Fractional conversion of thromboxane A2 and B2 to urinary 2,3-dinor-thromboxane B2 and 11-dehydrothromboxane B2 in the cynomolgus monkey

Following the intravenous administration of thromboxane (TX) B2, the stable hydration product of TXA2, to human and nonhuman primates the most abundant urinary metabolites are 2,3-dinor-TXB2 and 11-dehydro-TXB2. However, it is not known whether fractional conversion of TXB2 to its enzymatic metabolites is an accurate representation of TXA2 metabolism. Thus, we have compared the metabolic disposition of synthetic TXA2 and TXB2 via the beta-oxidation and 11-OH-dehydrogenase pathways in vivo in the monkey. TXA2 or TXB2 (20 ng/kg) was intravenously administered to four cynomolgus monkeys pretreated with aspirin in order to suppress endogenous TXA2 production. Urinary TXB2, 2,3-dinor-TXB2 and 11-dehydro-TXB2 were measured before, during and up to 24 h after thromboxane administration by means of reversed-phase high-performance liquid chromatography radioimmunoassay. Aspirin treatment suppressed urinary 2,3-dinor-TXB2 and 11-dehydro-TXB2 by approx. 75%. A similar fractional conversion of TXA2 and TXB2 into 2,3-dinor-TXB2 and 11-dehydro-TXB2 was found. These results suggest that TXA2 is hydrolyzed to TXB2 prior to enzymatic degradation and that metabolites of the latter represent reliable indices of TXA2 biosynthesis. Due to the variability in the conversion of thromboxanes into 2,3-dinor-TXB2 and 11-dehydro-TXB2, the measurement of both metabolites seems to represent a more reliable index of acute changes in TXA2 production.     

Solid-phase extraction of urinary 11-dehydrothromboxane B2 for reliable determination with radioimmunoassay.

In this paper we elaborate a one-step procedure for the selective extraction of urinary 11-dehydrothromboxane B2 on octylsilyl silica cartridges for reliable determination with radioimmunoassay. The immunoreactivity profile of nonselectively extracted urine after HPLC separation showed that as much as 70% of the total 11-dehydrothromboxane B2 immunoreactivity comigrates with polar interfering material. Its amount could be considerably decreased using acetonitrile:water (18:82, v/v) as wash solvent before elution of 11-dehydrothromboxane B2 from the cartridge. Alternatively, very high immunoreactive purity was achieved without the preceding wash step by selective elution of the analyte with dichloromethane:hexane (70:30). After both optimized steps in the extraction procedure were combined, immunoreactivity was found only in HPLC fractions corresponding to the retention volume of authentic 11-dehydrothromboxane B2. The homogeneity of this immunoreactivity was confirmed by two-step HPLC separation. A significant correlation of values was observed between samples measured after extraction and those measured after subsequent HPLC purification. A high correlation was also found with concentrations determined by radioimmunoassay using four different antisera. The values of 24 h excretion of 11-dehydrothromboxane B2 in 10 male volunteers (595 +/- 114 ng/g creatinine, mean +/- SD) as well as the inhibitory effect of acetylsalicylic acid (80 +/- 13%) closely correspond with those reported in the literature. This selective extraction procedure provides a high validity in radioimmunoassay without requiring any further purification step.     

Tandem mass spectrometric determination of 11-dehydrothromboxane B2, an index metabolite of thromboxane B2 in plasma and urine

11-Dehydrothromboxane B2 is one of the major enzymatic metabolites of thromboxane B2 (TXB2), a biologically inactive product of thromboxane A2. The short half-life of thromboxane A2 and ex vivo production of thromboxane B2 by platelet activation make these prostanoid metabolites inappropriate as indices of systemic thromboxane biosynthesis, whereas 11-dehydro-TXB2 has been shown to reflect the release of thromboxane A2 in the human blood circulation. Analysis of 11-dehydro-TXB2 in plasma and urine was performed by gas chromatography-mass spectrometry-mass spectrometry using the chemically synthesized tetradeuterated compound as an internal standard. The high selectivity of triple-stage quadrupole mass spectrometry (tandem mass spectrometry) considerably facilitates sample purification as compared to single quadrupole mass spectrometric determination. Plasma concentrations in five healthy male volunteers were in the range 0.8-2.5 pg/ml. Urinary excretion of 11-dehydro-TXB2 was higher than that of 2,3-dinor-TXB2: 1.2 +/- 0.36 micrograms/24 h vs 0.53 +/- 0.33 micrograms/24 h (n = 5). Thus 11-dehydro-TXB2 appears at present to be the best index metabolite of systemic TXA2 activity in plasma as well as in urine.     

Circulating and urinary thromboxane B2 metabolites in the rabbit: 11-dehydro-thromboxane B2 as parameter of thromboxane production

The metabolism of thromboxane B2 was studied in the rabbit. The aim of the study was to identify metabolites in blood and urine that might serve as parameters for monitoring thromboxane production in vivo. [5,6,8,9,11,12,14,15-3H8]-Thromboxane B2 was administered by i.v. injection to rabbits, and blood samples and urine were collected with brief intervals. The metabolic profiles were visualized by two-dimensional thin layer chromatography and autoradiography, and the structures of five major metabolites were determined using chromatographic and mass spectrometric methods. In urine the major metabolites were identified as 11-dehydro-TXB2 and 2,3,4,5-tetranor-TXB1, and other prominent products were 11-dehydro-2,3,4,5-tetranor-TXB1, 2,3-dinor-TXB1 and 2,3-dinor-TXB2. In the circulation, TXB2 was found to disappear rapidly. The first major metabolite to appear was 11-dehydro-TXB2, which also remained a prominent product in blood for the remainder of the experiment (90 min). With time, the profile of circulating products became closely similar to that in urine. TXB2 was not converted into 11-dehydro-TXB2 by blood cells or plasma. The dehydrogenase catalyzing its formation was tissue bound and was found to have a widespread occurrence: the highest conversion was found in lung, kidney, stomach and liver. The results of the present study suggest that 11-dehydro-TXB2 may be a suitable parameter for monitoring thromboxane production in vivo in the rabbit in blood as well as urinary samples, and possibly also several tissues. This was also demonstrated in comparative studies using radioimmunoassays for TXB2 and 11-dehydro-TXB2.     

Radioimmunoassay of 11-dehydrothromboxane B2 in human plasma and urine

Because of the discrepancy between the capacity of platelets to synthesize thromboxane B2 ex vivo and the actual synthetic rate in vivo, measurement of thromboxane B2 in plasma is highly influenced by sampling-related artifacts. We have developed and validated a radioimmunoassay for a major enzymatic derivative of thromboxane B2 with an extended plasma half-life, i.e., 11-dehydrothromboxane B2. The binding of the tracer is displaced by as low as 1 pg/ml of the homologous ligand, with a high degree of specificity for the open ring structure as well as for the omega side-chain. This method can detect changes in the plasma concentration and urinary excretion of 11-dehydrothromboxane B2 associated with stimulated short-term increases of thromboxane B2 secretion in the human circulation.     

A chemiluminescent immunoassay for urinary thromboxane B2.

Because of the vasoactive properties of thromboxane A2 and other related prostaglandins, much research has been conducted on drugs which alter their levels. Urinary levels of thromboxane B2 and 2,3-dinor thromboxane B2 (major urinary metabolite of thromboxane B2) are used as an indication of thromboxane production in-vivo. In order to accurately measure urinary TXB2 levels of subjects on investigative drugs which lower TXA2 and subsequently TXB2, a simple and sensitive analytical tool becomes necessary. We have thus developed a non-radioisotopic (chemiluminescent) assay for urinary TXB2. Sensitivity has been demonstrated to 5 pg/ml. The method correlates well with gas chromatography/mass spectrometry (the accepted reference method) even without column chromatographic purification prior to the conduct of the chemiluminescent assay (r = 0.96). In addition, we have demonstrated feasibility for a chemiluminescent assay to measure urinary 2,3-dinor TXB2.     

Changes in urinary thromboxane level in man during cardiopulmonary bypass: effect of thromboxane on renal tubules

ONO-3708, a thromboxane A2 (TXA2) antagonist, was administered at a dose of 2 micrograms/kg/min by a double blind method as compared with inactive placebo during cardiopulmonary bypass (CPB) procedure to study the changes of thromboxane B2 (TXB2) levels in plasma and urine and N-acetyl-glucosaminidase (NAG) level in urine. TXB2 levels in plasma and urine increased significantly (P less than 0.01) during CPB in the patients given ONO-3708 (ONO-3708 group) and in those given placebo (placebo group). The plasma TXB2 level as expected from the urinary TXB2 level was higher than the measured plasma TXB2 level showing increases in TXB2 originating from the kidney. The urinary NAG level, increased significantly (P less than 0.01) during CPB the NAG level in ONO-3708 group was significantly low as compared to placebo group. The levels of TXB2 in plasma and urine in ONO-3708 group were not different from those of the patients receiving placebo, indicating that ONO-3708 does not have any effect on TXA2 production. We concluded that the elevation of urinary TXB2 level might be due to increased TXA2 production in the kidney under hypoxic condition induced by hypotension and lowered perfusion during CPB. Furthermore, the increased production of TXA2 appears to suppress the functions of the renal proximal tubules.     

Regulation of urinary thromboxane B2 in man: Influence of urinary flow rate and tubular transport

Thromboxane B₂ (TxB) is excreted in human urine, but the mechanism of renal excretion and the quantitative relationship of urinary TxB to the active parent compound, thromboxane A₂, of renal or extrarenal origin is not established. To determine the effects of vasoactive hormones, uricosuric agents and urinary flow rate on TxB excretion, urinary TxB was measured by radioimmunoassay and mass spectrometry, and renal metabolism of blood TxB was determined by radiochromatography of urine after i.v. [³H]-TxB infusions. Basal TxB was 6.7 ± 1.1 ng/h during an oral water load, and TxB fell with s.q. antidiuretic hormone (to 3.4 ± 0.4 ng/h, P<0.01) and with fluid restriction (to 2.6 ± 0.5 ng/hr, P=0.001) in parallel with urinary volume. Urinary excretion of unmetabolized [³H]-TxB also fell (by 56%) with fluid restriction, implicating altered metabolism rather than synthesis as the mechanism of the urinary flow effect. Angiotensin II infusions slightly reduced both TxB and urine volume, consistent with a flow effect. In contrast, probenecid did not alter urine volume, but increased urinary uric acid (by 244%), TxB (from 5.6 ± 0.9 to 11.1 ± 2.9 ng/h) and urinary excretion of blood [³H]-TxB (by 243%) by similar amounts (all P<0.05), suggesting that TxB is actively reabsorbed in the proximal tubule, similarly to uric acid. Thus, urinary excretion of TxB of renal and extrarenal origin is regulated by proximal and distal tubule factors.     

Identification of the major urinary metabolite of thromboxane B2 in the monkey.

Thromboxane B2 (TxB2) was biosynthesized from prostaglandin endoperoxides (PGG2, PGH2) using guinea pig lung microsomes and infused into an unanesthetized monkey. Urine was collected and TxB2 metabolites were isolated by reversed phase partition chromatography and high performance liquid chromatography. A major metabolite (TxB2-M) was found to be excreted in greater than two-fold abundance relative to other metabolites. Its structure was determined by gas chromatography-mass spectrometry to be dinor-thromboxane B2. In vitro incubation of TxB2 with rat liver mitochondria yielded a C18 derivative with a mass spectrum identical to that of TxB2-M, substantiating that the major urinary metabolite of TxB2 in the monkey is a product of a single step of beta-oxidation.     

Circulating and urinary thromboxane B2 metabolites in the rabbit: 11-dehydro-thromboxane B2 as parameter of thromboxane production

The metabolism of thromboxane B₂ was studied in the rabbit. The aim of the study was to identify metabolites in blood and urine that might serve as parameters for monitoring thromboxane production in vivo. [5, 6, 7, 8, 9, 11, 12, 14, 15-³H₈]-Thromboxane B₂ was administered by i.v. injection to rabbits, and blood samples and urine were collected with brief intervals. The metabolic profiles were visualized by two-dimensional thin layer chromatography and autoradiography, and the structures of five major metabolites were determined using chromatographic and mass spectrometric methods.In urine the major metabolites were identified as 11-dehydro-TXB₂ and 2, 3, 4, 5-tetranor-TXB₁, and other prominent products were 11-dehydro-2, 3, 4, 5-tetranor-TXB₁, 2, 3-dinor-TXB₁ and 2, 3-dinor-TXB₂. In the circulation, TXB₂ was found to disappear rapidly. The first major metabolite to appear was 11-dehydro-TXB₂, which also remained a prominent product in blood for the remainder of the experiment (90 min). With time, the profile of circulating products became closely similar to that in urine. TXB₂ was not converted into 11-dehydro-TXB₂ by blood cells or plasma. The dehydrogenase catalyzing its formation was tissue bound and was found to have a widespread occurrence: the highest conversion was found in lung, kidney, stomach and liver.The results of the present study suggest that 11-dehydro-TXB₂ maybe a suitable parameter for monitoring thromboxane production in vivo in the rabbit in blood as well as urinary samples, and possibly also several tissues. This was also demonstrated in comparative studies using radioimmunoassays for TXB₂ and 11-dehydro-TXB₂.     

Impaired conversion of exogenous arachidonic acid by platelets to thromboxane B2 and correction of that deficiency by interferon-alpha

In the course of an investigation of cyclooxygenase and 12-lipoxygenase activity in platelets of patients with myeloproliferative syndrome receiving treatment with interferon-alpha 2 patients showed unusual results which have not been reported so far. Both patients had thrombocytosis, in one case associated with polycythaemia. In platelets of both patients, a reduced conversion of exogenous 14C arachidonic acid to TXB2 was observed accompanied by a shift in conversion to PGE2 and 12-HETE in one patient and to 12-HETE alone in the other before therapy. These findings were paradoxically associated with evidence of enhanced platelet activation in vivo. Treatment of both patients with interferon-alpha resulted in reversal of the biochemical abnormalities and in clinical remission.     

Production of urinary 11-keto-thromboxane B2 in normal and hypertensive pregnancies

Urinary levels of 11-keto-thromboxane B2 (11-keto-TXB2), were elevated at all gestational ages (12-41 weeks) compared with non-pregnant levels. 11-keto-TXB2 levels exceeded those of TXB2 throughout pregnancy, which suggested that 11-keto-TXB2 may be the major urinary metabolite of TXA2 in normotensive pregnancy, as in the non-pregnant state. This was reversed in women with mild pregnancy-induced hypertension (P.I.H.), such that urinary levels of TXB2 were higher (p less than 0.01) than those of 11-keto-TXB2. Since the 11-thromboxane dehydrogenase enzyme is found in the placenta, the low levels of 11-keto-TXB2 may be the result of placental damage decreasing the activity of the enzyme. The relationship between these findings and the aetiology of P.I.H. is not clear, but changes in urinary 11-keto-TXB2 may be of use in identifying those women at risk of developing P.I.H.     

Enzyme immunoassay of thromboxane B2

An immunoassay for thromboxane B2 was developed in which the hapten molecule was labeled with beta-galactosidase. The immunoprecipitate formed after competition between enzyme-labeled and unlabeled thromboxane B2 was subjected to a fluorometric assay of beta-galactosidase. Thromboxane B2 was detectable in the range of 0.1-30 pmol. Both enzyme immunoassay and radioimmunoassay showed essentially the same cross-reactivities with other prostaglandins and their metabolites when the same antibody was used. Known amounts of thromboxane B2 were added to human plasma, and the sample was applied to an octadecyl silica column. The extract was analyzed by enzyme immunoassay to examine the correlation between the added (x) and measured (y) thromboxane B2 (y = 1.09x + 11.07 pmol/ml, r = 0.99). A satisfactory correlation was observed between radioimmunoassay (x) and enzyme immunoassay (y) (y = 0.92x + 4.64 pmol/ml, r = 0.96). The validity of enzyme immunoassay was also confirmed by gas chromatography-mass spectrometry of a dimethylisopropylsilyl ether derivative of thromboxane B2 methyl ester. The method was applicable to the assay of thromboxane B2 produced from endogenous precursor during thrombin-induced aggregation of human platelets.     

Plasma thromboxane B2 in haemodialysed patients

Plasma thromboxane B2 (TXB2) concentration was measured in 7 cases of terminal renal failure before and after haemodialysis. The TXB2 levels were higher in the investigated group than in the control group (p less than 0.05). Haemodialysis induced a further increase in the TXB2 concentration. Increased thromboxane production may play a part in the pathogenesis of accelerated atherosclerosis in uraemic patients treated with chronic haemodialysis.     

Development of radioimmunoassay for thromboxane B2

A simple method for the preparation of rat liver urate oxidase is described. The enzyme was purified from rat liver homogenate by cell fractionation, detergent treatment, alkali treatment, and affinity chromatography on 8-aminoxanthine-bound Sepharose 4B. This enzyme preparation had a specific activity of 9.1 U/mg of protein and was purified about 1000-fold from the liver homogenate. After sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis followed by staining with Coomassie brilliant blue, this preparation yielded one protein band at a position corresponding to a molecular weight of 33,000.     

Metabolism of thromboxane B2 in the isolated perfused rat kidney: mass spectrometric identification of urinary products

The metabolism of thromboxane B2 (TXB2), the stable breakdown product of thromboxane A2, has been studied in isolated perfused kidney preparations using a recirculating system. In a first experiment, TXB2 was infused at a rate of 20 micrograms/kg per min. In a second experiment, a 1:1 mixture of TXB2 and octadeuterated TXB2 (0.4 microgram/kg per min each) was infused. Urinary samples collected during the infusion of TXB2 or vehicle were extracted on C18 cartridges and derivatized to methyl or pentafluorobenzyl ester, methyloxime, trimethylsilyl ether. Samples were analyzed by high-resolution gas chromatography-mass spectrometry in the electron impact and negative ion chemical ionization modes. Products of beta-oxidation, reduction of the delta 5,6 double bond and dehydrogenation at C-11 (2,3-dinor-TXB2, 2,3-dinor-TXB1, 2,3,4,5-tetranor-TXB1 and 11-dehydro-TXB2) were identified in addition to unmetabolized TXB2. 2,3,4,5-tetranor-TXB1 and 2,3-dinor-TXB1 were the most abundant metabolites.     

Structure and quantitative determination of the major urinary metabolite of thromboxane B2 in the guinea pig.

2,3-Dinor-thromboxane B2 was the major urinary metabolite of thromboxane B2 in the guinea pig. The structure was assessed mainly by mass spectrometric analysis of a number of derivatives of the metabolite and by chemical degradation by oxidative ozonolysis. A method for quantitative determination of 2,3-dinor-thromboxane B2 in guinea pig urine based on multiple ion analysis and octadeuterated 2,3-dinor-thromboxane B2 as internal standard was developed. The basal excretion of the metabolite was 65 +/- 36 (S.D.) ng/kg x 24 h (n = 19; range 19--140 ng). This level corresponded to an endogenous synthesis of 543 +/- 300 ng of TXB2. No increase in the excretion was seen after anaphylaxis, in contrast to what has earlier been reported for PGF2 alpha.     

Smoking alters thromboxane metabolism in man

Chronic smoking is a major risk factor of atherosclerosis and coronary heart disease. The measurement of three major thromboxane A2 metabolites, 11-dehydrothromboxane B2, 2,3-dinorthromboxane B2 and thromboxane B2, in the urines of 13 apparently healthy smokers (average 39 years, range 27-56 years) showed significantly elevated excretion rates for all thromboxane A2 metabolites as compared to 10 apparently healthy age-matched non-smokers (average 37 years, range 26-56 years). Importantly, characteristic alterations in the thromboxane A2 metabolite pattern were found in the urines of smokers. The contribution of 2,3-dinorthromboxane B2 to total measured excretion of thromboxane A2 metabolites was 59.2% in smokers (404.0 +/- 53.0 pg/mg creatinine) versus 19.4% in non-smokers (85.2 +/- 8.3 pg/mg creatinine), that of 11-dehydrothromboxane B2 35.7% in smokers (673.2 +/- 88.9 pg/mg creatinine) as compared to 75.5% in non-smokers (332.6 +/- 30.9 pg/mg creatinine). The contribution of thromboxane B2 (57.5 +/- 7.7 pg/mg creatinine in smokers versus 21.9 +/- 1.5 pg/mg creatinine in non-smokers) was similar at 5.1%. The excretion of cotinine, the major urinary metabolite of nicotine that correlates well with the reported daily cigarette consumption (r = 0.97, P less than 0.0001), showed a good correlation to thromboxane A2 metabolite excretion (2,3-dinorthromboxane B2: r = 0.92, P less than 0.0001; 11-dehydrothromboxane B2; r = 0.87, P less than 0.0001).     

Embryopathic effects of thromboxane B2 in the chick

Several prostaglandins of the E and F series are now known to be involved in reproduction and developmental events. However, there is as yet no such evidence for any of the other arachidonate metabolites. Thromboxane B2 is the stable metabolic end product of the biologically active but unstable intermediate thromboxane A. Administered to developing chick embryos at 48 and 72 hours incubation, thromboxane B₂ caused growth retardation and induced a high incidence of anomalies, in particular,everted viscera.