Low‐dose naproxen interferes with the antiplatelet effects of aspirin in healthy subjects: Recommendations to minimize the functional consequences

Objective

To investigate whether low‐dose naproxen sodium (220 mg twice a day) interferes with aspirin's antiplatelet effect in healthy subjects.

Methods

We performed a crossover, open‐label study in 9 healthy volunteers. They received for 6 days 3 different treatments separated by 14 days of washout: 1) naproxen 2 hours before aspirin, 2) aspirin 2 hours before naproxen, and 3) aspirin alone. The primary end point was the assessment of serum thromboxane B₂ (TXB₂) 24 hours after the administration of naproxen 2 hours before aspirin on day 6 of treatment. In 5 volunteers, the rate of recovery of TXB₂ generation (up to 72 hours after drug discontinuation) was assessed in serum and in platelet‐rich plasma stimulated with arachidonic acid (AA) or collagen.

Results

Twenty‐four hours after the last dosing on day 6 in volunteers receiving aspirin alone or aspirin before naproxen, serum TXB₂ was almost completely inhibited (median [range] 99.1% [97.4–99.4%] and 99.1% [98.0–99.7%], respectively). Naproxen given before aspirin caused a slightly lower inhibition of serum TXB₂ (median [range] 98.0% [90.6–99.4%]) than aspirin alone (P = 0.0007) or aspirin before naproxen (P = 0.0045). All treatments produced a maximal inhibition of AA‐induced platelet aggregation. At 24 hours, compared with baseline, collagen‐induced platelet aggregation was still inhibited by aspirin alone (P = 0.0003), but not by aspirin given 2 hours before or after naproxen. Compared with administration of aspirin alone, the sequential administration of naproxen and aspirin caused a significant parallel upward shift of the regression lines describing the recovery of platelet TXB₂.

Conclusion

Sequential administration of 220 mg naproxen twice a day and low‐dose aspirin interferes with the irreversible inhibition of platelet cyclooxygenase 1 afforded by aspirin. The interaction was smaller when giving naproxen 2 hours after aspirin. The clinical consequences of these 2 schedules of administration of aspirin with naproxen remain to be studied in randomized clinical trials.

     

Thromboxane inhibition during concurrent therapy with low-dose aspirin and over-the-counter naproxen sodium

Aspirin is the dominant antiplatelet therapy for cardiovascular disease. Naproxen is frequently used in aspirin-treated patients and may influence the antiplatelet effect of aspirin. We evaluated the pharmacodynamic interaction (lower bound of the one-sided 95% CI for serum TxB₂ inhibition?<?95%) between 220 mg immediate-release naproxen sodium (once or twice daily) and 81 mg daily immediate release aspirin at various dosing intervals. There was no interaction during the first day of concurrent treatment. After 10 days, irrespective of the timing and dose of naproxen in relation to aspirin dosing, a pharmacodynamic interaction occurred which persisted after discontinuing naproxen. In the control group (aspirin alone), the lower bound for serum TxB₂ inhibition was >?98% at all time points. The clinical relevance of these observations remains unknown and merits further investigation since over-the-counter naproxen is widely used to relieve pain by individuals taking low dose aspirin for cardioprotection.Clinical Trial Registration: NCT02229461     

Gastrointestinal safety of NO-aspirin (NCX-4016) in healthy human volunteers: a proof of concept endoscopic study

BACKGROUND AND AIMS: NCX-4016 is a nitric oxide-releasing derivative of aspirin with antiplatelet activity. The aim of this study was to investigate the effect of NCX-4016 on gastrointestinal mucosa and platelet functions in healthy human volunteers. METHODS: This was a parallel-group, double-blind, placebo-controlled study. Forty healthy subjects were randomly allocated to receive 7 days of treatment with NCX-4016 (400 and 800 mg twice daily), equimolar doses of aspirin (200 and 420 mg twice daily), or placebo. Upper endoscopies were performed before and at the end of the treatment period, and gastroduodenal lesions were graded using a predefined scoring system. Basal and posttreatment platelet aggregation in response to arachidonic acid (AA) and serum thromboxane (TX) B(2) and AA-stimulated platelet TXB(2) production were investigated. RESULTS: Mucosal endoscopic injury score on day 7 was 0.63 +/- 0.16 in the placebo group and 11.0 +/- 3.0 and 16.1 +/- 1.6 in healthy volunteers treated with 200 and 420 mg aspirin twice daily (P < 0.0001 vs. placebo). NCX-4016 was virtually devoid of gastric and duodenal toxicity, resulting in a total gastric and duodenal endoscopic score of 1.38 +/- 0.3 and 1.25 +/- 0.5 (P < 0.0001 vs. aspirin, not significant vs. placebo). NCX-4016 inhibited AA-induced platelet aggregation as well as serum TXB(2) and platelet TXB(2) generation induced by AA to the same extent as aspirin (not significant vs. aspirin). CONCLUSIONS: In this study, we have proven the concept that addition of an NO-donating moiety to aspirin results in a new chemical entity that maintains cyclooxygenase-1 and platelet inhibitory activity while nearly avoiding gastrointestinal damage.     

Effects of selective cyclooxygenase isoform inhibition on systemic prostacyclin synthesis and on platelet function at rest and after exercise in healthy volunteers

To test the hypothesis that selective inhibition of cyclooxygenase (COX)-2 would result in exercise-induced platelet activation by causing a shift in the endogenous thromboxane (TX)/prostacyclin balance, a double blind, randomized study comparing aspirin (300 mg/d) with rofecoxib (25 mg/d) (cross-over design, 14 days washout between treatments) in n = 10 trained healthy volunteers was carried out. Physical exercise resulted only in a minor platelet activation, as reflected by the expression of basal or ADP-stimulated platelet activation markers or basal plasma concentrations of TXB(2). Aspirin significantly reduced TXB(2) in plasma while rofecoxib significantly increased TXB(2) in urine. Although no increase in systemic prostacyclin concentration was observed, there was a significant exercise-related increase in both platelet cAMP and cGMP without any drug-related effects. It is concluded that, in trained healthy volunteers, selective inhibition of COX-1 (aspirin) or COX-2 (rofecoxib) does not affect systemic prostacyclin synthesis after physical exercise. However, our data do not exclude the possibility that in subjects at risk for atherothrombotic complications (e.g. patients with advanced atherosclerotic disease) COX-2 inhibitors may result in platelet activation by inhibiting endothelial prostacyclin formation.     

Prevalence and mechanism of nonsteroidal anti-inflammatory drug-induced clinical relapse in patients with inflammatory bowel disease.

BACKGROUND & AIMS: It has been variably suggested that nonselective NSAIDs and cyclooxygenase (COX)-2 selective inhibitors aggravate or ameliorate clinical disease activity in patients with inflammatory bowel disease. We assessed the effect of these drugs in patients with inflammatory bowel disease (n = 209) and the possible mechanisms. METHODS: First, patients with quiescent Crohn's disease and ulcerative colitis received the non-NSAID analgesic acetaminophen (n = 26) and the conventional NSAIDs naproxen (n = 32), diclofenac (n = 29), and indomethacin (n = 22) for 4 weeks. The Harvey-Bradshaw index was used to define relapse. Second, to assess the mechanism of relapse, intestinal inflammation was quantitated (fecal calprotectin) before and during treatment (20 patients/group) with acetaminophen, naproxen (topical effect, COX-1 and -2 inhibitor), nabumetone (COX-1 and -2 inhibitor), nimesulide (selective COX-2 inhibitor), and low-dose aspirin (selective COX-1 inhibition). RESULTS: Nonselective NSAIDs were associated with a 17%-28% relapse rate within 9 days of ingestion. No patient had an early relapse on acetaminophen, nimesulide, or aspirin, whereas those on naproxen and nabumetone (20%) experienced relapse. These clinical relapses were associated with escalating intestinal inflammatory activity. CONCLUSIONS: NSAID ingestion is associated with frequent and early clinical relapse of quiescent inflammatory bowel disease, and the mechanism appears to be due to dual inhibition of the COX enzymes. Selective COX-2 inhibition with nimesulide and COX-1 inhibition with low-dose aspirin appear to be well-tolerated in the short-term.     

Cumulative antiplatelet effect of low-dose enteric coated aspirin

Enteric coated aspirin (ECA) at doses of 325-1300 mg is an effective alternative to regular aspirin for inhibition of platelet activity while avoiding gastric irritation. The objectives of this study were to determine: (1) the lowest chronic dose of ECA providing effective inhibition of platelet activities, (2) the time course of the inhibition, and (3) the reappearance of platelet cyclo-oxygenase activity. Seven subjects were studied before and after seven daily doses of 40-325 mg ECA. Serum thromboxane (TX) B2 levels indicated that the lowest dose of ECA resulting in greater than 90% inhibition of platelet cyclo-oxygenase was 80 mg/d. Platelet aggregation and ATP release in response to collagen (1 microgram/ml) and arachidonic acid (1 mM) were abolished and bleeding times were prolonged from 6.1 +/- 1.5 min to 9.7 +/- 2.8 min (mean +/- SD, P less than 0.01). Examination of platelet cyclo-oxygenase activity on a daily basis revealed that 24 h after the first 80 mg dose serum TXB2 had decreased by approximately 60% and was suppressed by more than 90% after four doses. Recovery of platelet cyclo-oxygenase activity after a single 80 mg dose of ECA was delayed for 48-72 h indicating that aspirin reached the systemic circulation. We conclude that chronic inhibition of platelet activity may be achieved in a cumulative manner with 80 mg ECA/d.     

Aspirin-insensitive thromboxane biosynthesis in essential thrombocythemia is explained by accelerated renewal of the drug target

Essential thrombocythemia (ET) is characterized by enhanced platelet generation and thrombotic complications. Once-daily low-dose aspirin incompletely inhibits platelet thromboxane A(2) (TXA(2)) in the majority of ET patients. In the present study, we investigated the determinants of aspirin-insensitive platelet TXA(2) biosynthesis and whether it could be further suppressed by changing the aspirin dose, formulation, or dosing interval. In 41 aspirin-treated ET patients, the immature platelet count predicted serum TXB(2) independently of platelet count, age, JAK-2 V617F mutation, or cytoreduction (β = 3.53, P = .001). Twenty-one aspirin-treated patients with serum TXB(2) ≥ 4 ng/mL at 24 hours after dosing were randomized to the following 7-day regimens in a crossover design: enteric-coated aspirin 100 mg twice daily, enteric-coated aspirin 200 mg once daily, or plain aspirin 100 mg once daily. A twice-daily regimen caused a further 88% median (IQR, 78%-92%, P < .001) TXB(2) reduction and normalized the functional platelet response to aspirin, as assessed by urinary 11-dehydro-TXB(2) excretion and the VerifyNow Aspirin assay. Doubling the aspirin dose reduced serum TXB(2) only partially by 39% median (IQR, 29%-54%, P < .05). We conclude that the abnormal megakaryopoiesis characterizing ET accounts for a shorter-lasting antiplatelet effect of low-dose aspirin through faster renewal of platelet cyclooxygenase-1, and impaired platelet inhibition can be rescued by modulating the aspirin dosing interval rather than the dose.     

Selective inhibition of COX-2 in humans is associated with less gastrointestinal injury: a comparison of nimesulide and naproxen

BACKGROUND: Selective inhibitors of cyclooxygenase (COX)-2 may provoke less gastric damage and platelet inhibition than conventional non-steroidal anti-inflammatory drugs. AIMS: We compared the biochemical and gastrointestinal effects of nimesulide, a potent and selective COX-2 inhibitor, with naproxen which exhibits no selectivity. SUBJECTS: Thirty six healthy volunteers were randomised to nimesulide 100 mg or naproxen 500 mg twice daily for two weeks in a double blind, crossover study with a washout between treatments. METHODS: Gastrointestinal side effects were assessed by endoscopy, and by estimation of small intestinal absorption-permeability and inflammation. Comparisons were made between variables at the end of each treatment phase. RESULTS: Nimesulide caused significantly less gastric injury using the modified Lanza score (p<0.001) as well as reduced duodenum injury (p=0.039). Nimesulide had lower visual analogue scores (VAS) for haemorrhage and erosive lesions in the stomach (p<0.001) and for mucosal injection in the duodenum (p=0.039). Naproxen increased excretion of calprotectin, a marker of intestinal inflammation (5.5 (1.2) to 12.1 (2.1) mg/l) while nimesulide had no effect (treatment difference p=0.03). Naproxen abolished platelet aggregation to arachidonic acid and suppressed serum thromboxane B(2) (TXB(2)) by 98%, indices of COX-1 activity. In contrast, nimesulide had no significant effect on platelet aggregation, although it reduced serum TXB(2) by 29%. Production of prostaglandin E(2) and prostacyclin by gastric biopsies, also COX-1 dependent, was inhibited by naproxen, but not by nimesulide. COX-2 activity, determined as endotoxin induced prostaglandin E(2) formation in plasma, was markedly suppressed by both treatments. INTERPRETATION: Nimesulide has preferential selectivity for COX-2 over COX-1 in vivo at full therapeutic doses and induces less gastrointestinal damage than that seen with naproxen in the short term.     

Cyclooxygenase-2 expression is induced during human megakaryopoiesis and characterizes newly formed platelets

Cyclooxygenase (COX)-1 or -2 and prostaglandin (PG) synthases catalyze the formation of various PGs and thromboxane (TX) A(2). We have investigated the expression and activity of COX-1 and -2 during human megakaryocytopoiesis. We analyzed megakaryocytes from bone marrow biopsies and derived from thrombopoietin-treated CD34(+) hemopoietic progenitor cells in culture. Platelets were obtained from healthy donors and patients with high platelet regeneration because of immune thrombocytopenia or peripheral blood stem cell transplantation. By immunocytochemistry, COX-1 was observed in CD34(+) cells and in megakaryocytes at each stage of maturation, whereas COX-2 was induced after 6 days of culture, and remained detectable in mature megakaryocytes. CD34(+) cells synthesized more PGE(2) than TXB(2) (214 +/- 50 vs. 30 +/- 10 pg/10(6) cells), whereas the reverse was true in mature megakaryocytes (TXB(2) 8,440 +/- 2,500 vs. PGE(2) 906 +/- 161 pg/10(6) cells). By immunostaining, COX-2 was observed in <10% of circulating platelets from healthy controls, whereas up to 60% of COX-2-positive platelets were found in patients. A selective COX-2 inhibitor reduced platelet production of both PGE(2) and TXB(2) to a significantly greater extent in patients than in healthy subjects. Finally, we found that COX-2 and the inducible PGE-synthase were coexpressed in mature megakaryocytes and in platelets. We conclude that both COX-isoforms contribute to prostanoid formation during human megakaryocytopoiesis and that COX-2-derived PGE(2) and TXA(2) may play an unrecognized role in inflammatory and hemostatic responses in clinical syndromes associated with high platelet turnover.     

Overestimation of platelet aspirin resistance detection by thrombelastograph platelet mapping and validation by conventional aggregometry using arachidonic acid stimulation.

OBJECTIVES: This study sought to determine the prevalence of platelet aspirin resistance using methods that directly indicate the degree of platelet cyclooxygenase inhibition. BACKGROUND: Aspirin resistance in platelets may be overestimated by nonspecific laboratory measurements that do not isolate cyclooxygenase activity. METHODS: Arachidonic acid (AA)-induced light-transmittance platelet aggregation (LTA) and thrombelastography (TEG) platelet mapping were performed on the blood of healthy subjects (n = 6) before and 24 h after receiving 325 mg aspirin, and on 223 patients reporting compliance with long-term daily aspirin treatment (n = 203 undergoing percutaneous intervention [PCI] and n = 20 with a history of stent thrombosis). Aspirin resistance was defined as >20% aggregation by LTA or >50% aggregation by TEG. RESULTS: In healthy subjects, AA-induced aggregation by LTA was 82 +/- 10% before and 2 +/- 1% at 24 h after aspirin (p < 0.001), and aggregation by TEG was 86 +/- 14% before and 5 +/- 7% at 24 h after aspirin (p < 0.001). In compliant patients, AA-induced aggregation by LTA was 3 +/- 2% before PCI and 3 +/- 2% after PCI (p = NS), and aggregation by TEG was 5 +/- 9% before PCI and 6 +/- 14% after PCI (p = NS). Seven PCI patients were noncompliant, and all were aspirin sensitive after in-hospital aspirin treatment. Among 223 patients, only one patient ( approximately 0.4%) was resistant to aspirin treatment. CONCLUSIONS: Platelet aspirin resistance assessed by methods that directly indicate inhibition of cyclooxygenase is rare in compliant patients with coronary artery disease.     

Once- versus twice-daily aspirin treatment in patients with essential thrombocytosis

Insufficient platelet inhibition has been reported in up to 40% of aspirin-treated patients, including patients with essential thrombocytosis. To maintain sufficient platelet inhibition, a shorter dosing interval with aspirin has been suggested. We aimed to investigate the antiplatelet effect of low-dose aspirin given twice-daily compared to standard once-daily dosing in patients with essential thrombocytosis. We included 22 patients, who were treated for 7 days with standard once-daily aspirin (75 mg once-daily) followed by 7 days treatment of twice-daily aspirin (37.5 mg twice-daily). The two regimens were separated by 14 days aspirin washout. Blood samples were obtained 1h and 24h/12h after the last pill intake in each regimen. The effect of aspirin was evaluated by: (1) platelet aggregation measured by whole blood impedance aggregometry (Multiplate® Analyser) using arachidonic acid (ASPItest 0.5 mM) as agonist and (2) serum thromboxane B₂ levels determined using an enzyme-linked immunosorbent assay. The difference in platelet aggregation from 1h to the end of the dosing interval (24h/12h) was used to compare the two regimens. We demonstrated a significantly smaller difference in platelet aggregation in the twice-daily regimen compared to the once-daily: mean of difference = 228 AU*min (95% confidence interval (CI): 92–363, p < 0.01). In addition, a significantly smaller difference in thromboxane B₂ was demonstrated in the twice-daily regimen compared to the once-daily regimen: mean of difference = 16.3 ng/mL (95% CI: 9.9–22.7, p < 0.01). In conclusion, twice-daily dosing with low-dose aspirin provides a more consistent platelet inhibition compared with standard once-daily dosing in patients with essential thrombocytosis.     

De novo synthesis of cyclooxygenase-1 counteracts the suppression of platelet thromboxane biosynthesis by aspirin

Aspirin affords cardioprotection through the acetylation of serine529 in human cyclooxygenase-1 (COX-1) of anucleated platelets, inducing a permanent defect in thromboxane A2 (TXA2)-dependent platelet function. However, heterogeneity of COX-1 suppression by aspirin has been detected in cardiovascular disease and may contribute to failure to prevent clinical events. The recent recognized capacity of platelets to make proteins de novo paves the way to identify new mechanisms involved in the variable response to aspirin. We found that in washed human platelets, the complete suppression of TXA2 biosynthesis by aspirin, in vitro, recovered in response to thrombin and fibrinogen in a time-dependent fashion (at 0.5 and 24 hours, TXB2 averaged 0.1+/-0.03 and 3+/-0.8 ng/mL; in the presence of arachidonic acid [10 micromol/L], it was 2+/-0.7 and 25+/-7 ng/mL, respectively), and it was blocked by translational inhibitors, by rapamycin, and by inhibitors of phosphatidylinositol 3-kinase. The results that COX-1 mRNA was readily detected in resting platelets and that [35S]-methionine was incorporated into COX-1 protein after stimulation strongly support the occurrence of de novo COX-1 synthesis in platelets. This process may interfere with the complete and persistent suppression of TXA2 biosynthesis by aspirin necessary for cardioprotection.     

Effects of celecoxib and naproxen on renal function in nonazotemic patients with cirrhosis and ascites

Nonselective inhibition of cyclooxygenase (COX) by nonsteroidal anti-inflammatory drugs frequently induces renal failure in decompensated cirrhosis. Studies in experimental cirrhosis suggest that selective inhibitors of the inducible isoform COX-2 do not adversely affect renal function. However, very limited information is available on the effects of these compounds on renal function in human cirrhosis. This investigation consists of a double-blind, randomized, placebo-controlled trial aimed at comparing the effects of the selective COX-2 inhibitor celecoxib (200 mg every 12 hours for a total of 5 doses) on platelet and renal function and the renal response to furosemide (40 mg intravenously) with those of naproxen (500 mg every 12 hours for a total of 5 doses) and placebo in 28 patients with cirrhosis and ascites. A significant reduction (P < .05) in glomerular filtration rate (113 +/- 27 to 84 +/- 22 mL/min), renal plasma flow (592 +/- 158 to 429 +/- 106 mL/min) and urinary prostaglandin E(2) excretion (3430 +/- 430 to 2068 +/- 549 pg/min) and suppression of the diuretic (urine volume: 561 +/- 128 to 414 +/- 107 mL/h) and natriuretic (urine sodium: 53 +/- 13 to 34 +/- 10 mEq/h) responses to furosemide were observed in the group of patients treated with naproxen but not in the other two groups. Naproxen, but not celecoxib or placebo, significantly inhibited platelet aggregation (72% +/- 8% to 47% +/- 8%, P < .05) and thromboxane B(2) production (41 +/- 12 to 14 +/- 5 pg/mL, P < .05). In conclusion, our results indicate that short-term administration of celecoxib does not impair platelet and renal function and the response to diuretics in decompensated cirrhosis. Further studies are needed to evaluate the long-term safety of this drug in cirrhosis.     

Influence of aspirin on human megakaryocyte prostaglandin synthesis

Abstract: To evaluate whether currently popular aspirin regimens have an effect on the prostaglandin synthesis in human megakaryocytes we measured thromboxane B2 (TXB2) synthesis in response to thrombin stimulation in human megakaryocytes ex vivo. Human megakaryocytes were purified by Counterflow Centrifugal Elutriation from bone marrow punctures, taken from volunteers before and 2 hours after ingestion of one dose of 500 mg (n = 4), 80 mg (n = 4) or 40 mg (n = 2) aspirin. Subsequently, megakaryocytes were purified before and 12 h after ingestion of 80 mg (n = 3) aspirin twice daily for 1 week and 12 h after 500 mg (n = 3) aspirin. On average, 140 ± 102 × 10³ (mean ± 1 SD) megakaryocytes were recovered. We found that aspirin inhibits megakaryocyte cyclooxygenase in a dose-dependent manner. Two hours after 500 mg of aspirin, TXB2 synthesis in megakaryocytes was inhibited by 96.8 ±2%, whereas one dose of 80 and 40 mg aspirin showed an inhibition of 79.4 ± 13.7% and 80 ± 6.2% respectively. However, the inhibition of TXB2 synthesis seems not to be long-lasting since, 12 h after the ingestion of aspirin, an increase of megakaryocyte TXB2 production could be observed which reached significance after the 500 mg aspirin dosage (p < 0.048). We conclude that human megakaryocyte cyclooxygenase is sensitive to aspirin inhibition and that low doses of aspirin (40 and 80 mg) enter the systemic circulation and are able to inhibit megakaryocyte cyclooxygenase, but this inhibition is incomplete and megakaryocyte cyclooxygenase seems to recover within 12 h after ingestion of aspirin.     

阿司匹林或氯吡格雷作用下血小板不同活化途径的反应特点

目的探讨阿司匹林和氯吡格雷抑制血小板环氧酶(COX)-1途径和P2Y12受体活化的特点及两途径之间的交互关系。方法 20例健康男性志愿者按随机数余数分组法平均分为两组,分别服用阿司匹林(100 mg/d)和氯吡格雷(75 mg/d)连续7 d。并在服药和停药后第1、3、5、7天分别应用血栓弹力图、血小板功能分析仪和流式细胞仪观察血小板的抑制情况。结果服药后,氯吡格雷组的胶原-肾上腺素激活的闭孔时间(CEPI-CT)和胶原-腺苷二磷酸闭孔时间(CADP-CT)的变化差异均有统计学意义(F=27.2,P<0.01,F=25.3,P<0.05),阿司匹林组CEPI-CT迅速增至检测上限300 s,差异有统计学意义(F=36.7,P<0.01),而CADP-CT变化差异无统计学意义(F=2.12,P=0.13)。服药后阿司匹林组血小板COX-1途径抑制率增高至91.7%±0.9%(F=35.1,P<0.01),氯吡格雷组P2Y12受体抑制率由47.8%±3.1%增高至81.3%±3.8%(F=24.8,P<0.01),COX-1未受到有效抑制(F=1.85,P=0.11)。服药后两组CD62p表达降低50%(氯吡格雷组:F=28.7,P<0.01;阿司匹林组:F=20.7,P=0.02)。结论花生四烯酸诱导的COX-1途径活化与P2Y12受体活化可能存在交互作用,床旁即时检验有助于快速了解血小板功能状态,为监测有效的联合用药提供依据。     

Pharmacology and gastrointestinal safety of lumiracoxib, a novel cyclooxygenase-2 selective inhibitor: An integrated study.

BACKGROUND AND AIMS: Lumiracoxib is a structurally novel, acidic selective inhibitor of cyclooxygenase (COX)-2. We coordinated existing methodologies in a single study to evaluate potency, selectivity, and effect on the human gastrointestinal tract. METHODS: Twenty four healthy subjects (aged 18-45 years, 12 female) received high dose lumiracoxib (800 mg every day), standard dose naproxen (500 mg twice a day), or placebo for 8 days in a double-blind randomized crossover study. At the start and end of each dosing period, COX-2 selectivity was assessed by ex vivo serum thromboxane B(2) (COX-1) and lipopolysaccharide stimulated prostaglandin (PG) E(2) (COX-2), mucosal injury by endoscopy, and small and large bowel permeability by 0- to 5-hour and 5- to 24-hour (51)Cr-EDTA absorption. Plasma lumiracoxib was measured 2 hours after dosing on day 8 and vortex-stimulated ex vivo gastric mucosal PGE(2) synthesis at the end of each treatment period by enzyme immunoassay. RESULTS: Lumiracoxib was well absorbed and demonstrated similar potency to naproxen as a COX-2 inhibitor (77% and 66% inhibition, respectively, vs. placebo), but it differed in being more selective (24% and 97% inhibition of thromboxane B(2) vs. placebo). Gastric PGE(2) was reduced by 69% by naproxen (P < 0.001 vs. placebo) and 29% by lumiracoxib (P < 0.01 vs. placebo and naproxen). No subjects developed gastroduodenal erosions on lumiracoxib (vs. 75% on naproxen and 12.5% on placebo). (51)Cr-EDTA absorption increased significantly with naproxen but not lumiracoxib. CONCLUSIONS: Lumiracoxib is a potent selective inhibitor of COX-2 that causes little or no endoscopically detected stomach or duodenal injury or changes in bowel permeability.     

Preoperative aspirin administration improves oxygenation in patients undergoing coronary artery bypass grafting

OBJECTIVES: Release of thromboxane (Tx) A(2) by platelets may be one of multiple factors that are responsible for lung injury after cardiopulmonary bypass, leading to pulmonary vasoconstriction and impaired oxygenation. In experimental models, the inhibition of Tx receptor or its production improved lung function. The use of aspirin, which is used widely in the treatment of ischemic heart disease because of its antiplatelet activity, is usually discontinued a week before the patient undergoes the operation to restore normal platelet hemostatic function. The purpose of this study was to determine the relationship between the time of cessation of aspirin before coronary artery bypass surgery, and postoperative oxygenation and bleeding. DESIGN: A prospective clinical study comparing the effect of aspirin on postoperative oxygenation in patients who had been treated or had not been treated with aspirin. SETTING: Tx levels in the pericardial fluid, oxygenation, and bleeding were compared between the two groups. PATIENTS: Thirty-two patients with coronary artery disease who were undergoing coronary artery bypass grafting. Fourteen of these patients received aspirin until the day of the operation, whereas 18 patients stopped receiving aspirin at least 1 week before undergoing the operation.Main results: Mean (+/- SD) Tx levels in the pericardial fluid were significantly lower in the aspirin group (117 +/- 47 pg/mL) compared to those in the control group (1,306 +/- 2,048 pg/mL; p = 0.02). The duration of ventilation after the operation was significantly longer in the nonaspirin group (9.6 +/- 5.6 h vs 3.8 +/- 1.4 h, respectively; p = 0.0004). Po(2) reached a higher level while patients breathed 100% O(2) in the aspirin group (235 +/- 54 mm Hg vs 176 +/- 27 mm Hg, respectively; p = 0.001). The mean amount of bleeding during the first 24 h after surgery was increased in the aspirin group (710 +/- 202 mL) compared with the nonaspirin group (539 +/- 143 mL; p = 0.01), but these patients did not require more transfusions. CONCLUSIONS: The administration of aspirin until the operation may improve oxygenation with only a slight increase in bleeding. This improvement is probably mediated by antiplatelet activity and Tx inhibition by aspirin.     

Incomplete Inhibition of Platelet Secretion by Low-dose Aspirin

This study determines the effects of low-dose oral acetylsalicylic acid (Aspirin) on platelet aggregation and dense granule secretion in relation to inhibition of thromboxane formation. In addition, possible modifications of inhibition of platelet function by iloprost and linsidomine (SIN-1) were also studied. Aspirin (40 mg/day) was administered to 15 healthy male non-smoking volunteers for 8 consecutive days. Platelet function was measured ex vivo before and 12 h after the last drug intake. At the same times urinary excretion of thromboxane B(2) (TXB(2)) and 6-oxo-PGF(1α) were determined. Asirin treatment resulted in a significant (P < 0.01), by 65%, reduction of urinary TX B(2) excretion, whereas urinary excretion of 6-oxo-PGF(1α) remained unchanged, demonstrating the expected selectivity of low-dose aspirin for the platelet cyclooxygenase. There was also a nearly complete (93-95%) inhibition of collagen (0.3-5 μg/ml)-induced thromboxane formation in platelets. However, collagen-induced ATP-and 5-HT secretion was much less inhibited by aspirin and was reduced by only 20% at 5 μg/ml collagen. Similar results were obtained with ADP while thrombin (> 1.2 IU/ml)-induced 5-HT secretion was not antagonized at all. Also aspirin did not affect the inhibition of platelet function by iloprost and linsidomine (SIN-1). It is concluded that stimulation of platelet secretion by stronger stimuli, such as collagen or thrombin, is largely cyclooxygenase-independent and may not be detected by measuring serum thromboxane levels. This may be relevant for clinical situations with shear-stress-induced platelet activation, for example at carotis stenoses or other types of atherosclerotic plaques.     

Antiaggregative aspirin dosage at the affected vessel wall

The present study, using patients with Takayasu's disease (pulseless disease), characterized by segmentally affected arterial lesions and stenotic conditions with a nonspecific inflammatory morbid condition, was designed to assess whether or not a low dose of aspirin can practically exert its preventive effect against the aggregation of platelets that have just passed along a rough-surfaced arterial wall. Twenty Japanese women with Takayasu's disease were selected under the following criteria: A unilateral upper extremity was angiographically confirmed to be affected with the disease, while the contralateral limb was almost normal. Systolic blood pressure on the affected side was almost half that on the nonaffected side. The patients showed neither a positive CRP nor an accentuated ESR. In these patients, mean plasma levels of TXB2 and 3 microM ADP-induced platelet aggregation in blood obtained from the affected side were 156.5 +/- 17.7 pg/ml, and 59.5 +/- 6.0%, respectively, which were significantly high as compared with 104.5 +/- 17.6 and 41.7 +/- 8.8%, respectively, in samples from the nonaffected side. Forty and eighty mg of aspirin per day administered to two randomly composed groups, respectively, showed an improvement in platelet aggregability and TXB2 levels on the nonaffected side. In the affected limbs, though 80 mg/day led to significant decreases in TXB2 levels (108.0 +/- 7.8 pg/ml, p less than 0.05) and platelet aggregability (21.3 +/- 7.6%), the 40-mg regimen showed no significant reductions (134.6 +/- 9.4 pg/ml, 35.6 +/- 17.1%). Plasma levels of 6-keto PGF1 alpha revealed no differences between 40- and 80-mg regimens, or between before and after treatment.(ABSTRACT TRUNCATED AT 250 WORDS)     

Clinical pharmacology of platelet cyclooxygenase inhibition

Nonsteroidal anti-inflammatory drugs and sulfinpyrazone compete dose-dependently with arachidonate for binding to platelet cyclooxygenase. Such a process closely follows systemic plasma drug concentrations and is reversible as a function of drug elimination. Peak inhibition and extent of its reversibility at 24 hr varies consistently with individual pharmacokinetic profile. Inhibition of platelet cyclooxygenase activity by these agents is associated with variable effects on prostaglandin (PG) synthesis in the gastric mucosa and the kidney. Aspirin acetylates platelet cyclooxygenase and permanently inhibits thromboxane (TX) A2 production in a dose-dependent fashion when single doses of 0.1 to 2.0 mg/kg are given. Acetylation of the enzyme by low-dose aspirin is cumulative on repeated dosing. The fractional dose of aspirin necessary to achieve a given level of acetylation by virtue of cumulative effects approximately equals the fractional daily platelet turnover. Serum TXB2 measurements obtained during long-term dosing with 0.11, 0.22, and 0.44 mg/kg aspirin in four healthy subjects could be fitted by a theoretical model assuming identical acetylation of platelet (irreversible) and megakaryocyte (reversible) cyclooxygenase. For a given dose within this range, both the rate at which cumulative acetylation occurs and its maximal extent largely depend upon the rate of platelet turnover. Continuous administration of low-dose aspirin (20 to 40 mg/day) has no statistically significant effect on urinary excretion of either 6-keto-PGF1 alpha or 2,3-dinor-6-keto-PGF1 alpha, i.e., indexes of renal and extrarenal PGI2 biosynthesis in vivo. Whether a selective sparing of extraplatelet cyclooxygenase activity by low-dose aspirin will result in increased antithrombotic efficacy, fewer toxic reactions, or both remains to be established in prospective clinical trials.