Desmond J. Fitzgerald

Platelet Activation in Unstable Coronary Disease

Pathological and clinical studies have suggested that platelets have a role in the pathogenesis of unstable angina and myocardial infarction. However, the relation of platelet activation to episodic ischemia in patients with unstable angina is unknown. We assessed the biosynthesis of thromboxane and prostacyclin as indexes of platelet activation in patients with stable and unstable coronary disease by physicochemical analysis of metabolites in plasma and urine. Prostacyclin biosynthesis was markedly elevated in patients with acute myocardial infarction and correlated with plasma creatine kinase (r = 0.795; P less than 0.001). The largest rise in thromboxane synthesis was observed in patients with unstable angina, in whom 84 percent of the episodes of chest pain were associated with phasic increases in the excretion of thromboxane and prostacyclin metabolites. However, 50 percent of such increases were not associated with chest pain, possibly reflecting silent myocardial ischemia. These data indicate that platelet activation occurs during spontaneous ischemia in patients with unstable angina. The increment in prostacyclin biosynthesis during such episodes may be a compensatory response of vascular endothelium that limits the degree or effects of platelet activation. If so, biochemically selective inhibition of the synthesis or action of thromboxane A2 would be desirable in the treatment of unstable angina. In contrast, thromboxane inhibitors or antagonists would not be expected to be effective in patients with chronic stable angina, in whom there was no increase in the formation of thromboxane A2.

Ticlopidine and Clopidogrel

The thienopyridines ticlopidine and clopidogrel are inhibitors of platelet function in vivo. Their mode of action has not been defined, but it appears that they require conversion to as yet unidentified metabolites that are noncompetitive antagonists of the platelet ADP receptor. Inhibition of platelet aggregation with these compounds is delayed until 24 to 48 hours after administration. Maximum inhibition occurs after 3 to 5 days, and recovery is slow after drug withdrawal. Ticlopidine is effective in preventing cardiovascular events in cerebrovascular, cardiovascular, and peripheral vascular disease, with an efficacy that is similar to aspirin. However, its use is associated with significant and sometimes fatal adverse reactions, specifically neutropenia and bone marrow aplasia. Gastrointestinal side effects and skin rashes are common and result in discontinuation of therapy in up to 10% of patients. Clopidogrel is at least as effective as aspirin in preventing cardiovascular events in patients with a history of vascular disease. It appears to be safer than ticlopidine, although its efficacy in acute coronary syndromes or post-coronary-stent insertion has not been reported. Important outstanding issues are whether clopidogrel adds to the benefit of aspirin and whether the combination of these agents is safe. If so, this combination may become the standard for antithrombotic therapy in cardiovascular disease.

Marked platelet activation in vivo after intravenous streptokinase in patients with acute myocardial infarction.

We assessed thromboxane biosynthesis as an index of platelet activation in 6 patients with acute myocardial infarction receiving intravenous streptokinase. Urinary 2,3-dinor-thromboxane B2 and plasma 11-dehydro-thromboxane B2, major enzymatic metabolites of thromboxane A2, were markedly increased after intravenous streptokinase (11,063 +/- 2758 pg/mg creatinine and 33 +/- 10 pg/ml, respectively) compared with levels in patients not receiving thrombolytic therapy (502 +/- 89 pg/mg creatinine and 3 +/- 0.7 pg/ml). Prostacyclin biosynthesis also increased markedly after streptokinase coincident with the increase in thromboxane A2 formation. Administration of aspirin between the time of onset of coronary thrombosis and reperfusion both in man and in a canine preparation demonstrated that this reflected thromboxane biosynthesis de novo and not metabolism of preformed inactive thromboxane B2 washed out from the coronary circulation. Since the platelet is the major source of thromboxane A2, these findings suggest that there is marked platelet activation after coronary thrombolysis with streptokinase. Studies in vitro demonstrated that streptokinase enhanced platelet activation in a dose-dependent manner, resulting in the secondary release of thromboxane A2. The increase in platelet activation and thromboxane A2 biosynthesis may limit the therapeutic effect of intravenous streptokinase in acute myocardial infarction.

Cyclooxygenase-1 and -2-dependent prostacyclin formation in patients with atherosclerosis

BACKGROUND The formation of prostacyclin (PGI(2)), thromboxane (TX) A(2), and isoprostanes is markedly enhanced in atherosclerosis. We examined the relative contribution of cyclooxygenase (COX)-1 and -2 to the generation of these eicosanoids in patients with atherosclerosis. METHODS AND RESULTS The study population consisted of 42 patients with atherosclerosis who were undergoing surgical revascularization. COX-2 mRNA was detected in areas of atherosclerosis but not in normal blood vessel walls, and there was evidence of COX-1 induction. The use of immunohistochemical studies localized the COX-2 to proliferating vascular smooth muscle cells and macrophages. Twenty-four patients who did not previously receive aspirin were randomized to receive either no treatment or nimesulide at 24 hours before surgery and then for 3 days. Eighteen patients who were receiving aspirin were continued on a protocol of either aspirin alone or a combination of aspirin and nimesulide. Urinary levels of 11-dehydro-TXB(2) and 2,3-dinor-6-keto-PGF(1alpha), metabolites of TXA(2) and PGI(2), respectively, were elevated in patients with atherosclerosis compared with normal subjects (3211+/-533 versus 679+/-63 pg/mg creatinine, P<0.001; 594+/-156 versus 130+/-22 pg/mg creatinine, P<0.05, respectively), as was the level of the isoprostane 8-iso-PGF(2alpha). Nimesulide reduced 2, 3-dinor-6-keto-PGF(1alpha) excretion by 46+/-5% (378.3+/-103 to 167+/-37 pg/mg creatinine, P<0.01) preoperatively and blunted the increase after surgery. Nimesulide had no significant effect on 11-dehydro-TXB(2) before (2678+/-694 to 2110+/-282 pg/mg creatinine) or after surgery. The levels of both products were lower in patients who were taking aspirin, and no further reduction was seen with the addition of nimesulide. None of the treatments influenced urinary 8-iso-PGF(2alpha) excretion. CONCLUSIONS Both COX-1 and -2 are expressed and contribute to the increase in PGI(2) in patients with atherosclerosis, whereas TXA(2) is generated by COX-1.

8-Epi PGF2α Generation During Coronary Reperfusion

Background Myocardial reperfusion is believed to be associated with free radical injury. However, indexes of oxidative stress in vivo have been limited by their poor specificity and sensitivity. Isoprostanes are stable products of arachidonic acid formed in a nonenzymatic, free radical–catalyzed manner. We have developed a sensitive and specific assay for one of these compounds, 8-epi prostaglandin (PG) F2α. Methods and Results To address its utility as an index of oxidative stress during coronary reperfusion, we measured urinary levels by gas chromatography/mass spectrometry in a canine model of coronary thrombolysis, in patients with acute myocardial infarction treated with thrombolytic therapy, and in patients after elective coronary artery bypass surgery. Urinary 8-epi PGF2α was unchanged after circumflex artery occlusion in a canine model of coronary thrombolysis (n=13; 437.2±56.4 versus 432.7±55.2 pmol/mmol creatinine) but increased significantly ( P <.05) immediately after reperfusion (553.8±64.7 pmol/mmol). Urinary levels were increased ( P <.001) in patients (n=12) with acute myocardial infarction given lytic therapy (265.8±40.8 pmol/mmol) compared with age-matched control subjects (n=20; 91.5±11.8 pmol/mmol) and patients with stable coronary disease (n=20; 95.7±6.3 pmol/mmol). Preoperative levels rose from 113.2±11.8 to 248.2±86.3 pmol/mmol at 30 minutes into revascularization to 332.2±82.6 pmol/mmol by 15 minutes after global myocardial reperfusion ( P <.05) and dropped to 181.2±50.4 pmol/mmol at 30 minutes and 120.2±9.9 pmol/mmol at 24 hours after bypass surgery (n=5). Corresponding changes in spin adduct formation, found with electron paramagnetic resonance, were noted in 2 patients. Conclusions These data support the hypothesis that free radical generation occurs during myocardial reperfusion. Measurement of isoprostane production may serve as a noninvasive index of oxidative stress.

Integration of Proteomics and Genomics in Platelets A PROFILE OF PLATELET PROTEINS AND PLATELET-SPECIFIC GENES

Platelets, while anucleate, contain RNA, some of which is translated into protein upon activation. Hypothesising that the platelet proteome is reflected in the transcriptome, we identified 82 proteins secreted from activated platelets and compared these, as well as published proteomic data, to the transcriptional profile. We also compared the transcriptome of platelets to other tissues to identify platelet-specific genes and used ontology to determine gene categories over-represented in platelets. RNA was isolated from highly pure platelet preparations for hybridization to Affymetrix oligonucleotide arrays. We identified 2,928 distinct messages as being present in platelets. The platelet transcriptome was compared with the proteome by relating both to UniGene clusters. Platelet proteomic data correlated well with the transcriptome, with 69% of secreted proteins detectable at the mRNA level, and similar concordance was obtained using two published datasets. While many of the most abundant mRNAs are for known platelet proteins, messages were detected for proteins not previously reported in platelets. Some of these may represent residual megakaryocyte messages; however, proteomic analysis confirmed the expression of many previously unreported genes in platelets. Transcripts for well-described platelet proteins are among the most platelet-specific messages. Ontological categories related to signal transduction, receptors, ion channels, and membranes are over-represented in platelets, while categories involved in protein synthesis are depleted. Despite the absence of gene transcription, the platelet proteome is mirrored in the transcriptome. Conversely, transcriptional analysis predicts the presence of novel proteins in the platelet. Transcriptional analysis is relevant to platelet biology, providing insights into platelet function and the mechanisms of platelet disorders.

Decreased prostacyclin biosynthesis preceding the clinical manifestation of pregnancy-induced hypertension.

Patients who develop pregnancy-induced hypertension exhibit a lesser increment in prostacyclin biosynthesis than healthy pregnant subjects. Whether this precedes the development of clinical disease and therefore may be important in the pathogenesis of pregnancy-induced hypertension or is a secondary event is unknown. We prospectively determined prostacyclin biosynthesis in pregnant subjects at risk of developing pregnancy-induced hypertension by use of noninvasive approach, measurement of the urinary metabolite 2,3-dinor-6-keto-prostaglandin F1 alpha. Patients were recruited at less than 20 weeks gestation. After delivery, patients were retrospectively allocated by use of preset criteria, to one of four groups: pregnancy-induced hypertension (n = 12), hypertension in labor (n = 22), chronic hypertension (n = 9), and normotension (n = 24). There was a significant increase in prostacyclin biosynthesis in all study groups during gestation. However, patients who developed pregnancy-induced hypertension exhibited a lesser increment and this difference persisted throughout gestation. These results are consistent with a pathophysiologic role for altered prostacyclin biosynthesis in women with pregnancy-induced hypertension. In addition, decreased prostacyclin formation identifies a population at risk of developing pregnancy-induced hypertension. Such information would assist the design of clinical trials of drugs, such as aspirin, that might prevent the development of this disease.

Hematopoietic prostaglandin D2 synthase controls the onset and resolution of acute inflammation through PGD2 and 15-deoxyΔ12–14 PGJ2

Hematopoietic prostaglandin D2 synthase (hPGD2S) metabolizes cyclooxygenase (COX)-derived PGH2 to PGD2 and 15-deoxyΔ12–14 PGJ2 (15d-PGJ2). Unlike COX, the role of hPGD2S in host defense is ambiguous. PGD2 can be either pro- or antiinflammatory depending on disease etiology, whereas the existence of 15d-PGJ2 and its relevance to pathophysiology remain controversial. Herein, studies on hPGD2S KO mice reveal that 15d-PGJ2 is synthesized in a self-resolving peritonitis, detected by using liquid chromatography–tandem MS. Together with PGD2 working on its DP1 receptor, 15d-PGJ2 controls the balance of pro- vs. antiinflammatory cytokines that regulate leukocyte influx and monocyte-derived macrophage efflux from the inflamed peritoneal cavity to draining lymph nodes leading to resolution. Specifically, inflammation in hPGD2S KOs is more severe during the onset phase arising from a substantial cytokine imbalance resulting in enhanced polymorphonuclear leukocyte and monocyte trafficking. Moreover, resolution is impaired, characterized by macrophage and surprisingly lymphocyte accumulation. Data from this work place hPGD2S at the center of controlling the onset and the resolution of acute inflammation where it acts as a crucial checkpoint controller of cytokine/chemokine synthesis as well as leukocyte influx and efflux. Here, we provide definitive proof that 15d-PGJ2 is synthesized during mammalian inflammatory responses, and we highlight DP1 receptor activation as a potential antiinflammatory strategy.

Variable Platelet Response to Aspirin and Clopidogrel in Atherothrombotic Disease

Humans require rapidly responding, tightly regulated hemostasis because of their closed high-pressure circulatory system. Minor variation in response may predispose to pathological bleeding or thrombosis. In the appropriate setting, pharmacological intervention with antiplatelet therapy stabilizes the atherothrombotic phenotype, though with concomitant hemorrhagic risk. Populations with favorable risk–benefit ratios for acetylsalicylic acid (aspirin) and clopidogrel therapy have nevertheless been defined in major clinical trials. Treatment benefit is established for secondary prevention of cardiovascular and cerebrovascular events, management of acute coronary syndromes, and as an adjunct to percutaneous and surgical revascularization. There is evidence, however, that not all individuals respond comparably to antiplatelet drugs and hence the concept of aspirin and clopidogrel “resistance” has arisen. The term is misleading though because there are many determinants of failure to respond to treatment. Consistent levels of platelet inhibition are required to deliver effective therapy. Adverse consequences of variable response are particularly apparent when antiplatelet drugs are used as an adjunct to coronary revascularization. During percutaneous coronary intervention (PCI), atherosclerotic plaque is invariably disrupted, thrombosis occurs, and endothelial healing is delayed. Intensive periprocedural platelet inhibition minimizes morbidity and mortality, whereas persistence of a prothrombotic environment necessitates chronic antiplatelet therapy. Failure to provide adequate platelet inhibition in all individuals can result in stent thrombosis, myocardial infarction, and death.1,2 Platelet inhibition with aspirin at the time of coronary artery bypass graft surgery also provides benefit. Yet aggressive therapy with aspirin and clopidogrel combined may increase perioperative bleeding in some cases.3 These contrasting clinical problems underlie the need for a tailored approach to therapy and illustrate the requirement for consistent levels of platelet inhibition and a means to confirm individual response. Platelets adhere to sites of vascular injury; however, endothelial disruption is not a prerequisite. Atherosclerotic lesions are associated with impaired endothelial function and hence are …

Cyclooxygenase-1 haplotype modulates platelet response to aspirin

Summary.  Background: Aspirin (acetylsalicylic acid) irreversibly inhibits platelet cyclooxygenase (COX)‐1, the enzyme that converts arachidonic acid (AA) to the potent platelet agonist thromboxane (TX) A2. Despite clear benefit from aspirin in patients with cardiovascular disease (CAD), evidence of heterogeneity in the way individuals respond has given rise to the concept of ‘aspirin resistance.’Aims: To evaluate the hypothesis that incomplete suppression of platelet COX as a consequence of variation in the COX‐1 gene may affect aspirin response and thus contribute to aspirin resistance. Patients and methods: Aspirin response, determined by serum TXB2 levels and AA‐induced platelet aggregation, was prospectively studied in patients (n = 144) with stable CAD taking aspirin (75–300 mg). Patients were genotyped for five single nucleotide polymorphisms in COX‐1 [A‐842G, C22T (R8W), G128A (Q41Q), C644A (G213G) and C714A (L237M)]. Haplotype frequencies and effect of haplotype on two platelet phenotypes were estimated by maximum likelihood. The four most common haplotypes were considered separately and less common haplotypes pooled. Results: COX‐1 haplotype was significantly associated with aspirin response determined by AA‐induced platelet aggregation (P = 0.004; 4 d.f.). Serum TXB2 generation was also related to genotype (P = 0.02; 4 d.f.). Conclusion: Genetic variability in COX‐1 appears to modulate both AA‐induced platelet aggregation and thromboxane generation. Heterogeneity in the way patients respond to aspirin may in part reflect variation in COX‐1 genotype.