Inhibition Of Serum Thromboxane B2 Research Articles

Defining platelet response to acetylsalicylic acid: the relation between inhibition of serum thromboxane B2 and agonist-induced platelet aggregation.

Arachidonic acid (AA)-induced platelet aggregation (PA) and serum thromboxane B2 (TxB2) inhibition are widely used to indicate cyclooxygenase-1 activity and the antiplatelet effect of acetylsalicylic acid (ASA). Despite decades of investigations, the relation between these measurements remains unclear. We sought to evaluate the relation between AA-PA and serum TxB2 inhibition. We serially measured AA-PA (conventional aggregation), serum TxB2, plasma ASA and salicylic acid (SA) (liquid chromatography-mass spectrometry), and urinary 11-dehydro thromboxane B2 (u11-dh TxB2) (enzyme-linked immunosorbent assay) levels at 10 times over 24 hours in seventeen healthy volunteers receiving a single dose of 162mg chewed and swallowed ASA (n = 6), 50mg inhaled ASA (n = 6), or 100mg inhaled ASA (n = 5) (ClinicalTrials.gov Identifier: NCT04328883, April 1, 2020). Baseline variability was more pronounced with serum TxB2 (31-680ng/mL) as compared to maximal AA-PA (65-81%) and u11-dh TxB2 (1556-4440pg/mg creatinine). The relation between serum TxB2 inhibition and AA-PA was stepwise; after 30-40% inhibition of serum TxB2, AA-PA fell to < 5%. By receiver operating characteristic curve analysis using AA-PA < 5% to define aspirin responsiveness, serum TxB2 inhibition > 49% and u11-dh TxB2 < 1520 pg/mg creatinine met the definition. Our study demonstrates a non-linear relation between serum TxB2 inhibition and AA-PA. Aggregation was nil once TxB2 inhibition reached > 49%. Moreover, these results suggest that the definition of > 95% inhibition of serum TxB2 to indicate the level of platelet COX-1 inhibition needed for clinical efficacy may be overestimated and should be re-considered in future translational research investigations that attempt to link the clinical efficacy of ASA with a laboratory measurement cutoff.

Enteric Coating and Aspirin Nonresponsiveness in Patients With Type 2 Diabetes Mellitus

BackgroundA limitation of aspirin is that some patients, particularly those with diabetes, may not have an optimal antiplatelet effect. ObjectivesThe goal of this study was to determine if oral bioavailability mediates nonresponsiveness. MethodsThe rate and extent of serum thromboxane generation and aspirin pharmacokinetics were measured in 40 patients with diabetes in a randomized, single-blind, triple-crossover study. Patients were exposed to three 325-mg aspirin formulations: plain aspirin, PL2200 (a modified-release lipid-based aspirin), and a delayed-release enteric-coated (EC) aspirin. Onset of antiplatelet activity was determined by the rate and extent of inhibition of serum thromboxane B2 (TXB2) generation. Aspirin nonresponsiveness was defined as a level of residual serum TXB2 associated with elevated thrombotic risk (<99.0% inhibition or TXB2 >3.1 ng/ml) within 72 h after 3 daily aspirin doses. ResultsThe rate of aspirin nonresponsiveness was 15.8%, 8.1%, and 52.8% for plain aspirin, PL2200, and EC aspirin, respectively (p < 0.001 for both comparisons vs. EC aspirin; p = 0.30 for comparison between plain aspirin and PL2200). Similarly, 56% of EC aspirin–treated subjects had serum TXB2 levels >3.1 ng/ml, compared with 18% and 11% of subjects after administration of plain aspirin and PL2200 (p < 0.0001). Compared with findings for plain aspirin and PL2200, this high rate of nonresponsiveness with EC aspirin was associated with lower exposure to acetylsalicylic acid (63% and 70% lower geometric mean maximum plasma concentration [Cmax] and 77% and 82% lower AUC0–t [area under the curve from time 0 to the last time measured]) and 66% and 72% lower maximum decrease of TXB2, with marked interindividual variability. ConclusionsA high proportion of patients treated with EC aspirin failed to achieve complete inhibition of TXB2 generation due to incomplete absorption. Reduced bioavailability may contribute to “aspirin resistance” in patients with diabetes. (Pharmacodynamic Evaluation of PL2200 Versus Enteric-Coated and Immediate Release Aspirin in Diabetic Patients; NCT01515657)

Nonsteroidal Anti-Inflammatory Drugs and the Heart

Aspirin has been on the market for 115 years. Beginning with the marketing of indomethacin for the treatment of rheumatoid arthritis in 1963, at least 20 other nonsteroidal anti-inflammatory drugs (NSAIDs) with aspirin-like actions have been developed over the past 50 years,1 culminating with the introduction of a new class of selective inhibitors of cyclooxygenase (COX)-2, the coxibs, approximately 15 years ago.2 The NSAIDs represent the single most crowded family of drugs sharing the same therapeutic activities and mechanism of action, perhaps reflecting the unmet therapeutic need in the area of pain management and the large interindividual variability in response to these agents. NSAIDs provide symptomatic relief of pain and inflammation associated with a variety of human disorders, including the rheumatic diseases. Their shared therapeutic actions (ie, analgesic, anti-inflammatory, and antipyretic) are usually accompanied by mechanism-based adverse effects that can, at least in part, be attenuated as a function of individual pharmacokinetic or pharmacodynamic properties.1 Nuances in the tolerability of different NSAIDs had been described in the precoxib era on the basis of clinical trials of a few hundred patients treated for up to a few months with soft end points. More recently, however, important differences in safety have been demonstrated in head-to-head randomized comparisons of individual coxibs and 1 or more traditional NSAIDs that involved tens of thousands of patients treated for up to a few years with hard end points. Even more significantly, the interpretation of the effects of NSAIDs has been greatly enhanced by the availability, for the first time, of large, placebo-controlled trials that aimed to assess the potential for chemoprevention of colorectal cancer by rofecoxib or celecoxib. As a result of these developments, the whole field of NSAIDs has been illuminated during the past 15 years. Although epidemiological studies had previously associated …

Pharmacodynamics and Pharmacokinetics of a Novel, Low-Dose, Soft-Gel Capsule of Acetylsalicylic Acid in Comparison with an Oral Solution After Single-Dose Administration to Healthy Volunteers: A Phase I, Two-Way Crossover Study

Low-dose acetylsalicylic acid (ASA; aspirin) is well-established as a platelet anti-aggregating agent for the secondary prevention of cardiovascular events. The objective of this study was to investigate the non-inferiority of a novel ASA 75 mg soft-gel capsule formulation compared with a marketed powder for oral solution in terms of reduction in serum thromboxane B2 (TXB2), a surrogate for platelet aggregation. Pharmacokinetics and tolerability of the products were also investigated. In this randomised, two-way crossover study, 46 male and female healthy subjects received a single dose of the investigational products in two periods separated by a 14-day washout. Serum TXB2 and plasma ASA were determined up to 24 h post-dose. Maximum percentage of TXB2 inhibition (I max) and area under the inhibition-time curve (AUICt) were calculated. Non-inferiority was assumed if the lower limits of the 95 % confidence intervals (CIs) for the two pharmacodynamic parameters were above 85 %. The 95 % CI lower limits were 95.35 % for I max and 86.12 % for AUICt, i.e. within the pre-specified delta. Time to achieve I max did not differ between treatments (p = 0.88). The two formulations were bioequivalent as regards the extent of ASA exposure (area under the plasma concentration-time curve from zero to time t [AUCt] 90 % CIs 96.67-113.37); a delayed ASA absorption (later time to reach maximum plasma concentration [t max], lower maximum plasma concentration [C max]) was observed for the test product. No treatment-related adverse events were reported. In healthy subjects, the 75 mg soft-gel capsules were not inferior to the oral solution in terms of serum TXB2 inhibition, indicating that the novel formulation could be an effective alternative in the secondary prevention of cardiovascular events.

Influence of oxytetracycline on carprofen pharmacodynamics and pharmacokinetics in calves

A tissue cage model of inflammation in calves was used to determine the pharmacokinetic and pharmacodynamic properties of individual carprofen enantiomers, following the administration of the racemate. RS(±) carprofen was administered subcutaneously both alone and in combination with intramuscularly administered oxytetracycline in a four-period crossover study. Oxytetracycline did not influence the pharmacokinetics of R(-) and S(+) carprofen enantiomers, except for a lower maximum concentration (Cmax ) of S(+) carprofen in serum after co-administration with oxytetracycline. S(+) enantiomer means for area under the serum concentration-time curve (AUC0-96 h were 136.9 and 128.3 μg·h/mL and means for the terminal half-life (T(1/2) k10 ) were = 12.9 and 17.3 h for carprofen alone and in combination with oxytetracycline, respectively. S(+) carprofen AUC0-96 h in both carprofen treatments and T(1/2) k10 for carprofen alone were lower (P < 0.05) than R(-) carprofen values, indicating a small degree of enantioselectivity in the disposition of the enantiomers. Carprofen inhibition of serum thromboxane B2 ex vivo was small and significant only at a few sampling times, whereas in vivo exudate prostaglandin (PG)E2 synthesis inhibition was greater and achieved overall significance between 36 and 72 h (P < 0.05). Inhibition of PGE2 correlated with mean time to achieve maximum concentrations in exudate of 54 and 42 h for both carprofen treatments for R(-) and S(+) enantiomers, respectively. Carprofen reduction of zymosan-induced intradermal swelling was not statistically significant. These data provide a basis for the rational use of carprofen with oxytetracycline in calves and indicate that no alteration to carprofen dosage is required when the drugs are co-administered.

Effect of maximum OTC doses of naproxen sodium or acetaminophen on low-dose aspirin inhibition of serum thromboxane B2

Objectives:This study evaluated the platelet inhibitory effects of low-dose enteric-coated aspirin (EC-ASA) when used concomitantly with maximum over-the-counter (OTC) doses of naproxen sodium (NAPSO) or acetaminophen to determine whether NAPSO and acetaminophen interfere with the anti-platelet effect of aspirin.Research design and methods:Phase I, randomized, open-label, multi-dose, three-period, parallel group, pharmacodynamic trial conducted in healthy male and female volunteers (n = 47 randomized subjects and n = 37 evaluable subjects), mean age 40.2 years. All subjects received 5 days of EC-ASA 81 mg once daily followed by 5 days of EC-ASA 81 mg once daily alone or co-administered with either NAPSO 220 mg three times daily or acetaminophen 1 g four times daily.Primary outcome measure:Inhibition of serum thromboxane B2 (TXB2), as a marker of platelet cyclooxygenase-1 (COX-1) inhibition, measured on Day 11.Results:Mean inhibition of TXB2 on Day 11 was >99% for subjects taking EC-ASA alone as well as for those who received EC-ASA co-administered with NAPSO or acetaminophen. For subjects taking EC-ASA monotherapy, mean serum TXB2 inhibition was 99.7% (range 99.0–100%), for those taking EC-ASA with acetaminophen it was 99.6% (range 98.3–99.9%), and for those taking EC-ASA with NAPSO, mean serum TXB2 inhibition was 99.7% (range 99.2–100%).Study limitation:Small sample size and open-label trial design.Conclusions:The anti-platelet effect of EC-ASA 81 mg once daily was maintained following its co-administration with maximum OTC doses of NAPSO or acetaminophen.

Platelet inhibitory effects of OTC doses of naproxen sodium compared with prescription dose naproxen sodium and low-dose aspirin

Objectives: Prescription dose naproxen has been reported to have an antiplatelet effect similar to low-dose aspirin (ASA). This study evaluated the platelet inhibitory effects of over-the-counter (OTC) doses of naproxen sodium (NAPSO) compared to that of a prescription dose of NAPSO and to low-dose enteric-coated aspirin (EC-ASA).Research design and methods: This was a phase I, open-label, randomized, placebo-controlled, two-way crossover, multi-dose, pharmacodynamic trial conducted in healthy male and female volunteers (n = 48, mean age = 41.7 years). All subjects received 7 days of either prescription dose NAPSO (550 mg twice daily), OTC doses of NAPSO (220 mg two or three times daily), or placebo twice daily (period 1). After a minimum 6-day washout period, all subjects then received 7 days of EC-ASA 81 mg once daily (period 2). All study medications were taken by mouth.Primary outcome measure: Inhibition of serum thromboxane B2 (TXB2), as a marker of platelet cyclooxygenase-1 (COX-1) inhibition, measured 24 h after the day 7 morning dose. This was measured after both period 1 and period 2.Results: After 7 days of treatment in period 1, mean inhibition of TXB2 was 47% for placebo and ≥98% for all doses of NAPSO. After 7 days of EC-ASA 81 mg, mean inhibition of TXB2 was ≥ 97% (period 2).Study limitations: Out-patient study setting.Conclusions: These data suggest that OTC doses of NAPSO (220 mg two or three times daily) have an antiplatelet effect similar to EC-ASA 81 mg and to prescription dose NAPSO (550 mg twice daily).

Recent FDA Warning of the Concomitant Use of Aspirin and Ibuprofen and the Effects on Platelet Aggregation

Recent FDA Warning of the Concomitant Use of Aspirin and Ibuprofen and the Effects on Platelet Aggregation

Aspirin and Clopidogrel Resistance

Aspirin and clopidogrel provide significant clinical benefit in patients with cardiovascular disease. However, given the complexity of platelet activation, it is not surprising that aspirin or clopidogrel prevent a small proportion of cardiovascular events. Of late, the terms aspirin and clopidogrel "resistance" have entered the physicians' lexicon, and infer a lack of therapeutic response and a single underlying mechanism, which is misleading. The incidence of "resistance" detected in studies varies with the definition applied and assay used to measure response. Rather than true resistance, however, there is a variable response that reflects the unique pharmacology and pharmacokinetics of each drug, the clinical significance of which remains to be established. True "aspirin resistance" implies that cyclooxygenase-1 is less sensitive to inactivation by aspirin. Despite 95% inhibition of serum thromboxane B(2) by aspirin, residual platelet aggregation is detected in some cases, the clinical significance of which is unknown. Heritable factors directly and indirectly related to platelet cyclooxygenase may influence aspirin response. In contrast to aspirin, the response to clopidogrel is highly variable and reflects the bioavailability of the active metabolite and not "resistance" of the receptor to inhibition.

Dose–effect comparisons of the CINOD AZD3582 and naproxen on upper gastrointestinal tract mucosal injury in healthy subjects

Objective. The objective of this endoscopic study was to compare the effects on the gastroduodenal mucosa of healthy volunteers of different doses and dosing regimens of AZD3582, a cyclooxygenase-inhibiting nitric oxide donator (CINOD), with equimolar doses of naproxen. Material and methods. Healthy volunteers were enrolled in a single-centre, randomized, double-blind, crossover trial consisting of two 12-day treatment periods and employing six sequences. The groups were: AZD3582 750 mg daily versus 375 mg twice daily (n = 25), AZD3582 375 mg twice daily versus 750 mg twice daily (n = 25) and naproxen 250 mg twice daily versus 500 mg twice daily (n = 25). Results. Gastroduodenal tract damage was similar with AZD3582 375 mg twice daily and 750 mg twice daily (mean number of erosions and ulcers±SD: 2.88±3.95 versus 3.08±2.80, respectively; p=0.824; 1 ulcer counted as 10 erosions). There was an indication of decreased gastroduodenal toxicity with AZD3582 750 mg daily compared with 375 mg twice daily (0.92±2.08 versus 2.71±4.75, respectively; p=0.068). Gastroduodenal toxicity was significantly lower with AZD3582 375 mg twice daily than with naproxen 250 mg twice daily (2.88±3.95 versus 6.16±9.36; p<0.05), and with AZD3582 750 mg twice daily versus naproxen 500 mg twice daily (3.08±2.80 versus 6.68±6.97; p < 0.05). Equimolar twice-daily doses of AZD3582 and naproxen resulted in similar naproxen plasma levels and serum thromboxane B2 inhibition. Conclusions. AZD3582 has an improved gastroduodenal safety profile compared with equimolar doses of naproxen. The gastroduodenal effects of AZD3582 375 mg and AZD3582 750 mg twice daily are similar. A once-daily regimen of AZD3582 might be less gastrotoxic than a twice-daily regimen.

Pharmacodynamics, chiral pharmacokinetics and PK-PD modelling of ketoprofen in the goat.

There have been few studies of the pharmacodynamics of nonsteroidal antiinflammatory drugs (NSAIDs) using PK-PD modelling, yet this approach offers the advantage of defining the whole concentration-effect relationship, as well as its time course and sensitivity. In this study, ketoprofen (KTP) was administered intravenously to goats as the racemate (3.0 mg/kg total dose) and as the single enantiomers, S(+) KTP and R(-) KTP (1.5 mg/kg of each). The pharmacokinetics and pharmacodynamics of KTP were investigated using a tissue cage model of acute inflammation. The pharmacokinetics of both KTP enantiomers was characterized by rapid clearance, short mean residence time (MRT) and low volume of distribution. The penetration of R(-) KTP into inflamed (exudate) and noninflamed (transudate) tissue cage fluids was delayed but area under the curve values were only slightly less than those in plasma, whereas MRT was much longer. The S(+) enantiomer of KTP penetrated less readily into exudate and transudate. Unidirectional inversion of R(-) to S(+) KTP occurred. Both rac-KTP and the separate enantiomers produced marked inhibition of serum thromboxane B2 (TxB2) synthesis (ex vivo) and moderate inhibition of exudate prostaglandin E2 (PGE2) synthesis (in vivo); pharmacodynamic variables for S(+) KTP were Emax (%) = 94 and 100; IC50 (microg/mL) = 0.0033 and 0.0030; N = 0.45 and 0.58, respectively, where Emax is the maximal effect, IC50 the plasma drug concentration producing 50% of Emax and N the slope of log concentration/effect relationship. The IC50 ratio, serum TxB2:exudate PGE2 was 1.10. Neither rac-KTP nor the individual enantiomers suppressed skin temperature rise at, or leucocyte infiltration into, the site of acute inflammation. These data illustrate for KTP shallow concentration-response relationships, probable nonselectivity of KTP for cyclooxygenase (COX)-1 and COX-2 inhibition and lack of measurable effect on components of inflammation.

Pharmacokinetics and pharmacodynamics of ketoprofen enantiomers in calves.

The pharmacokinetics (PK) and pharmacodynamics (PD) of (S)- and (R)-ketoprofen (KTP) enantiomers were studied in calves after intravenous administration of each enantiomer at a dose of 1.5 mg/kg. Pharmacodynamic properties were evaluated using a model of acute inflammation, comprising subcutaneously implanted tissue cages stimulated by intracaveal injection of carrageenan. Chiral inversion of (R)-KTP to the (S)-antipode occurred. The R:S ratio in plasma was 33:1 5 min after administration, decreasing to 1:1 at 8 h. The calculated extent of inversion was 31 +/- 7%. The R:S ratio in inflammatory exudate was of the order 3:1 at all the sampling times and the ratio in transudate was approximately 2:1 for 6 h, declining to 1:1 at 30 h. Only (S)-KTP was detected in biological fluids after administration of this enantiomer. Elimination half-life was longer for the (S) (2.19 h) than the (R)-enantiomer (1.30 h) and volume of distribution was also somewhat higher for the (S)-enantiomer. Body clearance values were 0.119 l/kg/h for (S)-KTP and 0.151 l/kg/h for the (R)-antipode. For (R)-KTP effects obtained were considered as a hybrid, since they potentially reflect the actions of both enantiomers. Concentrations of LTB4 and the cytokines interleukin-1, interleukin-6, and tumor necrosis factor alpha, in exudate were not significantly affected by either (R)- or (S)-KTP treatments. Inhibition of ex vivo thromboxane B2 (TxB2) synthesis, exudate prostaglandin E2 (PGE2) synthesis, beta-glucuronidase release (beta-glu), and bradykinin-induced skin swelling was significant in both treated groups. PK/PD modelling was applied to the (S)-KTP treatment only. EC50 values for inhibition of serum TxB2, exudate PGE2 and beta-glu and BK-induced swelling were 0.047, 0.042, 0.101, and 0.038 microgram/ml, respectively. It is concluded that the low EC50 values for inhibition of TxB2 and PGE2 by (S)-KTP are likely to explain the effects produced by (R)-KTP administration, since concentrations of (S)-KTP in exudate of these calves following chiral inversion were at least 5 times higher than the EC50 at all sampling times. The data for beta-glu and bradykinin-induced swelling inhibition indicate possible inhibitory actions of (R)-KTP as well as (S)-KTP.

Flunixin pharmacokinetics and serum thromboxane inhibition in the dog.

Flunixin meglumine administered orally to beagle dogs at doses of 0.55, 1.10 or 1.65 mg/kg bodyweight was rapidly absorbed to produce maximum mean plasma concentrations of 2.40 +/- 0.70, 4.57 +/- 1.12 and 7.42 +/- 2.07 micrograms/ml, respectively. Thereafter, the plasma concentrations of flunixin fell rapidly to values less than 0.10 micrograms/ml from 24 hours after drug administration at all dosage levels. The maximum mean inhibition of serum thromboxane B2 was 91.5 per cent after the lowest dose of flunixin and 98.8 per cent for both the intermediate and high dose rates. At plasma concentrations of flunixin above 2 micrograms/ml there was more than 90 per cent inhibition of thromboxane.

Influence of Antacid Administrations on Aspirin Absorption in Patients With Chronic Renal Failure on Maintenance Hemodialysis

In order to investigate the possible interaction between oral aspirin and antacids in uremic patients on chronic hemodialysis, we administered to 5 uremic patients: (1) aspirin alone; (2) aluminum-magnesium hydroxide with aspirin; (3) aluminum-magnesium hydroxide followed (two hours) by aspirin; (4) calcium carbonate simultaneously with aspirin; and (5) calcium carbonate followed (two hours) by aspirin. In all the occasions, aspirin was given two hours after a standard lunch. Both antacid preparations induced comparable changes in aspirin mean peak plasma concentration (Cmax), if given simultaneously with aspirin, whereas no difference was found in other pharmacokinetic parameters. When antacids were followed (two hours) by aspirin, both Cmax and time of maximum concentration (Tmax) were significantly altered in respect to the value with aspirin alone. No changes in the time course of post aspirin serum thromboxane B2 were detected when aspirin and antacids were administered simultaneously, but the inhibition of serum thromboxane B2 was delayed when antacids were followed (two hours) by aspirin. These results indicate that the administration of antacids to uremic patients interferes with absorption of oral aspirin. This interference can be minimized if aspirin and antacids are given simultaneously.

Increased thromboxane biosynthesis in normal pregnancy is mainly derived from platelets

Thromboxane biosynthesis was determined in normal pregnant subjects by measurement of its major urinary and plasma metabolites, 2,3-dinor-thromboxane B2 and 11-dehydro-thromboxane B2. Urinary 2,3-dinor-thromboxane B2 increased early in pregnancy (731 +/- 124 pg/mg creatinine) compared with nonpregnancy (less than 350 pg/mg creatinine; p less than 0.001) and the postpartum period (155 +/- 42 pg/mg creatinine, p = 0.015) and remained elevated throughout gestation. Similarly, plasma and urinary 11-dehydro-thromboxane B2 were increased in pregnancy. To determine the cellular origin of the increase in thromboxane biosynthesis in pregnancy, platelet cyclooxygenase was selectively inhibited with aspirin in a dose of 120 mg orally followed by 20 mg twice daily for 7 days (n = 4). Selectivity was confirmed by measurement of urinary 2,3-dinor-6-keto-prostaglandin F1 alpha, an index of prostacyclin biosynthesis. Coincident with a 97% inhibition of serum thromboxane B2, urinary 2,3-dinor-thromboxane B2 was almost completely inhibited and paralleled the recovery of platelet cyclooxygenase after withdrawal of aspirin. This study demonstrates that thromboxane biosynthesis is increased in pregnancy. The increase is mainly platelet derived and is consistent with increased platelet activation throughout pregnancy.

Inhibition of thromboxane formation in vivo and ex vivo: implications for therapy with platelet inhibitory drugs

The capacity of platelets to generate thromboxane A2, reflected by measurement of serum thromboxane B2 (TxB2), greatly exceeds the systemic production of thromboxane in vivo. Thus, it is possible that substantial but incomplete inhibition of thromboxane formation ex vivo would still allow marked augmentation of thromboxane production in vivo. To address this hypothesis, we administered aspirin 120 mg, a selective inhibitor of thromboxane synthase (TxSl), 3-(1H-imidazol-1-yl-methyl)-2-methyl-1H-indole-1-propanoic acid (UK-38, 485) 200 mg, and a combination of both drugs to 12 healthy volunteers and measured the effects on serum TxB2 and urinary 2,3-dinor-thromboxane B2 (Tx-M), an index of endogenous thromboxane biosynthesis. Although serum TxB2 was maximally inhibited by 94 +/- 1% after aspirin and 96 +/- 2% after the TxSl, maximal depression of Tx-M was only 28 +/- 8% and 37 +/- 9%, respectively. Combination of aspirin with the TxSl resulted in a small but significant increase in inhibition of thromboxane generation ex vivo (98 +/- 1% v 94 +/- 1%; P less than 0.05), but a disproportionately greater fall in thromboxane synthesis in vivo (58 +/- 7%; P less than 0.01). Consistent with further inhibition of platelet thromboxane synthesis, addition of the TxSl abolished the transient decline in prostacyclin formation after aspirin alone. Administration of a lower dose of aspirin (20 mg) to 6 healthy subjects caused a small reduction in Tx-M (12 +/- 4%; P less than 0.05) and inhibited serum TxB2 by 48 +/- 2%. The relationship between inhibition of platelet capacity to form thromboxane ex vivo (serum TxB2) and synthesis in vivo (Tx-M) departed markedly from the line of identity. When total blockade of the capacity of platelets to generate thromboxane is approached, minor decrements in capacity result in a disproportionate depression of actual thromboxane biosynthesis. These results imply that pharmacologic inhibition of serum TxB2 must be virtually complete before thromboxane-dependent platelet activation is influenced in vivo.

Inhibition of Thromboxane Formation In Vivo and Ex Vivo: Implications for Therapy With Platelet Inhibitory Drugs

Abstract The capacity of platelets to generate thromboxane A2, reflected by measurement of serum thromboxane B2 (TxB2), greatly exceeds the systemic production of thromboxane in vivo. Thus, it is possible that substantial but incomplete inhibition of thromboxane formation ex vivo would still allow marked augmentation of thromboxane production in vivo. To address this hypothesis, we administered aspirin 120 mg, a selective inhibitor of thromboxane synthase (TxSl), 3-(1H-imidazol-1-yl- methyl)-2-methyl-1H-indole-1-propanoic acid (UK-38, 485) 200 mg, and a combination of both drugs to 12 healthy volunteers and measured the effects on serum TxB2 and urinary 2,3-dinor-thromboxane B2 (Tx-M), an index of endogenous thromboxane biosynthesis. Although serum TxB2 was maximally inhibited by 94 +/- 1% after aspirin and 96 +/- 2% after the TxSl, maximal depression of Tx-M was only 28 +/- 8% and 37 +/- 9%, respectively. Combination of aspirin with the TxSl resulted in a small but significant increase in inhibition of thromboxane generation ex vivo (98 +/- 1% v 94 +/- 1%; P less than 0.05), but a disproportionately greater fall in thromboxane synthesis in vivo (58 +/- 7%; P less than 0.01). Consistent with further inhibition of platelet thromboxane synthesis, addition of the TxSl abolished the transient decline in prostacyclin formation after aspirin alone. Administration of a lower dose of aspirin (20 mg) to 6 healthy subjects caused a small reduction in Tx-M (12 +/- 4%; P less than 0.05) and inhibited serum TxB2 by 48 +/- 2%. The relationship between inhibition of platelet capacity to form thromboxane ex vivo (serum TxB2) and synthesis in vivo (Tx-M) departed markedly from the line of identity. When total blockade of the capacity of platelets to generate thromboxane is approached, minor decrements in capacity result in a disproportionate depression of actual thromboxane biosynthesis. These results imply that pharmacologic inhibition of serum TxB2 must be virtually complete before thromboxane- dependent platelet activation is influenced in vivo.