Glycoprotein IIb/IIIa Receptor Number and Occupancy during Chronic Administration of an Oral Antagonist

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Vol. 295, Issue 2, 670-676, November 2000

Glycoprotein IIb/IIIa Receptor Number and Occupancy during Chronic Administration of an Oral Antagonist¹

Martin J. Quinn, Dermot Cox, J. Brendan Foley and Desmond J. Fitzgerald

The Centre for Cardiovascular Science, Department of Clinical Pharmacology, The Royal College of Surgeons in Ireland, Dublin, Ireland (M.J.Q., D.C., D.J.F.); and Cardiology Department, Core Research for Engineering, Science, and Technology Directorate, St. James's Hospital, Dublin, Ireland (J.B.F.)

	Abstract

Top Abstract Introduction Experimental Procedures Results Discussion References

Long-term treatment with oral glycoprotein (GP)IIb/IIIa antagonists has failed to produce significant clinical benefit. Wehave examined the pharmacology of xemilofiban in the evaluationof oral xemilofiban in controlling thrombotic events (EXCITE)trial. The EXCITE trial was a multicenter study of xemilofibanin 7232 patients undergoing percutaneous coronary intervention.Thirty-two patients randomized to xemilofiban (10 or 20 mg threetimes daily) or placebo were followed for up to 6 months. GPIIb/IIIareceptor number and occupancy were quantified using two monoclonalantibodies mAb1 and mAb2. mAb1 was used to quantify receptor number.mAb2 recognizes an epitope that is lost due to a ligand-inducedconformational change in GPIIb/IIIa and is a marker of receptoroccupancy. Platelet aggregation was performed by light transmission.In vitro, the active metabolite of xemilofiban (SC-54701) inhibitedmAb2 binding (IC₅₀ of 0.5 ± 0.1 × 10⁸ M) but not mAb1. In vivo, long-term therapy with xemilofibandid not alter GPIIb/IIIa receptor number. mAb2 binding was inhibitedthroughout the treatment period and recovered slowly after drugwithdrawal. Maximum inhibition of ADP-induced aggregation occurredat 4 to 7 h after the first dose of study medication. However,inhibition of platelet aggregation was low (between 24 and 45%)before dosing on days 60 and 180. There was no significant reboundincrease in platelet aggregation after drug withdrawal. Long-termxemilofiban therapy does not alter platelet GPIIb/IIIa receptornumber. Inhibition of platelet aggregation was poor at the endof each dosing interval and this may explain the failure of xemilofibanto alter clinicalevents.

	Introduction

Top Abstract Introduction Experimental Procedures Results Discussion References

Short-term blockade of the platelet fibrinogen receptor glycoprotein (GP)IIb/IIIa reduces ischemic complications in patientspresenting with acute coronary syndromes or undergoing percutaneouscoronary intervention (The EPIC Investigators, 1994; The CAPTUREInvestigators, 1997; The EPILOG Investigators, 1997; Brener etal., 1998; The EPISTENT Investigators, 1998; The PRISM Study Investigators,1998; The PRISM-PLUS Study Investigators, 1998). Several oralGPIIb/IIIa antagonists have been developed and have been studiedin a number of large-scale clinical trials (Zablocki et al., 1995;Weller et al., 1996; Muller et al., 1997). However, xemilofiban,an oral GPIIb/IIIa antagonist, showed no long-term clinical efficacyin patients after coronary angioplasty (O'Neill et al., 2000).Two other compounds, sibrafiban and orbofiban, increased mortalityand the risk of myocardial infarction in patients with acute coronarysyndromes (Cannon et al., 2000; The SYMPHONY Investigators, 2000).

As with i.v. GPIIb/IIIa antagonists, oral GPIIb/IIIa antagonists inhibit fibrinogen binding and platelet aggregation (Cannonet al., 1998; Kereiakes et al., 1998) and are effective in preventingvascular occlusion in a number of animal models of acute thrombosis(Frederick et al., 1998). However, the long-term effects of receptoroccupancy on platelet function and receptor number are unknown.It is possible that the clinical effect of long-term receptoroccupancy would be limited by an alteration in GPIIb/IIIa receptornumber or function, similar to that seen with G-protein-coupledreceptors. Here, we examine the effect of chronic GPIIb/IIIa receptorblockade with xemilofiban on receptor number and function whenadministered over 6 months. GPIIb/IIIa receptor number and occupancywere quantified using two antibodies, mAb1 (LYP18) (Boukercheet al., 1989) and mAb2 (4F8). mAb1 binds to a site also recognizedby abciximab but is not displaced by xemilofiban. mAb2 binds toa site on GPIIIa remote from the ligand binding site and its bindingis inhibited by several GPIIb/IIIa antagonists. Inhibition ofmAb2 binding is noncompetitive and is due to a conformationalchange in the receptor. Thus, mAb1 binding provides an estimateof GPIIb/IIIa receptor number, whereas mAb2 binding provides evidenceof receptor occupancy (Quinn et al., 1999).

	Experimental Procedures

Top Abstract Introduction Experimental Procedures Results Discussion References

Materials. The anti-GPIIIa monoclonal antibodies mAb1, clone LYP18; mAb2, clone 4F8; and GPIIb/IIIa receptor occupancy kits, which containmAb1, mAb2, isotypic control antibody, sheep anti-mouse horseradishperoxidase-linked secondary antibodies, and calibration beads,were provided by Dr. M. Canton (Biocytex, Marseille, France).ADP was purchased from Sigma Chemical Co. (St. Louis,MO).

Effects of Xemilofiban In Vitro. Blood from healthy donors, who had not taken aspirin or any other antiplatelet agent in the previous 7 days, was collectedinto sodium citrate 3.8%. SC-54701 (0.01-320 ng/ml), the activemetabolite of xemilofiban, was incubated with the blood for 30min at room temperature. Aliquots of each dilution were incubatedwith mAb1 or mAb2 (10 µg/ml final concentration) at room temperaturefor 20 min. Antibody binding was determined using fluoresceinisothiocyanate-labeled F(ab)₂ fragments of sheep anti-mouse IgGantibodies. The samples were fixed with 1 ml of 1% formaldehydeafter a 10-min incubation and analyzed by flow cytometry (FACScan;Becton Dickinson, Oxford, UK) at 488-nm excitation. Platelet populationswere gated according to their forward and side light scatter.Histograms were generated using 10,000 events and geometric meanfluorescence was calculated using the CELLQUEST software of theFACScan system (Becton Dickinson). The binding of an isotypiccontrol antibody was taken as nonspecific binding and was subtractedfrom the observed geometric mean fluorescence. Calibration beadswith a known amount of antibody per bead were used to convertthe observed mean fluorescence intensity of the samples to thenumber of GPIIb/IIIa receptors per platelet as previously described(Quinn et al., 1999).

For correlation of SC-54701 inhibition of mAb2 binding and inhibition of platelet aggregation, whole blood collected in sodiumcitrate 3.8% was centrifuged at 150g for 10 min and platelet-richplasma (PRP) was aspirated. The PRP was diluted to 150 × 10³ platelets/µl in PBS. This was performed to ensure saturationby the antibodies. The dilute PRP was incubated for 30 min withSC-54701 (0.35-1000 nM) or buffer as control. Aliquots of eachdilution were incubated with mAb1 or mAb2 (10 µg/ml) and analyzedas described above. Platelet aggregation of 500-µl aliquots ofthe dilute PRP/SC-54701 mixtures was measured by light transmission(Biodata PAP-4; Biodata Corporation, Horsham, PA) using 20 µMADP as the agonist. Results are expressed as a percentage of controlaggregation.

Effects of Xemilofiban In Vivo. This was a substudy of the EXCITE (evaluation of oral xemilofiban in controlling thrombotic events) trial, a multinationaldouble blind, randomized, controlled trial of the efficacy andsafety of xemilofiban in 7232 patients undergoing percutaneouscoronary intervention. Males and females (nonpregnant, nonlactating)between the age of 21 and 80 years with clinically significantcoronary artery disease (stable or unstable angina or previousmyocardial infarction) suitable for coronary intervention wereeligible forrecruitment.

Exclusion criteria included patients at increased risk of bleeding or with a family or personal history of a bleeding disorder,chronic (>1 month) total occlusion of the index artery, severeliver impairment, renal insufficiency (creatinine >1.5 mg/dl orage-adjusted creatinine clearance of <40 ml/min), uncontrolledhypertension, or history of malignancy within 1 year of screening.Anticoagulant and other antiplatelet therapy, excluding aspirin,or the chronic use of nonsteroidal anti-inflammatory therapy,was prohibited. Patients participating in the EXCITE trial inSt. James's Hospital (Dublin, Ireland) were recruited into thissubstudy. The protocol was reviewed and approved by the IrishMedicines Board and the Ethics Committee at St. James's Hospitaland all patients gave written informedconsent.

Study Protocol. Thirty to 90 min before the revascularization procedure, patients were randomized in a double blind fashion to 20 mg of xemilofibanor matching placebo and a maintenance dose of 10 or 20 mg of xemilofibanor matching placebo three times daily for 6 months. Aspirin wasadministered at a dose of 80 to 325 mg daily. Coronary angioplastywas performed in the usual manner. Heparin was administered beforeand during the procedure to maintain the activated clotting timebetween 250 and 350 s. Ticlopidine (250 mg) twice daily was administeredto stented patients randomized to placebo and a matching ticlopidineplacebo was administered to stented patients on xemilofiban for2 to 4 weeks after theprocedure.

Blood Samples. Blood samples were collected from a peripheral vein into 3.8% sodium citrate at baseline; at 1 to 2 h and 4 to 7 h after theinitial dose of medication on day 1; and before and 1 h afterdrug administration on the morning of day 60 ± 7 and day 180 ±7. Sampling was also performed at 24 and 48 h after the last doseofmedication.

Platelet Aggregation. Platelet aggregation studies were performed within 2 h of blood sampling. PRP was prepared as described above and the remainingplasma was centrifuged at 2500g for 5 min to obtain platelet-poorplasma. Platelet aggregation was determined 3 min after the additionof ADP (20 µM) to PRP at 37°C by light transmission (Biodata PAP-4;Biodata Corporation). The platelet aggregation at the differenttime points was expressed as a percentage of baseline plateletaggregation, before administration of thedrug.

GPIIb/IIIa Receptor Number and Occupancy. GPIIb/IIIa receptor number and occupancy were quantified using the GPIIb/IIIa receptor occupancy kit (Biocytex, Marseille,France), which contains the anti-GPIIIa monoclonal antibodiesmAb1 (LYP18) and mAb2 (4F8) and calibration beads. Analyses wereperformed within 6 h of blood collection. The 1 in 4 dilutionwas performed in platelet-poor plasma from the corresponding timepoint to avoid dilution of xemilofiban. The samples were analyzedby flow cytometry as describedabove.

Plasma Xemilofiban. Analyses of plasma levels of xemilofiban were performed using a fluorescence polarization immunoassay, with a limit of detectionof 3.5 ng/ml (Clinical Pharmacokinetics Laboratory, Buffalo,NY).

Statistical Analysis. Continuous data are presented as mean ± S.E. Analyses between xemilofiban and placebo-treated groups were performed by analysisof variance using DataDesk 6.0. Variables were assessed for systematicdeparture from normality using normal probability plots. All variableshad correlations of >0.950 with the expected normal distribution.If there was a significant difference between the placebo andactive treatment group, a three-category variable (placebo, 10mg and 20 mg tds) was used to do Scheffé post hoc tests for theeffect of dose. Plasma levels of SC-54701 were correlated withthe percentage of baseline platelet aggregation using Pearson'scorrelation coefficient. Aggregation was log transformed to linearizethe dose response. Values <1% and >99% were changed to 1 and 99%for theanalysis.

	Results

Top Abstract Introduction Experimental Procedures Results Discussion References

Effects of Xemilofiban In Vitro

The effect of SC-54701, the active metabolite of xemilofiban, on mAb1 and mAb2 binding in whole blood and PRP was studiedin vitro by flow cytometry. mAb2 binding was inhibited by SC-54701in a concentration-dependent manner with an IC₅₀ of 0.5 ± 0.1× 10⁸ M in whole blood and 0.8 ± 0.2 × 10⁸ M in PRP, P > .05. mAb1 binding was unaffected by xemilofiban.The inhibition of mAb2 binding in PRP correlated with SC-54701inhibition of ADP (20 µM)-induced platelet aggregation, with acorrelation coefficient of 0.9, P < .0001 (Fig. 1). However, thedose response for inhibition of aggregation was steeper than forinhibition of mAb2 binding, with maximum inhibition of ADP-inducedplatelet aggregation seen at a 60% reduction in mAb2.

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Fig. 1. A, effect of SC-54701, the active metabolite of xemilofiban, on mAb1 ( $black-diamond$ ) and mAb2 (

) binding to platelets in whole blood, in vitro. SC-54701 reduces mAb2 binding in a concentration-dependent manner with an IC₅₀ of 2.7 ± 0.5 ng/ml, whereas mAb1 binding is unaffected (n = 5). B, correlation between SC-54701 inhibition of mAb2 binding in PRP, expressed as a percentage of control and inhibition of ADP (20 µM)-induced aggregation in PRP as a percentage of control.

Effects of Xemilofiban In Vivo

Patient Population. Thirty-two patients were enrolled in the study between January and April 1998 and their baseline characteristics are shownin Table 1. Twelve patients were randomized to placebo, 10 patientsto xemilofiban (10 mg tds), and 10 patients to xemilofiban (20mg tds). Four patients randomized to xemilofiban (10 mg tds) andone patient randomized to xemilofiban (20 mg tds) were withdrawnbefore day 60. The reasons were bleeding in two patients (onegastrointestinal bleed and one recurrent nosebleeds), myocardialinfarction in one patient, withdrawal of consent in one patient,and failure to undergo a percutaneous coronary intervention inone patient. Day 60 follow-up data were not available for threepatients randomized to placebo; one patient was withdrawn beforeday 60 with a femoral artery pseudoaneurysm and two patients failedto attend for their day 60 follow-up. Three patients were withdrawnbefore their 6-month visit; two patients on placebo (both withcardiac endpoints) and one patient on xemilofiban (10 mg tds)because open-labeled ticlopidine had been added to their treatmentafter coronary stent insertion. Two patients on xemilofiban (20mg tds) did not return for their washout blood tests and one patienton placebo did not return for the 48-h blood test.

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TABLE 1
Demographic details
Numbers are percentages within each treatment group rounded to the nearest numeral

mAb1 and mAb2 Binding. In the study population, baseline GPIIb/IIIa receptor number determined by mAb1 binding was similar in the different treatmentgroups with 54,162 ± 2,455 receptors per platelet in patientsrandomized to placebo, 51,027 ± 2,886 in patients randomized toxemilofiban (20 mg tds), and 53,359 ± 2,602 in patients randomizedto xemilofiban (10 mg tds) (P = .7). GPIIb/IIIa receptor numberdid not change during treatment or after drug withdrawal (Fig.2A). Forty-eight hours after drug discontinuation, mAb1 identified53,521 ± 3,957 receptors in patients on placebo; 45,249 ± 6,208in patients on xemilofiban (10 mg tds); and 51,876 ± 5,031 inpatients on 20 mg tds, P = .4 (Fig. 2). There was no differencein the number of sites recognized by mAb2 at baseline in the differenttreatment groups, with 43,501 ± 1,823 sites per platelet in patientson placebo; 38,913 ± 1,981 sites in patients randomized to xemilofiban(20 mg tds); and 39,064 ± 2,924 in patients randomized to 10 mgtds (P = .3) (Fig. 2B). Four to 7 h after the initial dose of20 mg of xemilofiban, mAb2 binding was significantly reduced to13,026 ± 1,722 in patients randomized to xemilofiban (20 mg tds)and 10,229 ± 1,097 in patients randomized to xemilofiban (10 mgtds) (P < .0001). mAb2 binding remained inhibited during the treatmentperiod and had not recovered before drug administration on day60 or 180 (P < .0001). mAb2 binding recovered slowly after thelast dose on day 180 but was still significantly inhibited 48h after drug withdrawal, P = .004 (Fig. 2B). mAb2 binding didnot change in placebo-treated patients during the course of thestudy.

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Fig. 2. A, GPIIb/IIIa receptor number quantified by mAb1 binding, in patients randomized to placebo (

), xemilofiban (10 mg tds) (

), or xemilofiban (20 mg tds) ( $black-square$ ). B, GPIIb/IIIa receptor occupancy, quantified by mAb2 binding, in patients randomized to placebo (

), xemilofiban (10 mg tds) (

), or xemilofiban (20 mg tds) ( $black-square$ ). **P < .005, ***P < .001.

Inhibition of Platelet Aggregation. Maximum inhibition of ADP (20 µM)-induced platelet aggregation was observed at 4 to 7 h after the first dose of study medication,with aggregation at 86 ± 7% of baseline in patients on placebo,4 ± 3% of baseline in patients on 10 mg tds, and 4 ± 2% in patientson 20 mg tds (P < .00001). Trough levels of ADP-induced plateletaggregation, before drug administration on day 60, were similarin the two treatment groups at 67 ± 14% of baseline in patientson 10 mg tds and 55 ± 14% of baseline in patients on 20 mg tds.However, trough levels on day 180 showed less inhibition at 76± 10 and 71 ± 12% of baseline, respectively (Fig. 3). One hourafter drug administration on day 60, platelet aggregation was55 ± 14 and 26 ± 10% of baseline on 10 and 20 mg tds xemilofiban,respectively. One hour after drug administration on day 80, plateletaggregation was 55 ± 13 and 42 ± 14% of baseline on 10 and 20mg tds xemilofiban. Platelet aggregation had recovered within24 h of drug discontinuation and although there was a trend towardincreased platelet aggregation at 24 and 48 h after drug withdrawalin the active treatment groups, this did not reach statisticalsignificance (P = .123).

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Fig. 3. Ex vivo inhibition of platelet aggregation pre drug and 1 h post drug on day 1, 60, and 180, and 24 and 48 h after the last dose of medication in patients randomized to placebo ( $diamond$ ), xemilofiban (10 mg tds) ( $black-triangle$ ), or xemilofiban (20 mg tds) ( $black-square$ ). Results are expressed as a percentage of baseline aggregation. *P < .05, **P < .005.

Xemilofiban Plasma Levels. The plasma concentration of SC-54701, the active metabolite of xemilofiban, was assayed in 21 patients before and 1 h afterdrug administration on day 180. Twelve of the patients assayedwere on active drug (eight patients randomized to 20 mg tds andfour patients randomized to 10 mg tds) (Table 2). Plasma concentrationof SC-54701 correlated with the corresponding platelet aggregationexpressed as a percentage of baseline (r² = 0.77, P < .001) (Fig. 4), demonstrating that the metaboliteSC-54701 was largely responsible for the platelet inhibitory effectof xemilofiban.

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TABLE 2
Plasma levels of SC-54701 (ng/ml) on day 180 and during the 48-h washout

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Fig. 4. Correlation between platelet aggregation expressed as a percentage of baseline and plasma SC54701, the active metabolite of xemilofiban, measured pre and 1 h post the last dose of xemilofiban on day 180 (n = 12) and 24 and 48 h later (n = 9).

	Discussion

Top Abstract Introduction Experimental Procedures Results Discussion References

Oral GPIIb/IIIa antagonists have failed to prevent coronary events in patients with acute coronary syndromes (Cannon et al.,2000; The SYMPHONY Investigators, 2000) and after coronary angioplasty(O'Neill et al., 2000), although short-term administration ofi.v. agents has proved effective. One explanation is that thedegree of receptor occupancy and inhibition of platelet aggregationachieved with oral dosing is inadequate. Although the goal withi.v. agents is to achieve a consistent >80% receptor occupancyand inhibition of platelet aggregation, this is not possible withoral therapy given the intermittent mode of administration. Inthis study, xemilofiban inhibited ADP (20 µM)-induced plateletaggregation by greater than 95% 4 to 7 h after the first doseof xemilofiban on day 1. However, with long-term therapy, troughlevels were considerably lower at 30 to 45% inhibition, similarto previous reports (Kereiakes et al., 1998). The use of citrateanticoagulation may have overestimated the degree of plateletinhibition because low calcium concentrations increase the bindingof certain GPIIb/IIIa antagonists (Phillips et al., 1997). However,the IC₅₀ for inhibition of platelet aggregation by xemilofibanis reduced by only 30% in citrated versus D-phenylalanyl-N-[4-[(aminoiminomethyl)amino]-1-(chloroacetyl)butyl]-L-prolinamide(PPACK)-treated platelet-rich plasma (IC₅₀ 4 × 10⁸ versus 6 × 10⁸ M, respectively; M. J. Quinn and D. J. Fitzgerald, unpublisheddata). This is a minor change compared with the change in IC₅₀seen with eptifibatide (140-570 nM). Thus, the levels of plateletinhibition and receptor occupancy achieved in this study werewell below the levels of inhibition (>80%) required to preventcomplications at the time of coronary intervention (Coller, 1998).The low level of platelet inhibition may explain in part the lackof clinical benefit during long-term administration ofxemilofiban.

A second issue with GPIIb/IIIa antagonists is that they may act as partial agonists (Cox et al., 2000) and so long-term administrationmay influence receptor number or limit the degree of plateletinhibition. GPIIb/IIIa antagonists are largely designed to mimicreceptor recognition sites in adhesion proteins, particularlythe arginine-glycine-aspartate sequence (Zablocki et al., 1995).Many antagonists induce an active conformation in the receptor,that is, one capable of binding fibrinogen (Peter et al., 1998).GPIIb/IIIa antagonists also induce the appearance of previouslyhidden regions, so called ligand-induced binding sites (Kounset al., 1990; Honda et al., 1995). The functional relevance ofthese newly exposed regions is unclear. However, there is evidencethat GPIIb/IIIa antagonists that induce ligand-induced bindingsites provoke platelet activation, including Ca²⁺ transients and thromboxane formation and under some circumstances,platelet aggregation (Honda et al., 1998; Peter et al., 1998).

In addition to inducing the appearance of previously hidden epitopes, ligands may also induce the disappearance of an epitope,referred to as ligand-attenuated binding sites. Ligand attenuationof antibody binding has also been described for the fibronectinreceptor (Mould et al., 1996). The mAb2 epitope on GPIIIa behavesas a ligand-attenuated binding site in that the mAb2 site is remotefrom the ligand binding site (Quinn et al., 1999). Recent experimentssuggest that mAb2 binding reflects an active process. Thus, ligand-induceddisappearance of the mAb2 epitope is not seen in purified GPIIb/IIIaor GPIIb/IIIa expressed in HEK cells and is prevented by the plateletinhibitor prostaglandin E₁ (M. J. Quinn and D. J. Fitzgerald,unpublished observations). Thus, in addition to reporting on receptoroccupancy, the loss of the mAb2 epitope may signify partial agonistactivity. Xemilofiban prevented mAb2 binding both in vitro andin vivo, suggesting that it possesses some partial agonistactivity.

However, there was no evidence that this resulted in enhanced platelet aggregation, for example, during drug withdrawal whenplasma levels fell. This contrasts with the findings of Peteret al. (1998) suggesting that at low levels of GPIIb/IIIa antagonismplatelet aggregation is paradoxically enhanced. (It is worth notingthat mAb2 detected levels of receptor occupancy below the thresholdfor inhibition of aggregation and was a far more sensitive measureof the presence of the drug.) There was also no change in GPIIb/IIIareceptor number, measured as mAb1 binding and no increase in receptornumber during drugwithdrawal.

The recent results of the EXCITE data suggest that oral GPIIb/IIIa antagonists are ineffective in preventing coronary events.Indeed, the OPUS trial (Cannon et al., 2000) and the unpublishedSYMPHONY 2 have shown an increase in myocardial infarction anddeath, suggesting that the compounds act as partial agonists (Holmeset al., 2000). Our findings suggest that the degree of inhibitionof platelet aggregation with xemilofiban in EXCITE was far lessthan achieved with i.v. agents and this may explain the lack ofefficacy. Although xemilofiban induced a conformational changein the receptor, suggestive of a partial agonist effect, thisdid not translate into altered receptor number or enhanced plateletaggregation at low levels of receptoroccupancy.

	Footnotes

Accepted for publication July 31, 2000.

Received for publication May 23, 2000.

¹ This study was supported by grants from the Higher Education Authority and Health Research Board of Ireland, the CharitableInfirmary Charitable Trust, and the WellcomeTrust.

Send reprint requests to: Professor Desmond Fitzgerald, The Centre for Cardiovascular Science, Department of Clinical Pharmacology, The Royal College of Surgeons in Ireland, 123 St. Stephen's Green, Dublin 2, Ireland. E-mail: dfitzgerald{at}rcsi.ie

	Abbreviations

GP, glycoprotein; mAb1, monoclonal antibody 1, clone P18; mAb2, monoclonal antibody 2, clone 4F8; PRP, platelet-rich plasma; EXCITE, evaluation of oral xemilofiban in controlling thrombotic events trial; tds, three times daily.

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