Identification of etretinate metabolites in human bile

The metabolites of etretinate (Tegison) were investigated in bile obtained from two patients with biliary T-tubes. Bile samples were collected for 5 days after administration of a single, oral 100-mg dose of 14C-labeled etretinate. Radioactivity measurements indicated that the two patients excreted 9.6% and 8.0% of the dose in the 5-day bile. The etretinate metabolites in the bile were present mainly as beta-glucuronidase-labile conjugates. HPLC analyses of the beta-glucuronidase-treated bile samples showed no measurable concentrations (less than 10 ng/ml) of etretinate or the 13-cis acid, isoacitretin. Acitretin, the free acid of etretinate, was present and accounted for about 0.9% of the biliary radioactivity. The major portion of the radioactivity in the extracts of the beta-glucuronidase-treated bile samples consisted of two metabolites with shortened side chains. One was identified as the 11, 12-dihydro-13, 14, 15, 20-tetranor phenolic derivative of acitretin, which was previously identified as a human urinary metabolite. The other metabolite was identified as the 11, 12, 13, 14-tetrahydro-15-nor phenolic derivative of acitretin, which has not been previously identified as a metabolite of etretinate.     

Pharmacokinetic profile of two aromatic retinoids (etretinate and acitretin) in the obese Zucker rat

Etretinate accumulates in adipose tissue; this appears to account for its long terminal elimination phase in psoriatic patients. The purpose of the present study was to investigate the pharmacokinetic profile of etretinate and acitretin in a genetically obese rodent model, the Zucker rat. Pairs of obese and lean Zucker rats were dosed intravenously (0.5 mg/kg) and blood samples were collected. Plasma concentrations of etretinate and its major metabolites, acitretin and the cis isomer of acitretin (isoacitretin), were assayed by HPLC. The systemic clearance (CLs) of etretinate and the formation clearance (CLf) of the metabolite (acitretin) were lower in the obese rats (132 and 62.4 mL/min, respectively) compared with their lean littermates (197 and 126 mL/min, respectively). The remaining metabolic clearance (CLd) was identical for the lean and obese animals (70.9 and 69.9 mL/min, respectively). The ratio of metabolite-to-parent drug area under the plasma concentration-time curve (i.e., acitretin:etretinate) in the obese animal was less than that value in the lean animals (0.348 versus 0.811, respectively) following the administration of etretinate. Despite a doubling in the mean value (204 versus 87.9 mL), no statistically significant differences in the volume of distribution term for etretinate (Vdss) was observed in the obese animals, due to the large interanimal variability. The terminal phase half-life (t1/2) was significantly longer in the obese rats (3.52 versus 1.25 h). Following acitretin administration, no statistically significant differences were observed between the obese and lean animals for any of the parameters (CLs, Vdss, MRT, t1/2) of acitretin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Transplacental pharmacokinetics of teratogenic doses of etretinate and other aromatic retinoids in mice

The transplacental pharmacokinetics of single teratogenic doses of etretinate and motretinide were compared with particular emphasis on distribution and concentrations in the exposed embryos of the free acid metabolite, etretin. The three aromatic retinoids were also tested for their direct inhibitory effect on chondrogenesis in the limb bud mesenchymal cell "micromass" culture assay. After a standard dose of 100 mg/kg administered on day 11 of gestation in NMRI mice, all three compounds were teratogenic, but they differed from each other in potency. Etretinate was most active as a teratogen, equalling the potency of our standard all-trans-retinoic acid; every exposed fetus was deformed with severe shortening of all limb bones as well as cleft palate. Etretin was less potent than etretinate, and motretinide was considerably less active as a teratogen than the other two. In the in vitro assay, only etretin suppressed chondrogenesis and this activity was equivalent to that of all-trans-retinoic acid (IC50 of 12 ng/ml). Both etretinate and motretinide (which contain an ethyl ester and ethylamide terminal group, respectively) were essentially inactive in vitro, demonstrating the fact that a free carboxylic group may be a requirement for the in vitro suppression of chondrogenesis. These differences between the results obtained in vivo and in vitro could be resolved by pharmacokinetic investigations using HPLC methods. Both etretinate and motretinide were metabolized in vivo to etretin, their likely common teratogenic metabolite. The high teratogenic potency of etretinate was probably the result of high concentrations as well as AUC values of its metabolite etretin in the embryo. On the other hand, the comparatively low teratogenicity of motretinide could be related to approximately 5 x lower embryonic peak levels as well as AUC values of etretin. A comparison of these results with those previously obtained for all-trans- and 13-cis-retinoic acids confirms the correlation between embryonic exposure and teratogenic potency in the mouse. Our results indicate that pharmacokinetic studies are essential for the interpretation of relative teratogenic potencies of retinoids as well as apparent differences between in vivo and in vitro teratogenesis. A free carboxyl group at the terminal end of the tetraene chain was necessary for high activity of the retinoids studied.     

In vivo and in vitro influence of etretinate on erythrocyte membrane fluidity.

The molecular mechanisms underlying the action of synthetic retinoids have been studied intensively, but they are not fully understood yet. It is well known that retinoids exert their effects on gene expression via the retinoic acid receptor. Some observations suggest that the main aromatic retinoid etretinate (Tigason) exerts its therapeutic effect in psoriasis also through an action on the cell membrane. In this paper, we present the results of previously unreleased experiments (when Tigason was still in use) concerning the in vivo and in vitro influence of etretinate on erythrocyte membrane fluidity in psoriatic patients. Erythrocytes from healthy subjects and topically treated psoriatics were chosen as control groups. Membrane fluidity was measured by the electron paramagnetic resonance (EPR) spin-labelling technique. Erythrocytes from psoriatic patients had lower membrane fluidity, a lower antioxidant activity and a greater susceptibility to peroxidation than those from healthy subjects. After treatment with etretinate, a significant increase in erythrocyte membrane fluidity and in antioxidant activity as well as a decrease in lipid peroxidation were observed in erythrocytes from patients. Local therapy of psoriatic lesions had no influence on the improvement in membrane fluidity and antioxidant activity of erythrocytes. Incubation of erythrocytes from healthy controls and topically treated psoriatics with etretinate in vitro confirmed its fluidizing effect on erythrocyte membranes. These data may indicate that two mechanisms lead to an increase in erythrocyte membrane fluidity in psoriatic patients treated with Tigason: the first one, indirect, by improvement of the antioxidant defence system and cell protection against lipid peroxidation, and the second one, by a direct fluidizing effect of etretinate on the erythrocyte membrane.     

Pharmacokinetics of 14C-etretinate in healthy volunteers and two patients with biliary T-tube drainage

The pharmacokinetic profile of 14C-etretinate, a retinoid that is effective in the treatment of psoriasis, was studied in six healthy male volunteers and two biliary T-tube patients. Following a 100 mg oral dose of 14C-etretinate (20 microcurie), etretinate and its major blood metabolites (etretin, isoetretin) were measured by HPLC and total carbon-14 was measured in blood, bile, urine, and feces by liquid scintillation counting. Etretinate was extensively metabolized in healthy volunteers and in T-tube patients. During the absorption phase, 75 per cent of the total radioactivity in the blood could be accounted for as etretinate, etretin, and isoetretin whereas these compounds accounted for only approximately 12 per cent of the blood radioactivity in T-tube patients over the same time period. The blood concentrations of etretinate, etretin, and isoetretin appeared to be substantially reduced in T-tube patients compared to those in healthy volunteers. A higher proportion of the total drug was excreted in the feces and bile of the T-tube patients (84 per cent) than in the feces of healthy volunteers (62 per cent). The major factor responsible for the observed decrease in etretinate blood concentrations following biliary cannulation appears to be the reduced absorption of etretinate due to the elimination of solubilizing bile salts in the duodenum. Carbon-14 related material was detected in urine and feces for as long as 3 weeks in healthy subjects supporting the previous observation that a long terminal elimination half-life exists for etretinate, even following a single dose of the compound.     

Distinct conformers of alkylchrysene diol epoxide-deoxyguanosine adducts detected by proton NMR.

Proton NMR spectra, obtained in MeOH-d4, of the major DNA adduct of 5,7-dimethylchrysene-1,2-diol 3,4-epoxide, identified as 1(R),2(S),3(S)-trihydroxy-4(S)-(N2-deoxyguanosyl)-1, 2,3,4-tetrahydro-5,7-dimethylchrysene, showed the presence of two distinct conformers. One conformer, similar to those observed previously in spectra of peracetates of related DNA adducts of anti-diol epoxides of polynuclear aromatic hydrocarbons, had a chair-like conformation of the tetrahydrobenzo ring. The other conformer, which has not been previously observed, had a boat-like conformation of the tetrahydrobenzo ring. This conformer was converted to the chair-like conformer upon addition of D2O or trifluoroacetic acid to the MeOH-d4 solutions of the adduct. The new conformers were also observed in proton NMR spectra of major DNA adducts of 5-methylchrysene- and 5,6-dimethylchrysene-1,2-diol 3,4-epoxides.     

Metabolism of tracazolate. Metabolites in dog and rat urine

The urinary metabolites of tracazolate [4-n-butylamino-1-ethyl-6-methyl-1H-pyrazolo (3,4-b) pyridine-5-carboxylic acid ethyl ester], an anxiolytic agent, obtained from rats and dogs dosed with 14C-labeled tracazolate have been characterized. No unchanged tracazolate was detected. Fifteen metabolites were identified in dog urine, seven of which had not previously been found in rat blood and tissue. Eleven of these metabolites were also found in rat urine. The metabolites were formed by deesterification to the 5-carboxylic acid; N-deethylation of the pyrazole ring: oxidation at the gamma-position of the n-butylamino side chain; oxidation of the terminal carbon of this side chain; loss of the n-butylamino group; and hydroxylation of the 6-methyl group followed by condensation with the 5-carboxylic acid to form gamma-lactones. The major metabolites in dog urine were the desethyl-desbutyl-deesterified compound, the desbutyl-deesterified compound, and the desbutyl-desethyl-lactone. Loss of the butyl side chain and, also, lactone formation, appeared to occur to a lesser extent in the rat than in the dog.     

Determination of the metabolites of terfenadine in human urine by thermospray liquid chromatography—mass spectrometry

Thermospray liquid chromatography-mass spectrometry (TSP LC-MS) was used to determine human urinary metabolites of terfenadine after oral administration of terfenadine tablets. In addition to the two previously identified major metabolites, azacyclonol (MDL 4829) and the 'acid' metabolite (MDL 16,455), three additional metabolites were also detected. One of the additional metabolites was identified as the 'alcohol' metabolite (MDL 17,523) and the other two were proposed to be an 'aldehyde' and a 'ketone-acid' metabolites from their TSP mass spectra. The results of this study demonstrated that TSP LC-MS is a useful technique for the study of terfenadine biotransformation.     

Styrene oxide in blood, hemoglobin adducts, and urinary metabolites in human volunteers exposed to (13)C(8)-styrene vapors

Styrene is used in the manufacture of plastics and polymers and in the boat-building industry. The major metabolic route for styrene in rats, mice, and humans involves conversion to styrene-7,8-oxide (SO). The purpose of this study was to evaluate blood SO, SO-hemoglobin (SO-Hb) adducts, and urinary metabolites in styrene-exposed human volunteers and to compare these results with data previously obtained for rodents. Four healthy male volunteers were exposed for 2 h during light physical exercise to 50 ppm (13)C(8)-styrene vapor via a face mask. Levels and time profiles of styrene in exhaled air, blood, and urine (analyzed by GC) and urinary excretion patterns of mandelic acid and phenylglyoxylic acid in urine (analyzed by HPLC) were comparable to previously published volunteer studies. Maximum levels of SO in blood (measured by GC-MS) of 2.5-12.2 (average 6.7) nM were seen after 2 h, i.e., in the first sample collected after exposure had ended. The styrene blood level in humans was about 1.5 to 2 times higher than in rats and 4 times higher than in mice for equivalent styrene exposures. In contrast the SO levels in human blood was approximately fourfold lower than in mice. The level of hydroxyphenethylvaline (determined by GC-MS-MS) in pooled blood collected after exposure was estimated as 0.3 pmol/g globin corresponding to a SO-Hb adduct increment of about 0.003 pmol/g and ppmh. NMR analyses of urine showed that a major portion (> 95%) of the excreted (13)C-derived metabolites was derived from hydrolysis of SO, while only a small percentage of the excreted metabolites (< 5%) was derived from metabolism via phenylacetaldehyde. Signals consistent with metabolites derived from other pathways of styrene metabolism in rodents (such as glutathione conjugation with SO or ring epoxidation) were not detected.     

Effect of meals on the kinetics of etretinate

Eight healthy men received 100 mg oral doses of etretinate separated by two-week washout periods in an open, randomized, crossover study. Etretinate was administered during a complete fast, with a standard high fat breakfast, a standard high carbohydrate breakfast, and 16 ounces of whole milk. Plasma samples were obtained at specific times over a 48-hour period. Plasma concentrations of etretinate as well as two of its major metabolites were determined by a specific, reverse-phase, high-performance liquid chromatography method. Plasma concentrations of etretinate were greater when administered with a high fat meal and whole milk compared to ingestion with a high carbohydrate meal or during a complete fast. In contrast, there was no increase in the plasma concentrations of the active metabolites following any of the meals. These data indicate that chronic dosing of etretinate with milk or a high fat meal compared with fasting conditions will result in higher concentrations of etretinate, which may ultimately lead to higher metabolite concentrations.     

Structure identification and elucidation of mosapride metabolites in human urine,feces and plasma by ultra performance liquid chromatography-tandem mass spectrometry method

Abstract

1.?Mosapride citrate (mosapride) is a potent gastroprokinetic agent. The only previous study on mosapride metabolism in human reported one phase I oxidative metabolite, des-p-fluorobenzyl mosapride, in human plasma and urine using HPLC method. Our aim was to identify mosapride phase I and phase II metabolites in human urine, feces and plasma using UPLC-ESI-MS/MS.

2.?A total of 16 metabolites were detected. To the best of our knowledge, 15 metabolites have not been reported previously in human.

3.?Two new metabolites, morpholine ring-opened mosapride (M15) and mosapride N-oxide (M16), alone with one known major metabolite, des-p-fluorobenzyl mosapride (M3), were identified by comparison with the reference standards prepared by our group. The chemical structures of seven phase I and six phase II metabolites of mosapride were elucidated based on UPLC–MS/MS analyses.

4.?There were two major phase I reactions, dealkylation and morpholine ring cleavage. Phase II reactions included glucuronide, glucose and sulfate conjugation. The comprehensive metabolic pathway of mosapride in human was proposed for the first time.

5.?The metabolites in humans were compared with those in rats reported previously. In addition to M10, the other 15 metabolites in humans were also found in rats. This result suggested that there was little qualitative species difference in the metabolism of mosapride between rats and humans.

6.?In all, 16 mosapride metabolites including 15 new metabolites were reported. These results allow a better understanding of mosapride disposition in human.     

Urinary metabolites of timolol from humans and laboratory animals. Syntheses and beta-adrenergic blocking activities

Syntheses are reported for three metabolites (2-4) of timolol (1) formed by oxidative metabolism of the morpholine ring. GLC-MS comparisons are presented which establish that the two metabolites whose structures were previously in question are identical with their synthetic counterparts 2 and 3. In 2, metabolic oxidation of the 4-morpholinyl group of 1 had occurred at the carbon next to oxygen to give the 2-hydroxy-4-morpholinyl moiety, whereas in 3, the morpholine of 1 has been oxidized one step further and then ring opened to produce the N-(2-hydroxyethyl)glycine substituent. Biological testing of synthetic samples of the three major metabolites from human urine (3, 4, and 6) indicated that only 4, in which the morpholine moiety has been degraded to a 2-hydroxyethylamino group, had significant beta-adrenergic blocking activity (one-seventh that of timolol in anesthetized dogs).     

Determination of isotretinoin or etretinate and their major metabolites in human blood by reversed-phase high-performance liquid chromatography

A method is described for the quantitative analysis of isotretinoin and its 4-oxo metabolite, or of etretinate and its principal metabolites, in human blood in the range 10-2000 ng/ml. Following a simple one-step extraction, the compounds are determined by reversed-phase high-performance liquid chromatography (HPLC) with gradient elution and detection at 365 nm. This highly specific method separates the cis and trans isomers of the parent compounds and their metabolites. Examples are given of the application of this method to clinical studies of these two therapeutically important retinoids.     

In vitro metabolism of genistein and tangeretin by human and murine cytochrome P450s

Recombinant cytochrome P450 (CYP) 1A2, 3A4, 2C9 or 2D6 enzymes obtained from Escherichia coli and human liver microsomes samples were used to investigate the ability of human CYP enzymes to metabolize the two dietary flavonoids, genistein and tangeretin. Analysis of the metabolic profile from incubations with genistein and human liver microsomes revealed the production of five different metabolites, of which three were obtained in sufficient amounts to allow a more detailed elucidation of the structure. One of these metabolites was identified as orobol, the 3'-hydroxylated metabolite of genistein. The remaining two metabolites were also hydroxylated metabolites as evidenced by LC/MS. Orobol was the only metabolite formed after incubation with CYP1A2. The two major product peaks after incubation of tangeretin with human microsomes were identical with 4'-hydroxy-5,6,7,8-tetramethoxyflavone and 5,6-dihydroxy-4',7,8-trimethoxyflavone, previously identified in rat urine in our laboratory. By comparison with UV spectra and LC/MS fragmentation patterns of previously obtained standards, the remaining metabolites eluting after 14, 17 and 20 min. were found to be demethylated at the 4',7-, 4',6-positions or hydroxylated at the 3'- and demethylated at the 4'-positions, respectively. Metabolism of tangeretin by recombinant CYP1A2, 3A4, 2D6 and 2C9 resulted in metabolic profiles that qualitatively were identical to those observed in the human microsomes. Inclusion of the CYP1A2 inhibitor fluvoxamine in the incubation mixture with human liver microsomes resulted in potent inhibition of tangeretin and genistein metabolism. Other isozymes-selective CYP inhibitors had only minor effects on tangeretin or genistein metabolism. Overall the presented observations suggest major involvement of CYP1A2 in the hepatic metabolism of these two flavonoids.     

Urinary metabolites of clomethiazole. Detection and structural analysis by gas chromatography-mass spectrometry

As the result of a renewed extensive investigation of clomethiazole (Distraneurin) metabolism five previously unknown metabolites could be isolated from human urine. Their structures were elucidated by mass spectrometry. Whereas previous investigations on the metabolism of clomethiazole had demonstrated changes only of the ethyl group, we now found metabolites attached to the methyl group, too. The newly isolated compounds 5-(1-hydroxy-2-chloroethyl)-4-methylthiazole (9) and 5-(2-hydroxyethyl)-4-thiazole carboxylic acid lactone (5) were found to be more abundant in human urine than 4-methyl-5-thiazole acetic acid previously considered as the main metabolite.     

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.     

Pharmacokinetics of etretin and etretinate during long-term treatment of psoriasis patients

The aromatic retinoic acid derivative etretin has recently been introduced in the treatment of severe psoriasis and other dyskeratoses. Hitherto, the use of the carboxylic acid ester analogue, etretinate, has been hampered by an extremely long elimination half-life of up to 120 days for this drug. Seven patients of either sex from whom we recently reported single-dose pharmacokinetics have been studied after 1 and 3 months multiple dose administration of the drugs. Four were given etretin and three etretinate. Etretin, both as drug and as metabolite, was absorbed faster than etretinate as judged from t-lag, tm and t 1/2 ka. Etretin as drug was eliminated faster than the metabolite etretin, t 1/2 beta 2.39 +/- 1.16 days compared to 6.51 +/- 2.06 days. In patients receiving etretinate the terminal disposition or elimination half-lives for cisetretin (t 1/2 lambda 3 15.9 +/- 9.9 days) were longer than for the metabolite etretin and exhibit a pronounced interindividual variation from 4.25 to 22.8 days. Similarly, cis-etretin accumulated very marked in comparison to the metabolite etretin of the drug etretinate. Assuming 40% systemic availability for both drugs, the central compartment of distribution constituted about 12-32% in case of etretin and about 0.8-3.6% in case of etretinate of the calculated apparent total volume of distribution at steady state, which showed mean values of 3.5 and 39.6 1.kg.-1, respectively, presumably reflecting the higher lipophilic nature of the latter compound.     

Enzymic formation of dehydrogenated and hydroxylated metabolites from lysergic acid diethylamide by rat liver microsomes

1. The metabolism of lysergic acid diethylamide (LSD) was studied using rat liver microsomes, and two minor metabolites were obtained in addition to lysergic acid ethylamide and N⁶-desmethyl-lysergic acid diethylamide (nor-LSD) which were reported previously.

2. One of the metabolites was identified as lysergic acid ethylvinylamide, apparently formed by dehydrogenation of a diethylamide group in the side chain at the 8-position, and the other as the phenol 13-hydroxy-LSD.

3. The formation of both lysergic acid ethylamide and lysergic acid ethylvinylamide was similarly induced by pretreatment of rats with either phenobarbitone sodium or 3-methylcholanthrene, while nor-LSD formation was induced only by phenobarbitone and that of 13-hydroxy-LSD only by methylcholanthrene.     

Clinical pharmacokinetics of the retinoids

Etretinate, isotretinoin (13-cis-retinoic acid), and tretinoin (all-trans-retinoic acid) are retinoic acid analogues comprising a group of compounds known as the retinoids. However, they exhibit distinct and important differences with regard to their therapeutic and toxicological profiles. Tretinoin, due to a low oral therapeutic index, is limited almost exclusively to topical application, whereas etretinate and isotretinoin are therapeutically effective when given systemically by the oral route. Clinical doses of isotretinoin range from 0.5 to 8 mg/kg/day, with acute side effects appearing following doses of 1 mg/kg/day or greater. Plasma concentrations of isotretinoin following single and multiple doses peak between 2 to 4 hours and exhibit elimination half-lives of 10 to 20 hours. Isotretinoin blood concentration-time curves following a single- or multiple-dose regimen are well described by a linear model with biphasic disposition characteristics. Etretinate, which possesses a narrower therapeutic concentration range than isotretinoin, is used clinically at doses between 0.5 to 1.5 mg/kg/day; acute side effects appear following doses of 0.5 mg/kg/day or more. In most conditions, the retinoids produce a maximal effect in about 8 weeks (at the highest tolerated dose), with a slow recurrence of symptoms usually occurring within several weeks following cessation of treatment - except in the treatment of cystic acne with isotretinoin. Maintenance or intermittent dosing usually results in a prolongation of remission. Pharmacokinetically, the major difference between isotretinoin and etretinate is the much longer elimination half-life (120 days) of etretinate following long term administration. Recently, however, blood concentration versus time curves from day 1 to day 180 of etretinate therapy have been fitted by a single polyexponential pharmacokinetic equation without the need to invoke non-linearity in the kinetics. The observed lengthening of the elimination half-life with multiple dosing may thus be due to a lack of assay sensitivity at drug concentrations seen after single-dose administration, rather than to time-related alterations in the pharmacokinetics of etretinate.     

Single dose pharmacokinetics of etretin and etretinate in psoriatic patients

Etretin, an aromatic retinoic acid derivative, has recently been introduced as a possible substitute for etretinate in the treatment of severe psoriasis and other dyskeratoses. A total of nine patients with psoriasis of either sex in the age range 23-76 years was investigated after single dose oral drug administration, six were given 40 mg of etretin and three 40 mg of etretinate. A newly developed reversed-phase HPLC method was applied for simultaneous determination of etretin and etretinate in plasma. In patients receiving etretinate, the lag-time i.e. the time elapsing until appearance of first-order drug absorption was 1.24 +/- 0.27 for the parent drug and 0.69 hrs +/- 0.16 (mean value +/- S.D.) for its metabolite, etretin. Absorption half-times were 0.86 +/- 0.04 and 0.55 hrs +/- 0.09, respectively. The patients receiving etretin showed a lag-time of 0.42 hrs +/- 0.23 and an absorption half-time of 0.33 hrs +/- 0.28. This suggests that a fraction of etretinate is rapidly hydrolysed to etretin during the absorption process. The mean half-times of the distributory phases of disposition for etretinate and etretin were about 1 and 1.3 hrs and the apparent terminal half-lives were 6.57 +/- 2.09 and 5.52 hrs +/- 1.76, respectively. Assuming 40% systemic availability for both drugs the mean apparent volumes of distributions were calculated to be 1.50 +/- 0.46 and 1.31 l X kg-1 +/- 0.53 and mean plasma clearances were 177.8 +/- 105.8 and 175.9 ml X kg-1 X hr-1 +/- 81.4 for etretinate and etretin, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)