Lumiracoxib does not affect the ex vivo antiplatelet aggregation activity of low-dose aspirin in healthy subjects

This randomized, double-blind, placebo-controlled study evaluated the pharmacodynamic effects of concomitant low-dose aspirin and lumiracoxib in healthy subjects. Participants received lumiracoxib 400 mg once daily (n = 14) or placebo (n = 14) for 11 days, with concomitant low-dose aspirin (75 mg once daily) from days 5 to 11. Ex vivo pharmacodynamic assessments included assays of platelet aggregation and urinary thromboxane and prostacyclin metabolite profile. Arachidonic acid-stimulated platelet aggregation was reduced from 76.3% on day 4 to 4.8% on day 11 in the placebo group and from 75.8% on day 4 to 5.1% on day 11 in the lumiracoxib group. Collagen-induced platelet aggregation was reduced from 77.5% on day 4 to 52.8% on day 11 in the placebo group and from 79.5% on day 4 to 55.9% on day 11 in the lumiracoxib group. Urinary thromboxane and prostacyclin were unaffected by lumiracoxib. In conclusion, concomitant lumiracoxib did not interfere with the cyclooxygenase-1-mediated antiplatelet effects of low-dose aspirin.     

Celecoxib does not affect the antiplatelet activity of aspirin in healthy volunteers

Celecoxib is a novel cyclooxygenase-2-specific inhibitor for the management of acute pain, primary dysmenorrhea, and the signs and symptoms of arthritis. This double-blind, placebo-controlled study in 16 healthy volunteers evaluated whether celecoxib alters the effect of concomitant aspirin on platelet function. Volunteers received celecoxib (400 mg/day) or placebo for 4 days. On day 5, they also received a single 325 mg dose of aspirin with either 200 mg celecoxib or placebo. Thromboxane and platelet aggregation response to adenosine 5'-diphosphate (ADP), collagen, and arachidonic acid were measured before the first dose of celecoxib or placebo (baseline) and before dosing and 2 and 8 hours post dose on day 5. There was no significant difference in thromboxane inhibition between the two groups (percent inhibition: placebo 99.4%, celecoxib 99.0%; p = 0.555). There was also no significant difference in the effect of aspirin on platelet aggregation due to ADP, collagen, or arachidonic acid between the groups. Therefore, these data indicate that celecoxib does not alter the effects of aspirin on platelet function.     

Influence of nonsteroidal anti-inflammatory drugs on the antiplatelet effects of aspirin in rats

Low-dose aspirin acts by irreversibly acetylating internal cyclooxygenase-1 (COX-1) on platelets, thereby suppressing platelet aggregation. Because nonsteroidal anti-inflammatory drugs (NSAIDs) also inhibit COX-1, the antiplatelet effects of aspirin may be suppressed when it is co-administered with NSAIDs. In this study, the influences of ibuprofen, loxoprofen sodium and etodolac on the antiplatelet effects of aspirin were investigated in male Sprague-Dawley (SD) rats. Aspirin and/or NSAIDs were administered orally at single or multiple daily doses. Platelet aggregation (ADP and collagen were added as stimuli) and serum thromboxane B(2) (TXB(2)) concentrations were measured. The maximum inhibitions of aggregation in the aspirin before ibuprofen group were 41.0±7.8% for ADP and 38.7±5.4% for collagen at 6 h after administration; similar values were seen in the aspirin group; however, percent inhibitions in the aspirin before ibuprofen multiple administration group were lower than those in the aspirin group. Thus, the inhibitory effects of daily low-dose aspirin on platelets are competitively inhibited by the prolonged use of multiple daily doses of ibuprofen. In contrast, serum TXB(2) concentrations in all groups were lower than those in the control group (drug-free). This suggests that the relationship between the inhibition of platelet COX-1 and the suppression of platelet aggregation is nonlinear. When aspirin was administered with loxoprofen sodium, similar effects were observed; however, with etodolac, the antiplatelet effects in all groups were equal to those in the aspirin group. Accordingly, if co-administration with NSAIDs is necessary with low-dose aspirin, a selective COX-2 inhibitor, such as etodolac, should be used.     

Relationship of arachidonic acid concentration to cyclooxygenase-dependent human platelet aggregation

Inhibition of ex vivo arachidonic acid (AA)-induced aggregation is a biomarker for the isotype selectivity of cyclooxygenase (COX) inhibitors since platelets express COX-1 but not COX-2. At low concentrations, there is broad inter- and intrasubject variability in AA-induced aggregation of platelets ex vivo. This study defined a concentration that reliably induces aggregation without overcoming inhibition by therapeutic aspirin therapy (ASA, 81-mg) treatment. Logistic regression analysis of ex vivo aggregation, induced with increasing concentrations of AA in platelet-rich plasma (PRP), estimated that platelets from > or = 90% of subjects would aggregate at > or = 1.5 mM AA (95% confidence interval [CI], 1.1, 2.1). A concentration of 1.6 mM AA failed to aggregate platelets from 26 healthy volunteers, who had previously aggregated at this concentration, following six daily oral doses of 81 mg of ASA. These data demonstrate that 1.6 mM AA reproducibly induces platelet aggregation in PRP from healthy volunteers without overcoming the antiplatelet effect of daily low-dose aspirin therapy.     

Aspirin-induced gastric mucosal damage: prevention by enteric-coating and relation to prostaglandin synthesis.

1. Gastric damage induced by low-dose aspirin and the protective effect of enteric-coating was assessed in healthy volunteers in a double-blind placebo-controlled cross-over trial using Latin square design. Each was administered placebo, plain aspirin 300 mg daily, plain aspirin 600 mg four times daily, enteric-coated aspirin 300 mg daily, or enteric-coated aspirin 600 mg four times daily for 5 days. Gastric damage was assessed endoscopically, and gastric mucosal bleeding measured. 2. Aspirin 300 mg daily and 600 mg four times daily caused significant increases in gastric injury compared with placebo. Gastric mucosal bleeding was significantly more with the high dose, with a trend towards increased gastric erosions, compared with the low dose. 3. Enteric-coating of aspirin eliminated the injury caused by low dose aspirin and substantially reduced that caused by the higher dose. 4. All dosages and formulations caused similar inhibition of gastric mucosal prostaglandin E2 synthesis. 5. Serum thromboxane levels were suppressed equally with plain and enteric-coated aspirin. 6. In this short-term study in healthy volunteers, gastric toxicity from aspirin was largely topical, independent of inhibition of prostaglandin synthesis, and could be virtually eliminated by the use of an enteric-coated preparation.     

The effect of itazigrel and aspirin on the mucosa of the esophagus, stomach, and duodenum of normal subjects

The effects of aspirin, itazigrel (U-53,059; a new antiplatelet drug), and placebo on the mucosa of the esophagus, stomach, and duodenum were evaluated in this double-blind, randomized, placebo-controlled study. Six normal male subjects were included in each of five treatment groups: aspirin (325 mg each morning for five doses), aspirin (325 mg tid for 12 doses), itazigrel (25 mg each morning for five doses), itazigrel (50 mg tid for 12 doses), and placebo. Aspirin and itazigrel, at all doses investigated, significantly inhibited ex vivo, ionophore (A23187)-stimulated thromboxane B2 synthesis. Collagen-induced platelet aggregation was significantly inhibited on day 3 (P = .021) and day 5 (P = .002) in both aspirin and itazigrel groups as compared with placebo. Upper gastrointestinal endoscopy was performed before the first dose of drug (day 1) and two hours after the last dose (day 5) for each subject. A rating scale was used to score the amount of mucosal damage. The baseline (day 1) endoscopic scores revealed no significant differences between groups. On day 5, neither placebo nor itazigrel treatment groups showed any significant change compared with baseline. On day 5, both aspirin groups had significantly (P less than .001) more mucosal damage than the placebo group and either itazigrel group. It is concluded that in this relatively acute study, at doses that produce comparable inhibition of platelet aggregation and platelet cyclo-oxygenase, itazigrel was superior to aspirin in terms of toxicity to the upper gastrointestinal tract.     

Effects of d-003, a new substance purified from sugar cane wax, on platelet aggregation and plasma levels of arachidonic acid metabolites in healthy volunteers

D-003 is a mixture of very high molecular weight aliphatic acids purified from sugar cane wax showing cholesterol-lowering and antiplatelet effects proven in experimental and clinical studies. Experimental evidence indicates that inhibition of platelet aggregation induced by D-003 is associated with a reduction of thromboxane B2 (TxB2) and an increase of prostacyclin (Pgl2) serum levels. This double-blinded, randomized, placebo-controlled study was undertaken to investigate whether D-003 (20 mg/day) modifies serum levels of TxB2 and Pgl2 and inhibits platelet aggregation in human healthy volunteers. Thirty-one subjects were randomized to placebo or D-003 at 20 mg/day for 14 days. Serum levels of TxB2 and Pgl2 and platelet aggregation to arachidonic acid (AA) (1.75 mM) and collagen (1 microg/ml) were assessed. D-003 (20 mg/day) significantly reduced (p < 0.001) TxB2by 36.4% and increased Pgl2 serum levels by 31% compared with baseline, and these changes were different from placebo. As expected, D-003 significantly inhibited (p < 0.001) platelet aggregation to AA (81.9-65.6%) and to collagen (75.3-62.3%). No subject withdrew from the study. No drug-related disturbances were observed. We conclude that D-003 at 20 mg/day for 14 days significantly inhibited platelet aggregation to AA and collagen and reduced TxB2 and increased Pgl2 serum levels. These results are consistent with those observed in experimental models, indicating that the antiplatelet effect of D-003 is associated with the observed changes on the levels of AA metabolites. Further studies, however, should explore the mechanism involved in this action in greater depth.     

Platelet thromboxane A2/prostaglandin H2 receptors in human volunteers on low doses of aspirin

Administration of aspirin (81 mg/day for 2-3 weeks) in nine healthy volunteers (out of an initial ten subjects, only nine qualified) resulted in a greater than 95% decrease of thromboxane B2 production by thrombin-stimulated platelets. At the same time, ligand binding studies with a thromboxane A2 antagonist, 125I-PTA-OH, measurements of shape change, and aggregation of platelets stimulated with U46619, a prostaglandin H2 analogue, indicated that administration of aspirin to normal human subjects does not result in the up-regulation of platelet thromboxane A2/prostaglandin H2 receptors.     

Reduced Blood Platelet Sensitivity to Aspirin in Coronary Artery Disease: Are Dyslipidaemia and Inflammatory States Possible Factors Predisposing to Sub‐optimal Platelet Response to Aspirin?

The study was designed to assess blood platelet sensitivity to acetylsalicylic acid and its associations with dyslipidaemia and inflammation in coronary artery disease patients. Platelet non-responsiveness to aspirin is associated with an increased risk of serious cardiovascular events. Several environmental and hereditary factors are reportedly involved in sub-optimal acetylsalicylic acid response. Forty-five coronary artery disease patients and 45 non-coronary artery disease controls received acetylsalicylic acid at a daily dose of 75-150 mg. Controls were examined twice: on the day of entering the study and 10 days later. Urinary 11-dehydrothromboxane B2 was assessed as the marker of platelet thromboxane generation. Aggregation was studied in platelet-rich plasma using turbidimetric aggregometry with collagen and arachidonic acid. Fifty to seventy percent of coronary artery disease patients showed an extent of collagen-induced aggregation above the upper quartile of the reference range compared with 8-15% in controls (P<0.003). For arachidonic acid-activated aggregation these proportions were 45-50% in coronary artery disease versus 7% in controls (P<0.007). In coronary artery disease patients, the acetylsalicylic acid-mediated platelet inhibition positively correlated with increased triglycerides (in arachidonic acid-stimulated platelets, r=0.30, P=0.0018), total cholesterol (r=0.33, P<0.0001 in coll and arachidonic acid-activated platelets) and elevated serum C-reactive protein (CRP) (r=0.27, P=0.0024). In coronary artery disease patients urine 11-dehydrothromboxane B2 concentrations were significantly increased compared to controls after 10 day acetylsalicylic acid intake (563; 313-728 pg/mg creatinine versus 321; 246-488 pg/mg creatinine, P=0.04). The incidence of suboptimal acetylsalicylic acid response incidence was more common in patients with coronary artery disease. Acetylsalicylic acid inhibition of blood platelet reactivity and thromboxane generation was less effective in these patients. Dyslipidaemia and chronic inflammatory states may promote suboptimal acetylsalicylic acid response in coronary artery disease patients.     

The inhibition of cyclo-oxygenase of rabbit platelets by aspirin is prevented by salicylic acid and by phenanthrolines.

Salicylic acid, 1,10- and 1,7-phenanthroline prevented inhibition by aspirin of platelet aggregation and of generation of thromboxane A2 due to arachidonic acid, to the ionophore A21387, to thrombin and to collagen. Dithiothreitol, another drug which prevents aggregation and formation of thromboxane A2, but only reversibly, failed to interfere with the inhibition by aspirin. Irreversible inhibition by indomethacin and by the substrate analogue 5,8,11,14-tetraynoic acid was also unaffected by salicylic acid or by 1,10-phenanthroline, which thus probably exert a specific interaction with the aspirin-binding site. Inactivation of platelet cyclo-oxygenase with arachidonic acid led to inhibition of the formation of thromboxane A2 and of aggregation due to arachidonic acid itself and to collagen, but barely affected aggregation by thrombin, even though generation of thromboxane A2 was blocked. Use of salicylic acid and of reversible inhibitors of cyclo-oxygenase may help to unravel the mechanism of inhibition due to other agents.     

Pharmacokinetic and pharmacodynamic differences between two low dosages of aspirin may affect therapeutic outcomes

BACKGROUND: Meta-analyses of the prevention of major vascular events by aspirin suggest therapeutic equivalence of all dosages. However, the optimal dosage still remains problematic, and a recent trial found aspirin 160 mg/day to be more effective than 80 mg/day for secondary prevention of ischaemic stroke. OBJECTIVE: To evaluate two low dosages of aspirin in terms of pharmacokinetics and pharmacodynamics (inhibition of platelet thromboxane generation and urinary excretion of thromboxane and prostacyclin metabolites). DESIGN AND PARTICIPANTS: A randomised cross-over study was performed in 16 healthy volunteers (9 women and 7 men, 33.8 +/- 5.1 years old) given enteric-coated aspirin 80 or 160 mg/day for 7 days. METHODS: Plasma concentrations of salicylate and aspirin were measured by high-performance liquid chromatography (HPLC) after both the first and the last dose (days 1 and 7). The usual pharmacokinetic parameters were then derived. Serum thromboxane B2 (TxB2) was measured by radioimmunoassay. The urinary excretion of 11-dehydro-TxB2 and 2,3-dinor-6-keto-prostaglandin F1alpha were measured on 8-hour urine samples by immunoassay after extraction and HPLC separation, both before and after 7 days of drug administration. RESULTS: With the 160 mg dosage, but not with the 80 mg dosage, higher concentrations of aspirin were found at day 7 compared with day 1. For aspirin 80 mg/day, 24-hour area under the concentration-time curve (AUC24) was similar on days 1 and 7 (569 +/- 339 vs 605 +/- 377 microg. h/L), but increased from 904 +/- 356 microg. h/L on day 1 to 1355 +/- 883 microg. h/L on day 7 with the higher dosage. Similarly, the AUC24 for salicylate was similar on days 1 and 7 with the lower dosage, but significantly increased from day 1 to day 7 after the higher dosage. This paralleled inhibition of serum TxB2 levels (99% vs 95% average inhibition by 160 and 80 mg/day) and of urinary excretion of thromboxane metabolite (77% vs 61% average inhibition by 160 and 80 mg/day), without altering the excretion of prostacyclin metabolite.Conclusions: Inhibition of serum TxB2 generation and of thromboxane metabolite urinary excretion by the lower dosage of aspirin, although substantial, still appeared incomplete. The small but significant further increase of serum TxB2 inhibition by the higher dosage was accompanied by an even greater inhibition of urinary excretion. We suggest that in some instances this difference would translate into a greater clinical benefit with the higher aspirin dosage. Our findings may also contribute to better definition of the recent concept of 'aspirin resistance'.     

Effect of a single oral dose of aspirin on the platelet aggregation response to arachidonic acid.

1 The platelet aggregation response to arachidonic acid ex vivo was measured in six volunteers daily before and for 10 days after a single oral dose of 600 mg aspirin. 2 Arachidonic acid induced aggregation of platelets from all subjects before aspirin and aggregation occurred after an interval which varied inversely with the concentration of arachidonic acid. No aggregation occurred for 4 days after aspirin; a reduced response, compared with pre-aspirin values, was obtained on the 5th, 6th and 8th day. The values on days 7, 9 and 10 were not consistently different from the pre-aspirin values. In 6 subjects 24 h after aspirin ingestion the addition of 10--25% v/v normal platelets restored the aggregation response. 3 It is concluded that aspirin has an effect on the platelet precursors in the marrow in addition to its effect on circulating platelets.     

Aspirin dosage and thromboxane synthesis in patients with vascular disease

STUDY OBJECTIVE: To determine whether urinary 11-dehydrothromboxane B2 (d-TXB2) is a marker of aspirin resistance and define the relationship between aspirin dosage and concentrations of this thromboxane metabolite. DESIGN: Randomized, crossover study. SETTING: Two outpatient clinical centers. PATIENTS: Forty-eight patients (mean age 70 yrs) with vascular disease (52% clinical coronary artery disease, 29% cerebrovascular disease, 46% atrial fibrillation). INTERVENTION: Levels of serum thromboxane B2 and d-TXB2 were measured after patients were treated initially with aspirin 325 mg/day for 4 weeks, then again after random assignment to receive aspirin 81, 325, or 1300 mg/day for 4 weeks, and then again after resumption of 325 mg/day for 4 weeks. MEASUREMENTS AND MAIN RESULTS: During treatment with aspirin 325 mg/day, the mean +/- SD serum thromboxane B2 level was 0.9 +/- 1.2 ng/ml and median (interquartile range) was 0.4 (0.2-0.9) ng/ml. Mean urinary d-TXB2 was 16 +/- 7.9 ng/mmol creatinine, with a median of 15 (9.9-23) ng/mmol creatinine with aspirin 325 mg/day. After 4 weeks of aspirin 81 mg/day, levels of serum thromboxane B2 (p<0.01) and urinary d-TXB2 (p=0.04) were both significantly higher compared with aspirin 325 mg/day; for urinary d-TXB2, the median increase was 3.0 ng/mmol creatinine. After 4 weeks of treatment with aspirin 1300 mg/day, levels of serum thromboxane B2 (p<0.01) and urinary d-TXB2 (p<0.01) were both significantly lower compared with aspirin 325 mg/day; the median decrease in urinary d-TXB2 was 4.4 ng/mmol creatinine. CONCLUSION: Different aspirin dosages significantly affect serum and urinary markers of thromboxane synthesis.     

Effects of very low dose and enteric-coated acetylsalicylic acid on prostacyclin and thromboxane formation and on bleeding time in healthy subjects

Objective: Low dose acetylsalicylic acid (ASA) is widely used as an anti-aggregatory agent in the primary and secondary prevention of cardiovascular diseases. In an effort to spare prostacyclin formation and to reduce gastrointestinal side-effects, both very low doses and enteric-coated formulations of ASA have been introduced. However, it still remains unclear whether these different formulations and dosages are equally effective with respect to inhibition of platelet aggregation and thromboxane A₂ (TXA₂) formation. Methods: In a randomized study, we therefore investigated the effects of 100?mg ASA plain (p), 100?mg ASA enteric-coated (ec) and 40?mg ASA (p) to 36 healthy male subjects given for 7 days on platelet aggregation and endogenous prostanoid formation rates. Platelet aggregation and platelet TXB₂ release in platelet rich plasma (PRP) and serum TXB₂ and 6-keto-PGF_1α levels were determined at baseline and after 7 days of each medication. The urinary metabolites of TXA₂ (2,3-dinor-TXB₂) and prostacyclin (2,3-dinor-6-keto-PGF_1α) were measured by gas chromatography/tandem mass spectrometry in 24-h-urines at baseline and on day 7 of each medication. Results: Collagen-induced platelet aggregation was 73.1?±?1.6% of maximal aggregation at baseline. It was inhibited by 68.9%, 58.6% and 24.0% by ASA 100?mg plain, 100?mg enteric-coated, and 40?mg plain on day 7, respectively. Platelet TXB₂ release was 11?592.0?± 367.5?pg?·?ml^?1 PRP. It was inhibited by 90.1%, 86.5%, and 55.2% by ASA 100?mg plain, 100?mg enteric-coated, and 40?mg plain, respectively. Serum TXB₂ was almost completely reduced on day?7 by 100?mg ASA, but not by 40?mg ASA; serum 6-keto-PGF_1α was slightly, but significantly reduced in all three groups. Urinary 2,3-dinor-TXB₂ excretion was 196.0?±?41.5?pg?·?mg^?1 creatinine at baseline. It was reduced by 80.3% and 79.1% by ASA 100?mg plain and enteric-coated, respectively (each P?<?0.05 versus baseline), but only by 55.4% by ASA 40?mg plain (P?<?0.05 versus both formulations of ASA 100?mg). Conclusions: Our present data show that the plain and enteric-coated formulations of 100?mg ASA are equally effective in inhibiting platelet aggregation, platelet thromboxane production, and urinary 2,3-dinor-TXB₂ excretion rates. In contrast, a very low dose of 40?mg ASA was significantly less effective in inhibiting these indices of platelet activation in healthy human subjects. ASA enteric-coated 100?mg may be a useful alternative to 100?mg ASA (p) in patients with gastrointestinal side-effects, whereas 40?mg ASA (p) may be too low to inhibit sufficiently platelet activity in patients with cardiovascular diseases in whom platelet activity is increased.     

Single oral dose study of two isosorbide-based aspirin prodrugs in the dog

The objective of this study was to compare two aspirin prodrugs, isosorbide diaspirinate (ISDA) and a nitroaspirin (ISMNA), with aspirin in terms of effects on dog platelet function after administration of a single oral dose. Groups of six dogs were administered ISDA (2mg kg(-1)), ISMNA (4 mg kg(-1)) or aspirin (2mg kg(-1)). Blood was sampled at 1, 2, 4, 8, 12 and 24 h post-dosing and evaluated for capacity to generate post-clotting thromboxane (TX)B2. The aggregation response to arachidonic acid (AA) (100 microM), ADP (30 microM) or collagen (10 microg mL(-1)) was estimated at each time-point using the whole blood impedance method. Plasma ISMN following oral administration of ISMNA was also measured and compared with plasma ISMN following administration of a physical mixture of ISMN and aspirin. ISDA administration (2 mg kg(-1)) was associated with a significant reduction (P < 0.05) in serum TXB2 at 12 and 24 h (>90%) post-dosing and persistent inhibition of AA-induced platelet aggregation. ISDA administration caused a more marked depression of post-clotting TXB2 levels than aspirin in this study, although its ability to inhibit platelet aggregation was less consistent than that of aspirin. The nitroaspirin ISMNA was least effective at inhibiting platelet aggregation response or TXB2 production. The ISMN AUC(0-24 h) for the ISMNA-treated dogs was 77% of that for the physical mix-treated dogs and the tmax was delayed. This study indicates that the two aspirin esters cause aspirin-like effects on platelet function, probably through aspirin release, when administered orally to dogs.     

Comparison of antiplatelet activity of microencapsulated aspirin 162.5 mg (Caspac XL), with enteric coated aspirin 75 mg and 150 mg in patients with atherosclerosis

AIMS: A new formulation, low dose microencapsulated aspirin, permits slow absorption of aspirin and presystemic acetylation of platelet cyclo-oxygenase within the portal circulation, potentially avoiding deleterious effects on gastric and systemic prostaglandin synthesis. The objective of this study was to determine whether the administration of microencapsulated aspirin was as effective as enteric coated (EC) aspirin as an inhibitor of platelet function in patients with atherosclerosis. METHODS: One hundred and four patients were enrolled and randomised after a run in period of at least 14 days on aspirin EC 75 mg (day 0), to receive either microencapsulated aspirin 162.5 mg (n=34), aspirin EC 150 mg (n=36) or continue on aspirin EC 75 mg (n=34) for 28 days. Serum thromboxane B2 and collagen-induced platelet aggregation and release of 5-hydroxytryptamine (EC50 values) were measured on days 0 and 28. Aggregation/release EC50s were then repeated in the presence of a large dose of aspirin added in vitro to determine the EC50 at the maximum level of platelet inhibition. RESULTS: Median thromboxane B2 levels were low after 14 days run-in therapy with aspirin EC 75 mg, but significant further reductions were seen on day 28 in patients randomised to microencapsulated aspirin 162.5 mg (P=0.0368) and aspirin EC 150 mg (P=0.0004) compared with those remaining on aspirin EC 75 mg. Median EC50 s on day 28 showed small but significant increases from baseline (day 0) in aggregation in patients randomised to microencapsulated aspirin 162.5 mg (0.62-0.85, P=0.0482) and in both aggregation and release in patients randomised to aspirin EC 150 mg (0.95-1.20, P=0.0002, 8.4-11.7, P<0. 0001, respectively) signifying enhanced antiplatelet activity. No changes were seen in patients continuing on aspirin EC 75 mg. Results following addition of high dose aspirin in vitro suggest that mechanisms other than thromboxane synthesis may be operative in the long term effects of microencapsulated aspirin 162.5 mg and aspirin EC 150 mg over aspirin EC 75 mg. CONCLUSIONS: The results show good inhibition of thromboxane B2 synthesis and subsequent platelet activity by all preparations of aspirin, although both microencapsulated aspirin 162.5 mg and aspirin EC 150 mg are slightly more effective than aspirin EC 75 mg. A randomised trial is now required to determine whether microencapsulated aspirin is associated with fewer gastric side-effects.     

Protection of human gastric mucosa against aspirin—enteric coating or dose reduction?

BACKGROUND: Aspirin is widely used for cardiovascular prophylaxis. AIM: To compare the effectiveness of two widely-used strategies-dose reduction and enteric coating-for the minimization of gastric mucosal injury or toxicity. METHODS: Twelve healthy volunteers were studied. On four separate occasions each received, under blinded conditions, five daily doses of plain aspirin 300 mg, plain aspirin 75 mg, enteric-coated aspirin 300 mg or placebo. Ex vivo prostaglandin E2 synthesis was stimulated by the vortex mixing of gastric mucosal biopsies in Tris saline and measured by radioimmunoassay. Mucosal injury was quantified both by counting erosions and with a visual analogue scale. RESULTS: All three preparations reduced prostaglandin E2 synthesis by day five, by (median) 84% for plain aspirin 300 mg, by 80% for enteric coated aspirin 300 mg and by 63% for plain aspirin 75 mg. There was little mucosal injury prior to the start of each dose and period and no significant change with placebo. Plain aspirin caused a dose-dependent mucosal injury, with two (median, IQR 0-7) gastric erosions after five days of plain aspirin 75 mg, and 18 (2-26) after five days of plain aspirin 300 mg. With enteric-coated aspirin 300 mg there were 0 (0-1) gastric erosions (P = 0.003 compared to plain aspirin 300 mg P = 0.11, compared to plain aspirin 75 mg). CONCLUSION: Enteric coated aspirin reduces acute gastric mucosal injury to placebo levels, despite its inhibition of prostaglandin synthesis. Enteric coating is an appropriate strategy for the prevention of gastric mucosal damage induced by low-dose aspirin, which warrants systematic clinical evaluation.     

阿司匹林铜的抗血小板聚集作用

目的：研究阿司匹林铜（ＣｕＡｓｐ）对血小板聚集性的影响及其机制，方法；用Ｂｏｒｎ氏法测定ＣｕＡｓｐ对兔血小板聚集性的影响，用荧光光度法和放射免疫法观察ＣｕＡｓｐ对兔血小板５－羟色胺的释放和ＴＸＢ２的产生及血浆中ＴＸＢ２和６－ｋｅｔｏ－ＰＧＦ１α水平的影响，结果：ＣｕＡｓｐ体外呈浓度依赖性抑制花生四烯酸（ＡＡ）诱导的血小板聚集和５－羟色胺的释放（ＩＣ５０分别为１７和１９μｍｏｌ．Ｌ＾－１，９５％可信     

Effects of two preparations of 75-mg extended-release aspirin on platelet aggregation, prostanoids and nitric oxide production in humans

OBJECTIVE: The lowest dose of aspirin shown to be effective in the secondary prevention of thrombotic accidents is 75 mg/day. Presystemic acetylation of cyclooxygenase and the formation of salicylic acid in the liver are fundamental to ensure optimum antithrombotic effects of aspirin. This study was designed to compare the effects of two forms of extended-release aspirin (at 75 mg/day) on prostanoid and nitric oxide synthesis in healthy volunteers. METHODS: The participants in this single-blind cross-over study (n = 6) were randomly assigned to receive one of three different formulations: plain-formulated aspirin (PF), extended-release aspirin that released acetylsalicylic acid steadily over 5 h (EX5) or an extended-release formulation that released 49% of the drug during the first 2 h after intake (EX2) and the rest of the dose during the subsequent 5 h. Laboratory analyses were done for platelet aggregation and thromboxane B2 (in whole blood), 6-keto-prostaglandin F1alpha (in leucocytes), neutrophil nitric oxide production and plasma nitrite/ nitrate levels. RESULTS: The PF and EX2 formulations inhibited platelet aggregation by 97% with no significant difference in effect between the two. In contrast, maximum inhibition of aggregation by the EX5 formulation was only 30%. Similar effects were found for platelet thromboxane production: PF and EX2 led to 99% inhibition, whereas EX5 led to 76% inhibition (P < 0.05). The inhibition of prostacyclin production differed in all three treatments (63% for PF, 40% for EX2 and 24% for EX5). The increase in leucocyte nitric oxide production also differed in all three treatments (1.01-fold the basal value with PF, 1.4-fold with EX5 and 3.6-fold with EX2). Both extended-release formulations maintained high levels of nitric oxide production 24 h after the last dose, whereas in the PF period nitric oxide concentration had returned to basal values after this time. The changes in plasma nitrite concentrations in each period of treatment were similar to those seen for leucocyte nitric oxide. CONCLUSION: The pharmacodynamic profile of the extended-release formulations was better than that of plain-formulated aspirin in terms of thromboxane/prostacyclin balance and nitric oxide production. However, the EX2 formulation inhibited platelet function more effectively than did the EX5 formulation.