Repurposing Benzbromarone for Familial Amyloid Polyneuropathy: A New Transthyretin Tetramer Stabilizer

Transthyretin (TTR) is a homotetrameric protein involved in human amyloidosis, including familial amyloid polyneuropathy (FAP). Discovering small-molecule stabilizers of the TTR tetramer is a therapeutic strategy for these diseases. Tafamidis, the only approved drug for FAP treatment, is not effective for all patients. Herein, we discovered that benzbromarone (BBM), a uricosuric drug, is an effective TTR stabilizer and inhibitor against TTR amyloid fibril formation. BBM rendered TTR more resistant to urea denaturation, similarly to iododiflunisal (IDIF), a very potent TTR stabilizer. BBM competes with thyroxine for binding in the TTR central channel, with an IC50 similar to IDIF and tafamidis. Results obtained by isothermal titration calorimetry (ITC) demonstrated that BBM binds TTR with an affinity similar to IDIF, tolcapone and tafamidis, confirming BBM as a potent binder of TTR. The crystal structure of the BBM-TTR complex shows two molecules binding deeply in the thyroxine binding channel, forming strong intermonomer hydrogen bonds and increasing the stability of the TTR tetramer. Finally, kinetic analysis of the ability of BBM to inhibit TTR fibrillogenesis at acidic pH and comparison with other stabilizers revealed that benzbromarone is a potent inhibitor of TTR amyloidogenesis, adding a new interesting scaffold for drug design of TTR stabilizers.

Modifications of diflunisal and meclofenamate carboxyl groups affect their allosteric effects on GABAA receptor ligand binding

Gamma-aminobutyric acid type A receptors (GABAAR) are allosterically modulated by the nonsteroidal anti-inflammatory drugs diflunisal and fenamates. The carboxyl group of these compounds is charged at physiological pH and therefore penetration of the compounds into the brain is low. In the present study we have transformed the carboxyl group of diflunisal and meclofenamate into non-ionizable functional groups and analyzed the effects of the modifications on stimulation of [(3)H]muscimol binding and on potentiation of γ-aminobutyric acid-induced displacement of 4'-ethenyl-4-n-[2,3-(3)H]propylbicycloorthobenzoate. N-Butylamide derivative of diflunisal modulated radioligand binding with equal or higher potency than the parent compound, while diflunisalamide showed reduced allosteric effect as compared to diflunisal. Amide derivative of meclofenamate equally affected radioligand binding parameters, while both diflunisal and meclofenamate methyl esters were less active than the parent compounds. Our study clearly demonstrates that an intact carboxyl group in diflunisal and meclofenamate is not indispensable for their positive GABAAR modulation. Further derivatization of the compound might yield compounds with higher selectivity for GABAARs that could be utilized in drug development.

In-vitro study on the competitive binding of diflunisal and uraemic toxins to serum albumin and human plasma using a potentiometric ion-probe technique

The competitive binding of diflunisal and three well-known uraemic toxins (3-indoxyl sulfate, indole-3-acetic acid and hippuric acid) to bovine serum albumin (BSA), human serum albumin (HSA) and human plasma was studied by direct potentiometry. The method used the potentiometric drug ion-probe technique with a home-made ion sensor (electrode) selective to the drug anion. The site-oriented Scatchard model was used to describe the binding of diflunisal to BSA, HSA and human plasma, while the general competitive binding model was used to calculate the binding parameters of the three uraemic toxins to BSA. Diflunisal binding parameters, number of binding sites, ni and association constants for each class of binding site, Ki, were calculated in the absence and presence of uraemic toxins. Although diflunisal exhibits high binding affinity for site I of HSA and the three uraemic toxins bind primarily to site II, strong interaction was observed between the drug and the three toxins, which were found to affect the binding of diflunisal on its primary class of binding sites on both BSA and HSA molecules and on human plasma. These results are strong evidence that the decreased binding of diflunisal that occurs in uraemic plasma may not be solely attributed to the lower albumin concentration observed in many patients with renal failure. The uraemic toxins that accumulate in uraemic plasma may displace the drug from its specific binding sites on plasma proteins, resulting in increased free drug plasma concentration in uraemic patients.

Orally administered diflunisal stabilizes transthyretin against dissociation required for amyloidogenesis

OBJECTIVE

Rate-limiting transthyretin (TTR) tetramer dissociation and monomer misfolding enable misassembly into numerous aggregate morphologies including amyloid, a process genetically linked to and thought to cause amyloid pathology. T119M TTR trans-suppressor subunit inclusion into tetramers otherwise composed of disease-associated subunits ameliorates human amyloidosis by increasing the tetramer dissociation barrier. Diflunisal binding to the 99% unoccupied L-thyroxine binding sites in TTR also increases the tetramer dissociation barrier; hence, we investigated the feasibility of using diflunisal for the treatment of human TTR amyloidosis using healthy volunteers.

METHODS

Diflunisal (125, 250 or 500 mg bid) was orally administered to groups of 10 subjects for 7 days to evaluate serum diflunisal concentration, diflunisal binding stoichiometry to TTR, and the extent of diflunisal imposed TTR kinetic stabilization against urea- and acid-mediated TTR denaturation in human serum. The rates of urea-mediated tetramer dissociation and acid-mediated aggregation as a function of diflunisal concentration were also evaluated in vitro, utilizing physiologically relevant concentrations identified by the above experiments.

RESULTS

In the 250 mg bid group, 12 h after the 13th oral dose, the diflunisal serum concentration of 146 +/- 39 microM was sufficient to afford a TTR binding stoichiometry exceeding 0.95 +/- 0.13 ( approximately 1.75 corrected). Diflunisal binding to TTR at this dose slowed urea-mediated dissociation and acid-mediated TTR aggregation at least, threefold (p < 0.05) in serum and in vitro, consistent with kinetic stabilization of TTR.

CONCLUSION

Diflunisal-mediated kinetic stabilization of TTR should ameliorate TTR amyloidoses, provided that the nonsteroidal anti-inflammatory drug liabilities can be managed clinically.

Selective binding to transthyretin and tetramer stabilization in serum from patients with familial amyloidotic polyneuropathy by an iodinated diflunisal derivative

In familial amyloidotic polyneuropathy, TTR (transthyretin) variants are deposited as amyloid fibrils. It is thought that this process involves TTR tetramer dissociation, which leads to partially unfolded monomers that aggregate and polymerize into amyloid fibrils. This process can be counteracted by stabilization of the tetramer. Several small compounds, such as diclofenac, diflunisal and flufenamic acid, have been reported to bind to TTR in vitro, in the T4 (thyroxine) binding channel that runs through the TTR tetramer, and consequently are considered to stabilize TTR. However, if these agents bind plasma proteins other than TTR, decreased drug availability will occur, compromising their use as therapeutic agents for TTR amyloidosis. In the present work, we compared the action of these compounds and of new derivatives designed to increase both selectivity of binding to TTR and inhibitory potency in relation to TTR amyloid fibril formation. We found two diflunisal derivatives that, in contrast with diclofenac, flufenamic acid and diflunisal, displaced T4 from TTR in plasma preferentially over binding to albumin and thyroxine binding globulin. The same diflunisal derivatives also had a stabilizing effect on TTR tetramers in plasma, as studied by isoelectric focusing of whole plasma under semi-denaturing conditions. In addition, by transmission electron microscopy, we demonstrated that, in contrast with other proposed TTR stabilizers (namely diclofenac, flufenamic acid and diflunisal), one of the diflunisal derivatives tested efficiently inhibited TTR aggregation. Taken together, our ex vivo and in vitro studies present evidence for the selectivity and efficiency of novel diflunisal derivates as TTR stabilizers and as inhibitors of fibril formation.

Diflunisal Analogues Stabilize the Native State of Transthyretin. Potent Inhibition of Amyloidogenesis

Analogues of diflunisal, an FDA-approved nonsteroidal antiinflammatory drug (NSAID), were synthesized and evaluated as inhibitors of transthyretin (TTR) aggregation, including amyloid fibril formation. High inhibitory activity was observed for 26 of the compounds. Of those, eight exhibited excellent binding selectivity for TTR in human plasma (binding stoichiometry >0.50, with a theoretical maximum of 2.0 inhibitors bound per TTR tetramer). Biophysical studies reveal that these eight inhibitors dramatically slow tetramer dissociation (the rate-determining step of amyloidogenesis) over a duration of 168 h. This appears to be achieved through ground-state stabilization, which raises the kinetic barrier for tetramer dissociation. Kinetic stabilization of WT TTR by these eight inhibitors is further substantiated by the decreasing rate of amyloid fibril formation as a function of increasing inhibitor concentration (pH 4.4). X-ray cocrystal structures of the TTR.18(2) and TTR.20(2) complexes reveal that 18 and 20 bind in opposite orientations in the TTR binding site. Moving the fluorines from the meta positions in 18 to the ortho positions in 20 reverses the binding orientation, allowing the hydrophilic aromatic ring of 20 to orient in the outer binding pocket where the carboxylate engages in favorable electrostatic interactions with the epsilon-ammonium groups of Lys 15 and 15'. The hydrophilic aryl ring of 18 occupies the inner binding pocket, with the carboxylate positioned to hydrogen bond to the serine 117 and 117' residues. Diflunisal itself appears to occupy both orientations based on the electron density in the TTR.1(2) structure. Structure-activity relationships reveal that para-carboxylate substitution on the hydrophilic ring and dihalogen substitution on the hydrophobic ring afford the most active TTR amyloid inhibitors.

Preparation of solid dispersions of nonsteroidal anti-inflammatory drugs with acrylic polymers and studies on mechanisms of drug-polymer interactions

This work studied the mechanisms of interaction between Eudragit RS100 (RS) and RL100 (RL) polymers with 3 nonsteroidal anti-inflammatory drugs: diflunisal (DIF), flurbiprofen (FLU), and piroxicam (PIR). Solid dispersions of polymers and drugs at different weight ratios were prepared by coevaporation of their ethanol solutions. The resulting coevaporates were characterized in the solid state (Fourier-transformed infrared spectroscopy (FT-IR) IR, differential scanning calorimetry, powder-x-ray diffractometry) as well as by studying the in vitro drug release in a gastroenteric environment. Absorption tests from drug solutions to the solid polymers were also performed to better explain the mechanism of interactions between them. The preparative conditions did not induce changes in the crystalline state of the drugs (amorphization or polymorphic change). Drugs strongly interacted with the ammonium groups present in polymers, giving an electrostatic interaction that reinforced the mere physical dispersion of drug molecules within polymer networks. Such interactions are related to the chemical structure of the drugs and to their dissociated or undissociated state. The dispersion of drugs in the polymer matrices strongly influenced their dissolution rate, which appeared slower and more gradual than those of the pure drugs, when polymer ratios were increased. RL coevaporates usually displayed higher dissolution rates. The kinetic evaluation of the dissolution profile, however, suggested that both the drug solubility in the external medium and its diffusion capacity within the polymer network are involved. In the sorption experiments, RL showed a greater adsorptive capacity than RS, in relation to the greater number of quaternary ammonium functions, which behave as activity sites for the electrostatic interactions. In the presence of Tris-HCl buffer (pH 7.4), drug adsorption was reduced, as a consequence of the competition of the chloride ions with drug anions for the polymer binding sites. In general, DIF and FLU displayed a similar interaction with RS and RL active sites; PIR's was different. The different molecular structures of these agents can justify such findings. The presence of a carboxyl group (instead of another dissociable acidic moiety, like the hydroxy-enolic one in the PIR molecule) could help explain the strong interaction with RS and RL polymers' quaternary ammonium centers. Preliminary studies like ours are important in helping develop better forecasting and increasing the understanding of the incorporation/release behavior of drugs from particulate delivery systems that can be made from these polymers.

Inhibition of proliferation of HT-29 colon adenocarcinoma cells by carboxylate NSAIDs and their acyl glucuronides

Many nonsteroidal anti-inflammatory drugs (NSAIDs) which have antiproliferative activity in colon cancer cells are carboxylate compounds forming acyl glucuronide metabolites. Acyl glucuronides are potentially reactive, able to hydrolyse, rearrange into isomers, and covalently modify proteins under physiological conditions. This study investigated whether the acyl glucuronides (and isomers) of the carboxylate NSAIDs diflunisal, zomepirac and diclofenac had antiproliferative activity on human adenocarcinoma HT-29 cells in culture. Included as controls were the carboxylate NSAIDs themselves, the non-carboxylate NSAID piroxicam, and the carboxylate non-NSAID valproate, as well as its acyl glucuronide and isomers. The compounds were incubated at 1-3000 microM with HT-29 cells for 24 hr, with [3H]-thymidine added for an additional 2 hr incubation. IC50 values were calculated from the concentration-inhibition response curves for thymidine uptake. The four NSAIDs inhibited thymidine uptake, with IC50 values about 200-500 microM. All of the NSAID acyl glucuronides (and isomers, tested in the case of diflunisal) showed antiproliferative activity broadly comparable to the parent drugs. This activity may stem from direct uptake of intact glucuronide/isomers followed by covalent modification of proteins critical in the cell replication process. However, hydrolysis during incubation and cellular uptake of liberated parent NSAID will play a role. In HT-29 cells incubated with zomepirac, covalently modified proteins in cytosol were detected by immunoblotting with a zomepirac antibody, suggesting that HT-29 cells do have the capacity to glucuronidate zomepirac. The anti-epileptic drug valproate had no effect on inhibition of thymidine uptake, though, surprisingly, its acyl glucuronide and isomers were active. The reasons for this are unclear at present.

Rational design of diflunisal analogues with reduced affinity for human serum albumin

Many lead compounds bind to serum albumin and exhibit markedly reduced efficacy in vivo as compared to their potency in vitro. To aid in the design of compounds with reduced albumin binding, we performed nuclear magnetic resonance (NMR) structural and binding studies on the complex between domain III of human serum albumin (HSA-III) and diflunisal, a cyclooxygenase inhibitor with antiinflammatory activity. The structural studies indicate that the aromatic rings of diflunisal are involved in extensive and specific interactions with hydrophobic residues that comprise the binding pocket in subdomain IIIA. The carboxylic acid of diflunisal forms electrostatic interactions with the protein similar to those observed in the X-ray structure of HSA complexed to myristic acid. In addition to the structural studies, NMR-derived binding constants were obtained for diflunisal and closely related analogues to develop a structure-affinity relationship for binding to subdomain IIIA. On the basis of the structural and binding data, compounds were synthesized that exhibit more than a 100-fold reduction in binding to domain III of HSA, and nearly a 10-fold reduction in affinity for full length albumin. Significantly, several of these compounds maintain activity against cyclooxygenase-2. These results suggest a rational strategy for designing out albumin binding in potential drug molecules by using structure-based design in conjunction with NMR-based screening.

Glucuronidation of R- and S-ketoprofen, acetaminophen, and diflunisal by liver microsomes of adjuvant-induced arthritic rats

The effect of adjuvant-induced arthritis on hepatic microsomal glucuronidation was studied in the rat. Arthritis was induced by injection of Mycobacterium butyricum suspended in liquid paraffin. Vmax and the Michaelis-Menten constant values for the in vitro glucuronidation of R- and S-ketoprofen, acetaminophen, and diflunisal by liver microsomes obtained from control and adjuvant-induced arthritic rats were compared. In addition, uridine 5'-diphosphate-glucuronosyltransferase activity toward bilirubin and p-nitrophenol, as well as levels of cytochrome P-450 and beta-glucuronidase were determined in these microsomal preparations. Adjuvant-induced arthritis resulted in a significant reduction in hepatic cytochrome P-450 levels and in p-nitrophenol glucuronidation (5.65 +/- 0.40 versus 2.58 +/- 0.27 micromol.min/mg protein in control and arthritic rats, respectively, mean +/- S.E.M.). Glucuronidation of bilirubin and beta-glucuronidase activities in liver microsomes and in plasma were not affected by adjuvant-induced arthritis. Vmax (nmol/min/mg protein) for the formation of R-ketoprofen glucuronide, S-ketoprofen glucuronide, diflunisal phenolic glucuronide, and diflunisal acyl glucuronide was significantly decreased in arthritic rats (0.68 +/- 0.10, 0.77 +/- 0. 12, 0.044 +/- 0.005, 0.26 +/- 0.03, respectively) compared with control rats (1.45 +/- 0.04, 1.60 +/- 0.04, 0.087 +/- 0.008, 0.46 +/- 0.04, respectively). Glucuronidation of p-nitrophenol, ketoprofen and diflunisal, substrates which seem to be at least partly glucuronidated in the rat by isoenzymes of the UGT2B subfamily, was impaired in adjuvant-induced arthritis. Glucuronidation of bilirubin and acetaminophen, substrates of UGT1- isoenzymes, was not affected by adjuvant-induced arthritis. It seems, therefore, that adjuvant-induced arthritis in the rat leads to impaired glucuronidation of substrates of the UGT2B subfamily.

Hepatobiliary transport of diflunisal conjugates and taurocholate by the perfused rat liver: the effect of chronic exposure of rats to diflunisal

Acyl glucuronides are reactive electrophilic metabolites of carboxylate drugs which can form covalent adducts with endogenous macromolecules such as serum albumin and hepatic proteins. Such adducts have been suggested as initiating factors in certain immune and toxic responses to acidic drugs. In the present study, pretreatment of rats with high daily doses (50 mg/kg orally) of the non-steroidal anti-inflammatory drug (NSAID) diflunisal (DF) for 35 days, followed by perfusion of the isolated liver with 3 mg DF for 3 hr, resulted in appreciable concentrations of covalent adducts of DF with hepatic tissue (3.68 microg DF/g liver). Immunoblotting using a rabbit polyclonal DF antiserum showed the major DF-modified bands at about 110, 140 and 200 kDa. A vehicle-pretreated control group achieved adduct concentrations of only 0.37 microg DF/g liver, with the 200 kDa band not detectable in immunoblots. Elimination of DF from perfusate of the isolated perfused rat liver (IPRL) preparation was the same (t1/2 about 3.4 hr) in both DF- and vehicle-pretreated groups. Appearance of the sulfate (DS) conjugate, the major metabolite in perfusate, was also similar. However, higher concentrations of the acyl glucuronide (DAG) and phenolic glucuronide (DPG) conjugates were found in perfusate at later times, though a statistically significant difference in area under the concentration-time curve was found only in the case of DAG. At 3 hr, recoveries of dose as DAG and DPG were significantly higher in perfusate, but not in bile. No significant differences in uptake and biliary excretion of taurocholate were found between the two groups. The finding of higher perfusate concentrations of DAG and DPG could signal a minor compromise to biliary excretion processes for the glucuronides, though whether such a result is simply coincident with or attributable to DAG-derived covalent DF-protein adducts in liver remains indeterminate.

Disposition and covalent binding of diflunisal and diflunisal acyl glucuronide in the isolated perfused rat liver

Acyl glucuronides are intrinsically reactive metabolites of carboxylate drugs, capable of undergoing hydrolysis, intramolecular rearrangement (isomerization via acyl migration), and intermolecular transacylation reactions. Transacylation with nucleophilic groups located on protein molecules leads to covalent drug-protein adducts. Protein adducts can also form from the rearrangement isomers via a glycation mechanism. In this study, the isolated perfused rat liver preparation was used to separately trace the dispositions of the nonsteroidal anti-inflammatory drug diflunisal (DF), its reactive acyl glucuronide metabolite (DAG), and a mixture of DAG rearrangement isomers (iso-DAG), each administered at 30-microg DF equivalents/ml perfusate (four recirculating perfusions each group). After administration of DF, the drug was eliminated in a log linear manner over 3 hr, with apparent elimination half-life (t1/2) of 2.6 +/- 0.4 hr. The sulfate conjugate (DS), excreted almost exclusively into perfusate, accounted for 14.2% of the dose, with the phenolic glucuronide (DPG) and DAG (11.1 and 7.9% of dose, respectively) excreted primarily in bile. Only a small portion (2.3%) of the dose was recovered as novel "diglucuronides" (D-2G, arising from phenolic glucuronidation of iso-DAG), excreted exclusively in bile. Covalent DF-protein adducts were found in both perfusate (0.98%) and liver (0. 14%). After administration of DAG, rapid hydrolysis occurred (initial DAG t1/2 17.3 +/- 4.2 min). At 3 hr, recoveries (in comparison to DF-dosed perfusions) were similar for DF (51.7%) and DAG (8.3%), significantly decreased for DS (10.6%) and DPG (6.4%), and significantly increased for iso-DAG (0.8%), D-2G (9.1%), and covalent adducts in perfusate (1.49%) and liver (0.30%). After administration of iso-DAG, elimination from perfusate was slower (t1/2 55 +/- 15 min), and hydrolysis to DF was modest by comparison with DAG-dosed perfusions. Recoveries as iso-DAG and D-2G in bile were greatly enhanced (8.2 and 36.4%, respectively). Adduct formation was higher in liver (0.76% of dose) but not in perfusate (1.03%). Immunoblots of liver homogenates revealed drug-modified proteins at ca. 110 and 120 kDa. The results show that (a) DAG undergoes avid systemic deconjugation-conjugation cycling and isomerization to iso-DAG; (b) iso-DAG is more resistant to hydrolysis, is readily taken up by hepatocytes and undergoes novel metabolism (phenolic glucuronidation); and (c) the glycation pathway (i.e. using iso-DAG as substrate) plays a major role in formation of covalent DF-protein adducts in liver.

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.

Glucuronidation of diflunisal, (-)-morphine, 4-nitrophenol, and propofol in liver microsomes of two patients with Crigler-Najjar syndrome type I

In vitro glucuronidation was studied in liver microsomes from two patients with Crigler-Najjar type I (CN-I) disease and compared with the activity measured in microsomes prepared from six control human livers. The UDP-glucuronosyltransferase (UGT) activity was determined toward the following substrates: 4-nitrophenol, propofol, (-)-morphine (formation of the 3-glucuronide), and diflunisal (formation of the phenolic and acyl glucuronides). Glucuronidation of 4-nitrophenol was reduced in one of the CN-I livers (CN-I No. 1) (0.9 nmol min(-1)mg(-1)) and normal in the other CN-I liver (CN-I No. 2) (3.5 nmol min(-1) mg(-l)) compared to the control livers (5.6 +/- 29 nmol min(-1) mg(-1)), mean +/- S.D.). Propofol glucuronidation was not detectable (i.e. less than 0.100 nmol min(-l) mg(-1) in the CN-I No. 1 liver and normal in the CN-I No. 2 liver (1.78 nmol min(-1) mg(-1) against 1.52 +/ 0.72 nmol min(-l) mg(-) in the control livers). The glucuronidation of (-)-morphine to the 3-glucuronide and the formation of the phenolic and acyl glucuronides of diflunisal were normal in both CN-I livers compared to the control livers. Our results show that CN-I patients are heterogeneous regarding UGT activity toward the phenolic substances 4-nitrophenol and propofol.

Chemical and immunochemical comparison of protein adduct formation of four carboxylate drugs in rat liver and plasma

Carboxylate drugs usually form acyl glucuronide conjugates as major metabolites. These electrophilic metabolites are reactive, capable of undergoing hydrolysis, rearrangement, and covalent binding reactions to proteins. The last-mentioned property has the potential to initiate immune and other toxic responses in vivo. In this study, we compared the extent and pattern of covalent adduct formation in plasma and livers of rats dosed with the nonsteroidal anti-inflammatory drugs (NSAIDs) zomepirac (ZP) and diflunisal (DF), the hypolipidemic agent clofibric acid (CA), and the anti-epileptic agent valproic acid (VPA). These drugs form acyl glucuronides with diverse intrinsic reactivities (apparent first order degradation t 1/2 values of 0.5, 0.6, 3, and 60 h, respectively). Rats were dosed iv twice daily for 2 days (50 mg/kg for ZP, DF, and CA, 150 mg/kg for VPA). Chemical analysis of tissues obtained 6 h after the last dose revealed adduct concentrations of 0.31, 0.44, 0.28, and 0.05 micrograms of drug equivalents/mL of plasma and 2.21, 2.31, 0.96, and 0.96 micrograms of drug equivalents/g of liver for ZP, DF, CA and VPA treatments, respectively. For both plasma and liver, the higher concentrations of adducts were found with ZP and DF, which have the more reactive glucuronides. The low concentrations of VPA adducts found in plasma were in keeping with the very low reactivity of its glucuronide. In liver, however, VPA adducts achieved concentrations of the same order of magnitude as the other drugs and were accompanied by adducts of the (E)-2-en metabolite of VPA at 0.38 micrograms of VPA equivalents/g of liver. The liver data for VPA can be explained by an acyl CoA/beta-oxidation pathway of adduct formation in addition to that from acyl glucuronidation. Immunoblotting using rabbit polyclonal antisera raised against synthetic drug-protein adducts revealed major bands at 110, 140, and approximately 200 kDa in livers of ZP- and DF-treated rats. A fourth major band at 70 kDa in ZP-treated liver had the same apparent molecular weight as the only major band detected in CA-treated liver. A 140 kDa band was detected in liver tissue from VPA-treated rats, as well as several lower molecular weight bands. In plasma, the antisera specifically detected drug-modified serum albumin in samples from rats treated with ZP, DF, and CA, but not VPA. The results with this small series of carboxylate drugs suggested that (a) adduct concentrations in plasma but not liver could be related to acyl glucuronide reactivity, (b) while some modified proteins detected were common, the pattern of modification varied from drug to drug, and (c) caution should be exercised in attributing adduct formation exclusively to the acyl glucuronidation pathway.

Glucuronidation of diflunisal in liver and kidney microsomes of rat and man

1. The glucuronidation of diflunisal to its phenolic (DPG) and acyl glucuronide (DAG) was measured in vitro using microsomes prepared from rat (n = 4) and human (n = 6) liver and kidney tissue. UGT activities towards bilirubin, 4-nitrophenol and (-)-morphine were also determined. 2. beta-Glucuronidase activity towards phenolphthalein glucuronide was much lower in microsomes prepared from human liver (45.2 +/- 3.1 Fishman Units/mg protein), human kidney (22.0 +/- 3.3 FU/mg), and rat kidney (25.1 +/- 2.5 FU/mg) as compared with rat liver (118.7 +/- 8.8 FU/mg). 3. The formation rate of DAG significantly increased when saccharo-1,4-lactone, a beta-glucuronidase inhibitor, was added to the rat liver microsomal incubation medium. beta-Glucuronidase inhibition, however, had little effect on the formation rate of DAG in human liver microsomes, and no effect in rat and human kidney microsomes. The formation of DPG was not affected by the microsomal beta-glucuronidase activity. 4. Unlike rat kidney microsomes, which only formed DAG, human kidney microsomes formed both diflunisal glucuronides. Formation of both diflunisal glucuronides in human kidney microsomes (Vmax = 0.97 +/- 0.21 and 0.27 +/- 0.07 nmol/min/mg for formation of DAG and DPG respectively) represented 60-70% of the activity found in liver microsomes (Vmax = 1.58 +/- 0.32 and 0.40 +/- 0.08 nmol/min/mg for formation of DAG and DPG respectively). 5. These results demonstrate that the in vitro glucuronidation rate of diflunisal may be affected by the microsomal beta-glucuronidase activity particularly when using rat liver microsomes. Our results also demonstrate that the human kidney has an important UGT-activity towards diflunisal.

Effect of probenecid on the formation and elimination kinetics of the sulphate and glucuronide conjugates of diflunisal

The effect of probenecid on the pharmacokinetics of diflunisal and its glucuronide and sulphate conjugates was studied in 8 healthy volunteers. Diflunisal 250 mg b.d. was administered p.o. for 15 days and its steady state pharmacokinetics was evaluated on Day 16 after the last dose (control phase). Probenecid 500 mg b.d. was co-administered throughout the entire study period in the treatment phase of the study. The steady state plasma concentration of diflunisal was significantly higher during the probenecid treatment phase as compared to the control phase (104.0 vs. 63.1 micrograms.ml-1). This was the result of a significant decrease in the plasma clearance of diflunisal from 5.8 (control) to 3.4 ml.min-1 (probenecid co-administration). The metabolite formation clearances of both glucuronides were significantly decreased by probenecid, -45% and -54% for the phenolic and acyl glucuronide, respectively. The metabolite formation clearance of the sulphate conjugate was not affected by probenecid coadministration. Steady state plasma concentrations of the sulphate and glucuronide conjugates of diflunisal were 2.5- to 3.1-fold higher during probenecid co-administration, due to a significant reduction in the renal clearance of the three diflunisal conjugates. Probenecid also reduced the plasma protein binding of diflunisal, but only to a minor extent; the unbound plasma fraction of diflunisal at steady state averaged between 5 and 30% higher during probenecid co-administration.

Studies on the reactivity of acyl glucuronides--VIII. Generation of an antiserum for the detection of diflunisal-modified proteins in diflunisal-dosed rats

Acyl glucuronide metabolites of carboxylic drugs such as the salicylate derivative diflunisal (DF) have been shown to react with proteins to produce covalent adducts. To aid in the study of the formation and distribution of these adducts in both humans and rats, we raised an antiserum against human serum albumin modified by covalent attachment of DF via an amide bond, using a carbodiimide reagent. This antiserum had wide reactivity, reacting with all types of DF-modified proteins tested and with free DF (albeit at a lower affinity). It did not cross-react with other salicylates or other non-steroidal anti-inflammatory drugs. The antiserum has been used in immunoblotting to detect proteins covalently modified by DF in the plasma and livers of rats treated with the drug for 7 days. Although some cross-reactivity was apparent on the blots, a series of DF-modified proteins was found in cytosolic, mitochondrial and mixed membrane fractions of hepatocytes, with molecular weights ranging from 28 to 130 kDa.

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 reactivity of acyl glucuronides--VI. Modulation of reversible and covalent interaction of diflunisal acyl glucuronide and its isomers with human plasma protein in vitro

Acyl glucuronide conjugates are chemically reactive metabolites which can undergo hydrolysis, rearrangement (isomerization via acyl migration) and covalent binding reactions with protein. The present study was undertaken to identify factors modulating the reactivity of diflunisal acyl glucuronide (DAG) with human serum albumin (HSA) in vitro, by comprehensively evaluating the interplay of the three pathways above when DAG and a mixture of its 2-, 3- and 4-isomers (iso-DAG) were incubated with protein. Buffer, plasma, fraction V HSA, fatty acid-free HSA, globulin-free HSA and fatty acid- and globulin-free HSA were investigated at pH 7.4 and 37 degrees, each in the absence and presence of warfarin, diazepam and diflunisal (DF) as reversible binding competitors. DAG and iso-DAG were highly reversibly bound (ca. 98-99.5%) in plasma and HSA solutions. The binding was primarily at the benzodiazepine site, since displacement occurred in the presence of diazepam and fatty acids but not warfarin. DAG degradation, via rearrangement, hydrolysis and covalent adduct formation (in that order of quantitative importance), was retarded in plasma and HSA solutions compared to buffer. The protective effect of protein was afforded by the high reversible binding to the (non-catalytic) benzodiazepine site. The warfarin site appeared to be catalytic for DAG hydrolysis, whereas rearrangement appeared to be hydroxide ion-catalysed only. In contrast to DAG, iso-DAG degradation was greatly accelerated in the presence of protein, through both covalent binding and catalysis of hydrolysis. Covalent binding via DAG was increased in the presence of warfarin but decreased in the presence of diazepam, DF and fatty acids. The opposite effects were found for covalent binding via iso-DAG. The data suggest that covalent binding of DF to HSA via DAG and iso-DAG occurs by different mechanisms (presumably transacylation and glycation, respectively) at different sites (benzodiazepine and warfarin, respectively) whereas reversible binding occurs primarily at the same site (benzodiazepine).

Glucuronidation of diflunisal by rat liver microsomes. Effect of microsomal beta-glucuronidase activity

The in vitro formation rates of the phenolic (DPG) and acyl (DAG) glucuronides of diflunisal were investigated using rat liver microsomes. Preliminary studies showed that DAG hydrolysed rapidly (T1/2 = 12 min) when incubated in the presence of rat liver microsomes at pH 7.4 and 37 degrees. DPG was much more stable under the same conditions (T1/2 = 35 hr). Hydrolysis of DAG and DPG by rat liver microsomes was inhibited by 4 mM saccharolactone, a beta-glucuronidase inhibitor. The apparent Km and Vmax values for the formation of DAG in the absence and presence of 4 mM D-saccharic acid-1,4-lactone (saccharolactone) were the following: Km = 0.05 +/- 0.02 vs 0.08 +/- 0.02 mM and Vmax = 0.20 +/- 0.06 vs 0.43 +/- 0.07 nmol/min/mg protein (0 and 4 mM saccharolactone, respectively). The significant increase in apparent Vmax for DAG formation in the presence of saccharolactone can be explained by the inhibition of beta-glucuronidase-catalysed hydrolysis of DAG. Apparent Km and Vmax values for the formation rate of DPG were not affected by addition of saccharolactone to the incubation medium. These results indicate that beta-glucuronidase-catalysed hydrolysis of certain glucuronides formed during microsomal incubations may significantly affect the apparent glucuronidation rate due to the presence of a glucuronidation-deglucuronidation cycle.

Studies on the reactivity of acyl glucuronides--V. Glucuronide-derived covalent binding of diflunisal to bladder tissue of rats and its modulation by urinary pH and beta-glucuronidase

Acyl glucuronide conjugates of acidic drugs have been shown to be reactive metabolites capable of undergoing non-enzymic hydrolysis, rearrangement (isomerization via acyl migration) and covalent binding reactions with plasma protein. In an earlier study (King and Dickinson, Biochem Pharmacol 45: 1043-1047, 1993), we documented formation of covalent adducts of diflunisal (DF), a salicylate derivative which is metabolized in part to a reactive acyl glucuronide (DAG), with liver, kidney, skeletal muscle and small and large intestine (in addition to plasma protein) of rats given the drug i.v. twice daily at 50 mg DF/kg for 7 days. The present study shows that covalent adducts of DF were also formed with urinary bladder tissue of these rats, achieving concentrations (ca. 5 micrograms DF equivalents/g tissue) higher than those found in the other tissues noted above. After cessation of dosing, the adduct concentrations declined with an apparent T 1/2 value of ca. 20 hr. Adducts were also formed ex vivo in excised rat bladders in which DAG or a prepared mixture of its acyl migration isomers (iso-DAG) were incubated at pH 5.0, 6.5 and 8.0. After 8 hr incubation, the highest concentrations (ca. 11 micrograms DF equivalents/g) were produced with iso-DAG at pH 5.0, and the lowest (ca. 2.3 micrograms DF equivalents/g) with DAG at pH 5.0. However, a major competing reaction for DAG (at least at pH 5.0) was hydrolysis by beta-glucuronidases originating from bladder tissue. By contrast, iso-DAG was quite resistant to such hydrolysis. The phenolic glucuronide conjugate, another important metabolite of DF, was hydrolysed only slowly. Similar results were obtained in fresh rat urine adjusted to pH 5.0. The results support covalent DF adduct formation in rat bladder originating from both DAG and iso-DAG as ultimate reactants, though the extent of binding is modulated by both urinary pH and beta-glucuronidases.

Studies on the reactivity of acyl glucuronides--IV. Covalent binding of diflunisal to tissues of the rat

Acyl glucuronides have been shown to be reactive electrophilic metabolites capable of undergoing hydrolysis, rearrangement (isomerization via acyl migration) and covalent binding reactions to plasma protein. The present study was undertaken to explore the occurrence and extent of in vivo formation of covalent adducts of diflunisal (DF), a salicylate derivative which forms a reactive acyl glucuronide, with tissues and plasma protein of rats. Groups of rats were given 50 mg DF/kg i.v. twice daily for periods of up to 7 days. Steady state plasma concentrations of reversibly bound DF and its conjugates (as measured 6 hr after a dose) were achieved by the third day of dosing. T 1/2 values after cessation of dosing were about 5-10 hr. By contrast, covalent DF-tissue adducts steadily accumulated over the 7-day dosing period. Maximum concentrations, measured 6 hr after the last dose, were 4.8 (liver), 1.0 (kidney), 0.74 (plasma), 0.26 (small intestine minus contents), 0.27 (large intestine minus contents) and 0.20 (skeletal muscle) microgram DF/g tissue or/mL plasma. T 1/2 values of about 50, 67, 18, 38 and 43 hr were obtained for liver, kidney, plasma and small and large intestine (respectively) after cessation of dosing. Thus, the study of acyl glucuronide reactivity and the question of any derived toxicity or immune responses should consider the formation of long-lived adducts in tissues as well as in plasma.

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

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: 11.5 l.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.

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.

Studies on the reactivity of acyl glucuronides--II. Interaction of diflunisal acyl glucuronide and its isomers with human serum albumin in vitro

A major metabolite of diflunisal (DF) is its reactive acyl glucuronide conjugate (DAG) which can undergo hydrolysis (regeneration of DF), intramolecular rearrangement (isomerization via acyl migration) and intermolecular reactions with nucleophiles. We have compared the fate of DAG and its individual 2-, 3- and 4-O-acyl positional isomers (at ca. 55 micrograms DF equivalents/mL) after incubation with human serum albumin (HSA, 40 mg/mL) at pH 7.4 and 37 degrees. Initial half-lives (T1/2) for DAG and its 2-, 3- and 4-isomers were 53, 75, 61 and 26 min, respectively. DAG was more labile to hydrolysis than any of its isomers but the latter, in particular the 4-isomer, were much better substrates for formation of covalent DF-HSA adducts. After a 2-hr incubation, 2.4, 8.2, 13.7 and 36.6% of substrate DAG and its 2-, 3- and 4-isomers (respectively) were present as DF-HSA adducts. With long term incubation, the concentrations of adducts so generated in situ declined in a biphasic manner, with apparent terminal T1/2 values of ca. 28 days. DAG was much more labile to transacylation with methanol (i.e. formation of DF methyl ester) than an equimolar mixture of its isomers after incubation in a 1:1 methanol:pH 7.4 buffer solution at 37 degrees (T1/2 values of 5 and 70 min, respectively). The data do not support direct transacylation with nucleophilic groups on protein as the predominant mechanism of formation of covalent DF-HSA adducts in vitro.

Absence of phenolic glucuronidation and enhanced hydroxylation of diflunisal in the homozygous Gunn rat

1. The disposition of diflunisal (DF) was investigated in bile-exteriorized and intact homozygous Gunn rats given 10 and 50 mg/kg doses i.v. and in Wistar rats given 10 mg/kg doses i.v. 2. In Gunn rats, DF sulphate, DF acyl glucuronide, and a hitherto unidentified metabolite of DF, a conjugate of 3-hydroxy-DF, were identified as the major metabolites, accounting for approximately 37%, 16% and 11% respectively of 10 mg/kg doses and 35%, 24% and 15% respectively of 50 mg/kg doses in bile-exteriorized animals. There was no evidence for formation of DF phenolic glucuronide. 3. Total plasma clearance of DF and formation clearances of DF to DF sulphate and 3-hydroxy-DF were little affected by increase of dose from 10 to 50 mg DF/kg, whereas formation clearance of DF to DF acyl glucuronide was increased, but not significantly. 4. In Gunn rats with undisturbed bile flow into the gut, recoveries of DF sulphate and total 3-hydroxy-DF in urine increased to approximately 48% and 25% dose respectively at the expense of DF acyl glucuronide through enterohepatic recirculation. 5. In bile-exteriorized Wistar rats, DF phenolic glucuronide, DF acyl glucuronide, DF sulphate and 3-hydroxy-DF accounted for 16%, 27%, 14% and 2%, respectively, of 10 mg/kg doses. In intact Wistar rats, urinary recoveries of the metabolites were 15%, 13%, 23% and 5%, respectively. 6. Thus in comparison to Wistar rats, phenolic glucuronidation of DF was absent or negligible in homozygous Gunn rats, acyl glucuronidation was significantly decreased, sulphation was unchanged, and the 3-hydroxylation of DF was significantly enhanced.

Noninvasive approaches to tracing pathways in carbohydrate metabolism

Compounds that can be given safely in large quantity, conjugate with intermediates of carbohydrate metabolism in liver, and are excreted, allow large amounts of those intermediates to be isolated noninvasively. By administering labeled compounds that form those intermediates and determining the amount and/or distribution of label in those intermediates, the metabolism of those compounds can be traced. Thus, glucuronide formation has been used to sample hepatic uridine diphosphate glucose (UDP-glucose) and study glycogen metabolism and the pentose pathway, phenylacetate to sample hepatic alpha-ketoglutarate and estimate relative flux through the Krebs cycle, and acetylation to sample hepatic acetyl CoA. Interpretations require knowledge of the anatomical sites of formation of the intermediates, since more than one pool of an intermediate can exist in liver. The extent the labeled compound is metabolized in extrahepatic tissues also must be taken into account.

Contrasting systemic stabilities of the acyl and phenolic glucuronides of diflunisal in the rat

1. Diflunisal (DF) is metabolized in humans and rats primarily to its acyl glucuronide, phenolic glucuronide and sulphate conjugates. 2. After i.v. administration of DF acyl glucuronide to pentobarbitone-anaesthetized rats, DF and its phenolic glucuronide and sulphate conjugates appeared rapidly in plasma, indicating ready systemic hydrolysis of the acyl glucuronide and subsequent biotransformation of liberated DF. 3. Approximately 72% of the acyl glucuronide dose was recovered in bile and urine over 6 h: 52% as acyl glucuronide, 6% as phenolic glucuronide, 5% as sulphate, and 8% as isomers of the acyl glucuronide arising from intramolecular acyl migration. 4. Blockage of excretion routes by ligation of the ureters, bile duct, and both ureters and bile duct, decreased plasma clearance of the acyl glucuronide from 7.8 ml/min per kg to 6.0, 3.2 and 2.2 ml/min per kg respectively, and increased the apparent terminal plasma half-life of DF from 2.1 h to 2.6, 3.4 and 6.3 h, respectively. 5. By contrast, DF phenolic glucuronide was quite stable after i.v. administration at the same dose. 6. This study shows that systemic cycling between DF and its acyl glucuronide exists in the rat in vivo, with portions of each cycle of unstable acyl glucuronide through DF yielding stable phenolic glucuronide and (presumptively stable) sulphate conjugate.

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.

The effect of diethyl ether, pentobarbitone and urethane anaesthesia on diflunisal conjugation and disposition in rats

1. The disposition of diflunisal (DF) at 10 mg/kg i.v. was investigated over 4 h in bile-exteriorized male rats continuously anaesthetized with (a) diethyl ether inhalation (as required), (b) pentobarbitone sodium i.p. (55 mg/kg initially), (c) urethane i.p. (1500 mg/kg initially) or (d) urethane i.v. (750 mg/kg initially), and compared to that obtained in conscious rats. 2. Diethyl ether decreased the plasma clearance of DF to about 30% of control values, by inhibition of both glucuronidation and sulphation of DF. 3. Pentobarbitone anaesthesia caused only modest inhibition of DF elimination, with plasma clearance decreased to about 80% of control values. 4. Plasma profiles and biliary recovery of DF and its conjugates were little altered by urethane i.p. anaesthesia, but urinary recovery was low and variable because of the nearanuria produced by urethane via this administration route. 5. Urinary recovery of DF and its conjugates was satisfactory in rats given urethane i.v., but tissue distribution of DF was substantially decreased. 6. Pentobarbitone was considered to interfere least with DF disposition at the 10 mg/kg dose, and was selected as the most suitable anaesthetic agent for ongoing studies of disposition of DF and its conjugates in anaesthetized rats.

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

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.

Elimination of diflunisal as its acyl glucuronide, phenolic glucuronide and sulfate conjugates in bile-exteriorized and intact rats

1. The disposition of diflunisal (DF) was investigated in both bile-exteriorized and intact rats given 10 and 100 mg/kg doses intravenously (i.v.). 2. In addition to the phenolic glucuronide (DPG) and acyl glucuronide (DAG) conjugates, the sulfate conjugate (DS) was found to be a major metabolite. The glucuronides were excreted preferentially in bile, whereas DS was excreted almost exclusively in urine. 3. In bile-exteriorized animals, recoveries of DPG, DAG and DS in bile were 12.2%, 23.8%, 0.4%, respectively, and in urine, 10.3%, 5.6% and 15.2%, respectively, at the 10 mg/kg dose; and in bile, 11.3%, 41.6% and 1.0% respectively, and urine 2.9%, 1.1% and 17.0%, respectively, at the 100 mg/kg dose. 4. Total plasma clearance of DF and formation clearance of DF to DPG were reduced at the higher dose, suggesting saturation of this glucuronidation pathway. Formation clearances of DF to DAG and DS were little affected by the dose change. 5. Considerable enterohepatic recirculation of DF was apparent from the prolongation of DF and its conjugates in plasma of rats with an intact bile flow into the gut. The net metabolic effect of such cycling was enhancement of overall DS formation, from 15.6% and 18.0% of the 10 and 100 mg/kg doses, respectively, in bile-exteriorized rats to 28.5% and 42.1% of the doses respectively, in the intact animals.

Reactivity considerations in the analysis of glucuronide and sulfate conjugates of diflunisal

Reactivity of glucuronide and sulfate conjugates was taken into account in development of a simple isocratic HPLC method for direct assay of diflunisal (DF) and its acyl glucuronide (DAG), phenolic glucuronide (DPG), and sulfate (DS) conjugates. Whereas DPG was stable over the pH range 0-9, DAG was highly labile at neutral to slightly alkaline pH, undergoing rearrangement (isomerisation via acyl migration), hydrolysis, and in the presence of methanol, transesterification to DF methyl ester. The 2-, 3-, and 4-O-acyl positional isomers of DAG appeared as three pairs of peaks. Interconversion between partners of each pair occurred even under acidic conditions inhibitory to acyl migration, implicating mutarotation. DS was stable at neural to slightly alkaline pH, but underwent hydrolysis under relatively strongly acidic conditions. However, this hydrolysis was remarkably catalyzed (e.g., by 1,000-fold) in the presence of solvents (i.e., solvolysis) such as diethyl ether and ethyl acetate. DS (an acid) could not be extracted from aqueous solution because of this acidic solvolysis. Suitable conditions for simultaneous direct analysis (nonextractive, nonconcentrative) of DF and its reactive (DAG and DS) and unreactive (DPG) conjugates were achieved by working at pH of approximately 4.5. The procedure thus developed is suitable for plasma, urine, and bile samples, and has revealed the presence of new, as yet unidentified, metabolites of DF.

Pentose pathway in human liver

[1-14C]Ribose and [2-14C]glucose were given to normal subjects along with glucose loads (1 g per kg of body weight) after administration of diflunisal and acetaminophen, drugs that are excreted in urine as glucuronides. Distributions of 14C were determined in the carbons of the excreted glucuronides and in the glucose from blood samples drawn from hepatic veins before and after glucagon administration. Eighty percent or more of the 14C from [1-14C]ribose incorporated into the glucuronic acid moiety of the glucuronides was in carbons 1 and 3, with less than 8% in carbon 2. In glucuronic acid from glucuronide excreted when [2-14C]glucose was given, 3.5-8.1% of the 14C was in carbon 1, 2.5-4.3% in carbon 3, and more than 70% in carbon 2. These distributions are in accord with the glucuronides sampling the glucose unit of the glucose 6-phosphate pool that is a component of the pentose pathway and is intermediate in glycogen formation. It is concluded that the glucuronic acid conjugates of the drugs can serve as a noninvasive means of sampling hepatic glucose 6-phosphate. In human liver, as in animal liver, the classical pentose pathway functions, not the L-type pathway, and only a small percentage of the glucose is metabolized via the pathway.

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.

Differential effects of phenobarbital on ester and ether glucuronidation of diflunisal in rats

The relative contribution of ether and ester glucuronidation to diflunisal metabolism was assessed by studying the effects of enzyme inducers, phenobarbital (PB), 3-methylcholanthrene (3-MC) and beta-naphthoflavone (BNF). Treatment with either PB, 3-MC or BNF increased markedly the unbound intrinsic clearance of diflunisal. Saline-treated control rats showed a greater unbound intrinsic clearance of diflunisal than oil-treated controls indicating that repetitive treatment with oil had an effect on enzyme activity. Treatment with 3-MC and BNF appeared to cause a decrease in the biliary clearance of ether and ester glucuronide, but PB had little effect on the biliary clearance of glucuronides. Rats pretreated with PB showed a 3-fold increase in the fractional metabolite formation clearance of ether glucuronide and a 2-fold increase in the fractional metabolite formation clearance of ester glucuronide, suggesting differential effects of PB on ester and ether glucuronidation. A similar trend, but to a smaller extent, was also observed for 3-MC- and BNF-treated rats. These results suggest the possibility of selective induction of multiple forms of UDP-glucuronyltransferase involved in metabolism of diflunisal.

A diflunisal related fatality: a case report

A case is reported where the death of an individual resulted from the ingestion of diflunisal. Diflunisal was identified by a combination of liquid chromatography, UV spectrophotometry and colorimetry. Diflunisal was quantified in blood (260 mg/l), bile (71 mg/l), kidney (350 mg/kg), liver (400 mg/kg), stomach contents (34 mg) and urine (78 mg/l). No previous literature references discussing diflunisal related fatalities were available.

Evaluation of the teratogenicity and pharmacokinetics of diflunisal in cynomolgus monkeys

This study examined the pharmacokinetics and potential teratogenicity of the nonsteroidal antiinflammatory drug, diflunisal, in cynomolgus monkeys. Pregnant cynomolgus monkeys were administered 0.5% methyl cellulose, 20 mg/kg/day diflunisal, or 80 mg/kg/day diflunisal on Days 25 to 48 of gestation. There was no evidence of maternal toxicity, increased abortion rate, fetal growth retardation, or malformation. These data demonstrate that diflunisal is not teratogenic in cynomolgus monkeys over a dosage range of 20 to 80 mg/kg/day. Peak plasma levels of diflunisal were found 1 hr after oral administration of [14C]diflunisal at a dosage of 60 mg/kg and declined to low levels by 24 hr. The plasma elimination half-life was calculated to be 10.2 hr over the period of 1 to 8 hr postadministration. Intact diflunisal accounted for 96.4% of total plasma radioactivity at 0.5 hr and declined to a value of 74% at 8 hr. Plasma protein binding averaged greater than 99% over a concentration range of 62.5 to 250 micrograms/ml. Urinary excretion of diflunisal and metabolites averaged 66.5% of the dosage over the first 4 days postadministration, compared with 0.8% in the feces. The majority of activity represented conjugates of diflunisal. Embryo concentrations of diflunisal on Days 35 to 37 of gestation were 0.7 and 1.1% of maternal plasma level at 4 hr postadministration of 20 or 60 mg/kg, respectively.

Isolation and identification of a new major metabolite of diflunisal in man. The sulfate conjugate

A new metabolite of diflunisal has been identified in volunteers and patients after multiple dose administration. The metabolite was isolated from human urine by silica gel chromatography and was further purified by reversed phase HPLC. Arylsulfatase from Helix pomatia and from Aerobacter aerogenes completely hydrolyzed the isolated metabolite to diflunisal, although hydrolysis by bacterial arylsulfatase was extremely slow. Electron impact mass spectra for diflunisal and its sulfate conjugate were virtually identical. Negative ion fast atom bombardment mass spectra clearly showed the quasimolecular ion [M-H]- at m/z 329 (base peak) as well as a large fragment ion (90% relative intensity) at m/z 249 corresponding to the loss of the sulfate moiety. Urinary excretion patterns in volunteers and rheumatoid arthritis patients revealed that sulfate conjugation of diflunisal is a minor metabolic pathway after single 500-mg dose administration (less than 10% of the dose), whereas it becomes a major pathway (21.3-44.3% of the dose) following multiple doses (500 mg b.i.d.). In one volunteer, who ingested 500 mg diflunisal b.i.d. for 5 weeks, it was shown that the percentage of the dose excreted as diflunisal sulfate gradually increased during the first week to approximately 30% and stayed virtually unchanged for the remaining 4 weeks of diflunisal intake. These preliminary observations are not compatible with the idea that sulfate conjugation is capacity-limited at lower substrate concentrations than glucuronide conjugation, nor do they suggest that sulfation of diflunisal is rate-limited by depletion of inorganic sulfate body stores.

Dose-dependent pharmacokinetics of diflunisal in rats: dual effects of protein binding and metabolism

The purpose of this study was to define the dual effects of saturable metabolism and saturable protein binding on the pharmacokinetics of diflunisal. Steady-state diflunisal concentration and its unbound fraction were examined in seven groups of rats to determine the relationships of infusion rate, concentration and total and unbound clearances. The total body plasma clearance decreased initially and then went up as the concentration of diflunisal increased, whereas the intrinsic clearance of unbound drug decreased with increasing concentration. The former is a consequence of saturable metabolism as well as saturable protein binding; the latter is a consequence of saturable metabolism. The fraction of unbound diflunisal increased with concentration. The biliary excretion data of ester and ether glucuronide suggested that both the ester and ether glucuronidation processes are capacity-limited, although the enzyme system for ether glucuronide has a lower Km and capacity than the system responsible for the ester glucuronidation.

Multiple cobinding of two ligands to serum albumin: a stoichiometric description of binding equilibria

Binding equilibria for simultaneous binding of several molecules of two anionic ligands, sulfamethizole/warfarin in one series and sulfamethizole/diflunisal in another, to human serum albumin were studied by equilibrium dialysis. It was found that Klotz's stepwise binding equilibrium concept, extended to cover interaction of two ligands with one carrier, could be used for a quantitative description of binding equilibria. Reciprocity of ligand effects was established at all levels. Heterotropic anticooperativity was present among these pairs of ligands. The experiments were supplemented with observations of albumin binding equilibria for traces of warfarin in the presence of varying amount of oleate, up to 6 mol/mol albumin, by measuring dialysis rates for unbound warfarin. Binding of warfarin to albumin is enhanced upon binding of oleate up to 4 mol/mol albumin, and decreases at higher oleate concentrations. Using stoichiometric (stepwise) binding constants for oleate previously published by Ashbrook et al. [(1975) J. Biol. Chem. 250, 2333-2338], the reverse effect, of warfarin on binding of oleate, was calculated. Simultaneous binding of these ligands to albumin could be described according to the stoichiometric principles as used above for sulfamethizole/warfarin and sulfamethizole/diflunisal.

Effect of enterohepatic circulation on the pharmacokinetics of diflunisal in rats

The purpose of this study was to examine the effect of enterohepatic circulation on the pharmacokinetics of diflunisal in rats. The "linked animals" experiments provided evidence that diflunisal exhibits an enterohepatic circulation. Within 26 hr after iv administration of diflunisal (10 mg/kg) to rats, excretion was as follows: 42.2% of the dose, bile; 2.3%, unchanged drug; 27.8%, ester glucuronide; and 12.1%, ether glucuronide. On the average, approximately 65% of the amount of the drug and its glucuronides excreted in bile was reabsorbed from the gut. Biliary excretion and plasma data showed that biotransformation of diflunisal to its glucuronides is the rate-limiting step in their elimination. A concentration-dependent decrease in the partial formation clearance to ester glucuronide was observed with decreased concentration of diflunisal. These concentration-dependent kinetics can be at least partly explained by the nonlinear protein binding of diflunisal.

Diflunisal-induced maternal anemia as a cause of teratogenicity in rabbits

Diflunisal [5-(2,4-difluorophenyl)-salicylic acid] is a new analgesic antiinflammatory drug that, when administered orally to rabbits at 40 and 60 mg/kg/day, caused terata, most commonly axial skeletal defects. These same dosage levels also caused a severe maternal hemolytic anemia following a dramatic decrease in erythrocyte ATP levels. The teratogenicity, anemia, and depletion of ATP were unique to the rabbit among species examined. To test the possible causality between the teratogenic effects and anemia induced by diflunisal, a single dose of 180 mg/kg diflunisal was administered to rabbits on gestation day 5. This treatment produced an anemia that persisted through gestation day 15 in addition to causing the characteristic axial skeletal defects. Since diflunisal was cleared from maternal blood before gestation day 9, the critical day for induction of similar axial skeletal defects by hypoxia, the skeletal malformations probably resulted from maternal hypoxia secondary to anemia and not from a direct and specific effect of the drug on the embryo. In addition, we observed that the diflunisal level in the embryo was less than 5% of the peak maternal blood level probably as a result of high plasma protein binding of diflunisal in the maternal blood (greater than 98%). This relatively low placental transfer may explain the lack of diflunisal teratogenicity in rats and mice compared to aspirin which crosses the placenta more readily. These studies demonstrate that a species that exhibits unusually severe drug-specific maternotoxicity is probably an unsuitable model for the prediction of the teratogenic potential of that drug in humans.

Glucuronidation and elimination of diflunisal in the isolated perfused rat liver: effect of pretreatment with phenobarbitone, clofibric acid and spironolactone

The effects of pretreatment of rats with phenobarbitone, clofibric acid and spironolactone on the metabolism and biliary excretion of the salicylate derivative diflunisal have been studied using the isolated perfused liver. The clearance of diflunisal was increased significantly by pretreatment with each of the drugs. Biliary excretion of diflunisal acyl and phenolic glucuronides followed apparent first-order and Michaelis-Menten kinetics, respectively. Pretreatment with clofibric acid or spironolactone resulted in a significant increase in the biliary excretion of the phenolic glucuronide. Pretreatment with phenobarbitone or spironolactone enhanced biliary excretion of the acyl glucuronide, particularly during the first 2 hr. The concentration of the phenolic glucuronide in the perfusate increased steadily during the 6 hr perfusions, whereas the acyl glucuronide concentration was relatively stable, reflecting the ease of hydrolysis of acyl glucuronides under physiological conditions.

Diflunisal disposition and hypouricemic response in osteoarthritis

The disposition of diflunisal was studied at daily doses of 250, 500, 750, 1000 mg/day in 24 male patients (mean age 65 yr and mean creatinine clearance 72 ml/min). Each dose was given for 14 days and diflunisal apparent oral clearance and serum urate was measured on the last day of each dosing regimen. There was a dose-dependent decrease in mean diflunisal apparent oral clearance with dose from 628 ml/hr at 250 mg/day to 426 ml/hr at 1000 mg/day, with most of the decrease occurring at the lower doses and becoming less pronounced at doses of 750 and 1000 mg/day. There was a strong positive correlation between diflunisal apparent oral clearance and creatinine clearance. Diflunisal induced a hypouricemic effect at all doses, but the responses at doses of 750 and 1000 mg/day did not differ.