Identification of an N-Oxide as the Major Metabolite of the Analgesic O-(Diethylaminoethyl)-4-Chlorobenz-aldoxime Hydrochloride in Dogs

1. After oral administration to dogs of the analgesic O-(diethylaminoethyl)-4-chloro[7-¹⁴C]benzaldoxime hydrochloride together with piperazine hydro-chloride (2:1, w/w), at a dose of 4.5?mg/kg, the radioactivity was well absorbed and rapidly excreted. During 5 days, 81% of the dose (ca. 50% in 12?h) was excreted in urine and 10% in faeces.

2. Rates and routes of excretion of radioactivity were not altered in animals pre-treated with the drug for fourteen days.

3. Peak mean plasma concentrations of radioactivity (5.5 μg equiv./ml) occurred at 90 min after an oral dose and were higher than those at 2 min following an equivalent intravenous (3.4 μg equiv. /ml) or rectal (4.0 μg equiv. /ml) dose which gave a max. at 45?min.

4. The drug was rapidly and extensively metabolized and no unchanged drug was detected in the plasma or urine. The major urinary metabolite was the N-oxide of the parent compound accounting for 34% and 23% dose excreted in the urine of males and females respectively during 12?h after administration.     

HPLC/MS法研究左旋黄皮酰胺及其代谢物在Beagle犬血浆中的药代动力学HPLC/MS法研究左旋黄皮酰胺及其代谢物在Beagle犬血浆中的药代动力学

目的用HPLC/MS法研究左旋黄皮酰胺［(-)-clau］及其代谢物6-羟基-黄皮酰胺(6-OH-clau)在Beagle犬血浆中的药代动力学过程。方法Beagle犬灌胃左旋黄皮酰胺30 mg·kg^-1，采集静脉血样，血浆经乙酸乙酯萃取分离后，用HPLC/MS选择性正离子检测内标(格列吡嗪，［M+H］⁺，m/z 446)法测定左旋黄皮酰胺(［M+H］⁺，m/z 298)及6-羟基-黄皮酰胺(［M+H-H₂O］⁺，m/z 296)的浓度，以甲醇-水-冰醋酸(60∶40∶0.8)为流动相，流速1.0 mL·min^-1。用3P97软件计算药代动力学参数。结果左旋黄皮酰胺和6-羟基-黄皮酰胺分别在1.0～200 ng·mL^-1和0.2～40.0 ng·mL^-1线性关系良好(r>0.999)，萃取回收率均大于85%。原药及其代谢物的体内过程均符合二室模型；左旋黄皮酰胺及6-羟基-黄皮酰胺的C_max分别为(21±10) ng·mL^-1和(3.9±2.2) ng·mL^-1；T_max分别为(0.8±0.5) h和(1.3±0.5) h；T_1/2α分别为(0.9±0.6) h和(1.4±0.6) h；T_1/2β分别为(19±23) h和(13±12) h；AUC_{0-24 h}分别为(69±14) h·ng·mL^-1和(12±7) h·ng·mL^-1。结论Beagle犬灌胃左旋黄皮酰胺后迅速吸收，血药浓度一相消除很快，但末端消除较慢；其代谢物6-羟基-黄皮酰胺血药浓度经时过程与左旋黄皮酰胺相似，但血药浓度相对较小。     

Absolute configuration of the major metabolite of 5,5-diphenylhydantoin, 5-(4'-hydroxyphenyl)-5-phenylhydantoin.

Chemical conversions, optical comparisons, and chiroptical measurements (CD) were employed to determine the absolute configuration of the enantiomers of 5-(4'-hydroxyphenyl)-5-phenylhydantoin (HPPH) (1b and 1c). Studies on a key intermediate, (-)-2-cyclohexyl-2-phenylglycine (5b), led to the reexamination of the well-known rule of Clough-Lutz-Jirgensons. Optical comparisons by means of derivatization into hydantoins and 3-phenyl-2-thiohydantoins (application of Freudenberg's rule of shift) gave conclusions which were consistent with chiroptical measurements on the above compounds. Thus, (-)-HPPH (1c), the major metabolite of 5,5-diphenylhydantoin in man, has the S configuration. This assignment was confirmed by X-ray single-crystal structure analysis of (+)-HPPH 10-(+)-camphorsulfonate (18b).     

Identification of 4-oxo-13-cis-retinoic acid as the major metabolite of 13-cis-retinoic acid in human blood

The metabolites of 13-cis-retinoic acid (Accutane) were investigated in blood samples from human volunteers on chronic treatment for dermatological disorders. The major metabolite was isolated by reverse-phase high-pressure liquid chromatography and identified as 4-oxo-13-cis-retinoic acid by comparison of its mass and NMR spectra to the spectra of the reference compound. 4-Oxo-all-trans-retinoic acid was also identified, but the extent to which this compound was a metabolite of 13-cis-retinoic acid or an artifactual isomerization product of the major metabolite is unknown. Chromatographic data suggested that small amounts of 13-cis-retinoic acid, 4-hydroxy-13-cis-retinoic acid, and dioxygenated metabolites of 13-cis-retinoic acid may also be present in the blood. This study indicates that a major metabolic pathway of 13-cis-retinoic acid in humans is oxidation at C4 of the cyclohexenyl group.     

Identification and reactivity of the major metabolite (beta-1-glucuronide) of the anti-tumour agent 5,6-dimethylxanthenone-4-acetic acid (DMXAA) in humans

1. The novel anti-tumour agent 5,6-dimethylxanthenone-4-acetic acid (DMXAA) is extensively metabolized by glucuronidation and 6-methylhydroxylation, resulting in DMXAA acyl glucuronide (DMXAA-G) and 6-hydroxymethyl-5-methylxanthenone-4-acetic acid (6-OH-MXAA). 2. The major human urinary metabolite of DMXAA was isolated and purified by a solid-phase extraction (SPE) method. The isolated metabolite was hydrolysed to free DMXAA by strong base, and by beta-glucuronidase. Liquid chromatography-mass spectrometry (LC-MS) and spectral data indicated the presence of a molecular ion [M + 1]+ at m/z 459, which was consistent with the molecular weight of protonated DMXAA-G. 3. The glucuronide was unstable in buffer at physiological pH, plasma and blood with species variability in half-life. Hydrolysis and intramolecular migration were major degradation pathways. 4. In vitro and in vivo formation of DMXAA-protein adducts was observed. The formation of DMXAA-protein adducts in cancer patients receiving DMXAA was significantly correlated with plasma DMXAA-G concentration and maximum plasma DMXAA concentration. 5. At least five metabolites of DMXAA were observed in patient urine, with up to 60% of the total dose excreted as DMXAA-G, 5.5% as 6-OH-MXAA and 4.5% as the glucuronide of 6-OH-MXAA. 6. These data suggest that the major metabolite in patients' urine is DMXAA beta-1-glucuronide, which may undergo hydrolysis, molecular rearrangement and covalent binding to plasma protein. The reactive properties of DMXAA-G may have important implications for the pharmacokinetics, pharmacodynamics and toxicity of DMXAA.     

Hemodynamic profile of N-(2,5-dimethyl-1H-pyrrol-1-yl)6-(4-morpholinyl)-3-pyridazinamine hydrochloride in conscious dogs

The effects of N-(2,5-dimethyl-1H-pyrrol-1-yl)6-(4-morpholinyl)-3-pyridazinamine hydrochloride (MDL-899) on systemic, pulmonary, renal and coronary circulation and on myocardial contractility have been investigated in conscious dogs treated orally. The compound induced a decrease in systemic arterial blood pressure, slow in onset (peak effect at 4 h) and long-lasting (more than 7 h), by reducing total peripheral resistance, while the heart rate, cardiac output, cardiac work and myocardial contractility increased because of the reflex increase in sympathetic drive evoked by the blood pressure fall. Coronary and renal blood flows were increased for a long time. Pulmonary resistance was markedly decreased, but the pulmonary pressure was increased, probably due to the hyperkinetic activity triggered by the increases of cardiac output and heart rate. The hemodynamic changes induced by MDL-899 are qualitatively similar to those induced by hydralazine. The results suggest that the compound belongs to the class of vasodilators that act primarily on systemic arterioles to produce arteriolar dilation.     

Isolation and identification of the major urinary metabolite of 4-(4-fluorophenoxy)benzaldehyde semicarbazone after oral dosing to rats

4-(4-Fluorophenoxy)benzaldehyde semicarbazone (1) is a novel anticonvulsant affording excellent protection in the rat oral maximal electroshock (MES) screen as well as having an apparent protection index of over 300. The metabolism of this compound was studied by examining the urine or rats dosed orally with 50 mg/kg of 1 which revealed that most of the drug was converted into one metabolite 2. The structure of 2 was shown by mass spectrometry to be 1-[4-(4-fluoro-phenoxy)benzoyl]semicarbazide which was confirmed by an independent synthesis. Compound 2 was bereft of activity in the rat oral MES screen when nine times the ED50 dose of 1 was administered. This datum provided strong evidence that the anticonvulsant activity of 1 and related compounds is due to the intact molecules and is not produced by breakdown products in vivo.     

Identification of 1-hydroxypyrene as a major metabolite of pyrene in pig urine

1-Hydroxypyrene is a major metabolite of pyrene given orally to pigs. A method for isolating the metabolite from urine is described, utilizing C18-adsorbent cartridges, h.p.l.c. separation, and fluorescence detection. Unconjugated 1-hydroxypyrene can be detected in the urine of pigs following oral administration of as little as 1 mg pyrene. Identity of the 1-hydroxypyrene was confirmed by u.v.-absorption and fluorescence spectrometry, mass spectrometry, and by comparison with the retention time characteristic of synthetic 1-hydroxypyrene.     

Identification of detomidine carboxylic acid as the major urinary metabolite of detomidine in the horse.

Horse urine was investigated for metabolites by chromatography and mass spectrometry following the oral administration of the large animal analgesic sedative detomidine to two stallions and intravenous administration of [3H]-detomidine to a mare. Detomidine carboxylic acid and hydroxydetomidine glucuronic acid conjugate were identified in the urine after the oral doses. In addition, traces of free hydroxydetomidine were observed. About half of the radioactivity of [3H]-detomidine was excreted in the urine in 12 h after the i.v. dose (80 micrograms/kg). Most of the excretion occurred between 5 and 12 h in contrast to urine output which was highest 2-5 h after the dosing. The major radioactive metabolite in the urine was detomidine carboxylic acid. It comprised more than two thirds of the total metabolites in all the urine fractions collected. Its excretion profile was similar to that of total radioactivity. Hydroxydetomidine glucuronide was also excreted. It contributed 10-20% of the total metabolites in the urine. The free aglycone was only seen in the samples collected during the peak urine flow. A minor metabolite was tentatively characterized as the glucuronide of N-hydroxydetomidine.