Effects of bovine milk ingestion on urinary excretion of oxypurinol and uric acid.

OBJECTIVE: Although allopurinol is a xanthine oxidase inhibitor, its overall effect may be due to the action of oxypurinol, a metabolite of allopurinol and another xanthine oxidase inhibitor, since the biological half-life of oxypurinol is longer than that of allopurinol. Oxypurinol shares a renal transport pathway with uric acid and ingestion of bovine milk increases the urinary excretion of uric acid. Therefore, we investigated whether its ingestion promotes the urinary excretion of oxypurinol. SUBJECTS/METHODS: Bovine milk (15 ml/kg body weight) was administered to 6 healthy subjects who took allopurinol (300 mg) 12 h prior to ingestion. In addition, a control experiment was performed with the same subjects using the same protocol, except for the ingestion of water instead of bovine milk. Blood and urine samples were collected before and after bovine and water ingestion. RESULTS: In the bovine milk ingestion experiment, the urinary excretion values of oxypurinol and uric acid were increased by 18% and 38%, respectively, and the fractional excretion values of oxypurinol and uric acid were increased by 20% and 40%, respectively, whereas those did not change in the control experiment. In addition, the concentration of alanine and sum of concentrations of amino acids were increased by 16% and 20%, respectively, in the bovine milk ingestion experiment. CONCLUSION: These results suggest that bovine milk ingestion promotes the urinary excretion of oxypurinol as well as uric acid by increasing amino acid concentration.

A repeated oral administration study of febuxostat (TMX-67), a non-purine-selective inhibitor of xanthine oxidase, in patients with impaired renal function in Japan: pharmacokinetic and pharmacodynamic study.

BACKGROUND: Allopurinol has been widely used for treatment of hyperuricemia, however, it may be associated with various adverse effects. Febuxostat has been identified as a potentially safe and efficacious alternative. OBJECTIVES: A multicenter, open-label, parallel, between-group comparative study was conducted to investigate the effects of renal function on the pharmacokinetics, pharmacodynamics, and safety of febuxostat, a novel inhibitor of uric acid synthesis. METHODS: Based on creatinine clearance (Ccr), 29 subjects were assigned to 3 groups: normal renal function (Ccr ≥ 80 mL/min), mild renal dysfunction (80 mL/min > Ccr ≥ 50 mL/min), or moderate renal dysfunction (50 mL/min > Ccr ≥ 30 mL/min). Febuxostat was repeatedly orally administered at a dose of 20 mg/d for 7 days. RESULTS: Impaired renal function caused a slight increase in systemic exposure to unchanged febuxostat and its oxidative metabolites, but the exposure did not increase through repeated administration. Moreover, renal impairment did not markedly reduce the effects of febuxostat on plasma uric acid levels. There were no clinically significant adverse events even in patients with impaired renal function. CONCLUSIONS: Febuxostat is considered an inhibitor of uric acid synthesis that could be used in patients with mild to moderate renal impairment without dose adjustment.

Detection of allopurinol and oxypurinol in canine urine by HPLC/MS-MS: Focus on veterinary clinical pharmacokinetics.

Allopurinol is the most commonly used drug for the treatment of hyperuricemia in people, and in view of the risks of fatal hypersensitivity in patients with renal dysfunction, doses based on the glomerular filtration rate are proposed. In veterinary medicine, allopurinol is used in the treatment of canine leishmaniasis (CanL) caused by Leishmania infantum owing to the drug action of inhibiting the parasite's RNA synthesis. However, renal dysfunction frequently ensues from disease progression in dogs. The purpose of the present study was to standardize and validate a sensitive high-performance liquid chromatography-mass spectrometric (HPLC-MS/MS) method to determine the concentration of allopurinol and its active metabolite oxypurinol in canine urine for clinical pharmacokinetic investigation. Urine samples of eleven (11) dogs with naturally occurring CanL and in the maintenance phase of the treatment with alopurinol were used. For the chromatographic analysis of urine, the mobile phase consisted of a solution of 0.1 % formic acid (88 %) in 10 mM ammonium acetate. Separation of allopurinol and oxypurinol occurred in a flow of 0.8 mL/min on a C8 reverse phase column 5 µm, and acyclovir was the internal standard. The HPLC-MS/MS method was validated by reaching the limits of detection and quantification, reproducibility and linearity. The lower limit of quantification achieved by the method was 10 µg/mL for both allopurinol and oxypurinol. Calibration curves were prepared in blank urine added with allopurinol at concentrations of 10-1000 µg/mL, and oxypurinol at 10-200 µg/mL. Coefficients of variation of less than 15 % between intracurrent and intercurrent accuracy values were observed for both allopurinol and oxypurinol. Urine test samples remained stable after being subjected to freeze-thaw cycles and remaining at room temperature for 4 h. The method proved to be adequate to quantify allopurinol and oxypurinol in urine samples from dogs under treatment.

Plasma concentrations and urinary excretion of purine bases (uric acid, hypoxanthine, and xanthine) and oxypurinol after rigorous exercise.

To investigate the effects of exercise on the plasma concentrations and urinary excretion of purine bases and oxypurinol, we performed 3 experiments with 6 healthy male subjects. The first was a combination of allopurinol intake (300 mg) and exercise (VO2max, 70%) (combination experiment), the second was exercise alone (exercise-alone experiment), and the third was allopurinol intake alone (allopurinol-alone experiment). In the combination experiment, exercise increased the concentrations of purine bases and noradrenaline in plasma, as well as lactic acid in blood and the urinary excretion of oxypurines, whereas it decreased the urinary excretion of uric acid and oxypurinol as well as the fractional excretion of hypoxanthine, xanthine, uric acid, and oxypurinol. In the exercise-alone experiment, exercise increased the concentrations of purine bases and noradrenaline in plasma, lactic acid in blood, and the urinary excretion of oxypurines, whereas it decreased the urinary excretion of uric acid and fractional excretion of purine bases. In contrast, in the allopurinol-alone experiment, the plasma concentration, urinary excretion, and fractional excretion of purine bases and oxypurinol remained unchanged. These results suggest that increases in adenine nucleotide degradation and lactic acid production, as well as a release of noradrenaline caused by exercise, contribute to increases in plasma concentration and urinary excretion of oxypurines and plasma concentration of urate, as well as decreases in urinary excretion of uric acid and oxypurinol, along with fractional excretion of uric acid, oxypurinol, and xanthine. In addition, they suggest that oxypurinol does not significantly inhibit the exercise-induced increase in plasma concentration of urate.

Sustained reductions in oxipurinol renal clearance during a restricted diet.

The renal clearance of oxipurinol, the major metabolite of allopurinol, was studied in six healthy subjects during normal and restricted (low protein and low calorie) diets. A 600 mg oral dose of allopurinol was administered after 7 days of a normal diet (100 mg protein/day) and again after 2 and 4 weeks of a restricted diet (19 gm protein/day). The renal clearance of oxipurinol was reduced from 19.6 +/- 1.5 ml/min during the normal diet to 10.9 +/- 0.8 and 12.0 +/- 0.9 ml/min (both P less than 0.001) during the restricted diet at 2 and 4 weeks, respectively. These changes in oxipurinol renal clearance paralleled changes in uric acid renal clearance. Furthermore, the plasma oxipurinol half-life was increased from 27.0 +/- 1.7 hours during the normal diet to 51.1 +/- 4.3 and 45.7 +/- 3.7 hours (both P less than 0.001) during the restricted diet at 2 and 4 weeks, respectively. We conclude that dietary protein and calorie restriction cause a sustained reduction in the elimination of oxipurinol.

Effect of BOF-4272 on the oxidation of allopurinol and pyrazinamide in vivo. Is xanthine dehydrogenase or aldehyde oxidase more important in oxidizing both allopurinol and pyrazinamide?

Allopurinol or pyrazinamide was administered to rats treated with BOF-4272 (a potent xanthine oxidase inhibitor) to investigate to what degree xanthine dehydrogenase participates in the oxidation of these agents. BOF-4272 markedly decreased the plasma concentration and the urinary excretion of both oxypurinol and 5-hydroxypyrazinamide. It also decreased the sum of the urinary excretion of allopurinol and oxypurinol and that of pyrazinamide and its metabolites, although it did not affect the sum of the plasma concentrations of allopurinol and oxypurinol at 105 min after administration of allopurinol or the plasma concentration of pyrazinamide during the period after the administration of pyrazinamide. These results suggested that BOF-4272 almost completely inhibited the oxidation of allopurinol and pyrazinamide and had some effect on the excretion and/or the tissue incorporation of these two compounds. Since the in vitro study demonstrated that BOF-4272 did not inhibit the activity of aldehyde oxidase, which oxidized both allopurinol to oxypurinol and pyrazinamide to 5-hydroxypyrazinamide, the results suggested that xanthine dehydrogenase was the more important enzyme in converting allopurinol to oxypurinol and pyrazinamide to 5-hydroxypyrazinamide.

On the metabolism of allopurinol. Formation of allopurinol-1-riboside in purine nucleoside phosphorylase deficiency.

Allopurinol-1-riboside, a major metabolite of allopurinol, is commonly thought to be directly synthesized by purine nucleoside phosphorylase (PNP) in vivo. As this enzyme is otherwise believed to function in vivo primarily in the direction of nucleoside breakdown, we have determined by high performance liquid chromatography and a conventional chromatographic method the urinary metabolites of allopurinol in a child deficient of PNP. In this patient approximately 40% of urinary allopurinol metabolites consisted of allopurinol-1-riboside, thus proving the possibility of indirect formation of allopurinol-1-riboside via allopurinol-1-ribotide in vivo, catalysed by hypoxanthine guanine phosphoribosyltransferase (HGPRT) and a phosphatase.

Effect of norepinephrine on the urinary excretion of purine bases and oxypurinol.

To examine whether norepinephrine affects the plasma concentrations and urinary excretion of purine bases and oxypurinol, we orally administered allopurinol (300 mg) to 5 healthy subjects and 9 hours later intravenously administered norepinephrine (12 to 20 microg/kg body weight), which causes a more than 10 mm Hg increase in diastolic pressure for 2 hours. Norepinephrine decreased the urinary excretion of uric acid by 33% (P <.01), oxypurinol by 32% (P <.01), and xanthine by 51% (P <.01), as well as the fractional clearance of uric acid by 32% (P <.01), oxypurinol by 24% (P <.05), and xanthine by 21% (P <.05) when measured 1 to 2 hours after administration. These results indicate that norepinephrine decreases the urinary excretion of uric acid, oxypurinol, and xanthine, probably via hemodynamic change. It is also suggested that the hypouricemic effect of allopurinol may be more potent than that expected in gout patients with enhanced sympathetic tone, such as in salt-sensitive hypertension.

Effects of angiotensin II infusion on renal excretion of purine bases and oxypurinol.

The effect of angiotensin II infusion on the renal transport of purine bases and oxypurinol (a metabolite of allopurinol) was investigated in 5 healthy subjects who were orally given allopurinol (300 mg) 9 hours prior to the study. Angiotensin II was intravenously administered at 8 ng/min/kg for 2 hours. The fractional clearances of uric acid, xanthine, and oxypurinol were significantly decreased during angiotensin II infusion; however, that of hypoxanthine did not change. The urinary excretion levels of uric acid, xanthine, and oxypurinol were also significantly decreased during angiotensin II infusion. These results suggest that angiotensin II infusion affected the renal clearances of uric acid, xanthine, and oxypurinol through direct tubular transport and/or hemodynamic changes. Accordingly, the hypouricemic effect of allopurinol may be exaggerated in hypertensive gout patients with an enhanced renin-angiotensin system, since an increased biological half-life of oxypurinol is expected in these patients.

Effect of furosemide on renal excretion of oxypurinol and purine bases.

To examine whether furosemide affects the plasma concentration and urinary excretion of purine bases and oxypurinol, we administered allopurinol (300 mg) orally to 6 healthy subjects and then administered furosemide (20 mg) intravenously 10 hours later. Furosemide (20 mg) decreased the urinary excretion of uric acid by 40% (P < .01), oxypurinol by 39% (P < .05), and xanthine by 43% (P < .05) and the fractional clearance of uric acid by 45% (P < .01) and oxypurinol by 34% (P < .05) when measured 1 to 2 hours after administration. Moreover, furosemide increased the plasma concentration of uric acid by 6% at 1.5 hours after administration. These results indicate that furosemide may decrease the urinary excretion of uric acid and oxypurinol by acting on their common renal transport pathway(s). In addition, it is suggested that the effect of furosemide on oxypurinol is clinically important, since the hypouricemic effect of allopurinol may become more potent as a result.

Reduced renal clearance of oxypurinol during a 400 calorie protein-free diet.

A decrease in dietary protein intake lowers the clearance of a number of substances excreted principally by the kidney including uric acid and oxypurinol, the major metabolite of allopurinol. We studied the kinetics of uric acid and oxypurinol in seven healthy volunteers on a normal protein diet (2600 calories; 100 g protein) followed by a 400 calorie, protein-free diet. A 600 mg dose of allopurinol was given orally after 6 days of the normal protein diet and again after 2 days of the 400 calorie, protein-free diet. Two major findings emerged: first, the renal clearance of oxypurinol was reduced from 21.2 +/- 1.9 ml/min during the normal protein diet to 12.3 +/- 1.2 ml/min (P less than .05) during the 400 calorie, protein-free diet, and second, there was a striking diurnal difference in oxypurinol renal clearance with a 41% decrease in the oxypurinol clearance at night (8 PM to 8 AM) versus day (8 AM to 8 PM) on the 400 calorie, protein-free diet.

Evaluation of a thiazide-allopurinol drug interaction.

Allopurinol toxicity has been associated with the use of this drug in patients with renal insufficiency, a situation where the half-life of oxipurinol, the major metabolite of allopurinol, is prolonged. Allopurinol toxicity has also been associated with the concomitant use of allopurinol and thiazide diuretics. In the present study, the effect of hydrochlorothiazide administration on the renal clearance and serum half-life of oxipurinol has been studied in eight normal volunteers to determine if thiazides delay the clearance of oxipurinol. Oxipurinol's renal clearance and serum half-life were measured in each volunteer during a control period and again while the volunteer was receiving 50 mg/day hydrochlorothiazide for 1 week. No change in renal oxipurinol clearance (21.1 +/- 5.9 vs. 20.4 +/- 8.7 ml/min) or serum oxipurinol half-life (23.7 +/- 4.2 vs. 23.4 +/- 4.4 hours) was noted with the addition of thiazides. The association previously noted between the use of thiazide diuretics and the development of allopurinol toxicity cannot be explained by alterations in oxipurinol pharmacokinetics.

Difference of the plasma concentration and urinary excretion of allopurinol, oxypurinol, and purine bases between dietary intake and fasting.

To investigate how much the metabolism of allopurinol, oxypurinol, and purine bases during dietary intake (total calorie 2,083 kcal, total protein 107.5 g, total lipid 74.1 g, total carbohydrate 228.3 g, total purine 180.5 mg) differs from that during fast, allopurinol (300 mg) was administered to 5 normal subjects after a 6-hour fast and then breakfast was taken. Four and 10 hours after the administration of allopurinol lunch and dinner were taken, respectively. Two weeks later the same protocol was performed, except for the intake of only water instead of diet. The fractional clearances and urinary excretions of oxypurinol, uric acid, and the clearance of creatinine were increased by dietary intake, compared with the respective ones resulting from fasting. At the same time the plasma concentrations of hypoxanthine, xanthine, and oxypurinol were decreased in dietary intake, compared with the respective ones in fasting, while the urinary excretion of neither allopurinol, hypoxanthine, nor xanthine was affected. These results suggest that the administration of allopurinol at bed time (during the nocturnal fast) may be more effective than that after breakfast in order to decrease the plasma concentration of uric acid.

Effect of the angiotensin II receptor antagonist losartan on uric acid and oxypurine metabolism in healthy subjects.

OBJECTIVE: The acute effects of the angiotensin II receptor antagonist losartan on uric acid and oxypurine metabolism were evaluated. METHODS: Losartan (50 mg) was administered orally to 6 healthy males. Blood and urine samples for uric acid and oxypurine were collected before and up to 6 hours after losartan administration. The same examinations were performed later using enalapril (5 mg). RESULTS: Losartan decreased the serum uric acid concentration (from 5.9 +/- 0.9 to 5.2 +/- 1.0 mg/dl) and increased its fractional clearance, which reached a maximum after 2 hours, while enalapril did not. Losartan also induced an increase in the plasma concentration of hypoxanthine, peaking in the fourth hour, and a decrease in its urinary clearance, while the plasma xanthine concentration and its urinary clearance were unchanged. The extent of uric acid excretion was much greater than that of the oxypurines. CONCLUSIONS: Losartan, which has a high affinity for the urate/anion exchanger, has a transient uricosuric effect. Our data indicate that losartan induces a significant decrease in the urinary excretion of hypoxanthine without changes in xanthine.

Two siblings with classical xanthinuria type 1: significance of allopurinol loading test.

Two brothers with classical xanthinuria who lacked xanthine dehydrogenase activity were encountered. Their hypouricemia was caused by underproduction of uric acid. In their duodenal mucosa, no xanthine dehydrogenase (oxidase) activity was detected. The patients had no symptoms except for duodenal ulcer in one case. The conversion of allopurinol to oxipurinol during an allopurinol loading test for determining the type of classical xanthinuria revealed that the patients had classical type 1 xanthinuria, because aldehyde oxidase activity was present. Furthermore, the allopurinol loading test was conducted to determine the optimal examination times and specimens required for this test.

Etiopathogenesis of uncommon canine uroliths. Xanthine, carbonate, drugs, and drug metabolites.

Metabolic disorders, medication, and diagnostic agents may be associated with urolithiasis in dogs. Examples of uroliths that have been uncommonly encountered in dogs include xanthine, dolomite, tetracycline, and sulfonamides. Detection of these and other apparently uncommon uroliths requires a high index of suspicion and proper methods of analysis.

Prevention of recurrent uric acid and calcium oxalate stones by administration of the xanthine oxidase inhibitors Milurit 100 and Milurit 300.

Disturbances in purine metabolism with hyperuricaemia and/or hyperuricosuria are a risk factor in uric acid and Ca oxalate stone formation. By way of a competitive xanthine oxidase inhibition, the formation of uric acid is reduced by allopurinol. In investigations on two groups of patients, Milurit could be demonstrated to decrease the uric acid levels in serum and urine. No differences could be seen in the dosages of 3 x 100 mg or 1 x 300 mg Milurit. Therefore, in stone recurrence prevention, the administration of Milurit 300 is recommended.

[Methods of isolation and determination of urinary 4-thio-6-hydroxypyrazolo(3,4 d)pyrimidine in patients treated with thiopurinol]. / Méthodes d'isolement et de détermination de la 4-thio-6-hydroxypyrazolo(3,4-d)pyrimidine urinaire chez les patients traités par le thiopurinol

Oxithiopurinol, [4-thio-6-hydroxypyrazolo(3,4-d)pyrimidine] has been caracterized in urines of patients treated with Thiopurinol : the principle involved is the precipitation of both oxithiopurinol and uric acid in combination with cupric hydroxide. The urinary oxithopurinol content is determined by means of anion and cation exchange resins. 56 to 70 per cent of the daily dose of Thiopurinol are eliminated in urine as oxithiopurinol.

Determination of allopurinol and oxypurinol in human plasma and urine by liquid chromatography-tandem mass spectrometry.

Allopurinol is used widely for the treatment of gout, but its pharmacokinetics is complex and some patients show hypersensitivity, necessitating careful monitoring and improved detection methods. In this study, a sensitive and reliable liquid chromatography-tandem mass spectrometry method was developed to determine the concentrations of allopurinol and its active metabolite oxypurinol in human plasma and urine using 2,6-dichloropurine as the internal standard (IS). Analytes and the IS were extracted from 0.5ml aliquots of plasma or urine using ethyl acetate and separated on an Agilent Eclipse Plus C18 column using methanol and ammonium formate-formic acid buffer containing 5mM ammonium formate and 0.1% formic acid (95:5, v/v) as the mobile phase (A) for allopurinol or methanol plus 5mM ammonium formate aqueous solution (95:5, v/v) as the mobile phase (B) for oxypurinol. Allopurinol was detected in positive ion mode and the analysis time was about 7min. The calibration curve was linear from 0.05 to 5µg/mL allopurinol in plasma and 0.5-30µg/mL in urine. The lower limit of quantification (LLOQ) was 0.05µg/mL in plasma and 0.5µg/mL in urine. The intra- and inter-day precision and relative errors of quality control (QC) samples were ≤11.1% for plasma and ≤ 8.7% for urine. Oxypurinol was detected in negative mode with an analysis time of about 4min. The calibration curve was linear from 0.05 to 5µg/mL in plasma (LLOQ, 0.05µg/mL) and from 1 to 50µg/mL in urine (LLOQ, 1µg/mL). The intra- and inter-day precision and relative errors were ≤7.0% for plasma and ≤9.6% for urine. This method was then successfully applied to investigate the pharmacokinetics of allopurinol and oxypurinol in humans.

Mechanism of allopurinol induced TPMT inhibition.

Up to 1/5 of patients with wildtype thiopurine-S-methyltransferase (TPMT) activity prescribed azathioprine (AZA) or mercaptopurine (MP) demonstrate a skewed drug metabolism in which MP is preferentially methylated to yield methylmercaptopurine (MeMP). This is known as thiopurine hypermethylation and is associated with drug toxicity and treatment non-response. Co-prescription of allopurinol with low dose AZA/MP (25-33%) circumvents this phenotype and leads to a dramatic reduction in methylated metabolites; however, the biochemical mechanism remains unclear. Using intact and lysate red cell models we propose a novel pathway of allopurinol mediated TPMT inhibition, through the production of thioxanthine (TX, 2-hydroxymercaptopurine). In red blood cells pre-incubated with 250 µM MP for 2h prior to the addition of 250 µM TX or an equivalent volume of Earle's balanced salt solution, there was a significant reduction in the concentration of MeMP detected at 4h and 6h in cells exposed to TX (4 h, 1.68, p=0.0005, t-test). TX acts as a direct TPMT inhibitor with an apparent Ki of 0.329 mM. In addition we have confirmed that the mechanism is relevant to in vivo metabolism by demonstrating raised urinary TX levels in patients receiving combination therapy. We conclude that the formation of TX in patients receiving combination therapy with AZA/MP and allopurinol, likely explains the significant reduction of methylated metabolites due to direct TPMT inhibition.