Studies related to the origin of C18 neutral steroids isolated from extracts of urine from the male horse: the identification of urinary 19-oic acids and their decarboxylation to produce estr-4-en-17beta-ol-3-one (19-nortestosterone) and estr-4-ene-3,17-dione (19-norandrost-4-ene-3,17-dione) during sample processing.

For almost two decades we have known that enzymatic hydrolysis of "normal" urine samples from the entire male horse using Escherichia coli (E. coli) followed by solvolysis (ethyl acetate:methanol:sulphuric acid) results in the detection of significant amounts of estr-4-ene-3,17-dione (19-norandrost-4-ene-3,17-dione) along with estr-4-en-17beta-ol-3-one (19-nortestosterone, nandrolone) in extracts of the hydrolysed urine and that both steroids are isolated from the solvolysis fraction. This solvolysis process is targeted at the steroid sulphates. Also we have shown that 19-norandrost-4-ene-3,17-dione and 19-nortestosterone are isolated from testicular tissue extracts. Subsequently, evidence was obtained that 19-nortestosterone detected in extracts of "normal" urine from male horses may not be derived from the 17beta-sulphate conjugate. However, following administration of 19-nortestosterone based proprietary anabolic steroids to all horses (males, females and castrates), the urinary 19-nortestosterone arising from the administration is excreted primarily as the 17beta-sulphate conjugate. Thus, if the 19-nortestosterone-17beta-sulphate conjugate arises only following administration this has interesting implications for drug surveillance programmes to control administration of 19-nortestosterone based anabolic preparations to male horses. These results have led us to consider that the precursors to 19-nortestosterone and 19-norandrost-4-ene-3,17-dione, present in the urine prior to the hydrolysis steps, have the same basic structure except for the functionality at the 17-position. We have used preparative high pressure liquid chromatography (LC) and LC fractionation to separate these precursors from the high amounts of oestrogenic sulphates present in "normal" urine from the entire male horse. Purified fractions have then been studied by liquid chromatography-mass spectrometry (LC-MS) and gas chromatography-mass spectrometry (GC-MS) to identify the precursors.

In vivo biotransformation of metoprolol in the horse and on-column esterification of the aminocarboxylic acid metabolite by alcohols during solid phase extraction using mixed mode columns.

The in vivo biotransformation of metoprolol tartrate in the thoroughbred racehorse was studied after administration of a single oral dose. Metoprolol and its basic and bifunctional phase I metabolites were isolated from urine and plasma using mixed mode solid phase extraction (SPE) cartridges. The isolates were derivatised as trimethylsilyl ethers and analysed by capillary column gas chromatography--positive ion electron ionisation and ammonia chemical ionisation mass spectrometry. Metabolism was primarily confined to the oxidative transformations of the p-(2-methoxy)ethyl substituent. Metoprolol and five phase I metabolites were detected in horse urine. In common with man, rat and dog, the zwitterionic compound (+/-)-4-(2-hydroxy-3-isopropylaminopropoxy)-phenylacetic acid (H117/04), was the principle metabolite in the horse. This compound was readily isolated from both plasma and urine samples by SPE and, in addition, an unusual on-column esterification of the carboxylic acid moiety by alcohols was observed. Metoprolol and the major aliphatic acid metabolite were detected for about 10 and 40 h, respectively in unhydrolysed urine. After enzymatic hydrolysis, the detection period increased to 15 and 60 h, respectively indicating some phase II metabolism of metoprolol and its metabolites in the horse.

N-deethylation and N-oxidation of etamiphylline: identification of etamiphylline-N-oxide in greyhound urine by high performance liquid chromatography-mass spectrometry.

Millophyline-V, (etamiphylline camsylate) was administered intramuscularly to two racing greyhounds at a dose of 10 mg kg(-1). Unhydrolysed pre- and post-administration urine samples were extracted using mixed mode solid phase extraction (SPE) cartridges, the basic isolates derivatised as trimethylsilyl ethers and analysed by positive ion electron ionisation gas chromatography-mass spectrometry (GC/EI+/MS). The parent drug and one metabolite, N-desethyletamiphylline, were detected in urine for up to 72 h. For semi-quantification, urine samples were extracted on-line using a Prospekt sample handler. The analytes retained on the C2 SPE cartridge were eluted by the mobile phase directly on to the analytical high performance liquid chromatography column and analysed by positive ion atmospheric pressure chemical ionisation (LC/APCI+) MS in the multiple selective-ion recording mode. A major peak containing both ions (m/z) 280 and (m/z) 252 was observed. Full scan LC/APCI+/MS of the unknown indicated that the ion at (m/z) 280 was formed by the loss of an oxygen atom [MH+ -->(MH+-O)]. Samples were analysed by positive ion electrospray ionisation LC/MS on two different instruments and the unknown compound was identified as an N-oxide of the tert. nitrogen atom of the 2-(diethylamino)ethyl substituent on N7 of the theophylline nucleus. This compound has not been reported previously either as an in vivo or in vitro metabolite of etamiphylline in any species. Thermal decomposition of the N-oxide could lead to an increase the detection period of the parent drug during routine GC/MS screening of post-competition greyhound urine samples.

Identification of some N-hydroxylated metabolites of (+/-)-3,4-methylenedioxymethamphetamine in horse urine by gas chromatography-mass spectrometry.

1. The in vivo biotransformation of (+/-)-3,4-methylenedioxymethamphetamine [(+/-)-MDMA] in the thoroughbred horse was determined after oral administration. 2. Unconjugated compounds and aglycones were isolated from enzyme-hydrolysed urine by solid-phase extraction using mixed-mode cartridges. The basic isolates were derivatized (trimethylsilylether, TMS) and analysed by positive-ion electron ionization/gas chromatography-mass spectrometry (EI+/GC-MS). MDMA and 10 Phase I metabolites containing the arylisopropylamine substructure were detected. 3. N-Hydroxy amphetamine and N-hydroxymethamphetamine were synthesized. The EI + mass spectra of their O-TMS derivatives showed characteristic alpha-cleavage ions at m/z 132 and 146, respectively, as base peaks. Based upon these data, five putative N-hydroxylated metabolites of MDMA were detected. 4. In the horse, (+/-)-MDMA is metabolized by oxidative N-demethylation to form the primary amine methylenedioxyamphetamine (MDA). Both MDMA and MDA are further metabolized by oxidative demethylenation (cleavage and O-demethylation of the benzodioxole moiety) to form the corresponding catechols, 3-O-methylation to form the guaiacols and N-oxidation of the secondary and primary amine metabolites to form the hydroxylamines. 5. Both phenolic and N-hydroxy metabolites of (+/-)-MDMA undergo Phase II conjugation before excretion in urine.

Detection and identification of carprofen and its in vivo metabolites in greyhound urine by capillary gas chromatography-mass spectrometry.

Rimadyl (carprofen) was administered orally to the racing greyhound at a dose of 2.2 mg kg(-1). Following both alkaline and enzymatic hydrolysis, postadministration urine samples were extracted by mixed mode solid-phase extraction (SPE) cartridges to identify target analyte(s) for forensic screening and confirmatory analysis methods. The acidic isolates were derivatised as trimethylsilyl ethers (TMS) and analysed by gas chromatography-mass spectrometry (GC-MS). Carprofen and five phase I metabolites were identified. Positive ion electron ionisation (EI(+)) mass spectra of the TMS derivatives of carprofen and its metabolites show a diagnostic base peak at M(+)*. -117 corresponding to the loss of COO-Si-(CH(3))(3) group as a radical. GC-MS with positive ion ammonia chemical ionisation (CI(+)) of the compounds provided both derivatised molecular mass and some structural information. Deutromethylation-TMS derivatisation was used to distinguish between aromatic and aliphatic oxidations of carprofen. The drug is rapidly absorbed, extensively metabolised and excreted as phase II conjugates in urine. Carprofen, three aromatic hydroxy and a minor N-hydroxy metabolite were detected for up to 48 h. For samples collected between 2 and 8 h after administration, the concentration of total carprofen ranged between 200 and 490 ng ml(-1). The major metabolite, alpha-hydroxycarprofen was detected for over 72 h and therefore can also be used as a marker for the forensic screening of carprofen in greyhound urine.

In vivo biotransformation of 17 alpha-methyltestosterone in the horse revisited: identification of 17-hydroxymethyl metabolites in equine urine by capillary gas chromatography/mass spectrometry.

The in vivo phase I biotransformation of 17 alpha-methyltestosterone in the horse leads to the formation of a complex mixture of regio- and stereoisomeric C(20)O(2), C(20)O(3) and C(20)O(4) metabolites, excreted in urine as glucuronide and sulphate phase II conjugates. The major pathways of in vivo metabolism are the reduction of the A-ring (di- and tetrahydro), epimerisation at C-17 and oxidations mainly at C-6 and C-16. Some phase I metabolites have been identified previously by positive ion electron ionisation capillary gas chromatography/mass spectrometry (GC/EI + MS) mainly from the characteristic fragmentation patterns of their methyloxime-trimethylsilyl ether (MO-TMS), enol-TMS or TMS ether derivatives. Following oral administration of 17 alpha-methyltestosterone to two castrated thoroughbred male horses, the glucuronic acid conjugates excreted in post-administration urine samples were selectively hydrolysed by E. coli beta-glucuronidase enzymes. Unconjugated metabolites and the steroid aglycones obtained after enzymatic deconjugation were isolated from urine by solid-phase extraction, derivatised as MO-TMS ethers and analysed by GC/EI + MS. In addition to some of the known metabolites previously identified from the characteristic mass spectral fragmentation patterns of 17 alpha-methyl steroids, some isobaric compounds exhibiting a diagnostic loss of 103 mass units from the molecular ions with subsequent losses of trimethylsilanol or methoxy groups and an absence of the classical D-ring fragment ion were detected. From an interpretation of their mass spectra, these compounds were identified as 17-hydroxymethyl metabolites, formed in vivo in the horse by oxidation of the 17-methyl moiety of 17 alpha-methyltestosterone. This study reports on the GC/EI + MS identification of these novel 17-hydroxymethyl C(20)O(3) and C(20)O(4) metabolites of 17 alpha-methyltestosterone excreted in thoroughbred horse urine.

Biotransformation of cyclizine in greyhounds. 1: Identification and analysis of cyclizine and some basic metabolites in canine urine by gas chromatography-mass spectrometry.

1. The partial in vivo biotransformation of Marezine [(cyclizine.HCl); 1-diphenylmethyl-4-methylpiperazine hydrochloride] in the racing greyhound and the excretion of the unconjugated and conjugated (Phase II) basic metabolites of cyclizine in canine urine are reported. 2. Using copolymeric bonded mixed-mode solid-phase extraction cartridges, the basic isolates from both unhydrolysed and enzyme hydrolysed urine samples were isolated, derivatized as trimethylsilyl ethers and analysed by positive-ion electron ionization gas chromatography-mass spectrometry (EI(+)-GC-MS). Selected samples were analysed by positive-ion methane chemical ionization (CI(+))-GC-MS to aid structure elucidation of the putative metabolites. 3. Cyclizine was the major component excreted in post-administration urine. Five substrate-related basic compounds (M1--> M5) were tentatively identified by EI(+)- and CI(+)-GC-MS. The major Phase I metabolite was identified as norcyclizine [1-diphenylmethylpiperazine] (M1), the other metabolites (M2 --> M5) were tentatively identified as monohydroxylated products based on MS data. 4. Cyclizine and the N(4)-desmethyl metabolite (M1) are excreted unconjugated; the other four hydroxylated metabolites are excreted as Phase II conjugates (glucuronides and/or sulphates). Structures of the putative basic metabolites are presented. At least four other basic metabolites were also detected in post-administration urine, but could not be characterized from GC-MS data. 5. All unhydrolysed post-administration urine samples were analysed by selected ion monitoring EI(+)-GC-MS to quantify cyclizine and norcyclizine (M1) using authentic cyclizine as the analyte and chlorcyclizine as the internal standard. The level of M1 is expressed as 'cyclizine equivalents'. The duration of urinary elimination of cyclizine and M1 was obtained from their excretion profiles. 6. From these studies, cyclizine and norcyclizine (M1) would be the target compounds of choice in the development of screening and confirmatory methods for the detection of cyclizine administration to racing greyhounds. Information on any of the other metabolites may also be of some value for confirmatory analysis.

Biotransformation of cyclizine in greyhounds. 2: N(1)-dealkylation and identification of some neutral and phenolic metabolites in canine urine by gas chromatography-mass spectrometry.

1. The in vivo enzymatic Phase I biotransformation of cyclizine (Marezine in the racing greyhound has been shown to proceed via several different pathways. Aromatic and heterocyclic oxidation and the N(4)-demethylation of cyclizine lead to the formation of unconjugated and conjugated (Phase II) basic metabolites excreted in canine urine. 2. Enzymatic N(1)-dealkylation of cyclizine and its basic metabolites leads to the formation of the neutral and phenolic Phase I metabolites containing the diphenylmethane/methylene substructures. Further, Phase I metabolism of the neutral metabolites could also lead to the formation of several secondary phenolic products. These neutral and phenolic compounds are then excreted as unconjugated and Phase II conjugates in greyhound urine. 3. Following enzymatic deconjugation of selected post-Marezine administration urine samples from two greyhounds, the total aglycones were extracted and separated into neutral/acidic and basic fractions using copolymeric mixed-mode solid-phase extraction cartridges. 4. The neutral/acid isolates were further separated into neutral and phenolic fractions by column chromatography on a lipophilic strong anion-exchanger gel, triethylaminohydroxypropyl Sephadex LH-20 in OH(-) form. 5. The individual neutral and phenolic fractions obtained from the acid/neutral isolate were derivatized as trimethylsilyl ethers and analysed by positive-ion electron ionization gas chromatography-mass spectrometry (EI(+)-GC-MS). 6. Three compounds, diphenylmethane (M1), benzophenone (or diphenyl ketone, M2) and benzhydrol (M3), were identified in the neutral isolates by comparison of their EI(+) mass spectra with authentic standards. At least seven secondary compounds containing the functionalized diphenylmethylene substructure were detected in the phenolic isolates. As no authentic compounds are available, the structures of these putative metabolites (M4--> M10) were elucidated from an interpretation of the EI(+)-GC-mass spectra of their TMS derivatives.

Detection of fenspiride and identification of in vivo metabolites in horse body fluids by capillary gas chromatography-mass spectrometry: administration, biotransformation and urinary excretion after a single oral dose.

Studies related to the in vivo biotransforrmation and urinary excretion of fenspiride hydrochloride in the horse are described. After oral administration, the drug is metabolised by both phase I functionalisation and phase II conjugation pathways. Following enzymatic deconjugation, fenspiride and its phase I metabolites were isolated from post-administration biofluids using bonded co-polymeric mixed mode solid-phase extraction cartridges to isolate the basic compounds. Following trimethylsilylation (TMS), the parent drug and metabolites were identified by capillary gas chromatography-mass spectrometry (GC-MS). Fenspiride (A) and seven metabolites (B-->G) arising from oxidation on both the aromatic and heterocyclic substructures were detected in urine. The positive ion electron ionisation mass spectra of the TMS derivatives of fenspiride and its metabolites provided useful information on its metabolism. Positive ion methane chemical ionisation-GC-MS of the derivatives provided both derivatised molecular mass and structural information. Unchanged fenspiride can be detected in post-administration plasma and urine samples for up to 24 h. Maximum urinary levels of 100-200 ng ml(-1) were observed between 3 and 5 h after administration. After enzymatic deconjugation, the major phenolic metabolite (G) can be detected in urine for up to 72 h. This metabolite is the analyte of choice in the GC-MS screening of post-race equine urine samples for detection of fenspiride use. However, a distinct difference was observed in the urinary excretion of this metabolite between the thoroughbred horses used in UK study and the quarterbred and standardbred horses used for the USA administrations.

Studies into aromatase activity associated with fetal allantochorionic and maternal endometrial tissues of equine placenta. Identification of metabolites by gas chromatography mass spectrometry.

Maternal endometrial and fetal allantochorionic tissues were separated manually from the placentae of seven healthy thoroughbred and three pony mares, ranging in gestational age from 100 to 318 days. The homogeneity of subcellular fractions prepared from these tissues was assessed initially using the marker enzymes, succinate dehydrogenase, NADPH cytochrome C reductase and lactate dehydrogenase for the mitochondrial, microsomal and cytosolic fractions, respectively. Light microscopy and histochemical analysis demonstrated that the separated fetal allantochorionic membrane, which is made up of allantoic and chorionic epithelia, contained no significant contamination of maternal tissues. The maternal endometrium, however, was found to contain appreciable amounts of fetal chorion torn off during the separation process. Tissue homogenates and subcellular fractions were incubated with testosterone together with [4-(14)C] and [(2)H5 or (2)H3] labelled analogues in either an NADPH (1 mM) or a NADPH-regenerating environment; control experiments (without additional cofactor) were also performed. After extraction of the tissue homogenates, neutral and phenolic (oestrogen) unconjugated steroids were separated by column chromatography. Radiolabelled studies revealed that in allantochorionic tissue incubations 67-77% of testosterone was converted to oestrogenic material, subcellular fractionation indicating that oestrogen production was largely confined to the microsomal fraction and time-course studies showing that the rate of formation appeared to be linear up to 90 min. In contrast, only 5-25% conversion occurred using maternal endometrial tissues, which could be accounted for by the contaminating presence of fetal chorion. No oestrogen production was detected in control incubations. These radiolabelled studies demonstrate that aromatase activity is located on the fetal allantochorionic surface and, together with the histochemical data, further delineate this activity to the chorion in mature equine placenta. Gas chromatographic-mass spectrometric (GC-MS) analysis of the phenolic extracts from allantochorionic tissue homogenate incubations indicated the presence of substrate-derived oestradiol-17beta (E2), 6-oxo-oestradiol-17beta (6-oxo-E2) and 6beta-hydroxyoestradiol-17beta (6beta-OH-E2). Whereas all three oestrogens were identified as metabolites from testosterone in incubations performed using allantochorionic tissue homogenates and post-mitochondrial suspensions (PMS), only E2 was identified from incubations performed using microsomal fractions prepared from this tissue. We conclude that both the microsomal and cytosol fractions are required for the conversion of E2 to the 6-oxygenated species in vitro. Using stable isotope-labelled substrates and GC-MS analysis the mechanism of formation of these metabolites from these in vitro incubation studies may be inferred. GC-MS analysis of the neutral extracts from allantochorionic tissue homogenate incubations confirmed the presence of small quantities of substrate-derived 5(10)-oestrenediols. No substrate-derived 5(10)-oestrene-3,17-diols were detected in extracts from microsomal preparations incubated in the absence of cytosol. These data suggest that demethylation of C19 steroids to produce C18 neutral steroids may require the synergistic action of enzymic activities that appear to reside both in the microsomal and cytosolic fractions of equine allantochorionic tissues.

Detection of quinine and its metabolites in horse urine by gas chromatography-mass spectrometry.

After oral administration of quinine sulfate to a thoroughbred mare, seven urine samples were obtained over a 45.5 h period. Using gas chromatography -electron impact ionization and positive-ion chemical ionization mass spectrometry, quinine and five putative metabolites were detected and tentatively identified in enzyme-hydrolysed post-administration urine; all metabolites involved some form of oxidation. The parent drug could be detected for about 16 h and some phase I biotransformation products for up to 40 h post-administration.

Methylprednisolone hemisuccinate and metabolites in urine from patients receiving high-dose corticosteroid therapy.

A reversed-phase high-performance liquid chromatographic (RP-HPLC) method for the measurement of methylprednisolone hemisuccinate (MPHS) and its metabolites methylprednisolone (MP), 20-alpha- (20a-HMP), and 20-beta-hydroxymethylprednisolone (20b-HMP) in urine is described. The metabolites were extracted from urine samples using Extrelut columns and eluted with ethylacetate. The mobile phase for RP-HPLC comprised methanol:citrate buffer:tetrahydrofuran (30:65:5, vol/vol/vol) with UV detection at 251 nm. Fractions were collected, pooled and the metabolites present were identified by gas chromatography-mass spectrometry and normal-phase HPLC (NP-HPLC). By RP-HPLC 30 +/- 7.3% (mean +/- 1 SD) of the dose was detected in the 0-24 h urine sample following a 1 g MPHS infusion to patients with rheumatoid arthritis; MPHS contributed 9.9 +/- 5.0%, MP 12.1 +/- 2.9%, 20a-HMP 7.8 +/- 2.2%, and 20b-HMP 1.0 +/- 0.3%, respectively. A further 1.0 +/- 0.9% of the administered dose was detected in urine collected 24-48 h postinfusion.

Screening and confirmatory analysis of beta-agonists, beta-antagonists and their metabolites in horse urine by capillary gas chromatography-mass spectrometry.

A method for the screening and confirmatory analysis of beta-agonists and -antagonists in equine urine is described. Following initial enzymic hydrolysis, the basic drugs and metabolites are extracted using Clean Screen DAU or Bond Elut Certify cartridges, and analysed as their trimethylsilyl ether or 2-(dimethyl) silamorpholine derivatives by capillary gas chromatography-mass spectrometry. The method proved to be very sensitive and selective for basic drugs. After administration of therapeutic doses of propranolol, metoprolol, timolol, isoxsuprine and clenbuterol to thoroughbred horses, the parent compound/metabolites could be detected in urine for upto 14-120 h depending on the drug.

The use of stable isotopes and gas chromatography/mass spectrometry in the identification of steroid metabolites in the equine.

Stable isotope gas chromatography/mass spectrometry has been used successfully in the elucidation of structures of urinary steroid metabolites in the horse and in the identification of metabolites isolated from in vivo perfusion and in vitro incubation studies using equine tissue preparations. Deuterium-labeled steroids, testosterone, dehydroepiandrosterone, and 5-androstene-3 beta,17 beta-diol have been synthesized by base-catalyzed isotope exchange methods and the products characterized by gas chromatography/mass spectrometry. [16,16(-2)H2]Dehydroepiandrosterone (plus radiolabeled dehydroepiandrosterone) was perfused into a testicular artery of a pony stallion and was shown to be metabolized into 2H2-labeled testosterone, 4-androstenedione, isomers of 5-androstene-3,17-diol, 19-hydroxytestosterone, and 19-hydroxy-4-androstenedione. In further studies, equine testicular minces have been incubated with 2H2-labeled and radiolabeled dehydroepiandrosterone and 5-androstene-3 beta, 17 beta-diol. The metabolites, whose identity was confirmed by stable isotope gas chromatography/mass spectrometry, proved the interconversion of the two substrates, as well as formation of testosterone and 4-androstenedione. The aromatization of dehydroepiandrosterone was also confirmed, together with the formation of an isomer of 5(10)-estrene-3,17-diol from both substrates showing 19-demethylation without concomitant aromatization. In studies of the feto-placental unit, the allantochorion was shown to aromatize [2H5]testosterone to [2H4]estradiol, the loss of one 2H from the substrate being consistent with aromatization of the A ring. The formation of 6-hydroxyestradiol was also confirmed in this study. The same technique has been valuable in determining the structure of two metabolites of nandrolone isolated from horse urine.(ABSTRACT TRUNCATED AT 250 WORDS)

Comparison of the use of mass spectrometry and methylene unit values in the determination of the stereochemistry of estranediol, the major urinary metabolite of 19-nortestosterone in the horse.

The stereochemistry of an isomer of 5-estrane-3,17 alpha-diol, the major metabolite of 19-nortestosterone in horse urine has been established by the use of methylene unit (MU) values. The empirical MU values of the bis-trimethylsilyl (TMS) derivatives of the eight available isomers of 5-androstane-3,17-diol and four isomers of 5-estrane-3,17 beta-diol were determined by capillary gas chromatography using three different columns. From this data the theoretical MU values for the bis-TMS derivatives of the four 5-estrane-3,17 alpha-diol isomers were predicted. Comparison of the experimentally determined MU value of the urinary metabolite with those of the theoretical values established the correct stereochemistry of the steroid. This method has been compared with the use of gas chromatography-mas spectrometry in the determination of the stereochemistry of unknown metabolites.

Steroids in equine testes: the identification of endogenous 19-hydroxy and 19-nor neutral steroids by gas chromatography--mass spectrometry.

After homogenization of testicular tissue from stallions aged 1, 2 and 5 years, the unconjugated and conjugated steroids were isolated by a combined solvent-solid extraction procedure. The conjugates were further separated into glucuronides and sulphates by chromatography using Sephadex LH-20. After enzyme hydrolysis and solvolysis of the respective conjugate classes, the three extracts, unconjugated steroids, aglycones and solvolysed sulphates, were purified by chromatography using Kieselgel 60H columns. Five fractions were resolved from each extract; an aliquot of each fraction was derivatized to form the methoxime-trimethylsilyl ethers and the steroids were identified by combined gas chromatography-mass spectrometry. The results have shown that in stallion testes (1) steroidogenesis proceeds by both the 4-ene and the 5-ene pathways, (2) age-linked changes occur in both unconjugated and sulphoconjugated steroid fractions and (3) 19-hydroxy androgens and the 19-nor (C18) neutral steroids (19-norandrostenedione and 19-nortestosterone) are detected only in the unconjugated fraction whereas oestrene, the isomers of oestradiol and of 5(10)-oestrene-3,17-diol are the only steroids detected in the sulphoconjugate fraction. It is suggested that the unconjugated 19-oxygenated androgens present in stallion testes are converted to 19-nor neutral steroids by a reverse aldol reaction and a mechanism showing the putative intermediates in their formation is illustrated.

Biotransformation of 1-dehydrotestosterone in the equine male castrate: identification of the neutral unconjugated and glucuronic acid conjugated metabolites in horse urine.

The in vivo biotransformation of (1,2(n)-3H)1-dehydrotestosterone was studied in three equine male castrates and a number of neutral metabolites were identified in the urinary unconjugated and glucuronic acid conjugate fractions by gas chromatography/mass spectrometry. The metabolites were extracted from aliquots of the 0-24 h urine samples by Amberlite XAD-2 and separated into combined unconjugated plus glucuronic acid conjugated and sulphoconjugated fractions by Sephadex LH-20 column chromatography. After enzymatic hydrolysis of the glucuronides, the crude neutral unconjugated steroids plus the aglycones were partially purified by Kieselgel H chromatography and identified as their methyloxime trimethylsilyl derivatives. In the unconjugated fraction, the major metabolites were isomers of androsta-1,4-diene-6,16,17-triol-3-one. In the aglycone fraction a small amount of the parent steroid was present but the major metabolite was the 17 alpha isomer androsta-1,4-dien-17 alpha-ol-3-one. Other metabolites containing the 1,4-dien-3-one group were isomers of androsta-1,4-diene-16,17-diol-3-one and androsta-1,4-diene-6,16-diol-3-one. Reduction of the 4-ene functionality leading to the formation of 5-androst-1-en-16-ol-3,17-dione, 5-androst-1-ene-16,17-diol-3-one and of the 1-ene functionality leading to the formation of testosterone and its further reduction leading to the formation of C19O2 and C19O3 androstane metabolites was observed. Some interesting features on the electron impact fragmentations of the methyloxime trimethylsilyl derivatives of steroids containing a 1,4-dien-3-one group were also observed.