The metabolic fate of two new psychoactive substances - 2-aminoindane and N-methyl-2-aminoindane - studied in vitro and in vivo to support drug testing.

The aim of this study was to characterize the in vitro and in vivo metabolism of 2-aminoindane (2,3-dihydro-1H-inden-2-amine, 2-AI), and N-methyl-2-aminoindane (N-methyl-2,3-dihydro-1H-inden-2-amine, NM-2-AI) after incubations using pooled human liver microsomes (pHLMs), pooled human liver S9 fraction (pS9), and rat urine after oral administration. After analysis using liquid chromatography coupled to high-resolution mass spectrometry, pHLM incubations revealed that 2-AI was left unmetabolized, while NM-2-AI formed a hydroxylamine and diastereomers of a metabolite formed after hydroxylation in beta position. Incubations using pS9 led to the formation of an acetyl conjugation in the case of 2-AI and merely a hydroxylamine for NM-2-AI. Investigations on rat urine showed that 2-AI was hydroxylated also forming diasteromers as described for NM-2-AI or acetylated similar to incubations using pS9. All hydroxylated metabolites of NM-2-AI except the hydroxylamine were found in rat urine as additional sulfates. Assuming similar patterns in humans, urine screening procedures might be focused on the parent compounds but should also include their metabolites. An activity screening using human recombinant N-acetyl transferase (NAT) isoforms 1 and 2 revealed that 2-AI was acetylated exclusively by NAT2, which is polymorphically expressed.

Fate of ptaquiloside-A bracken fern toxin-In cattle.

Ptaquiloside is a natural toxin present in bracken ferns (Pteridium sp.). Cattle ingesting bracken may develop bladder tumours and excrete genotoxins in meat and milk. However, the fate of ptaquiloside in cattle and the link between ptaquiloside and cattle carcinogenesis is unresolved. Here, we present the toxicokinetic profile of ptaquiloside in plasma and urine after intravenous administration of ptaquiloside and after oral administration of bracken. Administered intravenously ptaquiloside, revealed a volume of distribution of 1.3 L kg-1 with a mean residence-time of 4 hours. A large fraction of ptaquiloside was converted to non-toxic pterosin B in the blood stream. Both ptaquiloside and pterosin B were excreted in urine (up to 41% of the dose). Oral administration of ptaquiloside via bracken extract or dried ferns did not result in observations of ptaquiloside in body fluids, indicating deglycosolidation in the rumen. Pterosin B was detected in both plasma and urine after oral administration. Hence, transport of carcinogenic ptaquiloside metabolites over the rumen membrane is indicated. Pterosin B recovered from urine counted for 7% of the dose given intravenously. Heifers exposed to bracken for 7 days (2 mg ptaquiloside kg-1) developed preneoplastic lesions in the urinary bladder most likely caused by genotoxic ptaquiloside metabolites.

Study on the metabolism of 5,6-methylenedioxy-2-aminoindane (MDAI) in rats: identification of urinary metabolites.

1. 5,6-Methylenedioxy-2-aminoindane (MDAI) is a member of aminoindane drug family with serotoninergic effect, which appeared on illicit drug market as a substitute for banned stimulating and entactogenic drugs. 2. Metabolism of MDAI, which has been hitherto unexplored, was studied in rats dosed with a subcutaneous dose of 20 mg MDAI.HCl/kg body weight. The urine of rats was collected within 24 h after dosing for analyses by HPLC-ESI-HRMS and GC/MS. 3. The main metabolic pathways proceeding in parallel were found to be oxidative demethylenation followed by O-methylation and N-acetylation. These pathways gave rise to five metabolites, namely, 5,6-dihydroxy-2-aminoindane, 5-hydroxy-6-methoxy-2-aminoindane, N-acetyl-5,6-methylenedioxy-2-aminoindane, N-acetyl-5,6-dihydroxy-2-aminoindane and N-acetyl-5-hydroxy-6-methoxy-2-aminoindane, which were found predominantly in the form of corresponding glucuronides and sulphates. However, the main portion of administered MDAI was excreted unchanged. 4. Minor metabolites formed primarily by hydroxylation at various sites include cis- and trans-1-hydroxy-5,6-methylenedioxy-2-aminoindane, 5,6-methylenedioxyindan-2-ol and 4-hydroxy-5,6-methylenedioxy-2-aminoindane. 5. Identification of all metabolites except for glucuronides, sulphates and tentatively identified 4-hydroxy-5,6-methylenedioxy-2-aminoindane was supported by synthesised reference standards.

Indacaterol determination in human urine: validation of a liquid-liquid extraction and liquid chromatography-tandem mass spectrometry analytical method.

BACKGROUND: Indacaterol is a novel once-a-day inhaled ultra-long-acting ß2-agonist. Quantitative bioanalysis supports pharmacokinetic and clinical research. The aim of the current work was to validate an in-house developed high performance liquid chromatography (HPLC)-tandem mass spectrometry (MS/MS) analytical method for indacaterol determination in human urine samples. METHODS: A liquid-liquid extraction method has been developed to extract indacaterol from human urine samples using ethyl acetate. Indacaterol dry extract was reconstituted with 200 µL of the mobile phase (acidified water:methanol (30:70, v/v)) of which 5 µL was needed for the HPLC-MS/MS analysis. Indacaterol was eluted on a reversed C18 stationary phase with an isocratic mobile phase at a flow of 1 mL/min. Formoterol was the internal standard (IS). The MS/MS detection was employed with a turbo-ion spray ionization in the positive ion mode. A consensus of the international Guidelines for Bioanalytical Method Validation was followed. RESULTS: Indacaterol was detected at a mass to charge ratio (m/z) of 393.3 and its MS/MS daughter at 173.2. The retention times of indacaterol and IS were 1.60 and 1.20 min, respectively. Validated calibration curves were linear over a range of 0.075-100 ng/mL with correlation coefficients (r)≥0.990. The curves' regression weighting factor was 1/x. Method specificity was established in six different human urine batches. No matrix interference was observed. The intra- and inter-batch precision and accuracy within±20% (at lower limit) and±15% (other quality control (QC) levels) were confirmed. The indacaterol mean recovery (precision) percentages at Low, Mid, and High QC levels were 93.5 (3.84), 89.8 (2.15), and 92.2 (2.17), respectively. Short-term, long-term, freeze-thaw, and auto-sampler stability results were accepted. CONCLUSIONS: A specific, accurate and precise HPLC-MS/MS method has been validated for indacaterol quantification in human urine. This simple method is reproducible and robust to support future, indacaterol-related pharmacokinetic, bioequivalence and clinical studies.

Metabolism and pharmacokinetics of indacaterol in humans.

The metabolism, pharmacokinetics, and excretion of [(14)C]indacaterol were investigated in healthy male subjects. Although indacaterol is administered to patients via inhalation, the dose in this study was administered orally. This was done to avoid the complications and concerns associated with the administration of a radiolabeled compound via the inhalation route. The submilligram doses administered in this study made metabolite identification and structural elucidation by mass spectrometry especially challenging. In serum, the mean t(max), C(max), and AUC(0-last) values were 1.75 h, 0.47 ng/ml, and 1.81 ng · h/ml for indacaterol and 2.5 h, 1.4 ngEq/ml, and 27.2 ngEq · h/ml for total radioactivity. Unmodified indacaterol was the most abundant drug-related compound in the serum, contributing 30% to the total radioactivity in the AUC(0-24h) pools, whereas monohydroxylated indacaterol (P26.9), the glucuronide conjugate of P26.9 (P19), and the 8-O-glucuronide conjugate of indacaterol (P37) were the most abundant metabolites, with each contributing 4 to 13%. In addition, the N-glucuronide (2-amino) conjugate (P37.7) and two metabolites (P38.2 and P39) that resulted from the cleavage about the aminoethanol group linking the hydroxyquinolinone and diethylindane moieties had a combined contribution of 12.5%. For all four subjects in the study, ≥90% of the radioactivity dose was recovered in the excreta (85% in feces and 10% in urine, mean values). In feces, unmodified indacaterol and metabolite P26.9 were the most abundant drug-related compounds (54 and 17% of the dose, respectively). In urine, unmodified indacaterol accounted for ∼0.3% of the dose, with no single metabolite accounting for >1.3%.

Metabolism of (2S)-pterosin A: identification of the phase I and phase II metabolites in rat urine.

The metabolic profile of the potent hypoglycemic agent, (2S)-pterosin A (1), in rat urine via intragastrical oral administration was investigated. In total, 19 metabolites (M1-M19) were identified. Among these, 16 metabolites were characterized by high-performance liquid chromatography solid-phase extraction-tube transfer-NMR, and seven metabolites were further isolated from the treated urine to enable further structural determination. Twelve of these are new compounds. The phase I metabolites of 1 were formed via various oxidations at positions C-3, C-10, C-12, C-13, or C-1 followed by decarboxylation of C-10 or C-14, and lactonization at C-12/C-14 or C-14/C-12. The phase II metabolites were glucuronide conjugates from the parent compound or phase I metabolites. The major metabolites were found to be (2S)-14-O-glucuronylpterosin A (M9), (2S)-2-hydroxymethylpterosin E (M14), and (±)-pterosin B (M19). Quantitative HPLC analysis of metabolites, based on similar UV absorption and use of the regression equation of 1, indicated that ∼71% 1 was excreted as metabolites in rat urine.

[Simultaneous determination of trace diphacinone and chlorophacinone in biological samples by high performance liquid chromatography coupled with ion trap mass spectrometry].

A rapid qualitative and quantitative method for the simultaneous determination of trace diphacinone and chlorophacinone in biological samples has been established. The method mainly serves for the emergent poisoning detection. The whole blood was treated with methanol-acetonitrile (50/50, v/v) and the urine was cleaned-up by Waters Oasis HLB SPE cartridges. The samples were separated on an Extend C18 column (150 mm x 4.6 mm, 5 microm) by using the mobile phase consisted of ammonium acetate-acetic acid (0.02 mol/L, pH 5.5) - methanol (15/85, v/v). The determination was performed by high performance liquid chromatography coupled with ion trap mass spectrometry (HPLC-IT-MS) using a negative electrospray ionization interface in the multiple reaction monitoring (MRM) mode. The transitions of m/z 339 --> 167 for diphacinone and m/z 373 --> 201 for chlorophacinone were selected for the quantificantions. For the whole blood samples, the calibration curves were linear within the ranges of 1.0 - 200.0 microg/L and 0.5 - 100.0 microg/L; the limits of quantification were 1.0 microg/L and 0.5 microg/L; the spike recoveries were 90.1% - 92.2% and 87.6% - 93.4%, the intra-day relative standard deviations (RSDs) were less than 6.8% and 7.4%, and the inter-day RSDs were less than 9.9% and 10.9% for diphacinone and chlorophacinone, respectively. For the urine samples, the calibration curves were linear within the ranges of 0.2 - 40.0 microg/L and 0.1 - 20.0 microg/L; the limits of quantification were 0.2 microg/L and 0.1 microg/L; the spike recoveries were 90.1% -94.5% and 90.0% -98.0%, the intra-day RSDs were less than 6.1% and 7.3%, and the inter-day RSDs were less than 8.9% and 11.2% for diphacinone and chlorophacinone, respectively. This method is simple and sensitive for the satisfactory determination of trace diphacinone and chlorophacinone residues in poisoned patients for the clinical diagnosis.

Rapid and sensitive liquid chromatography-tandem mass spectrometry: assay development, validation and application to a human pharmacokinetic study.

Rasagiline is a highly potent, selective and irreversible second-generation monoamine oxidase inhibitor with selectivity for type B of the enzyme (MAO-B). The present studies aimed at developing and validating a rapid and sensitive liquid chromatography-tandem mass spectrometric (LC-MS/MS) method for determination of rasagiline in human plasma and urine. LC-MS/MS analysis was carried out on a Finnigan LC-TSQ Quantum mass spectrometer using positive ion electrospray ionization (ESI(+)) and selected reaction monitoring (SRM). The assay for rasagiline was linear over the range of 0.01-40 ng/mL in plasma and 0.025-40 ng/mL in urine. It took 5.5 min to analyze a sample. The average recoveries in plasma and urine samples were both >85%. The RSD of precision and bias of accuracy were less than 15% and 10%, respectively, of their nominal values based on the intra- and inter-day analysis. The developed method was proved to be suitable for use in clinical pharmacokinetic study after single oral administration of 0.5, 1 and 2 mg rasagiline mesylate tablets in healthy Chinese volunteers.

Determination of therapeutics with growth-hormone secretagogue activity in human urine for doping control purposes.

The administration of growth-promoting agents such as human growth hormone as well as compounds with respective secretagogue activity is prohibited in sports according to the regulations of the World Anti-Doping Agency. Acetylcholine esterase inhibitors have been demonstrated to stimulate growth-hormone secretion in elderly humans, and new orally active drugs have been developed to provide alternatives to therapeutic injections of growth-hormone preparations. Preventive anti-doping strategies include method development for emerging drugs and potentially misused compounds. Hence, the mass spectrometric dissociation behavior of three acetylcholine esterase inhibitors (donepezil, galantamine and rivastigmine) and a structural analogue to the growth-hormone secretagogue SM-130686 were studied using high-resolution/high-accuracy orbitrap mass spectrometry. These data provided substantial information for screening procedures, complementing common methods of sports drug testing. Using liquid-liquid extraction and subsequent liquid chromatography/tandem mass spectrometry (LC/MS/MS) analysis, the four target analytes were determined at urinary concentrations of 15-20 ng/mL, recoveries ranged from 55-97%, and assay precisions were calculated at 5.2-15.8% (intraday) and 10.2-21.6% (interday) for all compounds. The applicability of the developed assay to authentic urine specimens was tested using two administration study urine samples after application of Reminyl (galantamine) and Aricept (donepezil). In both cases, the administered drug and the respective desmethylated metabolites were detected.

Absorption, distribution, metabolism, and excretion of donepezil (Aricept) after a single oral administration to Rat.

Donepezil hydrochloride (Aricept) is a drug for the treatment of Alzheimer's disease. The absorption, distribution, metabolism, and excretion of donepezil were investigated in male Sprague-Dawley rats after a single oral administration. Orally administered (14)C-labeled donepezil was absorbed rapidly. The plasma level of unchanged donepezil declined more rapidly than that of radioactivity, and the brain level of radioactivity declined almost in parallel with the plasma level of unchanged donepezil. The ratio of donepezil to total radioactivity in brain was 86.9 to 93.0%, indicating low permeability of the metabolites through the blood-brain barrier. No heterogeneous localization of radioactivity was recognized in the brain and the concentration in each part of the brain was 1.74 to 2.24 times the plasma concentration. Cumulative biliary, urinary, and fecal excretion of radioactivity in bile duct-cannulated rats was 72.9, 24.4, and 8.84%, respectively, of the administered radioactivity at 48 h after administration. These results indicate that the absorption of donepezil is almost complete, and that its metabolites are mainly excreted into feces through the bile and some of them are subject to enterohepatic circulation. The metabolism of donepezil was extensive in rats and involved O-demethylation, aromatic hydroxylation, N-dealkylation, N-oxidation, and glucuronide conjugation of O-demethylate. The structures of the metabolites were determined by mass spectrometry and (1)H-NMR analysis. In plasma, urine, and bile, O-glucuronides accounted for the majority of the radioactivity, and in brain, unchanged donepezil was mostly detected. No metabolites were found in brain. There was no notable accumulation of radioactivity in whole blood and tissues.

Determination of L-756 423, a novel HIV protease inhibitor, in human plasma and urine using high-performance liquid chromatography with fluorescence detection.

A method for the determination of L-756 423, a novel HIV protease inhibitor, in human plasma and urine is described. Plasma and urine samples were extracted using 3M Empore extraction disk cartridges in the C18 and MPC (mixed-phase cation-exchange) formats, respectively. The extract was analyzed using HPLC with fluorescence detection (ex 248 nm, em 300 nm), and included a column switching procedure to reduce run-time. The assay was linear in the concentration range 5 to 1000 ng/ml when 1-ml aliquots of plasma and urine were extracted. Recoveries of L-756 423 were greater than 84% over the calibration curve range using the described sample preparation procedures. Intra-day precision and accuracy for this assay was less than 9% RSD and within 7%, respectively. Inter-day variabilities for the plasma (n=17) and urine (n= 10) were less than 5% and 3% for low (15 ng/ml) and high (750 ng/ml) quality control samples. Bovine serum albumin (0.5%) was used as an additive to urine to prevent precipitation of L-756 423 during the storage of clinical samples. The assay was used in support of human clinical trials.

Metabolism and elimination of 14C-donepezil in healthy volunteers: a single-dose study.

AIM: The aim of this study was to investigate the metabolism and elimination of donepezil HCl in humans, following the administration of a single 5 mg (liquid) oral dose containing a mixture of unlabelled and 14C-labelled donepezil. METHODS: This was an open-label, non-randomized study in healthy male volunteers (n = 8). Characterization of donepezil metabolism and elimination was performed by analysing blood, urine and faecal samples collected over a 10-day period following drug administration. Each collected sample was assayed for total radioactivity, and aliquots from specified time-points and/or pooled samples were assayed for the presence of donepezil metabolites by thin-layer chromatography (TLC). Donepezil concentrations in plasma were determined by HPLC. RESULTS: Recovery of radioactivity in subject samples averaged 72% of the administered dose. Recovery of the administered dose in urine (57%) was significantly greater than that recovered in faeces (15%). Unchanged donepezil accounted for the largest component of the recovered dose in each matrix. Three metabolic pathways were identified: (i) O-dealkylation and hydroxylation to metabolites M1 and M2, with subsequent glucuronidation to metabolites M11 and M12; (ii) hydrolysis to metabolite M4; and (iii) N-oxidation to metabolite M6. In plasma, the parent compound accounted for about 25% of the dose recovered during each sampling period, as well as of the cumulative dose recovered. The recovered residue showed higher levels of the hydroxylated metabolites M1 and M2 than of their glucuronide conjugates M11 and M12, respectively. In urine, the parent compound accounted for 17%, on average, of the dose recovered from each pooled sample, as well as of the total recovered dose. The major metabolite was the hydrolysis product M4, followed by the glucuronidated conjugates M11 and M12. In faeces, the parent compound also predominated, although it accounted for only 1%, of the recovered dose. A large percentage of the radioactivity in faeces consisted of unidentified very polar metabolites, which were retained at the TLC origin. Of the extracted metabolites, the hydroxylation products M1 and M2 were the most abundant, followed by the hydrolysis product M4 and the N-oxidation product M6. CONCLUSIONS: Donepezil is hepatically metabolized and the predominant route for the elimination of both parent drug and its metabolites is renal, as 79% of the recovered dose was found in the urine with the remaining 21% found in the faeces. Moreover, the parent compound, donepezil, is the predominant elimination product in urine. The major metabolites of donepezil include M1 and M2 (via O-dealkylation and hydroxylation), M11 and M12 (via glucuronidation of M1 and M2, respectively), M4 (via hydrolysis) and M6 (via N-oxidation).

Pharmacokinetics of Camonagrel in experimental animal: rat, rabbit and dog.

Camonagrel is a novel selective thromboxane synthetase inhibitor. The aim of this study was to determine its main pharmacokinetic parameters in rats, rabbits and dogs after intravenous and oral administration at doses of 10 mg kg(-1). Plasma and urine concentrations of camonagrel were analyzed by HPLC with UV detection. Pharmacokinetics of camonagrel was generally fitted to a two-compartmental model and the values which defined the absorption process were: Cmax = 15.96 microg.ml(-1), Tmax approximately 0.33 h, AUC(0-infinity) (oral) approximately 12.45 microg x h x ml(-1) (rat, n=3 per pont); Cmax approximately 2.04 mg x ml(-1), Tmax approximately 1.50 h, AUC(0-infinity) (oral) approximately 4.85 microg x h x ml(-1) (rabbit, n=3); Cmax approximately 18.60 microg x ml(-1), Tmax approximately 0.44 h, AUC(0-infinity) (oral) approximately 13.40 microg x h x ml(-1) (dog, n=4). The more representative values in the distribution and elimination phase were: protein binding rate approximately 80% in the three species ("in vitro" experiment); t(1/2beta) approximately 0.22 h (rat, i.v.), = 0.28 h (rabbit i.v.) and approximately 0.45 h (dog i.v.); CI approximately 635.73 ml x h(-1) (rat i.v.), approximately 448.26 ml x h(-1) (rabbit i.v.) and approximately 463.8 ml x h(-1) (dog i.v.). The absolute bioavailability of camonagrel was approximately 79.1% in rat, approximately 21.7% in rabbit and approximately 59.3% in dog. Available elimination data in rat indicated that Camonagrel was mainly excreted in urine (approximately 80%) as unchanged drug. An unknown minor metabolite (approximately 10%) was observed only after oral dosing. Finally, the main pharmacokinetic parameters of camonagrel in rats, rabbits and dogs are presented, which allow to define its absorption, distribution and elimination processes in these species.

Formation and pharmacokinetics of the active drug candoxatrilat in mouse, rat, rabbit, dog and man following administration of the prodrug candoxatril.

1. Candoxatrilat, an active neutral endopeptidase inhibitor, was released rapidly from the inactive prodrug candoxatril in vivo in mouse, rat, rabbit, dog and man. 2. Oral doses of [14C]-candoxatril were cleared rapidly, mostly by ester hydrolysis to candoxatrilat, in mouse, dog and man. A complementary intravenous study in man with [14C]-candoxatrilat showed that the active drug was virtually completely renally cleared. Neither candoxatril nor candoxatrilat underwent chiral inversion in man. 3. Systemic availability of candoxatrilat from the oral prodrug was estimated to be 88, 53, 42, 17 and 32% in mouse, rat, rabbit, dog and man respectively. Plasma clearance of candoxatril was too rapid to enable pharmacokinetic parameter calculation in mouse and rabbit; for man, the apparent oral clearance was 57.9 ml/min/kg and the elimination half-life was 0.46 h. 4. For intravenous candoxatrilat, total plasma clearance values were 32, 15, 5.5, 5.8 and 1.9 ml/min/kg for mouse, rat, rabbit, dog and man respectively. Renal clearance values were 8.7, 7.2, 2.9 and 1.7 ml/min/kg for mouse, rat, dog and man and these approximate to the respective glomerular filtration rates. Allometric scaling with respect to bodyweight across the species allowed reasonable prediction of the above two clearance parameters in man.

Bioavailability and pharmacokinetics of a fixed combination of delapril/indapamide following single and multiple dosing in healthy volunteers.

The study objective was to obtain detailed information on the bioavailability and pharmacokinetics of the new fixed combination of delapril and indapamide following single and multiple dosing. For this reason, the study was performed in two parts, separated by a medication-free period of at least 7 days. In the single dose part, one tablet, containing 30 mg delapril and 2.5 mg indapamide, was administered to 12 male volunteers; in the multiple dose part, the volunteers received one tablet of the test preparation, once daily over 7 days. Following single and on the last day of the multiple dosing regimen, blood samples were withdrawn and serum concentrations of delapril and its metabolites M1, M2 and M3 and whole blood concentrations of indapamide were quantified by means of HPLC methods. In addition, urine samples were collected following single and multiple dosing for evaluation of the cumulative amount of delapril and its metabolites M1-M3 excreted in urine. For the area under the curve, calculated from time 0 to infinity (AUC(0-infinity)) the study revealed, following single dosing, mean values of delapril and its metabolites M1, M2 and M3 of 281, 2178, 739 and 716 h.ng/ml, respectively; for indapamide the mean value was 1597 h.ng/ml. The corresponding mean values found after multiple dose administration were 272, 2071, 857 and 598 h.ng/ml for delapril and its metabolites, respectively and 1536 h.ng/ml for indapamide. Evaluation of the cumulative amount of delapril and its metabolites M1-M3 excreted in urine (Ae) demonstrated mean values following single dosing (observation period 36 h) of 705, 4521, 454 and 4203 micrograms, respectively; the corresponding values after multiple dose administration (observation period 24 h) of the test preparation were 655, 4679, 469 and 4801 micrograms, respectively. The most important pharmacokinetic parameters AUC(0-infinity) and Ae were statistically compared by analysis of variance (ANOVA) and 90% confidence intervals were calculated. It may be concluded from the results of this study, that the bioavailability and pharmacokinetic parameters of the test preparation after single dosing and after multiple doses correspond well. The undesired side effects observed are known to occur after administration of the test preparation. The occurrence was a little more frequent after multiple dose application in comparison with the single dose administration.

Metabolism and nephrotoxicity of indan in male Fischer 344 rats.

Indan, a component of fuels, solvents, and varnishes, is metabolized in male Fischer 344 rats to 1-indanol, 2-indanol, 5-indanol, 1-indanone, 2-indanone, 2-hydroxy-1-indanone, cis-1,2-indandiol, and trans-1,2-indandiol. The metabolites were identified using the techniques of gas chromatography (GC) and gas chromatography/mass spectrometry (GC/MS). The rats treated with indan demonstrated the classic lesions of hydrocarbon-induced nephropathy. The kidney damage produced was less than that found for tetralin and other branched-chain acyclic hydrocarbons.

Pharmacokinetics of a new angiotensin I converting enzyme inhibitor (delapril) in patients with deteriorated kidney function and in normal control subjects.

Pharmacokinetic properties of a new angiotensin-converting enzyme inhibitor, delapril (CV-3317), which converts to two active metabolites (M-1 and M-2) and one inactive metabolite (M-3) after oral administration, were investigated in six subjects with normal, 10 subjects with slight (SRF), and six subjects with markedly (MRF) deteriorated kidney function. The elimination half-life of M-1 was prolonged significantly in subjects with MRF and that of M-3 was also prolonged in subjects with SRF or MRF. The peak plasma drug concentration, time to reach peak concentration (tmax), and AUC were significantly larger in subjects with SRF and MRF than in normal subjects, except for Tmax in subjects with SRF. In M-2 and unchanged delapril, no difference was observed. The 24-hour cumulative urinary excretion of those metabolites was significantly lower in subjects with MRF than in normal subjects. Plasma angiotensin-converting enzyme activity, suppressed at 4 hours in all subjects, remained significantly low in patients with MRF at 24 hours. Blood pressure was reduced more in subjects with chronic renal failure. It was concluded that delapril is excreted mainly through the kidney and its pharmacodynamics and biologic effects are affected by the renal dysfunction.

Gas chromatographic/mass spectrometric studies of the urinary metabolites of male rats given indan.

The identified urinary metabolites of male rats exposed to indan are: 1- and 2-indanone; 1-, 2- and 5-indanol; 2- and 3-hydroxyl-1-indanone; and cis- and trans-indan-1,2-diol. Indan causes kidney damage in male rats in a manner similar to the cyclic hydrocarbons cis- and trans-decalin and JP-10. Lesions produced by indan occur only in male rats and not in female or control rats.

Metabolite identification of missile fuel JP-10 by gas chromatography mass spectrometry.

The identification of the metabolites of the Air Force missile fuel JP-10 was accomplished. 5-Hydroxy-JP-10 was identified as the urinary metabolite of rats, mice and hamsters exposed to JP-10. 5-Keto-JP-10 was a major metabolite found in kidney extracts of male rats exposed to JP-10 but not found in kidney extracts from female rats or from other species. Sex-related differences in the formation of 5-keto-JP-10 in rats were studied.

Gas chromatographic determination of a diuretic-antihypertensive agent, (+/-)-[[6,7-dichloro-2-(4-fluorophenyl)-2-methyl-1-oxo-5-indanyl] oxy]acetic acid, in biological fluids.

A method for the measurement of a potential diuretic-antihypertensive agent, (+/-)-[[6,7-dichloro-2-(4-fluorophenyl)-2-methyl-1-oxo-5-indanyl] oxy]acetic acid, in biological fluids is described. The procedure involves the addition of a related internal standard to the specimens followed by extraction of the acids into toluene at pH 1. The indanyloxyacetic acids, following back-extraction into base and reextraction into methylene chloride at an acidic pH, are converted to methyl esters by reaction with ethereal diazomethane for subsequent gas chromatographic analysis. The sensitivity of the method is such that 5 ng of drug in 1 mL of biological specimen can be quantitated using a 63Ni electron-capture detector. The recovery from plasma in the 5-2000-ng/mL range (n = 53) was 97.0 +/- 16.3%. Differences were noted in the disposition of the enantiomers of this agent in dogs following a pharmacologically active dose.