs could be monitored in urine: dosulepin, mirtazapine, moclobemide, nefazodone, trazodone, venlafaxine, and zolpidem. Olanzapine and zotepine were detectable in human urine only under steady-state conditions, and low-dose zopiclone was detectable only in overdose. The detection limit was less than 100 ng/mL (signal-to-noise ratio = 3) for the parent drugs.     

Target urinary analytes for the gas chromatographic- mass spectrometric detection of procyclidine and benzhexol in drug abuse cases

The two antiparkinsonian drugs procyclidine and benzhexol are presently finding considerable favor for their euphoric hallucinogenic effects among drug abusers in some countries. In anticipation of their possible scheduling in national drug laws, gas chromatography-mass spectrometry (GC-MS) methods for their detection in urine will be required. However, because of uncertainty of the metabolic fate of the two drugs in humans, the urinary target analytes for GC-MS detection were not well defined. The problem was addressed in the present study in which it was found that mono-hydroxy metabolites, where hydroxylation took place at the cyclohexane ring in both drugs, could be endorsed as the major target analytes. The metabolites could only be detected as the mono- and/or di-trimethylsilyl (TMS) derivatives. The predominance of either derivative depended on the temperature and time of heating with the derivatizing reagent. Because of the basic properties of the hydroxy metabolites, analytic method optimization was needed for their detection in urine included extraction under basic pH conditions. Urine hydrolysis with β-glucuronidase did not have an effect on the recovery of the metabolites, but was usually performed in search for other drugs. Because of the relative abundance of ions, the electron impact mass spectra of the mono-TMS derivatives and the chemical ionization (CI) mass spectra of the mono- and di-TMS derivatives of the hydroxy metabolites of both drugs were found to be more structurally informative. The CI mass spectra of the di- TMS derivatives have the additive advantage of being potentially useful for quantitative analysis.     

Characterization of the urinary metabolites of merbarone in cancer patients.

Phase-I clinical trials in cancer patients of merbarone (MB), a thiobarbituric acid derivative with curative activity against the murine leukemias, were recently completed. Reverse-phase HPLC of urine samples from treated patients showed the presence of two major metabolites, identified as 4'-hydroxymerbarone and 2-oxo-desthiomerbarone, eluting prior to the parent drug. In addition, a third polar metabolite, largely masked in liquid chromatograms by poorly retained endogenous urinary constituents, was detected and characterized as 4'-hydroxy-2-oxo-desthiomerbarone. Several minor metabolites, one of greater polarity and several less polar than MB, remain to be identified. Initial structural elucidations were ascertained from methane chemical ionization mass spectroscopy upon isolating MB and its metabolites from patient urine by solid-phase extraction. Quasi-molecular ion patterns at masses consistent with the drug and three oxidative metabolites were apparent. Molecular ion shifts that occurred after treating the urine isolate with acetic anhydride under Schotten-Baumann conditions indicated that two of the metabolites were phenolic derivatives. A high-resolution 1H-NMR spectrum (500 MHz) of the urine isolate exhibited a well-resolved aromatic region containing peaks consistent with those determined for synthetically prepared reference standards of each metabolite. This evidence was further substantiated by obtaining UV spectra during HPLC with a diode array detector. Chromatographic peak identification was established from the correspondence of retention times and UV spectra with the synthetic compounds. These studies demonstrate that MB is subject to extensive oxidative metabolism in humans. However, metabolite plasma levels are exceedingly low throughout the course of a 5-day continuous infusion, suggesting that metabolite excretion rates may exceed their rates of formation. Furthermore, since the relative concentrations of the major metabolites in urine are appreciably higher than that of MB, metabolite renal clearance is apparently greater than that of the drug.     

Screening procedure for detection of antidepressants of the selective serotonin reuptake inhibitor type and their metabolites in urine as part of a modified systematic toxicological analysis procedure using gas chromatography-mass spectrometry

A gas chromatographic-mass spectrometric (GC-MS) screening procedure was developed for detection of selective serotonin reuptake inhibitors (SSRIs) in urine as part of a systematic toxicological analysis procedure. After acid hydrolysis of one aliquot of urine, another aliquot was added. The mixture was then liquid-liquid extracted at pH 8-9, acetylated, and GC separated. Using mass chromatography with the ions m/z 58, 72, 86, 173, 176, 234, 238, and 290, the possible presence of SSRIs 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 recorded during this study. The overall recoveries of citalopram, sertraline, and paroxetine ranged between 60 and 80%, and those of fluoxetine and fluvoxamine, which were destroyed during acid hydrolysis, were between 40 and 45%. The coefficients of variation were less than 10-20%, and the limit of detection was at least 100 ng/mL (signal-to-noise ratio = 3). This method allowed the detection of therapeutic concentrations of citalopram, fluoxetine, fluvoxamine, paroxetine, and sertraline in human urine samples.     

基于UPLC/QTOF-MS的代谢组学研究辛伐他汀对不同性别小鼠尿液中代谢物的影响

目的:基于代谢组学技术研究辛伐他汀对小鼠尿液中脂类代谢物的影响.方法:收集给予药物辛伐他汀后不同天数的小鼠尿液样品,采用超高效液相色谱-高分辨飞行时间质谱(UPLC/Q-TOF MS )联用,Acquity BEH C18色谱柱,流动相为水-乙腈,梯度洗脱,电喷雾离子源,负离子检测模式,通过数据采集进行代谢轮廓分析.采...     

A novel metabolic pathway of morphine: formation of morphine glucosides in cancer patients

AIMS: To characterize directly the conjugated metabolites of morphine in urine samples of cancer patients. METHODS: Urine samples from the patients were treated by solid-phase extraction method and chromatographed using three high-performance liquid chromatography systems. Conjugated metabolites were directly detected with liquid chromatographic/ion trap mass spectrometric (LC/MSn) technique by selected ion monitoring, full scan MS/MS and MS3 modes. RESULTS: Six conjugated metabolites including two new metabolites M5 and M6 were found. Morphine-3-glucuronide (M-3-G) and morphine-6-glucuronide (M-6-G) were identified by comparing their l.c. retention times and multistage mass spectra with those of the reference substances. Two novel metabolites, morphine-3-glucoside and morphine-6-glucoside, as well as normorphine glucuronides were identified by comparing their mass fragment patterns and l.c. retention times with those of M-3-G and M-6-G. Hydrolysis of urine samples with beta-glucosidase and beta-glucuronidase provided further evidence of the metabolites M5 and M6 as morphine glucosides. The excretion amounts of morphine conjugates in urines were in the order of morphine glucuronides, morphine glucosides and normorphine glucuronides. CONCLUSIONS: In the present study, the applications of l.c. separation and multistage mass spectra have permitted the direct identification of conjugated metabolites of morphine. To our knowledge, this is the first report about O-linked glucosides of morphine at 3-aromatic and 6-aliphatic hydroxyl groups.     

The biotransformation of fenetylline

After oral administration of 3,7-dihydro-1,3-dimethyl-7-2 [(1-methyl-2-phenylethyl)-amino-ethyl]-1H-purine-2,6-dione (fenetylline, Captagon), 7 new metabolites could be detected in urine besides 4 known substances. The metabolites were identified by gas chromatography (GC) and by comparison of the mass spectra (MS) of metabolites with those of authentic reference compounds using a combined GC/MS method.     

大鼠尿中人参皂苷Rd及其代谢物的LC-MS研究

目的探讨人参皂苷Rd在大鼠体内的代谢产物及转化途径。方法选择SD大鼠6只，单剂量口服和静脉给予人参皂苷Rd，分段收集给药前和给药后0～24 h尿样，将尿样分时段合并后采用旋转薄膜蒸发浓缩，以固相萃取小柱纯化处理，采用高效液相色谱-串联飞行时间质谱进行检测。结果通过比较给药前后的TOF总离子流图，对尿中推测的代谢物和标准物质的出峰时间及相关化合物选择离子扫描二级质谱图进行了比较分析，结果在尿中发现了7种代谢产物，系统分析了这些代谢产物的代谢转化规律及可能结构。结论大鼠尿中人参皂苷Rd的主要转化途径为氧化、水解、结合及异构化代谢反应。     

液相色谱-串联电喷雾离子阱质谱法研究人尿中埃坡霉素D的主要代谢产物

目的：研究埃坡霉素D在人尿中的主要代谢产物。方法：受试者6名静脉滴注埃坡霉素D,收集0～72h尿样,经SPE固相萃取小柱分离纯化后,采用液相色谱-串联电喷雾离子阱质谱法（LC—MS^n）对样品进行分析,通过比较空白尿样和给药后的尿样的总离子流色谱图和选择离子扫描色谱图,分析可能的代谢产物。代谢产物的结构鉴定主要依据代谢产物的各级质谱图与原药的各级质谱图的相关性推断所得。结果：在人尿中共检测到11种主要的代谢产物,根据所提供的代谢产物标准品鉴定出3种代谢产物的结构,代谢方式主要有氧化、还原、水解和结合反应。结论：本方法选择性好,为深入研究埃坡霉素类药物在人体内的代谢规律提供了可靠的方法和可参考的依据。     

Comprehensive drug screening by integrated use of gas chromatography/mass spectrometry and Remedi HS

The authors evaluated an integrated approach for the screening of drugs in biosamples consisting of gas chromatography/mass spectrometry analysis of serum or whole blood (SB/GC-MS) and of high-performance liquid chromatographic and ultraviolet (HPLC-UV) analysis of urine with the REMEDi HS Biorad system (U/REM) (Bio-rad; Segrate, MI, Italy). Urine and blood samples from 26 suspected intoxicated patients and from 22 suspected lethal poisoning cases were examined. Eighty-one of the 99 parent drugs/main metabolites detected were identified by SB/GC-MS and 54 with U/REM. Thirty-six drugs/metabolites were identified with both methods, 45 by SB/GC-MS alone, and 18 by U/REM alone. Absence of the mass spectrometry (MS) spectra in the reference library and high polarity of the analytes were the main reasons for failed identification by SB/GC-MS. Unsuccessful identifications with U/REM were basically caused by the absence of the UV spectra in the reference library or by low chromatographic and spectroscopic selectivity as in the case of barbiturates and benzodiazepines (BZD), which represented 11% and 51%, respectively, of the 45 SB/GC-MS unique identifications. Urine samples of 14 BZD-positive cases were also submitted to enzymatic hydrolysis and analyzed with the REMEDi UBz assay, and results were compared with those obtained by SB/GC-MS: 14 of the 22 identified BZD were detected with both methods, three by U/REM only, and five by SB/GC-MS only. In conclusion, the integrated use of SB/GC-MS and U/REM approaches greatly enhances the amount and quality of analytical information obtainable by applying either method alone.     

用液相色谱-离子阱质谱联用法检测兔体液中阿普唑仑及其主要代谢产物

建立鉴别体液中阿普唑仑及其主要代谢物的高效液相色谱 电喷雾离子阱质谱联用(LC/MSn)法 .采用LC/MSn联用技术 ,检测家兔灌胃给药后血样和尿样中阿普唑仑原形药及其羟基化代谢物、葡萄糖苷酸型结合物 ,得到了它们的色谱、质谱以及特征碎片离子信息 .阿普唑仑的最低检测限小于 1ng .本法专属性强 ,可推广至其他生物检材的测定 ,尤其适用于需快速响应的临床和法医毒物分析     

Analysis of topiramate and its metabolites in plasma and urine of healthy subjects and patients with epilepsy by use of a novel liquid chromatography-mass spectrometry assay

A novel liquid chromatography-mass spectrometry (LC-MS) method was developed and validated for quantification of topiramate (TPM) and its metabolites 10-hydroxy topiramate (10-OH-TPM), 9-hydroxy topiramate (9-OH-TPM), and 4,5-O-desisopropylidene topiramate (4,5-diol-TPM) in plasma and urine. The method uses 0.5 mL of plasma or 1 mL of urine that is extracted with diethyl ether and analyzed by LC-MS. Positive ion mode detection enables tandem mass spectrometric (MS/MS) identification of the aforementioned four compounds. Calibration curves of TPM, 4,5-diol-TPM, 9-OH-TPM, and 10-OH-TPM in plasma and urine were prepared and validated over the concentration range of 0.625 to 40 microg/mL using TPM-d(12) as an internal standard. Calibration curves were linear over this concentration range for TPM and its metabolites. Accuracy and precision ranged in urine from 83% to 114% and 4% to 13% (%CV), respectively, and in plasma from 82% to 108% and 6% to 13%, respectively. The applicability of the assay was evaluated by analyzing plasma samples from a healthy subject who received a single oral dose of TPM (200 mg) and urine samples from 11 patients with epilepsy treated with TPM (daily dose between 100 to 600 mg) alone or with other antiepileptic drugs. Only TPM was detected and quantified in the plasma samples, and its concentration ranged between 0.7 and 4.3 microg/mL. The concentrations of TPM and 10-OH TPM were quantifiable in all urine samples and ranged from 20 to 300 microg/mL for TPM and from 1 to 50 microg/mL for 10-OH-TPM. The metabolites 4,5-diol-TPM and 9-OH-TPM were also detected in all urine samples, but their concentrations were quantifiable only in 4 patients. An unidentified peak in the chromatograms obtained from patients' urine was attributed to 2,3-O-desisopropylidene topiramate (2,3-diol-TPM). Due to a lack of reference material of 2,3-diol TPM and the similar MS/MS spectrum with 4,5-diol-TPM, the calibration curves of 4,5-diol-TPM were used for the quantification of its isomer 2,3-diol-TPM. Based on these determinations, the apparent 2,3-diol-TPM-to-TPM concentration ratio in patients' urine ranged from 0.05 to 0.51 and the 10-OH-TPM-to-TPM ratio ranged from 0.02 to 0.17. In conclusion, a novel LC-MS method for the assay of TPM and four of its metabolites in plasma and urine was developed. Its utilization for analysis of urine samples from patients with epilepsy showed that the method was suitable for analysis of TPM and its metabolites in clinical samples. Two quantitatively significant TPM metabolites (10-OH-TPM and 2,3-diol-TPM) and two quantitatively minor metabolites (9-OH-TPM and 4,5-diol-TPM) were detected and quantified in urine samples from patients with epilepsy.     

Biotransformation studies of di-acid angiotensin converting enzyme inhibitors

The biotransformation of di-acid angiotensin converting enzyme inhibitors (I) to cyclized lactam metabolites was studied in the urine of rats using gas chromatography-mass spectrometry. Chemical synthesis of the corresponding piperazine-dione metabolite (III) was achieved by reaction of enalapril, perindopril or ramipril with acetic acid anhydride followed by hydrolysis of the ester group by sodium in ethanol or by acid hydrolysis. Electron impact and chemical ionization mass spectra confirmed the structure of these potential novel metabolites. Selected ion monitoring of urinary extracts demonstrated small amounts (less than 5%) of these lactams for all three inhibitors, however, it was shown that the majority of these lactams were formed as a result of sample treatment rather than due to biotransformation.