Evaluation of the Antiinflammatory Activity of a Dual Cyclooxygenase-2 Selective/5-Lipoxygenase Inhibitor, RWJ 63556, in a Canine Model of Inflammation

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Vol. 282, Issue 2, 1094-1101, 1997

Evaluation of the Antiinflammatory Activity of a Dual Cyclooxygenase-2 Selective/5-Lipoxygenase Inhibitor, RWJ 63556, in a Canine Model of Inflammation

T. Kirchner, D. C. Argentieri, A. G. Barbone, M. Singer, M. Steber, J. Ansell, S. A. Beers, M. P. Wachter, W. Wu, E. Malloy, A. Stewart and D. M. Ritchie

The R.W. Johnson Pharmaceutical Research Institute, Raritan, New Jersey.

	Abstract

Top Abstract Introduction Methods Results Discussion References

Sterile perforated polyethylene spheres (wiffle golf balls) were implanted s.c. in beagle dogs. A local inflammatory reactionwas elicited within the spheres by injecting carrageenan. Changesin leukocyte count, prostaglandin E₂, thromboxane B₂ and leukotrieneB₄ levels were monitored in fluid samples collected over a 24-hrperiod. Blood samples were also collected at various time pointsand analyzed for prostaglandin E₂ and leukotriene B₄ productionafter ex vivo calcium ionophore treatment. Effects of standardantiinflammatory agents (aspirin, indomethacin, dexamethasone,tenidap and zileuton) and newer cyclooxygenase-2 (COX-2) selectiveagents (nimesulide, nabumetone and SC-58125) were determined afteroral administration. Ex vivo inhibition of cyclooxygenase productsynthesis (prostaglandin E₂, thromboxane B₂) in whole blood wasused as an indicator of activity for the constitutive COX-1 isoform,although inhibition of the synthesis of these mediators in thechamber exudate during an inflammatory process is believed torepresent COX-2 inhibition. Treatment effects on leukotriene B₄production were also determined both ex vivo in whole blood andin the fluid. All of the compounds tested, except aspirin, inhibitedleukocyte infiltration into the fluid exudate. Inhibitors thatexert their effects on both isozymes of cyclooxygenase attenuateproduction of cyclooxygenase metabolites in both the inflammatoryexudate and in peripheral blood ex vivo, although COX-2 selectiveinhibitors only demonstrated activity in the exudate. A 5-lipoxygenaseinhibitor (zileuton), a corticosteroid (dexamethasone) and a dualCOX-2 selective/5-lipoxygenase inhibitor (RWJ 63556) had similarprofiles in that they all inhibited cell infiltration and eicosanoidproduction in the fluid and also attenuated leukotriene B₄ productionin both the fluid and blood.

	Introduction

Top Abstract Introduction Methods Results Discussion References

NSAIDs alleviate the hyperalgesic symptoms associated with inflammation by inhibiting the COX enzyme and the resultant inhibitionof prostaglandin synthesis from arachidonic acid (Vane, 1971).However, these drugs have been associated with GI side effects(Whittle et al., 1980, De Witt and Smith, 1988, Fries et al.,1989) thought to result from inhibition of constitutive cyclooxygenaseproducts in the mucosa of the GI tract (Main and Whittle, 1975).Prostaglandins are believed to play a role in maintaining theintegrity of the mucosal lining (Robert et al., 1967, Dajani etal., 1975, Kauffman and Grossman, 1978, Boughton-Smith and Whittle,1981). Recently, a second isoform of COX-2 has been discovered(Xie et al., 1991, Kujubu et al., 1991, O'Banion et al., 1991,Hla and Neilson, 1992, Xie et al., 1992) and shown to be inducedduring an inflammatory event (Maier et al., 1990, O'Banion etal., 1992). The constitutive isozyme (COX-1) is also expressedduring an inflammatory reaction; however, not to the same degreeas the induced isozyme (COX-2) (Sano et al., 1992, Mitchell etal., 1993, Meade et al., 1993, Crofford et al., 1994). BecauseCOX-2 is induced during inflammation and COX-1 is thought to beresponsible for GI protection, it is conceivable that a selectiveinhibitor of COX-2 may provide antiinflammatory effects withoutcausing deleterious GI side effects (Masferrer et al., 1994);however, this concept has not yet been clinically proven.

Although nonselective or COX-1 selective NSAIDs are therapeutically effective, most of these drugs have other pharmacologicalactivities (Walker et al., 1976, Siegel et al., 1979, Abramsonand Weissman, 1989) which may contribute to their antiinflammatoryefficacy. An agent that selectively inhibits the inducible COX-2isozyme may alleviate the symptoms of inflammation without causingthe gastrointestinal side effects, although it may not preventthe progression of the inflammatory disorder. The clinical antiinflammatoryefficacy of specific selective COX-2 inhibitors has yet to bedetermined. This study evaluated several of the newer in-vitroCOX-2 selective inhibitors (SC-58125, nimesulide and nabumetone)in a canine model of local inflammation induced by carrageenaninto a subcutaneous chamber. The oral effects of these selectiveCOX-2 inhibitors were compared to those of standard NSAIDs (aspirin,indomethacin and tenidap) that inhibit both isoforms of cyclooxygenase.In addition, several compounds which do inhibit chemotactic responseswere evaluated in this system, including a glucocorticoid (dexamethasone),a 5-LO inhibitor (zileuton) and a new dual COX-2 selective/5-LOinhibitor (RWJ 63556). Inhibition of leukocyte influx into thechamber was used as an indicator of antiinflammatory activity.Selective inhibition of prostanoid production in the inflammatoryexudate and peripheral blood was used as an indicator of COX-1/COX-2enzyme selectivity, because COX-2 should be induced during aninflammatory response and prostanoid production in the blood shouldbe indicative of the constitutive COX-1 response. Additionally,5-LO activity was evaluated by quantitating LTB₄ production inthe exudate and the blood.

	Methods

Top Abstract Introduction Methods Results Discussion References

In Vitro COX-1, COX-2, 5-LO Assays

Specific COX-1 and 5-LO activity was assayed using methods previously described (Argentieri et al., 1994) Briefly, rat basophilicleukemia (RBL-1) cells (ATCC 1378-CRL, American Type Cell Culture,Rockville, MD) were used to evaluate COX-1 and 5-LO activity.A cell-free homogenate was prepared by subjecting the cells toa polytron followed by centrifugation at 9000 × g. The CaCl₂ -dependentproduction of cyclooxygenase and 5-LO products from ¹⁴C-arachidonic acid (NEN, Boston, MA) in the 9000 × g supernatantwas monitored in the presence of vehicle or drug. Products wereisolated by acidification and extraction, followed by thin layerchromatography. Radioactive areas corresponding to cyclooxygenaseand 5-lipoxygenase products, PGD₂ and 5-HETE, respectively, werequantitated using a BIOSCAN imaging scanner 200 (BIOSCAN, Washington,DC). The data were expressed as percent inhibition of productsas compared to vehicle treatment and IC₅₀ values were calculatedfrom curve fit equations derived using the linear least-squaresregression method (Cricket Graph III, Computer Associates International,Islandia, NY).

Evaluation of specific COX-2 activity of a compound was performed using a whole cell assay with ECV-304 (human, endothelial,umbilical cord) cells (ATCC # 1998-CRL, American Type Cell Culture,Rockville, MD). These cells were cultured in Media 199/10% bovineserum albumin (BioWhitaker, Walkersville, MD) at 37°C and 5% CO₂,then trypsinized and plated at a density of 9 × 10⁴ cells per well of a 96 well plate before assay. Approximately28 hr later, 50 µg/ml PMA (Sigma, St. Louis, MO) and 2 µM ionomycin(Sigma, St. Louis, MO) (final concentrations) were added to eachwell. Cells were incubated in the presence of vehicle or drugfor 18 hr. PGE₂ production was determined via RIA (PerSeptiveBiosystems, Framingham, MA) after the addition of 30 µM arachidonicacid. The data were expressed as percent inhibition of productsas compared to vehicle treatment and IC₅₀ values were calculatedfrom curve fit equations derived using the linear least-squaresregression method (Cricket Graph III, Computer Associates International,Islandia, NY).

Carrageenan-Induced Inflammation in Dogs

Surgical implantation of subcutaneous chambers. Seventy-two beagle dogs of either sex, approximately 1 yr of age and weighing 8 to 13 kg were used in this study. Purpose-breddogs were purchased from Marshall Farms (North Rose, NY) and housedin an American Association for Accreditation of Laboratory AnimalCare (AAALAC) accredited facility. All procedures conformed tothe requirements of the Animal Welfare Act and were conductedaccording to the United States Department of Health and HumanServices Guide for the Care and Use of Laboratory Animals. Thestudy was approved by the Institutional Animal Care and Use Committee.The dogs were housed singly in 12-sq.ft. stainless steel cagesand were fed Purina (St. Louis, MO) High Density Canine Diet oncedaily. Water was provided ad libitum. The rooms were maintainedat 64 to 84°F and 30 to 70% humidity with a 12-hr diurnal cycle.

The dogs were fasted 12 hr before surgical implantation of the chambers. They were anesthetized with pentobarbital sodium(approximately 30 mg/kg, i.v.) (Abbott Laboratories, North Chicago,IL), intubated and anesthesia was maintained with isoflurane (Anaquest,Madison, WI) for the duration of the sterile surgical procedure.The dorsal cervical and proximal thoracic areas of each dog wasshaved, scrubbed, and draped. A horizontal skin incision, approximately6.5 to 7 cm in length, was made distal to the shoulder blade andlateral to the spine using a scalpel. The subcutis was gentlyundermined and extended proximally to receive the ball using Metzenbaumscissors and forceps. A perforated polyethylene "wiffle" golfball, approximately 4.2 cm in outer diameter (O.D.), which hadbeen gas sterilized with ethylene oxide, was then introduced intothe subcutis of each dog and sutured in place to the underlyingsubcutis with two ligatures placed through the holes of the balland the underlying musculature fascia (using 0 Vicryl). The subcutaneoustissue was then closed, abating any dead space, using a continuoussuture pattern (0 Vicryl). Stainless steel staples were used forskin closure. Staples were removed after 10 days. Butorphanoltartrate (0.4 mg/kg, s.c.) (Fort Dodge Laboratories, Fort Dodge,IA), as an analgesic, was administered once after surgery. Animalswere also given sulfadiazine/trimethoprim antibiotic (30 mg/kg,p.o.) (Syntex, West Des Moines, IA) once daily for 5 days postoperatively.

Carrageenan-induced inflammation. After a postoperative recovery period of at least 1 mo, a 1-ml sample of exudate from each dog was aspirated from within thechamber using a 1-ml syringe and 20-gauge 1-inch needle insertedthrough one of the perforations in the ball. The area was cleansedwith 70% ethanol before each sample was collected. Immediatelyafter obtaining the sample, 1.5 ml of 0.33% sterile carrageenanlambda (Sigma Chemical Co., St. Louis, MO) was injected into thechamber. Samples of the exudates were obtained again at 5 and24 hr post carrageenan challenge and are indicative of the inflammatoryresponse. Dilutions of the samples were made in saline and analyzedfor leukocyte count using a Coulter Sample Stand and MultisizerII (Coulter Corp, Miami, FL). Samples of exudate (200 µl) werealso extracted in ethanol (1 ml) for measurement of eicosanoidcontent. The precipitate was centrifuged at 4°C (6 min, 12,000rpm) and the supernatant was stored at -20°C until analyzed forthe presence of PGE₂, TxB₂ and LTB₄ by enzyme-linked immunosorbantassays (ELISA Technologies, Lexington, KY). The exudate withinthe chambers was evacuated after the last sample was obtainedand the dogs were allowed a recovery period of at least 4 wk betweencarrageenan challenges. The dogs were used repeatedly for up to1 yr and they served as their own controls when measuring treatmenteffects on the inflammatory response elicited by carrageenan.Compounds were administered orally in gelatin capsules immediatelyafter carrageenan challenge when various treatments were evaluated.

Heparinized blood samples were drawn simultaneously with the chamber exudates for evaluation of drug effects on the noninflammatoryex-vivo production of eicosanoids (PGE₂, TxB₂ and LTB₄) aftertreatment with calcium ionophore A23187 (0.28 mg/ml suspendedin 4% DMSO/HBSS). The method used for eicosanoid production hasbeen previously described (Argentieri et al., 1994

). ELISAs wereperformed on methanol extracted blood samples to determine eicosanoid(PGE₂, TxB₂ and LTB₄) concentrations. Ex vivo LTB₄ samples werediluted 1:200 in enzyme immunoassay buffer supplied in the kitsbefore ELISA was performed. The PGE₂ produced by peripheral bloodcells is indicative of the constitutive COX-1 response due tothe absence of an ongoing inflammatory reaction.

FACScan determination of differential cell populations in fluid exudate. Aliquots (0.5 ml) of chamber exudate were treated with the Whole Blood Erythrocyte Lysing Kit (R&D Systems, Minneapolis, MN)according to the manufacturer's protocol. Briefly, 2 ml lysingbuffer were added to each fluid sample. After vigorous mixing,the samples were incubated at room temperature for 10 min andthen centrifuged at 300 × g for 5 min. The supernatants were removedand the cells were washed with 2 ml wash buffer, followed by centrifugationat 300 × g for 5 min. The pellets were resuspended in 1 ml ofwash buffer with 100 ml of 10X fixative. The chamber cells werethen analyzed on a FACScan flow cytometer (Becton Dickinson, SanJose, CA). Differential cell percentages were determined usingthe LYSYS II program (Becton Dickinson, San Jose, CA).

Western blot analysis of COX-2 protein produced by granulocytes during an inflammatory response. Chamber exudate was centrifuged at 200 × g for 10 min to pellet cells. The cells were washed with PBS and centrifuged again.The supernatants were discarded and the pellets were frozen at-20°C until further processing. Upon thawing, cell pellets wereresuspended in 0.5 ml lysis buffer (50 mM Tris, 150 mM NaCl, 0.1%Triton X-100, pH 7.5 with 1 mM phenylmethylsulfonyl fluoride)and incubated on ice for 30 min. Samples were centrifuged for15 min at 10,000 × g at 4°C. The supernatant was then incubatedwith 6 µl rabbit antihuman COX-2 polyclonal antibody (Cayman,Ann Arbor, MI) with mixing for 1 hr at 4°C. Protein-A Sepharosewas then added to the sample and again the sample was mixed for1 hr. Samples were centrifuged for 5 sec and the supernatant wasdiscarded. The pellets were then washed two times with 1 ml lysisbuffer containing 0.1% Triton X-100 and 1 time with lysis bufferwithout Triton X-100, discarding the supernatant after each wash.The Sepharose pellet was resuspended in 30 µl PAGE loading buffer,boiled for 5 min and run on a 10% polyacrylamide SDS gel underreducing conditions. The proteins were blotted onto ImmobilonPVDF membrane (Millipore, Bedford, MA) and probed with COX-2 antibody(Cayman, Ann Arbor, MI) at a 1:1000 dilution. Proteins were visualizedby ECL Western blotting (Amersham, Arlington Heights, IL) accordingto manufacturer's procedure.

	Results

Top Abstract Introduction Methods Results Discussion References

Specific enzyme effects of compounds (table 1) were evaluated in-vitro on COX-1, COX-2 and 5-LO as described in "Methods."Aspirin, indomethacin and tenidap demonstrated preferential inhibitionof COX-1, which is consistent with the activity of standard NSAIDs.In the specific enzyme systems, nimesulide and SC-58125 are COX-2selective inhibitors (Magni, 1993, Bevilacqua and Magni, 1993,Davis and Brogden, 1994, Isakson et al., 1994, Seibert et al.,1994). None of these cycooxygenase inhibitors exhibited 5-LO inhibition.Zileuton was the only 5-LO selective compound tested, althoughRWJ-63556 (N-[5-(4-fluorophenoxy)thien-2-yl] methanesulfonamide),demonstrated marked selectivity for COX-2 (IC50 COX-2 = 1.86 µM,IC50 COX-1 > 10 µM) and additionally potently inhibited 5-LO (IC50= 0.13 µM).

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TABLE 1
In vitro IC₅₀ calculations of various eicosanoid synthesis inhibitors

These compounds were evaluated for their oral activity on carrageenan-induced inflammation in s.c. chambers in dogs. Carrageenanadministration produces a significant influx of leukocytes intothe exudate which peaks by 24 hr (fig. 1) and is maintained overa period of 3 or more days. Leukocyte counts usually begin toreturn to initial baseline values by day 6 (data not shown). Theincrease in leukocyte count is reproducible, as evidenced by repeatedcontrol responses measured in 31 dogs. Control responses wereevaluated twice in each dog with 2 to 8 mo and one to four treatmentresponses administered between each control experiment (fig. 2).Flow cytometry analysis of the samples revealed a shift in thefluid cell populations from primarily lymphocytes at time 0 topredominantly granulocytes by 24 hr postchallenge (fig. 3). Fluidsmears, examined microscopically, showed that the granulocytesthat infiltrate the chamber were primarily neutrophils but alsoincluded a low percentage of macrophages and mast cells. The patencyof the implanted chambers was very good, as only 3 of the 72 animalsrequired the removal of the chamber due to infection or severeresponses to the administration of carrageenan.

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Fig. 1. Leukocyte influx into subcutaneous chambers after carrageenan challenge. Values represent the mean ± SEM (n = 72). *Significantchanges from baseline levels, P < .0001 using one-tailed one-sidedt test.

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Fig. 2. Reproducibility of the control response to carrageenan. Values represent the mean ± S.E.M. (n = 31). Control responses wereevaluated twice with 2 to 8 mo and one to four treatment responsesadministered between each control experiment. *Significant fromcorresponding point, P < .05 using Student's t test.

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Fig. 3. FACScan analysis of leukocyte populations in chamber fluid samples removed before and 24-hr postcarrageenan challenge in anindividual dog. Sample size = 10,000 events.

Because cells involved in the inflammatory process release eicosanoid metabolites of arachidonic acid (Higgins and Lees, 1984,Jagels and Hugli, 1994), the inflammatory response was furthercharacterized using ELISA to measure changes in the concentrationof these products in the inflammatory exudate. The cyclooxygenaseproducts, PGE₂ and TxB₂, increased along with granulocytic infiltrationover the course of the study. LTB₄ concentration was increasedat 5 hr, but fell below baseline levels by 24 hr (fig. 4), thusassessment of 5-LO inhibition could only be made at 5 hr postchallenge.The inflammatory response should be accompanied by productionof COX-2 protein. Western blot analysis using antihuman COX-2antibody and lysed exudate cells from the dogs was performed todetermine if the cyclooxygenase products released during the reactionwere due to the upregulation of the inducible COX-2 gene. COX-2protein was expressed over the 24-hr experimental period. Thisprotein was not evident in 0-hr samples or in samples where thedogs were treated with dexamethasone (3 mg/kg, P.O.) (fig. 5).Studies have shown that dexamethasone inhibits the expressionof COX-2 induced by a variety of stimuli (Masferrer et al., 1990,Masferrer et al., 1992).

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Fig. 4. Changes in eicosanoid concentration in exudate during the inflammatory response. Each bar represents the mean change frombaseline control ± S.E.M. (n = 72). *Significant (P < .05), **Significant(P < .0001) from baseline using one-tailed one-sample t test.

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Fig. 5. Western blot analysis using antihuman COX-2 antibody with lysed cells collected in exudates from a single control dog andfrom another treated with dexamethasone (3 mg/kg, p.o.).

The oral activity and selectivity of standard antiinflammatory agents were evaluated in this model. The compounds were administeredin gelatin capsules at the time of carrageenan challenge (0 hr).The effects of indomethacin (3 mg/kg, p.o.), which inhibits bothCOX-1 and COX-2 in vitro, are illustrated in figure 6. Granulocyteinfiltration and ex vivo PGE₂ production in whole blood were inhibitedmore than 60%, although the PGE₂ concentration in the exudatewas inhibited more than 90% throughout the course of the study,demonstrating indomethacin's lack of selectivity for COX isozymes.In comparison, nimesulide (10 mg/kg, p.o.), a compound more specificfor COX-2 in vitro (Magni, 1993, Bevilacqua and Magni, 1993, Davisand Brogden, 1994), attenuated the early increase in cell infiltrationalthough having no inhibitory activity at 24 hr, but continuedto inhibit PGE₂ production in the exudate. The lack of activityof nimesulide on COX-1 is evident by its lack of inhibitory activityon the ex-vivo production of PGE₂ in blood (fig. 6). Dose/responsecurves were generated to obtain ED₅₀s from linear regression.The activities of a number of compounds were compared on eachparameter evaluated (table 2). In this model, all of the moreCOX-1 selective inhibitors tested demonstrated ex-vivo activityon prostaglandin production in the blood. Although indomethacinand tenidap were effective inhibitors of cell infiltration andPGE₂ production in the exudate, aspirin inhibited only the prostaglandinlevels but had no effect on cell migration. The corticosteroid,dexamethasone, effectively inhibited the inflammatory componentsmeasured in this model without altering eicosanoid productionex vivo. Zileuton, a 5-LO inhibitor, also inhibited the influxof granulocytes and PGE₂ present in the fluid at 24 hr. The selectiveCOX-2 inhibitors, nimesulide and SC-58125, reduced both cell influxand PGE₂ production throughout the 24-hr period with no effecton ex vivo eicosanoid production. The metabolite of nabumetonehas been reported to be a COX-2 inhibitor (De Witt et al., 1993,Friedel et al., 1993), thus nabumetone acts in a similar fashionto nimesulide and SC-58125 in vivo. The dual COX-2 selective/5-LOinhibitor, RWJ 63556, is a potent inhibitor of leukocyte influxover a period of 24 hr and maintains its in vitro profile on eicosanoids.

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Fig. 6. Mean percent inhibition of control responses to carrageenan by indomethacin (3 mg/kg, p.o., n = 7) or nimesulide (10 mg/kg,p.o., n = 3). The granulocyte influx is indicative of an inflammatoryreaction, although elevated fluid PGE₂ and ex vivo PGE₂ productionare indicative of COX-2 and COX-1 responses, respectively. Eachdog served as its own control.

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TABLE 2
In vivo ED50 calculations of various antiinflammatory agents

	Discussion

Top Abstract Introduction Methods Results Discussion References

The method developed for this study was adapted from other models of inflammation in rabbits, dogs and horses (Higgins etal., 1987, Lees et al., 1987, Clemons et al., 1992, Zech et al.,1993, McKellar et al., 1994). Many characteristics of the inflammatoryprocess can be evaluated in this model, which imposes minimaldistress on the animals and is reproducible over time. Carrageenanis reported to initiate inflammation locally by activation ofthe complement pathway and by a selective cytopathic effect onmacrophages which become activated to release degradative lysosomalenzymes. The response elicited in this model is characterizedby neutrophil infiltration into the exudate over 24 hr. A varietyof vasoactive and chemotactic inflammatory mediators (prostaglandins,leukotrienes) are also involved in the carrageenan-induced response(Weissman et al., 1980, Higgins and Lees, 1984, Hansen et al.1992, Jagels and Hugli, 1994, Leirisalo-Repo, 1994,, Siminiaket al., 1995, Fujishima and Aikawa, 1995). Western blot analysisof cells obtained from exudates indicated that COX-2 expressionis up-regulated during the inflammatory response in this modeland is inhibited by dexamethasone treatment. This analysis suggeststhat there is some degree of cross-reactivity of the human COX-2antibody between human and canine proteins. Therefore, in thismodel, the elevated prostanoid levels observed in the exudateduring the inflammatory response are used as an indicator of aninducible COX-2 response, although the ex vivo production of prostanoidsin the blood is considered a constitutive COX-1 mediated event.Enhanced LTB₄ concentration was only evident in the 5-hr samplesin this model although cell numbers continued to increase over24 hr. It may be possible for leukocyte infiltration to occurduring 5-LO inhibition because carrageenan exerts its effectsby activating the complement pathway, thus starting a cascadeof events that produce several chemotactic factors such as C5a,chemokines and LTB₄. However, inhibition of chemotaxis due to5-LO products during an inflammatory response does appear an effectiveapproach to inhibit inflammation, as evidenced by the effectsof zileuton. The decrease in LTB₄ levels observed at 24 hr postchallengemay be attributed to the high numbers of neutrophils that invadethe chamber because these cells have been reported to catabolizeLTB₄ into less biologically active products (Shak and Goldstein,1985).

Standard NSAIDs inhibited cell influx in this model at clinically effective doses, as demonstrated by the inhibitory activityof indomethacin and tenidap. These compounds are COX-1 inhibitorsas evidenced by their inhibition of ex vivo prostanoid production.Newer COX-2 selective compounds also inhibited leukocyte influxand demonstrate COX-2 selectivity by preferentially inhibitingprostanoid (PGE₂ and TxB₂) production in the exudate during theinflammatory response versus the ex-vivo production in peripheralblood. Dexamethasone is a potent antiinflammatory agent in thismodel without demonstrating COX-1 activity in the ex-vivo bloodassay. This is consistent with the proposed COX-2 activity ofglucocorticoids (Masferrer et al., 1990, 1992).

Although this system appears to be capable of detecting antiinflammatory effects on leukocyte infiltration and COX-1/COX-2selectivity of cyclooxygenase inhibitors, it also indicates that5-lipoxygenase products may play an important role in the inflammatoryresponse. Zileuton, a selective 5-LO inhibitor, is a potent antiinflammatoryagent in this system and reduces PGE₂ concentration in the exudateat 24 hr. Because LTB₄ is a potent chemotactic factor derivedfrom the 5-LO pathway, this effect on PGE₂ production might beexplained by the decreased number of cells present to producemediators or that zileuton may exert its effects through additionalmechanisms. The lack of an antiinflammatory effect on leukocyteinflux by aspirin, although inhibiting PGE₂ production (table2) is not surprising because COX inhibitors do not exert anyeffects on chemotactic factors such as C5a, IL-8 or LTB₄. Thismay also support the suggestion that NSAIDs may not exert theirantiinflammatory effects by cyclooxygenase inhibition alone andthat cyclooxygenase inhibition does not always result in attenuationof the inflammatory process (Walker et al., 1976, Siegel et al.,1979, Abramson and Weissman, 1989). Selective, although not necessarilyspecific, COX-2 inhibitors such as SC-58125 and nimesulide producedan antiinflammatory effect on granulocyte influx at 5 hr (ED₅₀s= 0.4 and 15.8 mg/kg, P.O., respectively), although demonstratinglittle activity at 24 hr. However, in both cases the inhibitionof the COX-2 regulated PGE₂ production in exudate was more pronouncedat 24 hr when the inhibition of cell influx was minimal. Neithercompound was a potent inhibitor of PGE₂ production in blood. However,both compounds produced a decrease in LTB₄ production in exudateat 5 hr, corresponding to their antiinflammatory activity. Thesedata suggest a possible association between inhibition of leukotrieneproduction and the inhibition of cell influx and that selectiveinhibitors of COX-2 do not appear to exert their effect throughCOX inhibition alone, because the inhibition of COX-2 does notappear to correlate with the antiinflammatory activity in thismodel. Indeed, many antiinflammatory agents exert their activitythrough more than one mechanism, such as cytokine modulation andantihistaminic activity (Griswold, et al., 1993, Rossoni et al.,1993) and it may be that COX-2 inhibition alone will not inhibitan inflammatory response.

In this model, RWJ 63556 is a potent, orally active COX-2 selective/5-LO inhibitor and maintains its antiinflammatory andLTB₄ inhibitory effects throughout the entire 24-hr experimentalduration. This compound is an aryl methane sulfanamide which isstructurally related to nimesulide, a known COX-2 selective inhibitor.It is possible that it may derive 5-LO activity by forming a 6membered iron chelating ring among the sulphur of the thiaphene,one of the oxygen atoms on the sulfonamide moiety and the metalion on the active site of 5-LO. It may be advantageous for a compoundto have both activities, because prostaglandins have been implicatedin enhancement of LTB₄ mediated inflammation (Ferreira and Vane,1979, Raud et al., 1989, Hedqvist et al., 1990) and the data obtainedin this study suggests that effective antiinflammatory compoundselicit their effects on cell influx during times of reduced LTB₄concentration in the exudate. Inhibition of PGE₂ alone in theexudate does not appear to correlate with inhibition of cell influx.This correlation appears to hold for zileuton, nabumetone, RWJ63556 and dexamethasone. Only tenidap appears to deviate fromthese observations. Tenidap inhibits leukocyte infiltration (ED₅₀< 3 mg/kg, P.O.) although inhibiting PGE₂ production in both theexudate and the blood, demonstrating little COX-2 selectivity,with essentially no inhibition of LTB₄ production. Perhaps thereported cytokine modulating activities of tenidap (Otternesset al. 1991, Breedveld, 1994, Conti et al., 1994, Wylie et al.,1995, Madhok, 1995) account for its antiinflammatory activityby inhibiting the activities of chemotactic cytokines. The otherclasses of agents evaluated in this model (glucocorticoids, COX-1/COX-2inhibitors, 5-LO inhibitors) maintain their antiinflammatory activitythroughout the experimental period when accompanied by decreasedLTB₄ levels in the exudate.

RWJ 63556, an orally active dual COX-2 selective/5-LO inhibitor, produces significant antiinflammatory activity in this dogmodel of local inflammation and may represent a new class of antiinflammatorycompounds which are needed for the effective treatment of inflammatorydiseases, such as rheumatoid arthritis, without causing deleteriousGI side effects. A dual COX-2 selective/5-LO inhibitor may providesymptomatic relief of hyperalgesia and inhibit the cell infiltrationthat leads to tissue damage at sites of inflammation. Additionally,a new in vivo model of local inflammation is described which yieldsinformation about many aspects of the response although minimizingdistress and the number of animals required to evaluate new antiinflammatorytherapies.

	Footnotes

Accepted for publication April 4, 1997.

Received for publication January 10, 1997.

Send reprint requests to: Thomas Kirchner, Department of Inflammation Research, The R.W. Johnson Pharmaceutical Research Institute, Route 202, Raritan, NJ 08869.

	Abbreviations

COX, cyclooxygenase; PGE₂, prostaglandin E₂; TxB₂, thromboxane B₂; LTB₄, leukotrine B₄; COX-1, cyclooxygenase-1; COX-2, cyclooxygenase-2; 5-LO, 5-lipoxygenase; RBL-1, rat basophilic leukemia cells; PGD₂, prostaglandin D₂; 5-HETE, 5-hydroxy eicosatetraenoic acid; RIA, radioimmunoassay; ELISA, enzyme linked immunosorbant assay; PAGE, polyacrylamide gel electrophoresis; SC-58125, ORTHO-{[4-(4-aminophenyl)sufonyl}phenylaminocarbonyl} benzoic acid; RWJ 63556, N-[5-(4-fluorophenoxy)thien-2-yl]methane sulfonamide: GI, gastrointestinal: NSAIDs, nonsteroidal antiinflammatory drugs.

	References

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