Sex-difference and the effects of smoking and oral contraceptive steroids on the kinetics of diflunisal

Summary The single dose pharmacokinetics of diflunisal were studied in 4 groups of 6 young volunteers: control men, control women, women taking low estrogen oral contraceptive steroids (OCS), and women smokers (10–20 cigarettes/day).The plasma clearance of diflunisal was significantly higher in men (0.169 ml·min^–1·kg^–1) and in women on OCS (0.165 ml·min^–1·kg^–1) as compared to control women (0.108 ml·min^–1·kg^–1). Partial metabolic clearances of diflunisal by the three conjugative pathways (phenolic and acyl glucuronide formation, sulphate conjugation) were all increased in men and women OCS users as compared to control women. Statistically significant increases, however, were only observed for the partial metabolic clearance of diflunisal by phenolic glucuronidation between men and women (2.91 vs. 1.85 ml·min^–1 respectively), and for the partial clearance by acyl glucuronidation between OCS users and control women (4.81 vs. 3.01 ml·min^–1 respectively).Smoking resulted in a moderate increase (35%) in plasma diflunisal clearance. However, a significant reduction in total urinary recovery of diflunisal and its glucuronide and sulphate conjugates was found in smokers (70.5% in smokers as compared to 84.2–87.2% in the 3 other study groups). Consequently, smoking may have induced hydroxylation, a minor oxidative metabolic pathway of diflunisal recently discovered in man.     

The effect of probenecid on paracetamol metabolism and pharmacokinetics

Summary The influence of probenecid on the pharmacokinetics of paracetamol was investigated in a group of healthy volunteers.Pretreatment with probenecid caused a significant decrease in paracetamol clearance (6.23 to 3.42 ml·min^–1·kg^–1). The urinary excretion of paracetamol sulphate (243 to 193 mg); and paracetamol glucuronide (348 to 74.5 mg) were significantly reduced, whereas that of paracetamol was unchanged.Probenecid was shown to be an uncompetitive inhibitor of paracetamol glucuronidation in vitro, using rat liver microsomes.     

Studies on the renal excretion of the acyl glucuronide, phenolic glucuronide and sulphate conjugates of diflunisal.

1. In five healthy male volunteers given multiple doses of diflunisal (DF), renal clearances (CLR) of the acyl glucuronide (DAG), phenolic glucuronide (DPG) and sulphate (DS) conjugates were about 42, 25 and 13 ml min-1, respectively. 2. These relatively low CLR values are probably due largely to the very high plasma protein binding of the conjugates, found in vitro to be 99.0%, 97.8% and 99.45%, respectively. 3. Thus glomerular filtration plays the minor and active tubular secretion the major role in renal excretion of the three conjugates. 4. This conclusion was supported by the effect of probenecid co-administration, which decreased CLR of DAG and DPG by about 70%. CLR for DS could not be calculated when probenecid was co-administered (because of interference by probenecid metabolites in the analysis of DS in urine). 5. Water-induced diuresis had no effect on CLR of the DF conjugates, consistent with tubular reabsorption being negligible.     

Interindividual variation in the capacity-limited renal glucuronidation of probenecid by humans

A dose of 1,000 mg probenecid was administered orally to 14 human volunteers in order to quantify the maximal rate of formation and excretion of probenecid acyl glucuronide in the urine. Probenecid showed dose-dependent pharmacokinetics. Plasma protein binding of probenecid was high, being somewhat higher in males (90.7±1.4%) than in females (87.9±1.4%; p=0.0019). It was shown that probenecid is metabolized by cytochrome P-450 into at least two phase I metabolites. Each of the metabolites accounted for less than 12% of the dose administered; the main metabolite probenecid acyl glucuronide, representing 42.9±13.2% of the dose, was only present in urine and not in plasma. The renal excretion rate-time profile of probenecid acyl glucuronide showed a plateau value in the presence of an acidic urine pH. This plateau value was maintained for about 10 h at the dose of 1,000 mg. The height of the plateau value depended on the individual and varied between 250 and 800g/min (15–50 mg/h). It was inferred that probenecid acyl glucuronide is formed in the kidney during blood-to-lumen passage through the tubular cells. We conclude that the plateau value in the renal excretion rate of probenecid glucuronide reflects itsV _max of formation.     

Modulated pharmacokinetics and increased small intestinal toxicity of methotrexate in bilirubin-treated rats

Objectives The effect of bilirubin treatment on the pharmacokinetics and small intestinal toxicity of methotrexate was evaluated in rats, since bilirubin and its glucuronide conjugates can suppress multidrug resistance‐associated protein‐mediated transport. Methods Rats were treated intravenously with bilirubin and the various clearances and tissue distribution of methotrexate were estimated under a steady‐state plasma concentration. Intestinal toxicity induced by methotrexate was also evaluated by measuring the leakage of alkaline phosphatase (ALP) activity. Probenecid, an inhibitor for multidrug resistance‐associated protein and organic anion transporters, was used for comparison. Key findings The treatment with bilirubin increased the steady‐state plasma concentration and reduced biliary excretion clearance, urinary excretion clearance and intestinal exsorption clearance of methotrexate, as did treatment with probenecid. The intestinal absorption and jejunum distribution of methotrexate also significantly increased in bilirubin‐ and probenecid‐treated rats. A greater leakage of ALP activity to the luminal fluid, with a lower ALP activity in the intestinal mucosal membrane after intestinal perfusion of methotrexate, was observed in bilirubin‐ and probenecid‐treated rats. Conclusions Hyperbilirubinemia, which is involved under various disease states, may increase the small intestinal accumulation and toxicities of methotrexate, since high plasma concentrations of conjugated bilirubin can suppress the function of multidrug resistance‐associated proteins, which facilitate the efflux of methotrexate out of cells.     

The disposition of paracetamol and the accumulation of its glucuronide and sulphate conjugates during multiple dosing in patients with chronic renal failure

Summary We have compared the disposition of oral paracetamol (1.0 g t.d.s. for 10 days) in 6 healthy volunteers and 6 conservatively-managed patients with chronic renal failure (mean plasma creatinine 451 mol·l^–1). Blood was sampled daily for 10 days before the morning dose of paracetamol.Each day the pretreatment plasma concentrations of paracetamol were higher in the renal failure patients than in the volunteers, with mean values over the 10 days of 3.1 and 1.1 mg·l^–1 respectively. The mean daily plasma concentrations of the sulphate and glucuronide conjugates of paracetamol were markedly higher in the renal failure group and apparent steady-state concentrations of about 25 and 85 mg·1^–1 were reached on the 2nd and 6th days respectively. The mean steady-state plasma concentrations of the glucuronide conjugate on the 7th to 10th days of treatment were positively correlated with the plasma creatinine concentration (r=0.97), but this relationship did not hold for the sulphate conjugate. Cysteine and mercapturate conjugates could only be detected in one patient.Predictions of steady-state concentrations based on previous studies with single doses of paracetamol in renal failure patients were remarkably accurate for the glucuronide but not for the sulphate conjugate.These results are consistent with some extra-renal elimination of retained paracetamol conjugates in patients with chronic renal failure, with limited regeneration of the parent compound. The sulphate metabolite did not accumulate as predicted, possibly because of depletion of inorganic sulphate.     

Diflunisal and its conjugates in patients with renal failure.

Six patients with renal failure were given a single oral dose (250 mg) of diflunisal. In contrast to the acyl glucuronide, the phenolic glucuronide and sulphate conjugates showed the capacity to accumulate in plasma, suggesting that systemic instability of the acyl glucuronide contributes, via hydrolysis, to plasma concentrations of diflunisal itself. Although earlier studies in renal failure patients have almost certainly underestimated diflunisal clearance (by overestimation of plasma diflunisal concentrations through unrecognized acidic hydrolysis of diflunisal sulphate during analysis), the present results suggest that the reported decrease in clearance was not attributable only to this analytical artifact.     

Probenecid inhibits the renal clearance of frusemide and its acyl glucuronide.

The effect of oral probenecid (1 g) on the pharmacokinetics of frusemide (80 mg p.o.) and its acyl glucuronide was studied in nine healthy subjects. Probenecid significantly increased the t1/2,z of frusemide from 2.01 +/- 0.68 to 3.40 +/- 1.48 h (P = 0.0015) and significantly decreased oral clearance from 164 +/- 67.0 to 58.3 +/- 28.1 ml min-1 (P = 0.0001). No effect of probenecid on the plasma protein binding of frusemide was detected. Probenecid significantly increased the tmax of the metabolite frusemide acyl glucuronide from 1.4 to 2.6 h, but had no effect on the tlag, Cmax, t1/2,z and plasma protein binding. The urinary recoveries of unchanged frusemide (39.2 +/- 10.2 vs 34.4 +/- 8.6%, P = 0.28) and its acyl glucuronide (12.1 +/- 2.7 vs 11.8 +/- 3.7%, P > 0.8) were not altered by probenecid. However, probenecid decreased the renal clearance of both frusemide (128 +/- 49 vs 44.0 +/- 18.6 ml min-1, P = 0.0002) and the acyl glucuronide (552 +/- 298 vs 158 +/- 94.0 ml min-1, P < 0.0001). The non-renal clearance of frusemide (36.7 +/- 21.0 vs 15.2 +/- 13.4 ml min-1, P = 0.0068) was also decreased. The clinical relevance of the study relates to the possible conjugation of frusemide in the kidney and the role of the conjugate in the pharmacodynamic effect.     

The effects of frusemide and probenecid on the pharmacokinetics of phenprocoumon

We have studied the pharmacokinetics of phenprocoumon with and without co-administration of frusemide and probenecid in two groups of 17 healthy volunteers.Frusemide 40 mg b.i.d. for 7 days did not interact with phenprocoumon to a significant extent. Probenecid 500 mg q.i.d. for 7 days significantly accelerated the overall elimination of phenprocoumon, as indicated by a decrease in AUC from 295 to 157 g · h · ml^–1, and a reduction in the fraction of the dose excreted by the kidneys.     

Both phenolic and acyl glucuronidation pathways of diflunisal are impaired in liver cirrhosis

Summary The pharmacokinetics of diflunisal, a salicylate derivative that undergoes phenolic and acyl glucuronidation as well as sulphate conjugation, has been studied after a single oral dose (250 mg) in patients with cirrhosis (n=5) and in healthy controls (n=5).The plasma clearance of total (bound + unbound) diflunisal was 10.2 ml · min^–1 in the control subjects and it was not affected by cirrhosis (10.9 ml · min^–1). The plasma protein binding of diflunisal was significantly reduced in cirrhosis; the percentage of unbound diflunisal in plasma was 0.089 in the controls and 0.147 in the patients with cirrhosis. Plasma clearance of unbound diflunisal was significantly impaired in cirrhosis: 11.51 · min^–1 in control subjects vs 7.41 · min^–1 in cirrhotics.In cirrhotic patients, the unbound partial clearances to the phenolic and acyl glucuronides were both significantly reduced, by approximately 38%. The unbound partial clearance to the sulphate conjugate was not significantly affected by cirrhosis.The results show that both the phenolic and acyl glucuronidation pathways of diflunisal are equally susceptible to the effects of liver cirrhosis.     

Capacity-limited renal glucuronidation of probenecid by humans A pilotVmax-finding study

Probenecid shows dose-dependent pharmacokinetics. When in one volunteer the dose is increased from 250 to 1,500 mg orally, thet _1/2 increased from 3 to 6 h. TheC _max was 14g/ml with a dosage of 250 mg, 31g/ml with 500 mg, 70g/ml with 1,000 mg and 120g/ml with 1,500 mg. Thet _max remained 1 h for all four dosages. The AUC/dose ratio increased with the dose, indicating nonlinear elimination. The total body clearance declined from 64.5 ml/min for 250 mg to 26.0 ml/min for 1,500 mg. The renal clearance of probenecid remained constant, 0.6–0.8 ml/min. Protein binding of probenecid is high (91%) and independent of the dose. The phase I metabolites show lower protein binding values (34–59%). The protein binding of probenecid glucuronidein vitro (spiked plasma) is 75%. Probenecid is metabolized by cytochrome P-450 to three phase I metabolites. Each of the metabolites accounts for less than 10% of the dose administered; the percentage recovered in the urine is independent of the dose. The main metabolite probenecid glucuronide is only present in urine and not in plasma. The renal excretion rate-time profile of probenecid glucuronide shows a plateau value of approximately 700g/min (46 mg/h) with acidic urine pH. The duration of this plateau value depends on the dose: 2 h at 500 mg, 10 h at 1,000 mg and 20 h at 1,500 mg. It is demonstrated that probenecid glucuronide must be formed in the kidney during its passage of the tubule. The plateau value in the renal excretion rate of probenecid value reflects itsV _max of formation.     

Direct measurement of probenecid and its glucuronide conjugate by means of high pressure liquid chromatography in plasma and urine of humans

Probenecid with its phase-I metabolites, and phase-II glucuronide conjugate can be analysed by a gradient high pressure liquid chromatographic method. Probenecid glucuronide in plasma with pH 7.4 is not stable and declines to 10% of the original value within 6 h (t_1/21 h). Probenecid glucuronide is stable in urine with pH 5.0, moderately unstable at pH 6.0 (t_1/210 h), and unstable at pH 8.0 (t_1/20.5 h). Probenecid glucuronide is stable in water and 0.01 mol/l phosphoric acid in the autosampler of the high pressure liquid chromatograph. The decrease in concentration in water is 5.5% during 9 h and 0% in diluted acid. Probenecid glucuronide and the phase-I metabolites were not detectable in plasma. The main compound in fresh urine is the phase-II conjugate probenecid glucuronide (62% of a 500 mg dose); the phase-I metabolites are present and only a trace of probenecid is present. The percentage of the dose of the phase-I metabolites varies between 5 and 10, while hardly any probenecid is excreted unchanged (0.33%).     

Effects of blockage of urine and/or bile flow on diflunisal conjugation and disposition in rats

1. The effects of surgical blockage of either or both of the urinary and biliary excretion routes on the elimination of diflunisal (DF) and its conjugates were investigated in pentobarbitone-anaesthetized rats given DF at 10mg/kg i.v.

2. In control animals the acyl glucuronide and phenolic glucuronide conjugates were excreted predominantly in bile, whereas the sulphate conjugate was eliminated almost exclusively in urine.

3. Bilateral ureter ligation had little effect on DF elimination, except for accumulation of the sulphate conjugate in plasma. Compensatory biliary excretion did not occur.

4. Total plasma clearance of DF decreased from 1.01 to 0.68 ml/min per kg following bile duct ligation. Plasma concentrations and urinary excretion of the glucuronides were elevated.

5. In rats with blockage of both urinary and biliary excretion routes, total plasma clearance of DF decreased to 0.59 ml/min per kg. Both the sulphate and phenolic glucuronide conjugates accumulated in plasma, whereas the acyl glucuronide peaked at 30 min and then declined in parallel with DF. The latter result indicates systemic instability of DF acyl glucuronide with hydrolytic regeneration of DF as the likely major consequence.     

Effects of blockage of urine and/or bile flow on diflunisal conjugation and disposition in rats

1. The effects of surgical blockage of either or both of the urinary and biliary excretion routes on the elimination of diflunisal (DF) and its conjugates were investigated in pentobarbitone-anaesthetized rats given DF at 10 mg/kg i.v. 2. In control animals the acyl glucuronide and phenolic glucuronide conjugates were excreted predominantly in bile, whereas the sulphate conjugate was eliminated almost exclusively in urine. 3. Bilateral ureter ligation had little effect on DF elimination, except for accumulation of the sulphate conjugate in plasma. Compensatory biliary excretion did not occur. 4. Total plasma clearance of DF decreased from 1.01 to 0.68 ml/min per kg following bile duct ligation. Plasma concentrations and urinary excretion of the glucuronides were elevated. 5. In rats with blockage of both urinary and biliary excretion routes, total plasma clearance of DF decreased to 0.59 ml/min per kg. Both the sulphate and phenolic glucuronide conjugates accumulated in plasma, whereas the acyl glucuronide peaked at 30 min and then declined in parallel with DF. The latter result indicates systemic instability of DF acyl glucuronide with hydrolytic regeneration of DF as the likely major consequence.     

Renal tubular transport of paracetamol and its conjugates in the dog.

1 The renal tubular transport of paracetamol and its conjugates was investigated with renal clearance and stop flow studies in the dog. Paracetamol is sparingly bound to plasma proteins and therefore undergoes glomerular filtration. It is reabosrbed in the renal tubules by simple diffusion. 2 The conjugates of paracetamol, the sulphate and the glucuronide, both undergo glomerular filtration being weakly protein bound. At low concentrations in plasma both compounds are secreted by an active transport process. At higher concentrations both compounds are reabsorbed. Clearances are not dependent on urinary pH or flow rate. It is concluded that reabsorption is not a passive process but that there is an active bidirectional transport of the conjugates. 3 Net tubular secretion of the sulphate, but not the glucuronide, conjugate was inhibited by the administration of probenecid.     

Capacity-limited renal glucuronidation of probenecid by humans

Probenecid shows dose-dependent pharmacokinetics. When in one volunteer the dose is increased from 250 to 1,500 mg orally, thet _1/2 increased from 3 to 6 h. TheC _max was 14μg/ml with a dosage of 250 mg, 31μg/ml with 500 mg, 70μg/ml with 1,000 mg and 120μg/ml with 1,500 mg. Thet _max remained 1 h for all four dosages. The AUC/dose ratio increased with the dose, indicating nonlinear elimination. The total body clearance declined from 64.5 ml/min for 250 mg to 26.0 ml/min for 1,500 mg. The renal clearance of probenecid remained constant, 0.6–0.8 ml/min. Protein binding of probenecid is high (91%) and independent of the dose. The phase I metabolites show lower protein binding values (34–59%). The protein binding of probenecid glucuronidein vitro (spiked plasma) is 75%. Probenecid is metabolized by cytochrome P-450 to three phase I metabolites. Each of the metabolites accounts for less than 10% of the dose administered; the percentage recovered in the urine is independent of the dose. The main metabolite probenecid glucuronide is only present in urine and not in plasma. The renal excretion rate-time profile of probenecid glucuronide shows a plateau value of approximately 700μg/min (46 mg/h) with acidic urine pH. The duration of this plateau value depends on the dose: 2 h at 500 mg, 10 h at 1,000 mg and 20 h at 1,500 mg. It is demonstrated that probenecid glucuronide must be formed in the kidney during its passage of the tubule. The plateau value in the renal excretion rate of probenecid value reflects itsV _max of formation.     

Biliary excretion of diflunisal conjugates in patients with T-tube drainage

Summary The urinary and biliary excretion of diflunisal and its glucuronide and sulphate conjugates were studied in 10 patients following cholecystectomy.Total urinary excretion (0–24 h) was 36.6±16.4% of the 250 mg dose. Biliary excretion (0–24 h) was restricted to the phenolic and acyl glucuronides and accounted for 3.7±2.3% of the dose. An inverse relationship existed between urinary and biliary excretion of diflunisal and its conjugates.The data indicate that the reduced plasma clearance of diflunisal in patients with renal failure may, at least in part, be due to increased biliary excretion of diflunisal glucuronides followed by hydrolysis in the gut and reabsorption of diflunisal i.e. enterohepatic cycling.     

The effect of multiple dosage on the kinetics of glucuronidation and sulphation of diflunisal in man.

1. The single (250 and 500 mg) and multiple dose (250 and 500 mg twice daily for 15 days) pharmacokinetics of diflunisal were compared in young volunteers. 2. The plasma clearance of diflunisal was lowered significantly after multiple dose administration (5.2 +/- 1.2 and 4.2 +/- 0.7 ml min-1 for the 250 and 500 mg twice daily regimens, respectively) as compared with single dose administration 11.4 +/- 3.1 and 9.9 +/- 2.0 ml min-1 for the 250 and 500 mg single doses, respectively). 3. The partial metabolic clearances of diflunisal by acyl and phenolic glucuronide formation were lowered significantly (greater than 50%) after multiple dose administration. 4. The urinary recovery of diflunisal sulphate increased as a function of dose: 6.1 +/- 2.8 and 9.1 +/- 3.5% following the 250 and 500 mg single dose, respectively, and 10.9 +/- 3.1 and 15.9 +/- 3.6% following the 250 and 500 mg twice daily regimens. The partial metabolic clearance of diflunisal by sulphate conjugation was unchanged following multiple dose administration. 5. The plasma protein binding of diflunisal was concentration-dependent. Analysis of unbound plasma clearances of diflunisal showed that its total plasma clearance following 500 mg twice daily was affected by both saturable glucuronidation and concentration-dependent plasma binding.     

Effect of Probenecid on the Enantioselective Pharmacokinetics of Oxprenolol and Its Glucuronides in the Rabbit

Purpose. To study the effect of probenecid on the stereoselective pharmacokinetics of oxprenolol and its glucuronides in the rabbit. Methods. An oral dose of 50 mg/kg racemic oxprenolol was given to nine rabbits twice, in random sequence with and without the concurrent administration of probenecid. Oxprenolol enantiomers were determined in plasma and urine by an enantioselective HPLC method. Oxprenolol glucuronides were measured in plasma and urine after enzymatic hydrolysis. Results. The disposition of the oxprenolol enantiomers in rabbits is stereoselective, mainly due to a difference in metabolism. Renal excretion is only a minor elimination route for unchanged oxprenolol, and the renal clearances of the enantiomers are similar. Pre-treatment with probenecid did not affect the plasma concentrations of the oxprenolol enantiomers, but there was a slight decrease in their urinary excretion. The plasma concentrations of the oxprenolol glucuronides are much higher than those of the parent enantiomers, and those of (S)-glucuronide are about twice those of its antipode. About 10% of the oxprenolol dose is excreted in the urine as glucuronides. The renal clearances of both glucuronides are similar, and markedly higher than the creatinine clearance. After probenecid, the mean glucuronide plasma levels were markedly higher, with for both glucuronides a more than twofold increase in mean AUC. Probenecid decreased the renal clearance of both glucuronides to about 30%. Moreover, it decreased slightly the formation clearance of (S)-glucuronide, while the formation clearance of (R)-glucuronide was not significantly influenced. Conclusions. Our results show that in the rabbit, both oxprenolol glucuronide diastereomers are actively secreted by the kidney, and that this process is inhibited by probenecid.     

Effect of probenecid on the renal and nonrenal clearances of zidovudine and its distribution into cerebrospinal fluid in the rabbit

The effect of probenecid on the renal excretion of zidovudine (3'-azido-3'-deoxythymidine; AZT) and its distribution into CSF was studied in the rabbit. Although probenecid is chemically unrelated to AZT, it has been shown that probenecid inhibits AZT elimination in Acquired Immunodeficiency Syndrome (AIDS) patients. The effect of probenecid on the renal clearance of AZT after an iv bolus dose was studied in crossover experiments in the absence (control) and the presence of a continuous iv infusion of probenecid. Probenecid coadministration increased the AZT plasma AUC by 70%, by proportionally decreasing the total body clearance. The renal clearance decreased by 50%. The effect of probenecid on the renal clearance of AZT at steady state was studied by measuring the renal clearance of AZT at different steady-state plasma probenecid concentrations. The renal clearance of AZT decreased with increasing probenecid concentration, suggesting competitive inhibition of the secretion of AZT in the renal tubule. The relationship between AZT renal clearance and probenecid plasma concentrations, during and after probenecid iv infusion in conscious and in anesthetized uretercannulated rabbits, showed hysteresis, indicating that probenecid plasma concentration is different from the concentration at the site of interaction. This suggests the presence of an effect compartment for the inhibition of AZT renal excretion by probenecid. The effect of probenecid on the CSF distribution of AZT was also studied in the rabbit. Probenecid coadministration caused a sevenfold increase in the AZT AUCCSF in probenecid-treated rabbits when compared with controls.(ABSTRACT TRUNCATED AT 250 WORDS)