Metabolism of the vitamin D analog EB1089 by cultured human cells: redirection of hydroxylation site to distal carbons of the side-chain.

1(S),3(R)-dihydroxy-20(R)-(5'-ethyl-5'-hydroxy-hepta-1'(E),3' (E)-dien-1'-yl)-9,10-secopregna-5(Z),7(E),10(19)-triene (EB1089) is a novel synthetic analog of 1 alpha,25-dihydroxyvitamin D [1,25-(OH)2D3] with potential for use in the treatment of hyperproliferative disorders. It has an altered side-chain structure compared to 1,25-(OH)2D3, featuring 26,27 dimethyl groups, insertion of an extra carbon atom (24a) at C-24, and two double bonds at C-22,23 and C-24,24a. In vitro metabolism of EB1089 was studied in a human keratinocyte cell model, HPK1A-ras, previously shown to metabolize 1,25-(OH)2D3. Four metabolites were formed, all of which possessed the same UV chromophore as EB1089, indicating the retention of the side-chain conjugated double bond system. Two metabolites were present in sufficient quantities to identify them as 26-hydroxy EB1089 (major product) and 26a-hydroxy EB1089 (minor product), based on mass spectral analysis and cochromatography with synthetic standards. Similar metabolites were generated in vivo and using a liver postmitochondrial fraction in vitro (Kissmeyer et al., companion paper). Studies with the human hepatoma Hep G2 gave rise to 2 isomers of 26-hydroxy EB1089. Studies using ketoconazole, a general cytochrome P450 inhibitor, implicated cytochrome P450s in the formation of the EB1089 metabolites. COS-1 transfection cell experiments using vectors containing CYP27 and CYP24 suggest that these cytochrome P450s are probably not involved in 26- or 26a-hydroxylation of EB1089. Other experiments that examined the HPK1A-ras metabolism of related analogs containing only a single side-chain double bond: 1(S),3(R)-dihydroxy-20(R)-(5'-ethyl-5'-hydroxy-hepta-1' (E)-en-1'-yl)-9,10-secopregna-5(Z),7(E),10(19)-triene (MC1473; double bond at C-22,23) and 1(S),3(R)-dihydroxy-20(R)-(5'-ethyl-5'-hydroxy-hepta-3'(E)-en-1'-yl)-9, 10-secopregna-5(Z),7(E),10(19)-triene (MC1611; double bond at C-24,24a) revealed that the former compound was subject to 24-hydroxylation and the latter compound was mainly 23-hydroxylated. Metabolism experiments involving EB1089, MC1473, and MC1611 in competition with [1 beta-3H]1,25-(OH)2D3 in HPK1A-ras confirmed that CYP24 is probably not involved in the metabolism of EB1089 whereas, in the case of MC1473 and MC1611, it does appear to carry out side-chain hydroxylation. Our interpretation is that the conjugated double bond system in the side-chain of EB1089 is responsible for directing the target cell hydroxylation to the distal positions, C-26 and C-26a. We conclude that EB1089 is slowly metabolized via unique in vitro metabolic pathways, and that these features may explain the relative stability of EB1089 compared to other analogs in vivo.

Use of gas chromatographic-mass spectrometric techniques in studies of androst-16-ene and androgen biosynthesis in human testis; cytosolic specific binding of 5alpha-androst-16-en-3-one.

Homogenates of histologically normal human testis from three men were incubated separately with pregnenolone, 16-dehydropregnenolone, 5alpha-pregnane-3,20-dione, 3beta-hydroxy-5alpha-pregnan-20-one and androsta-5,16-dien-3beta-ol (androstadienol) in the presence of NADPH in a study of androst-16-ene and androgen biosynthesis. After the addition of internal standards and initial extraction and purification, metabolites were identified using gas chromatography-mass spectrometry (GC-MS) and monitoring selectively for three principal ions in each case at the appropriate GC retention time. Quantification was achieved by comparison with calibration lines for authentic steroids, together with the appropriate internal standards, prepared by monitoring three ion fragments for each analyte. In all experiments, androstadienol was found to be the major androst-16-ene metabolite of pregnenolone (seven times the control, i.e. endogenous, quantity; 19.8 +/- 3 ng/100 mg homogenate protein, mean +/- SEM, n = 9). Pregnenolone was also converted to androsta-4,16-dien-3-one (androstadienone) with three times the endogenous quantity (44 +/- 10 ng/100 mg homogenate protein, mean +/- SEM, n = 9) being formed. The formation of testosterone occurred only in trace amounts in the incubations of testis taken from one man (a 69-yr-old) but appreciable yields (six times endogenous levels 90 +/- 7 ng/100 mg homogenate protein, mean +/- SEM, n = 9) were found with testes from two younger men. Only traces of 5alpha-dihydrotestosterone were detected. Using androstadienol as the substrate, androstadienone was shown to be the major metabolite (approximately 10 times greater than control incubations) together with 5alpha-androst-16-en-3alpha- and 3beta-ols at approximately twice the endogenous quantities (5 ng/100 mg homogenate protein). In some incubations with androstadienol, 5alpha-androst-16-en-3-one (5alpha-androstenone) was formed (32 +/- 1 ng/100 mg homogenate protein/h; mean +/- SEM, n = 3); surprisingly, no endogenous 5alpha-androstenone could be detected. No evidence was obtained for the production of testosterone or 5alpha-DHT from androstadienol. Using cytosolic fractions of human testis, specific (displaceable) binding of 5alpha-androstenone was determined, with binding sites of approximately 200 fmol/mg tissue and a Ka of approximately 8 nmol/l.

Breath-alcohol concentration may not always reflect the concentration of alcohol in blood.

A case is described of a 37-year-old man who was breath tested by the U.K. police following a traffic accident and was found to have a breath-alcohol concentration of 70 micrograms/100 mL--twice the U.K. legal limit. The defendant protested vigorously that he had not consumed sufficient alcohol to account for this excessive reading, and Widmark calculations, assuming his account of the alcohol consumed was accurate, suggested his contention was possibly correct. No evidence was obtained suggesting that the Lion Intoximeter used for the breath analysis was anything other than accurate. Alcohol loading tests were therefore carried out in the laboratory on two separate occasions, showing that breath-alcohol concentrations grossly in excess of the legal limit (140 micrograms/100 mL) were obtained when the amount of alcohol administered would have been expected to give a theoretical maximum of 35 micrograms/100 mL. A blood sample taken at the point when the breath-alcohol concentration was 70 micrograms/100 mL was shown to contain 54 mg of alcohol/100 mL of blood. Dental examination of the defendant showed that he had had extensive work carried out, including three bridges. A possible explanation, therefore, for these anomalous results is that the excessive breath-alcohol concentrations might be due to mouth alcohol retained in the bridges or periodontal spaces, although a careful fraud by the subject of this report cannot be ruled out.(ABSTRACT TRUNCATED AT 250 WORDS)

In vivo dihydrotachysterol2 metabolism in normal man: 1 alpha- and 1 beta-hydroxylation of 25-hydroxydihydrotachysterol2 and effects on plasma parathyroid hormone and 1 alpha,25-dihydroxyvitamin D3 concentrations.

It has recently been shown that in the rat, dihydrotachysterol (DHT) is extensively metabolized in the side-chain in vivo along pathways similar to those of vitamin D. In addition 25-hydroxy-DHT2 [25OHDHT2] is hydroxylated at C1, producing both 1 alpha- and 1 beta- hydroxy compounds. An in vivo study in 1988 demonstrated that in normal adult subjects receiving oral DHT2, plasma 1 alpha,25-dihydroxyvitamin D [1,25-(OH)2D] concentrations fell, but with unchanged plasma PTH levels. Down-regulation of 1,25-(OH)2D3 production by 25-(OH)DHT2 or some other unknown metabolite was also suggested as an explanation for these observations. To investigate whether either of the newly characterized 1 alpha,25- or 1 beta,25-(OH)2DHT2 was formed in vivo in normal man, DHT2 (approximately 1 mg/day, orally) was administered to healthy volunteers (three males and one female). Plasma was analyzed by high performance liquid chromatography and gas chromatography-mass spectrometry, demonstrating the formation of both 1 alpha,25- and 1 beta,25-(OH)2DHT2 in vivo in normal human subjects. Plasma levels of 1,25-(OH)2D3, PTH, ionized and total calcium, inorganic phosphate, and alkaline phosphatase were monitored. The plasma concentrations of DHT2, 25OHDHT2, and 1 alpha,25- and 1 beta,25-(OH)2DHT2 were measured by gas chromatography-mass spectrometry. In all volunteers, plasma ionized calcium increased slightly during DHT2 administration; 1,25-(OH)2D3 and PTH concentrations fell. Plasma levels of DHT2 and its metabolites rose over the same period. The average fall in the level of plasma 1,25-(OH)2D (60-70 pmol/L) was mirrored by a rise in the concentration of 1 alpha,25-(OH)2DHT2 (550 pmol/L). This ratio is appropriate, because it has previously been shown that in a reconstituted COS cell, 1 alpha,25-(OH)2DHT3 has roughly one tenth the potency of 1,25-(OH)2D3. At maximum concentration, the ratios of DHT2/25OHDHT2/1 beta,25-(OH)2DHT2/1 alpha,25-(OH)2DHT2 were approximately 10:1:2:0.1. The concentration of 1 beta,25-(OH)2DHT2 was greater than that of 25OHDHT2, and the ratio of 1 alpha,25- to 1 beta,25-(OH)2DHT2 (1:20) was substantially lower than that in rat plasma (3:10). The data presented here suggest that the active DHT2 metabolite in man is 1 alpha,25-(OH)2DHT2 and that the fall in plasma 1,25-(OH)2D seen during DHT therapy may be partly the result of suppressed PTH secretion.

In vivo metabolism of the vitamin D analog, dihydrotachysterol. Evidence for formation of 1 alpha,25- and 1 beta,25-dihydroxy-dihydrotachysterol metabolites and studies of their biological activity.

Dihydrotachysterol (DHT), a reduced vitamin D analog in which the A-ring has been rotated through 180 degrees is a biologically active molecule which can be used to study the structural requirements for the calcemic and cell differentiating properties of the vitamin D hormone, 1 alpha,25-dihydroxyvitamin D3 (1 alpha,25-(OH)2D3), as well as to investigate the specificity of the enzyme systems that catalyze the formation of this hormone. In this study we showed that dihydrotachysterol was metabolized in vivo into a significant polar metabolite observed on straight-phase high performance liquid chromatography (HPLC) which subsequently split into two peaks on reverse-phase HPLC. These two metabolites were identified by HPLC and gas chromatography-mass spectrometry techniques as 1 alpha,25-(OH)2DHT and 1 beta,25-(OH)2DHT. This pair of metabolites was formed from either DHT2 or DHT3. Standard 1 alpha,25-(OH)2DHTs were generated in vitro from chemically synthesized 1-hydroxydihydrotachysterol precursors using a liver hepatoma cell system. Both 1 alpha,25-(OH)2D2 and 1 alpha,25-(OH)2DHT3 showed a binding affinity to the mammalian vitamin D receptor only 50-100 less than 1 alpha,25-(OH)2D3 whereas 1 beta,25-(OH)2DHTs showed poor binding. On the other hand 1 beta,25-(OH)2DHT3 bound to the rat vitamin D transport protein (DBP) with stronger affinity than did 1 alpha,25-(OH)2DHT3. When tested in a COS-1 cell transfection assay system using a rat osteocalcin vitamin D responsive element coupled to a growth hormone reporter gene, 1 alpha,25-(OH)2DHT3 showed a biological activity only 10 times lower than 1 alpha,25-(OH)2D3. It is therefore suggested that 1 alpha,25-(OH)2DHT probably represents the metabolite of DHT responsible for some of its in vivo effects although we cannot rule out in vivo effects of other metabolites identified. Our studies suggest that 1 alpha,25-dihydroxylated DHTs represent a promising novel group of vitamin D analogs worthy of study for cell differentiation as well as calcemic properties.

GC-MS studies of 16-androstenes and other C19 steroids in human semen.

Human semen was examined for the presence of 16-androstenols, 16-androstenones and androgens. Extracts were analysed by gas chromatography-mass spectrometry after derivatization of steroids under study. In a qualitative study, 5 alpha-androst-16-en-3 alpha- and 3 beta-ols, 5,16-androstadien-3 beta-ol and 5 alpha-androstan-3 beta-ol were detected in a semen pool A. Hydroxyl groups were converted to tert-butyldimethylsilyl ethers, the ions selected for monitoring being [M-57]+, consistent with loss of the tert-butyl group. For a more detailed quantitative study, a second semen pool B was used. In this case, all hydroxyl groups were converted to trimethylsilyl ethers, while oxo groups were not derivatized. As with semen pool A, separation of steroids was achieved using capillary gas chromatography with appropriate temperature programming. Quantification was carried out by mass spectrometry using selected ion monitoring of two significant ions and appropriate internal standards. The following steroids were identified at the concentrations indicated: 5 alpha-androst-16-en-3 alpha- and 3 beta-ols and 5,16-androstadien-3 beta-ol (concentration range, 0.5-0.7 ng/ml). 5 alpha-Androst-16-en-3-one and 4,16-androstadien-3-one were also present at levels of 0.7-0.9 ng/ml. Two androgens, testosterone and 5 alpha-dihydrotestosterone were found at concentrations of 0.5 and 0.3 ng/ml, respectively. These data, showing the presence of 16-androstenes and androgens in human semen, appear to be consistent with testicular formation of these steroids. The possible significance of the odorous 16-androstenes is discussed.

The use of octadecyl-bonded microparticulate silica in the separation of free and bound fractions during saturation analysis of vitamin D metabolites.

The use of octadecyl-bonded microparticulate silica to separate free and bound fractions during the saturation analysis of 25-hydroxyvitamin D and 1,25-dihydroxyvitamin D has been investigated. A slurry of octadecyl-bonded silica in an appropriate incubation buffer was prepared and used in parallel with a conventional dextran-coated charcoal suspension in several assay procedures. Standard curves, non-specific binding and plasma values were compared. A competitive protein binding assay for 25-hydroxyvitamin D and two radioreceptor assays and one radioimmunoassay for 1,25-dihydroxyvitamin D were investigated. In most cases the octadecyl-bonded silica preparation gave the more favourable results; its action was rapid, time- and temperature-independent, and it produced low non-specific binding and higher B0 values in all the assays examined. It was in our hands easier to use than dextran-coated charcoal. The use of octadecyl-bonded silica is recommended as an efficient agent for the separation of free and bound fractions in the saturation analysis of vitamin D metabolites.

Polar metabolites of dihydrotachysterol3 in the rat. Comparison with in vitro metabolites of 1 alpha,25-dihydroxydihydrotachysterol3.

The metabolism of 25-hydroxydihydrotachysterol3 (25-OH-DHT3) to more polar metabolites was investigated in vivo in the rat and compared with the in vitro metabolism of 1 alpha,25-dihydroxy-DHT3 (1 alpha,25-(OH)2DHT3) in the osteosarcoma cell line UMR 106. Rats were given 2 mg of DHT3 in divided doses at 0 and 6 hr. Plasma was collected 24 hr after the initial dose, extracted, separated, and polar metabolites purified by HPLC. A number of polar metabolites were formed in vivo with mass spectrometric characteristics which suggested that they were derived from a previously isolated metabolite of 25-OH-DHT3, T3/H. Of these, four were isolated and identified as 24-oxo-T3/H, 24-hydroxy-T3/H, 26-hydroxy-T3/H and the 26,23-lactone of T3/H. In view of the identification of T3/H as a mixture of 1 alpha- and 1 beta-hydroxylated 25-OH-DHT3, osteosarcoma cells (UMR 106) were incubated with chemically synthesized 1 alpha,25-(OH)2DHT3 in an attempt to determine from which component of the T3/H mixture these metabolites were derived. Again, more polar metabolites were formed and five of these were isolated by lipid extraction, purified by HPLC and identified as 24-oxo-1 alpha,25-(OH)2DHT3, 1 alpha,23,25-(OH)3DHT3, 24-oxo-1 alpha,23,25-(OH)3DHT3, 1 alpha,24,25-(OH)3DHT3 and 1 alpha,25,26-(OH)3DHT3. Three of the in vitro metabolites were similar to those found in rat plasma but only two of these metabolites were available in sufficient amounts to allow comparison. The chromatographic characteristics, using HPLC and gas chromatography, of these two pairs of metabolites (24-oxo and 24-hydroxy) were examined and it was demonstrated that they were not the same. It is therefore suggested that the polar metabolites formed in vivo are in fact metabolites of the T3/Hb component (1 beta,25-(OH)2DHT3) rather than the T3/Ha component (1 alpha,25-(OH)2DHT3). Supporting evidence for this suggestion was obtained when a small quantity of 1 beta,25-(OH)2DHT3, obtained from chemically synthesized 1 beta-OH-DHT3 by incubation with Hep 3B cells, was further incubated in the osteosarcoma UMR 106 system. Preliminary studies indicated that the putative 24-oxo and 24-hydroxy metabolites formed from 1 beta,25-(OH)2DHT3 had chromatographic and mass spectral properties almost indistinguishable from those of corresponding metabolites of T3/H formed in vivo. All the metabolites formed in vivo and in vitro are components of two metabolic pathways described previously for 25-hydroxyvitamin D3 and also for 25-OH-DHT3.

The metabolism of dihydrotachysterols: renal side chain and non-renal nuclear hydroxylations in vivo and in vitro.

The metabolism of dihydrotachysterol (DHT), a hydrogenated analogue of vitamin D, has been studied in vivo using man and rat and in vitro using the perfused rat kidney, and hepatoma (3B) and osteosarcoma (UMR-106) cell lines. In vivo a large number of metabolites appeared in the plasma of rats given DHT2 and DHT3. Of particular interest was a compound more polar than 25-hydroxy-DHT, which has been designated compound H. Further study of this compound showed that it was composed of two components, one (Ha) being in much lower concentration than the other (Hb). The production of T2/H (peak H from DHT2) was demonstrated in human plasma after administration of oral DHT2. Comparison of the metabolites formed in vivo with those isolated from the rat kidney perfused with 25-hydroxy-DHT3 in vitro showed that 25-hydroxy-DHT3 was metabolized along two metabolic pathways previously described for vitamin D, culminating in the production of 25-hydroxy-DHT3-23,26-lactone and 23,25-dihydroxy-24-oxo-DHT3. The osteosarcoma cell line metabolized 25-OH-DHT3 in vitro along the same two metabolic pathways already demonstrated in the perfused rat kidney. More polar metabolites than compound H seen in rat plasma in vivo were shown to be metabolites of compound H and similar metabolites were also produced in the osteosarcoma cell line from chemically synthesized 1 alpha,25-dihydroxy-DHT3. The hepatoma cell line 25-hydroxylated DHT and no feed-back inhibition was observed. Use of the hepatoma cell to 25-hydroxylate a number of chemically synthesized 1-hydroxy-DHTs indicated that compound Ha was indistinguishable from 1 alpha,25-dihydroxy-DHT whereas compound Hb is possibly 1 beta,25-dihydroxy-DHT. Studies with the VDR in both chick gut and calf thymus indicated that 1 alpha,25-dihydroxy-DHT is very effective in displacing radiolabelled 1 alpha,25-dihydroxyvitamin-D3 and is thus most likely to be the calcaemic metabolite of DHT.

Gas chromatography-mass spectrometry in the investigation of on-column dehydration of steroid hormones during gas-liquid chromatography.

Some underivatized steroids when injected onto conventional packed columns for gas-liquid chromatography underwent varying degrees of dehydration. This problem was traced to the presence of small pieces of broken glass on the top of the column at the point of injection. This observation provoked an examination of the effect of pre-column dehydration on a number of different types of steroids. Powdered aluminium was placed in the injection liner of a Hewlett-Packard gas chromatograph fitted with an HP1 capillary column connected to a mass selective detector, and injections were made using a new high temperature septumless injection system at temperatures between 200 and 400 degrees C. 5 alpha-androstan-3 alpha-ol, a simple monofunctional C19 steroid chosen as a model to establish optimum conditions, underwent dehydration at injection temperatures greater than 250 degrees C and the product reached a maximum at 400 degrees C when no unchanged steroid was present. Monohydroxylated androgens and oestrogens underwent dehydration at 400 degrees C producing products whose mass spectra indicated they were monenes, although the position of the double bond could not be assigned. Polyfunctional androgens and oestrogens and corticosteroids underwent complex changes producing a number of products some of whose structures could not be determined. The dehydration products had the advantage that they had relatively intense high mass ions and for suitable steroids this might provide enhanced sensitivity of detection during mass fragmentography. In such cases dehydration was reproducible and straight line standard curves were obtained. C27 and C28 secosteroids (vitamins D2 and D3) and some of their metabolites (e.g. 25-hydroxyvitamin D) underwent efficient dehydration, again producing products with intense molecular ions. In the case of 24,25-dihydroxyvitamin D3 and 25,26-dihydroxyvitamin D3, dehydration produced different products which were easily resolved in the chromatographic system used. Dehydration of vitamin D metabolites eliminates the need for derivatization and gives enhanced sensitivity of measurement by gas chromatography-mass spectrometry.

Stable isotope-labeled vitamin D, metabolites and chemical analogs: synthesis and use in mass spectrometric studies.

Methods for the measurement of vitamin D and its metabolites using stable isotope-labeled internal standards and mass spectrometry are reviewed. The synthesis of both labeled and unlabeled standards is illustrated, and details of the synthesis of (26,26,27,27,27(-2)H5)-25,26-dihydroxyvitamin D3 and (28,28,28(-2)H3)-24,25-dihydroxyvitamin D2 are given. The use of in vitro biologic systems for the production of further metabolites of deuterated 25-hydroxyvitamin D3 is discussed. Use of deuterated 25-hydroxydihydrotachysterol3 as a substrate in the isolated perfused rat kidney has provided valuable data for the assignment of structure to a number of metabolites of 25-hydroxydihydrotachysterol3 formed in this system.

Plasma 24,25-dihydroxyvitamin D3 concentrations in X-linked hypophosphatemic mice: studies using mass fragmentographic and radioreceptor assays.

Previous studies have suggested that both plasma 24,25-dihydroxyvitamin D [24,25-(OH)2D] concentrations and renal 25-hydroxyvitamin D-24-hydroxylase activity are increased in mice with X-linked hypophosphatemia (Hyp mice). However, because the plasma levels of 24,25-(OH)2D seemed surprisingly high, we repeated these assays using two different techniques. Mass fragmentographic and radioreceptor assays were employed to compare the plasma concentrations of 25-hydroxyvitamin D (25-OHD) and 24,25-(OH)2D in normal mice with those in Hyp mice. These assays yielded 24,25-(OH)2D concentrations much lower than previously reported in mice (both normal and Hyp). The concentrations of 25-OHD3 and 24,25-(OH)2D3, determined by mass fragmentography, were lower in Hyp mice than in controls [25-OHD3, 9.7 +/- 0.4 versus 14.6 +/- 0.6 ng/ml, p less than 0.01; 24,25-(OH)2D3, 7.1 +/- 0.3 versus 10.4 +/- 0.4 ng/ml, p less than 0.01]. Plasma 25-OHD concentration was the main determinant of plasma 24,25-(OH)2D, and the ratio of 25-OHD3 to 24,25-(OH)2D3 obtained from mass fragmentographic measurements did not differ between the two groups (1.40 +/- 0.05 versus 1.36 +/- 0.03 ng/ml, NS in normal and Hyp groups, respectively). Separate measurement of plasma 25-OHD, 24,25-(OH)2D, and 25-OHD3-26,23-lactone by radioreceptor assay showed no difference between either plasma 24,25-(OH)2D, or the ratio of 25-OHD concentration to 24,25-(OH)2D concentration among Hyp and control animals. In neither study was plasma phosphate concentration related to the 25-OHD3:24,25-(OH)2D3 ratio.(ABSTRACT TRUNCATED AT 250 WORDS)

Carrier gas flow-rate and injection system in capillary gas chromatography of unconjugated and glycine-conjugated bile acids.

The first description of successful capillary gas chromatography of intact glycine-conjugated bile acid derivatives used an automatic solid injection system and required very high carrier gas flow-rates (approximately 20 ml/min) to obtain satisfactory peak shape. Peak heights of unconjugated bile acid derivatives using this injection system and the low flow-rates (1-2 ml/min) usually used for such gas chromatographic analyses were very susceptible to small changes in flow-rate. This system has been re-examined in an attempt to explain this anomalous behaviour. An alternative injection system, the all-glass dropping needle, was also investigated. No explanation for the very high carrier gas flow-rates required when using the automatic solid injection system was found. The dropping needle injection system, however, produced excellent separation of bile acids and their glycine conjugates as dimethylethylsilyl ethers-methyl esters on non-polar wall-coated capillary columns using normal carrier gas flow-rates of 1-2 ml/min. It is clear that the automatic solid injection system originally used has some problem associated with it which can only be overcome, in the case of bile acids and their glycine conjugates, by increasing the carrier gas flow-rate to very high levels.

An apparent fatal overdose of terodiline.

The results of a forensic toxicological investigation on a young man with an unknown cause of death are reported here. Analysis revealed the presence of a possibly fatal level of terodiline in blood and urine. No other drugs were detected. Terodiline was detected by thin-layer and gas-liquid chromatography and identified by gas chromatography/mass spectrometry. Quantification was carried out by a mass fragmentographic procedure using the m/z 100 from terodiline for selective ion monitoring (SIM). The blood and urine concentrations were found to be greater than 10 mg/L, whereas therapeutic concentrations in serum are usually not more than 1 mg/L. Support and confirmation of the laboratory results was provided at the subsequent inquest. It was revealed that the deceased had died from the inhalation of vomit due to an oral overdose of terodiline. To the best of our knowledge this is the first reported death due to fatal poisoning with terodiline in the United Kingdom.

Measurement of 25-hydroxyvitamin D2, 25-hydroxyvitamin D3, 24,25-dihydroxyvitamin D2 and 25,26-dihydroxyvitamin D2 in a single plasma sample by mass fragmentography.

A specific and sensitive assay for the measurement of the concentration of 25-hydroxyvitamin D2, 25-hydroxyvitamin D3, 24,25-dihydroxyvitamin D2 and 25,26-dihydroxyvitamin D2 in a single plasma sample is described, using stable isotope dilution mass fragmentography. After addition of appropriate deuterium-labelled internal standards, plasma samples were treated with acetonitrile to precipitate protein, and vitamin D metabolites were extracted on prepacked microparticulate reverse-phase cartridges. Further purification was achieved using straight-phase cartridges and high-performance liquid chromatography. Gas chromatography-mass spectrometry was carried out after appropriate derivatisation of samples and standards. The method has been evaluated in terms of specificity, recovery of added standards, and reproducibility.

Use of mass spectrometry in the identification of in vivo and in vitro metabolites of dihydrotachysterol3 in the rat.

The metabolism of dihydrotachysterol3 (DHT3), a vitamin D analogue, has been investigated in vivo in the rat after intraperitoneal injection, and the metabolism of the 25-hydroxylated metabolite of DHT3 was studied in vitro in the isolated perfused rat kidney. A large number of metabolites have been obtained and some have been identified. The rat plasma or kidney perfusate were extracted and the metabolites separated by high-performance liquid chromatography (HPLC) in straight- and reverse-phase systems and using cyano columns. Metabolites were identified, using a photodiode array assembly which monitored the HPLC eluate, by the characteristic ultraviolet spectrum of DHT compounds. Tentative structures were assigned to some of the metabolites obtained on the basis of their mobility in the various HPLC systems used in comparison to that of known metabolites of vitamin D. Gas chromatography/mass spectrometry (GC/MS) and direct probe mass spectrometry have been used to confirm the identity of seven metabolites formed in vitro, of which only two have been definitely shown also to be formed in vivo. GC/MS was carried out after derivatization forming trimethylsilyl ethers, n-butyl boronate cyclic esters, and N-O-methyl oximes before and after oxidation with sodium periodate and/or reduction with sodium borohydride. Molecular ions of these compounds are usually of low abundance and characteristic mass fragments at m/z 273, 255 and 121 are always seen with metabolites of DHT.

The measurement of vitamins D2 and D3 and seven major metabolites in a single sample of human plasma using gas chromatography/mass spectrometry.

Selected ion monitoring of vitamin D metabolites has previously been described but there has been only one detailed description of the measurement by gas chromatography/mass spectrometry (GC/MS) of a number of metabolites in a single plasma sample. We describe here a GC/MS method, using stable isotope labelled internal standards, which allows the estimation of vitamins D2 and D3, and their 25-hydroxy, 24,25-dihydroxy and 25,26-dihydroxy metabolites in a single 2 ml sample of plasma, although more is needed for the measurement of 1,25-dihydroxyvitamin D3. Plasma was extracted on Bond Elut C18 cartridges and initial fractionation carried out on Sep-Pak SIL. Straight-phase high-performance liquid chromatography was required for separation of polyhydroxylated metabolites prior to GC/MS using an LKB 2091 mass spectrometer with conventional packed columns. n-Butylboronate esters were formed across vicinal hydroxyls, followed by formation of trimethylsilyl ethers using trimethylsilylimidazole. The [M - 90 - 15]+ ion for each compound was monitored. Deuterated internal standards were not available for all metabolites and it was necessary to use (2H6)D3 and (2H6)25OHD3 as standards for the measurement of D2 and D3, and 25OHD3 and 25OHD2, respectively, and (2H6)24,25(OH)2D3 as a standard for 24,25(OH)2D3 and 25,26(OH)2D2. Although the [M - 90 - 15]+ ion of 24,25(OH)2D and 25,26(OH)2D has the same mass: charge ratio, derivatives of these compounds are completely separated in the GC system used. The intra-assay precision for all these assays is usually less than 5%.

Isolation and identification of seven metabolites of 25-hydroxydihydrotachysterol3 formed in the isolated perfused rat kidney: a model for the study of side-chain metabolism of vitamin D.

The in vivo metabolism of dihydrotachysterol3, an analogue of vitamin D3 and a potent calcemic factor, has been studied in the rat. This in vivo metabolism is compared to the in vitro metabolism of 25-hydroxydihydrotachysterol3 in the perfused rat kidney. Using mass spectrometry and ultraviolet spectroscopy, we have identified seven novel metabolites derived from 25-hydroxydihydrotachysterol3. The seven compounds represent intermediates on two renal pathways (24-oxidation and 26,23-lactone formation) also observed for 25-hydroxyvitamin D3. No evidence was found for the renal synthesis of a 1-hydroxylated metabolite of 25-hydroxydihydrotachysterol3 analogous to the hormone 1,25-dihydroxyvitamin D3. Two of the compounds formed in vitro, 24,25-dihydroxydihydrotachysterol3 and 25-hydroxydihydrotachysterol 26,23-lactone, were also formed in vivo. In vivo studies also revealed the formation of two other unidentified metabolites which are presumed to be formed nonrenally and may be calcemic factors. This work shows that dihydrotachysterol3 metabolism is complex and probably utilizes the same side-chain enzymes as vitamin D3. In addition, our work also confirms that intermediates postulated to lie on pathways to 26,23-lactone in the vitamin D3 series are also formed for the side chain in dihydrotachysterol3.