Vesico-hepato-renal cycling of acidic drugs via their reactive acyl glucuronide metabolites? Studies with diflunisal in rats.

1. Deconjugation-reconjugation cycling of acidic drugs is known to occur in vivo via the hydrolysis of their reactive acyl glucuronide metabolites during their circulation in the blood (systemic cycling) or during their passage through the gut after biliary excretion (enterohepatic cycling). Whether such cycling occurs after renal excretion via hydrolysis in the urinary bladder followed by absorption of liberated drug (vesico-hepato-renal cycling) was investigated in rats using diflunisal (DF) and its acyl glucuronide (DFAG) as model compounds. 2. After administration of DF (1 mg/0.5 mL buffer, pH 7) into the bladder of anaesthetized bile-exteriorized rats, DF appeared rapidly in plasma, achieving peak concentrations of 7 micrograms/mL at 1 h. At 4 h, 30% of the dose was recovered as metabolites, mainly DFAG and DF phenolic glucuronide (DFPG) in bile, while 30% was recovered as unchanged DF from the bladder. 3. By contrast, after intravesical administration of an equimolar amount of DFAG at pH 7 or 5, DFAG itself was not detectable in plasma. Plasma concentrations of DF were barely detectable, with only approximately 1% of the administered dose recovered as metabolites in bile. 4. The data thus show that, although DF itself undergoes facile absorption from the urinary bladder of healthy rats, vesico-hepato-renal cycling of DF via DFAG appears to be of only minor quantitative importance.

Excretion of 3-hydroxy-diflunisal as a monosulphate conjugate--identification using ESI-MS.

Electrospray-ionization mass spectrometry was used to identify a novel, highly polar metabolite of diflunisal isolated from Gunn rat urine. Negative ion spectra were obtained of the sulphate conjugate of diflunisal and the new metabolite, which was identified as a sulphate conjugate of 3-hydroxydiflunisal.

Analysis of polymorphic variation in drug metabolism: III. Glucuronidation and sulfation of diflunisal in man.

The urinary excretion of diflunisal (D) and its metabolites diflunisal sulfate (DS), diflunisal phenolic glucuronide (DPG), and diflunisal acyl glucuronide (DAG) were measured in 110 healthy, drug-free Caucasian volunteers given 50 mg of diflunisal by mouth. When expressed as fractional recoveries, DS, DPG, and DAG were strongly negatively correlated with one another. Metabolic ratios, on the other hand, correlated positively and tended to localize variability within a single enzyme pathway. Thus, females using estrogen-containing oral contraceptives were shown to excrete 50% less DS and 20% more DAG than non-users, and recoveries of DS were reduced by about 30% in cigarette smokers. Kernel density analyses of the log metabolic ratios of DS and DPG were broad-based and unimodal. However, kernel density estimates of the distribution of log metabolic ratios of DAG showed 3 peaks, 1 of which (an extensive metabolizer polymorph) could be removed by excluding contraceptive-using females. Similarly, there were 2 poor metabolizer peaks in the distribution of log metabolic ratios of DS attributable to cigarette smoking and, in females, use of an oral contraceptive. Thus, we conclude that the metabolism of diflunisal is altered by cigarette smoking and oral contraceptives, and that kernel density estimation, as applied to log metabolic ratios, is a sensitive and specific method for detection of polymorphic variation in drug metabolism.

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.

Studies on the reactivity of acyl glucuronides--I. Phenolic glucuronidation of isomers of diflunisal acyl glucuronide in the rat.

Diflunisal (DF) is metabolized primarily to its acyl glucuronide (DAG), phenolic glucuronide (DPG) and sulphate (DS) conjugates. Whereas DPG and DS are stable at physiological pH, DAG is unstable, undergoing hydrolysis (regeneration of DF) and rearrangement (intramolecular acyl migration to the 2-, 3- and 4-O-acyl-positional isomers). We have compared the in vivo disposition of DAG with that of an equimolar mixture of its three isomers after i.v. administration at 10 mg DF equivalents/kg to conscious, bile-exteriorized rats. After dosing with DAG, excretion in urine and bile (46% as DAG), hydrolysis (as assessed by recovery of 9% DPG and 8% DS resulting from reconjugation of liberated DF) and rearrangement (17% recovery as isomers of DAG) were important pathways. Highly polar metabolites excreted almost exclusively in bile and accounting for 13% of the dose were identified as an approximate 4:1 mixture of the 2- and 3-O-isomers of DAG which had been glucuronidated at the phenolic function of the salicylate ring i.e. "diglucuronides" of DF. Evidence for trace quantities only of the phenolic glucuronides of the 4-O-isomer of DAG, and of DAG itself, was found. After dosing rats with an equimolar mixture of the isomers, 52% was recovered (as the isomers) in urine and bile in 6 hr. Hydrolysis was less important--less than 3% (total) of the dose was recovered as DPG and DS. The phenolic glucuronides of the 2- and 3-O-isomers (ratio ca. 3:7) accounted for 37%. Evidence for appreciable formation of the phenolic glucuronide of the 4-O-isomer was not found. In one rat dosed with DPG, there was no evidence for further glucuronidation of the salicylate ring at its carboxy function. The data suggest that the 2- and 3-O-isomers of DAG, but not the 4-O-isomer, DAG itself or DPG, are good substrates for further glucuronidation.

Identification of a hydroxy metabolite of diflunisal in rat and human urine.

1. A new metabolite of diflunisal, a hydroxy derivative, has been identified in rat and human urine following administration of diflunisal. 2. This hydroxy metabolite of diflunisal is excreted in urine of both species as a polar conjugate, most likely a sulphate. 3. Attempts to isolate the polar conjugate in pure form were unsuccessful due to its rapid hydrolysis in the presence of acid, and organic solvents such as diethyl ether. Its breakdown product, however, was more stable and was isolated and purified by semi-preparative h.p.l.c. Unequivocal identification as 3-hydroxy-diflunisal (i.e. hydroxylation in position 3 of the salicylic acid ring) was accomplished by means of FAB-mass spectrometry and n.m.r. spectroscopy. 4. The contribution of this oxidative metabolic pathway to the overall elimination scheme of diflunisal is more important in rat than in man. Gunn rats excrete more of the hydroxy diflunisal conjugate in urine (20-30% of a 50 mg/kg i.v. dose of diflunisal) than Wistar rats. In healthy humans, hydroxylation of diflunisal contributes only to a small extent to the overall biotransformation of diflunisal.

Pharmacokinetics of diflunisal in patients.

There are few pharmacokinetic data available on the disposition of diflunisal in patients; this study, therefore, looked at the oral absorption, distribution and elimination of this drug. Ten pharmacokinetic profiles obtained from 8 patients showed a maximum plasma diflunisal concentration of 62.0 +/- 26.5 mg/L after 2.76 +/- 1.87 hours, and an area under the plasma concentration-time curve (AUC) of 678.3 +/- 362.3 mg/L.h. Significant intra- and intersubject variability was observed in this group of patients. Analysis of biliary secretion of diflunisal in 4 patients suggested a biliary elimination and subsequent enterohepatic circulation ranging between 2.4 and 15.1%. The AUC for diflunisal in synovial fluid collected from 66 patients was about 70% of that for plasma. In none of 28 patients studied could any trace of diflunisal be observed in cerebrospinal fluid, even though the sensitivity of the assay allowed detection of concentrations as low as 0.01 mg/L.

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.

Effect of experimental diabetes on elimination kinetics of diflunisal in rats.

The effects of insulin-deficient diabetes on the elimination of diflunisal were investigated in streptozotocin-treated rats. Diflunisal, a fluorinated salicylate with nonsteroidal antiinflammatory properties, is eliminated primarily as the ester and ether glucuronides. After an iv injection of a 10 mg/kg dose, diabetic rats cleared diflunisal more rapidly than control rats; time-averaged total body clearances were 1.96 +/- 0.29 and 1.10 +/- 0.12 ml/min/kg, respectively. For a low clearance drug such as diflunisal, changes in the total body clearance can result from changes in the extent of plasma protein binding and/or drug metabolic rate. To determine whether the pronounced changes in elimination clearance in diabetic rats were due to the changes in plasma protein binding or enzyme activity, diflunisal was infused to obtain steady state kinetics. At steady state, the unbound intrinsic clearance increased from 43.4 +/- 16.4 ml/min/kg in the control rats to 82.5 +/- 21.1 ml/min/kg in diabetic rats at a high infusion rate (72 micrograms/min). When the infusion rate was lowered to 4.5 micrograms/min, the respective values for the unbound intrinsic clearance were 353 +/- 101 ml/min/kg and 561 +/- 112 ml/min/kg. Diabetic rats, however, showed no changes in plasma protein binding of diflunisal. The data suggest that the elimination of diflunisal was increased as a result of increased enzyme activity. Insulin treatment appeared to reverse the diabetic effect, suggesting that the effect on drug metabolism was the result of insulin deficiency and not a secondary or nonspecific effect of streptozotocin.(ABSTRACT TRUNCATED AT 250 WORDS)

High-performance liquid chromatographic method for the simultaneous quantitation of diflunisal and its glucuronide and sulfate conjugates in human urine.

A direct high-performance liquid chromatographic (HPLC) assay was developed to simultaneously quantitate diflunisal and its three known metabolites (i.e., the phenolic and acyl glucuronides and the sulfate conjugate) in human urine. Chromatographically pure standards of the diflunisal conjugates were isolated from urine of volunteers following ingestion of multiple doses of diflunisal (500 mg twice daily). Diflunisal, its three conjugates, and an internal standard (naproxen) were separated on a reversed-phase column using gradient elution. The column eluate was monitored fluorometrically (excitation: 258 nm; emission: 428 nm). Urine samples were diluted with phosphate buffer (pH 5.75) and injected onto the column. The limit of detection was approximately 1 microgram/mL for each conjugate and 0.1 microgram/mL for diflunisal. Due to the presence in most urine samples of significant concentrations of rearrangement products of the biosynthetic 1-O-acyl glucuronide of diflunisal, the acyl glucuronide could not be reliably quantitated by direct injection of diluted urine samples. Instead, diflunisal acyl glucuronide was quantitated indirectly following alkaline hydrolysis of the urine samples. The method has been successfully used to investigate the dose-dependent glucuronidation and sulfation of diflunisal in humans.

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

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.

Steady-state disposition of diflunisal: once- versus twice-daily administration.

To evaluate the steady-state bioequivalence of the nonsteroidal antiinflammatory analgesic agent, diflunisal, administered once versus twice daily, 13 healthy volunteers received diflunisal as follows: 1000 mg at 8:00 AM and 500 mg at 8:00 AM and 8:00 PM, each for 14 days in a randomized crossover study. The mean (+/- SD) steady-state peak plasma concentrations were significantly greater after once-daily dosing (186 +/- 25 micrograms/ml vs 150 +/- 37 micrograms/ml; p less than 0.01). The time to peak concentration was also longer after the single-dose regimen (2.5 +/- 0.8 vs 1.9 +/- 0.9 hr; p less than 0.05). The regimens were similar with respect to the mean 24-hour area under the plasma concentration-time curve at steady state (2839 +/- 612 vs 2782 +/- 778 micrograms.hr.ml-1), steady-state plasma concentrations (118 +/- 25 vs 116 +/- 32 micrograms/ml), trough plasma concentration (85 +/- 27 vs 92 +/- 28 micrograms/ml) as well as 24-hour urinary excretion (776 +/- 79 vs 771 +/- 89 mg) of diflunisal. Based on urinary recoveries, the bioequivalence ratio (once vs twice daily) was 1.01 +/- 0.08. These results indicate that diflunisal administered once daily might offer comparable therapeutic effects but be more convenient than a twice-daily regimen.

Assay methodology for quantification of the ester and ether glucuronide conjugates of diflunisal in human urine.

Diflunisal is a salicylate derivative with analgesic and anti-inflammatory properties. It is excreted in the urine as an ether glucuronide, a 1-O-acyl glucuronide and as unchanged drug. The 1-O-acyl glucuronide rearranges to isomeric esters of glucuronic acid under neutral to alkaline pH conditions. The development of a urine assay for the conjugates enables the elucidation of diflunisal non-linear pharmacokinetics. The assay quantitates the ether and ester glucuronides and free diflunisal in urine at 0.5-1.0 micrograms/ml. Analysis of the glucuronides does not require authentic standards.

High-performance liquid chromatographic analysis of diflunisal in plasma and urine: application to pharmacokinetic studies in two normal volunteers.

A high-performance liquid chromatographic (HPLC) assay with fluorescence detection has been developed for the determination of diflunisal in plasma and urine. The plasma or urine, containing naproxen as the internal standard, was extracted with ether-hexane (1:1). The samples were analyzed on a microparticulate column, and the compounds were eluted using a mobile phase of 0.05 M phosphate buffer (pH 3) and methanol. Plasma samples were analyzed from two healthy male subjects who received a 250- and 750-mg oral dose of diflunisal 3 weeks apart. The data were analyzed according to a two-compartment open model. There was a disproportionate increase in the area under the plasma concentration-time curves (AUC 750 mg/AUC 250 mg was 3.84 for subject A and 4.22 for subject B) and a reduction in plasma clearance after the 750-mg dose of diflunisal. These data suggest that the kinetics of diflunisal may be dose dependent.

Effect of antacids on the bioavailability of diflunisal in the fasting and postprandial states.

Diflunisal is long-acting salicylate derivative. We examined the effect of single concomitant doses of three antacids on diflunisal bioavailability under fasting or fed conditions (30 min after finishing a standard meal). With the use of an open, randomized, and balanced design, one 250-mg diflunisal tablet was given to each of 12 healthy men under six conditions: fasted, no antacid; fed, no antacid; fasted, 15 ml of aluminum hydroxide gel; fed, 15 ml of aluminum hydroxide gel; fasted, 10 ml magnesium hydroxide suspension; and fed, 15 ml of an aluminum hydroxide/magnesium hydroxide mixture. Diflunisal plasma 0- to 48-hr area uiven to each of 12 healthy men under six conditions: fasted, no antacid; fed, no antacid; fasted, 15 ml of aluminum hydroxide gel; fed, 15 ml of aluminum hydroxide gel; fasted, 10 ml magnesium hydroxide suspension; and fed, 15 ml of an aluminum hydroxide/magnesium hydroxide mixture. Diflunisal plasma 0- to 48-hr area uiven to each of 12 healthy men under six conditions: fasted, no antacid; fed, no antacid; fasted, 15 ml of aluminum hydroxide gel; fed, 15 ml of aluminum hydroxide gel; fasted, 10 ml magnesium hydroxide suspension; and fed, 15 ml of an aluminum hydroxide/magnesium hydroxide mixture. Diflunisal plasma 0- to 48-hr area under the time curve (AUC), peak plasma concentrations, and 0-to 96-hr urinary excretion were determined. Food (alone) decreased peak plasma concentrations by 16% (P less than 0.05) but did not affect AUC or urinary excretion. Under fasting conditions, aluminum hydroxide reduced AUC by 26% (P less than 0.01), peak plasma concentrations by 46% (P less than 0.01), and urinary excretion by 14% (P less than 0.05). Magenisuum hydroxide suspension (in the fasting state) increased the early plasma concentrations (by 130% at 0.5 hr and 64% at 1 hr, P less than 0.05) and increased AUC by 10% (P less than 0.05) but had no effect on urinary excretion. In the fed state neither aluminum hydroxide nor the aluminum hydroxide/magnesium hydroxide mixture had any detectable effect.

Failure of alkaline diuresis to enhance diflunisal elimination.

1 The effects of alkaline diuresis on the elimination of a single oral dose of 750 mg diflunisal were studied in six healthy male volunteers. 2 The plasma concentrations and half-life of diflunisal were not reduced by alkaline diuresis. 3 The 72 h urinary recovery of unchanged diflunisal was more than doubled with alkaline diuresis, but even so, only 5-7% of the administered dose was excreted unchanged. 4 With alkaline diuresis there was a significant increase in the mean renal clearance of diflunisal from 0.27 to 0.46 ml/min, but there was no significant correlation between the renal clearance of diflunisal and urine flow or pH. 5 However, there was a significant increase in the overall mean renal clearance of diflunisal from 0.22 ml/min over the period 0-24 h to 0.73 ml/min from 48-72 h. 6 Forced alkaline diuresis is unlikely to be of value in diflunisal poisoning.