ADP receptors: inhibitory strategies for antiplatelet therapy

The interaction of adenosine-5'-diphosphate (ADP) with its platelet receptors (P2Y(1) and P2Y(12)) plays a very important role in thrombogenesis. The thienopyridine ticlopidine was the first specific antagonist of the platelet P2Y(12) ADP receptor to be tested in randomized clinical trials for the prevention of arterial thrombotic events. Although ticlopidine reduces the incidence of vascular events in patients at risk, it also unfortunately has some significant drawbacks: a relatively high incidence of toxic effects, which may be fatal in some cases; delayed onset of action; and a high interindividual variability in response. A second thienopyridine, clopidogrel, has superseded ticlopidine, because it is also an efficacious antithrombotic drug and is less toxic than ticlopidine. However, clopidogrel is not completely free from faults: severe toxic effects, albeit occurring much less frequently than with ticlopidine, may still complicate its administration to patients; the onset of pharmacologic action can be accelerated by the use of large loading doses, but may still not be optimal; the high interpatient variability in response remains an important issue. These concerns justify the continued search for agents that can further improve the clinical outcome of patients with atherosclerosis through greater efficacy and/or safety. A new thienopyridyl compound, prasugrel, which is characterized by higher potency and faster onset of action compared with clopidogrel, is currently under clinical evaluation. Two direct and reversible P2Y(12) antagonists, cangrelor and AZD6140, feature very rapid onset and reversal of platelet inhibition, which make them attractive alternatives to thienopyridines, especially when rapid inhibition of platelet aggregation or its quick reversal are required. Along with new the P2Y(12) antagonists, inhibitors of the other platelet receptor for ADP, the antagonists P2Y(1), are under development and may prove to be effective antithrombotic agents.     

Prasugrel: a novel thienopyridine antiplatelet agent. A review of preclinical and clinical studies and the mechanistic basis for its distinct antiplatelet profile

Prasugrel (CS-747, LY640315) is a novel member of the thienopyridine class of oral antiplatelet agents that includes ticlopidine and clopidogrel. Like other thienopyridines, prasugrel is a prodrug that is inactive in vitro. Prasugrel's distinct chemical structure permits efficient conversion to its active metabolite with a less rigorous dependence on specific cytochrome P-450 enzymes. Prasugrel is rapidly converted in vivo to an active metabolite (R-138727) that binds specifically and irreversibly to the platelet P2Y 12 purinergic receptor inhibiting ADP-mediated platelet activation and aggregation. Preclinical studies indicated that prasugrel is approximately 10- and 100-fold more potent at inhibiting ex vivo platelet aggregation and in vivo thrombus formation than clopidogrel and ticlopidine, respectively. Early clinical data in healthy subjects confirmed the greater platelet inhibition and consistency with prasugrel compared to clopidogrel. While the active metabolites of prasugrel and clopidogrel resulted in similar levels of platelet inhibition in vitro, the amount of each active metabolite generated in vivo was quite different-prasugrel (60 mg) resulting in an approximately 12-fold greater exposure to its active metabolite compared with clopidogrel (300 mg). This observation provides a mechanistic basis for the faster, greater, and more consistent inhibition of platelet aggregation observed with prasugrel. Clinical studies in patients with cardiovascular disease confirmed the potent antiplatelet effect of prasugrel compared with clopidogrel. Collectively, these phase 1/1b studies and a phase 2 study (JUMBO-TIMI 26) aided in dose selection for the recently completed phase 3 trial (TRITON-TIMI 38) in patients with acute coronary syndrome undergoing percutaneous coronary intervention.     

Intracellular signaling as a potential target for antiplatelet therapy

Three classes of inhibitors of platelet aggregation have demonstrated substantial clinical benfits. Aspirin acts by irreversibly inhibiting COX-1 and therefore blocking the synthesis of proaggregatory thromboxane A (2) (TxA(2)). The indirect acting (ticlopidine, clopidogrel, prasugrel) and the direct acting (ticagrelor) antagonists of P2Y(12) block the thrombus stabilizing activity of ADP. Parenteral GP IIb-IIIa inhibitors directly block platelet-platelet interactions. Despite well-established benefits, all antiplatelet agents have important limitations: increased bleeding and gastrointestinal toxicities (aspirin), high incidence of thrombotic thrombocytopenic purpura (ticlopidine), potentially nonresponders (clopidogrel), severe bleeding (prasugrel, GP IIb-IIIa antagonists) and "complicated" relationships with aspirin ticagrelor). In this chapter, we present the genetic and pharmacological evidence that supports the development and expectations associated with novel antiplatelet strategies directed at intrasignaling pathways.     

ADP Receptor Antagonism

ADP is one of the most important mediators of both physiologic hemostasis and thrombosis. Development and utilization of agents that block ADP receptors on the platelet membrane, namely thienopyridines, has represented a major advancement for treatment of patients undergoing percutaneous coronary interventions and those with acute coronary syndromes. Currently, clopidogrel, a second-generation thienopyridine that inhibits the ADP P2Y(12) receptor, represents the treatment of choice, in addition to aspirin, for the prevention of stent thrombosis. Further, long-term adjunctive use of this ADP P2Y(12) receptor antagonist is also associated with improved clinical outcomes in high-risk patients, and represents the standard of care for these patients. Despite the unambiguous clinical benefit associated with clopidogrel, accumulating experience with this drug has also led to identification of some of its drawbacks, which are related to inadequate platelet inhibition with standard dosage regimens as well as to its irreversible antiplatelet effects. This has led to the questioning of currently recommended clopidogrel dosage regimens as well as to the development of novel and more potent ADP P2Y(12) receptor antagonists, some of which are also reversible agents. Numerous studies are currently ongoing with the objective of demonstrating how more potent platelet inhibition using higher loading and maintenance dose regimens of clopidogrel or novel ADP P2Y(12) receptor antagonists - such as prasugrel, ticagrelor (AZD 6140) and cangrelor - will affect clinical outcomes. This article reviews the current knowledge of platelet ADP P2Y(12) receptor antagonism and the projected developments in this field.     

The influence of P2Y12 receptor deficiency on the platelet inhibitory activities of prasugrel in a mouse model: evidence for specific inhibition of P2Y12 receptors by prasugrel

Prasugrel is a novel orally active thienopyridine with faster, higher and more reliable inhibition of platelet aggregation than clopidogrel reflecting its metabolism in vivo to an active metabolite with selective P2Y(12) antagonistic activity. Several lines of evidence support the contention that prasugrel provides selective P2Y(12) receptor antagonistic activity. To date, however, direct evidence of P2Y(12) specific action by prasugrel in vivo is limited. In the present study, effects of prasugrel on ex vivo platelet aggregation were examined in wild type (WT) and P2Y(12)(-/-) mice. In WT mice, prasugrel showed platelet inhibition that was 8.2 times more potent than clopidogrel. In P2Y(12)(-/-) mice, ADP induced platelet aggregation was minimal, and its extent was similar to that in prasugrel-treated WT mice. In addition, no further inhibition of platelet aggregation was observed after administration of prasugrel to P2Y(12)(-/-) mice. Furthermore, prasugrel-treated WT mice showed similar aggregation patterns using collagen- and murine PAR-4 agonist peptide to those of P2Y(12)(-/-) mice treated with vehicle or prasugrel. Overall, these results clearly provide additional in vivo evidence that prasugrel has selective P2Y(12) antagonistic activity.     

AZD6140

Oral antiplatelet therapy with P2Y(12) receptor blockers (especially clopidogrel) is the current choice of treatment during acute coronary syndromes and percutaneous interventions. To address the various limitations of thienopyridine therapy (including response variability and non-responsiveness) a novel drug, AZD6140, is under clinical development. AZD6140 is an oral and reversible P2Y(12) receptor blocker that does not require hepatic conversion to an active metabolite and produces an overall superior ADP-induced platelet inhibition with less response variability than clopidogrel. It has fast onset and offset actions that may be advantageous in patients who may have to undergo immediate surgery.     

Platelet P2Y12 receptor inhibition by thienopyridines: status and future

Thienopyridines have a well-established role in the treatment of coronary artery disease, especially in the setting of acute coronary syndromes and percutaneous coronary interventions. Ticlopidine, the first FDA-approved thienopyridine, was shown to be effective in reducing coronary events in high risk patients, but the original enthusiasm was hampered by concerns about its serious bone marrow toxicity. Clopidogrel a second generation thienopyridine with lesser side effects, is not only at least as effective as ticlopidine, but in combination with a low dose of aspirin, has been demonstrated to reduce the risk of major cardiovascular events in acute coronary syndrome patients in large-scale, randomised trials. Recent studies have highlighted major flaws in clopidogrel pharmacokinetics due to its delayed onset of action, and much attention has been devoted to the phenomenon of clopidogrel ‘resistance’. Among the novel, third generation thienopyridines, prasugrel as compared to clopidogrel has demonstrated lower inter-patient response variability and a reduced incidence of ischaemic events, but at an increased risk of major bleeding. Currently, several studies are continuing to test new direct P2Y12 receptor antagonists, such as cangrelor and AZD6140, characterised by a faster reversal of platelet inhibition.     

Optimizing platelet P2Y12 inhibition for patients undergoing PCI

Guidelines recommend that dual antiplatelet therapy using aspirin and clopidogrel should be administered to the majority of patients with acute coronary syndromes, including those undergoing percutaneous coronary intervention (PCI). However, the results of a large randomized, placebo-controlled study suggest that a 300-mg loading dose of clopidogrel must be administered at least 15 h prior to PCI in order to achieve a significant reduction in peri-PCI thrombotic events. Other data suggest that 2 h of pretreatment may be sufficient if a 600-mg loading dose is used. Since it is often difficult to achieve an adequate pretreatment goal with clopidogrel in clinical practice, more rapid achievement of platelet P2Y(12) inhibition may improve patient outcomes. Prasugrel, [6-[2-(3,4-diflurophenyl) cyclopropyl1-1-y1] amino-2-propylthio-9-D-ribofuranosyl-9H-purine (AZD6140), and cangrelor are platelet P2Y(12) receptor antagonists currently in development that offer faster acting inhibition of adenosine diphosphate (ADP)--induced platelet aggregation. These agents act upon the same platelet receptor as clopidogrel, but are distinguished by their routes of administration, reversibility, and pharmacodynamic properties. Prasugrel is an orally administered agent that provides faster, higher, and more consistent inhibition of platelet aggregation than clopidogrel. The results of Phase II testing suggest that the risk of bleeding is similar in prasugrel- and clopidogrel-treated patients. AZD6140 is another orally administered platelet inhibitor with rapid and reversible action. Again, Phase II testing suggests similar bleeding risk for clopidogrel. Preliminary evidence suggests that clinical outcomes may be better in prasugrel- and AZD6140-treated patients than in clopidogrel-treated patients. Cangrelor is an intravenously administered, reversible, short-acting agent with a rapid onset of activity. Bleeding risk and clinical outcomes data are similar in cangrelor- and abciximab-treated patients. The results of ongoing Phase III clinical trials involving more than 40,000 patients will demonstrate whether these agents fulfill their potential to improve outcomes in PCI-treated patients by providing faster, higher, and more consistent inhibition of platelet aggregation.     

Future prospects in anti-platelet therapy: a review of potential P2Y12 and thrombin receptor antagonists

Atherothrombosis is an acute complication that develops on the surface of a ruptured atheromatous plaque or as a consequence of endothelial erosion that may cause myocardial infarction or ischemic stroke. Anti-platelet therapy has been highly effective at reducing atherothrombotic risk. However, patients continue to experience thrombotic events despite the use of agents such as aspirin and clopidogrel. Many of these events occur, in part, because of the inadequate response to these drugs. This has prompted the pursuit of novel agents with aspirations of optimizing anti-platelet therapy. New opportunities have emerged to address the deficiencies in current anti-platelet agents. Among these are thrombin receptor antagonists, such as SCH530348 and P2Y12 receptor antagonists, such as prasugrel, cangrelor, and AZD6140. The patents describe these novel compounds and compositions, their ability to inhibit platelet activation and/or aggregation and their use in the treatment of atherothrombotic diseases. These drugs have pharmacologic properties that translate into increased potency, more rapid onset of action, and less variability in response compared to standard therapy. In this review, we highlight the current data on these potential drugs and the role they could play in atherothrombotic disease.     

Prasugrel versus Clopidogrel Antiplatelet Therapy after Acute Coronary Syndrome

Antithrombotic therapy is imperative in the management of patients presenting with an acute coronary syndrome (ACS). The combination of antiplatelet therapy in conjunction with antithrombotic therapy has become the standard of care in improving the morbidity and mortality of patients with an ACS and in reducing ischemic complications of percutaneous coronary intervention. Patients with an ACS are at increased risk for a recurrent event, both in-hospital and for several months afterward. Secondary prevention to reduce these events is accomplished through the establishment of appropriate medical therapy. Dual antiplatelet therapy with aspirin and adenosine 5'-diphosphate P2Y(12) receptor blockers such as ticlopidine or clopidogrel are integral components of this regimen; however, both of these thienopyridines have a relatively slow onset of action and variable bioavailability. Prasugrel, a third-generation thienopyridine approved by the US FDA in 2009, has a more rapid onset of platelet inhibition than clopidogrel and ticlopidine because of increased efficiency of prodrug-to-active metabolite conversion. The result is higher and less variable concentration of the active metabolite within 60 minutes following oral dosing. Phase II and III trials assessing the safety and efficacy of prasugrel have been completed, including JUMBO-TIMI 26, PRINCIPLE-TIMI 44, and TRITON-TIMI 38. These trials demonstrated greater inhibition of platelet aggregation and lower rates of the composite endpoint of death, non-fatal myocardial infarction, and stroke compared with clopidogrel. However, major bleeding occurred more frequently with prasugrel treatment than with clopidogrel. This review highlights the current state of evidence-based antiplatelet therapy and provides guidance on appropriate use of prasugrel in cardiovascular medicine.     

Thienopyridines and Other ADP-Receptor Antagonists

Platelet P2Y12 receptor inhibition plays a pivotal role in preventing thrombotic vascular events in patients with ACS and in patients undergoing percutaneous coronary intervention (PCI). Among the P2Y12 receptor inhibitors, the group of thienopyridines include ticlopidine, clopidogrel and prasugrel, all of which are orally administered prodrugs leading to irreversible P2Y12 receptor inhibition. Non-thienopyridine derivatives including ticagrelor, cangrelor and elinogrel do not require metabolic activation and lead to a reversible P2Y12 receptor inhibition in contrast to thienopyridines. The extend of platelet inhibition is subject to the administered antiplatelet agent and influenced by individual genetic and clinical factors. Insufficient platelet inhibition, termed high platelet reactivity (HPR) is associated with an increased risk for ischemic events after PCI whereas exceeding platelet inhibition results in an increased bleeding risk. Pharmacologic properties and clinical outcome data differ substantially between the existing P2Y12 receptor inhibitors. Whether individualized antiplatelet treatment incorporating different P2Y12 receptor inhibitors improves patients' clinical outcomes warrants further investigation.     

血小板P2Y12受体拮抗剂临床研究进展

P2Y12受体拮抗剂是一类作用于血小板P2Y12受体、抑制血小板聚集的药物,临床上主要用于预防和治疗心血管疾病的血栓事件。氯吡格雷是目前临床上首选的双重抗血小板药物之一,但其疗效受限于CYP2C19基因的多态性、与质子泵抑制剂(PPIs)的相互作用和起效缓慢等。目前,一些新型P2Y12受体拮抗剂类抗血小板药物(如普拉格雷、替卡格雷等)已经进入临床,几项大型临床试验对其疗效和安全性进行了评价。本文对比了新型P2Y12受体拮抗剂与氯吡格雷在药理学、药代动力学、有效性和安全性方面的差异,并探讨其临床应用,为临床合理用药提供参考。     

Prasugrel

Clinical trials have demonstrated the superior clinical efficacy of dual antiplatelet therapy with a thienopyridine (a P2Y(12) receptor blocker) and aspirin (COX-1 inhibitor) in patients undergoing stenting as well as patients with acute coronary syndromes. However, clopidogrel treatment is associated with a wide response variability and non-responsiveness in selected patients. The latter phenomenon is linked to the occurrence of recurrent ischaemic events including stent thrombosis in the recent studies. Prasugrel is a new thienopyridine derivative that produces more potent platelet inhibition and a rapid onset of action that is associated with irreversible P2Y(12) receptor blockade. The latter properties of prasugrel may provide a superior alternative to clopidogrel, with less response variability and a decreased prevalence of non-responsiveness.     

The effect of selective antihypertensive drugs on the vascular remodeling-associated hypertension: insights from a profilin1 transgenic mouse model

Thienopyridines (ticlopidine, clopidogrel, and prasugrel) require in vivo metabolism to exhibit a critical thiol group in the active form that binds to the P2Y12 platelet receptor to inhibit platelet activation. We hypothesized that formation of thienopyridine-derived nitrosothiols (ticlopidine-SNO, clopidogrel-SNO, and prasugrel-SNO) occurs directly from the respective parent drug. Pharmaceutical-grade thienopyridine (ticlopidine, clopidogrel chloride, clopidogrel sulfate, clopidogrel besylate, or prasugrel) was added to nitrite in aqueous solution to form the respective thienopyridine-SNO (Th-SNO). An isolated aortic ring preparation was used to test vasoactivity of the Th-SNO derivatives. Increasing nitrite availability resulted in increased Th-SNO formation for all drugs (other than ticlopidine). Th-SNO induced significant endothelium-independent relaxation of preconstricted aortic rings. Clopidogrel-chloride-SNO displayed rapid-release kinetics in a chemical environment, which was reflected by immediate and transient vasorelaxation when compared with the SNO derivatives of the other thienopyridines. Accounting for differences in yield, clopidogrel-chloride-SNO exhibited the greatest propensity to immediately relax vascular tissue. Th-SNO derivatives exhibit nitrovasodilator properties by supplying NO that can directly activate vascular soluble guanylate cyclase to induce vasorelaxation. Differences in SNO yield and vasoactivity exist between thienopyridine preparations that might be important to our understanding of the direct pharmacological effectiveness of thienopyridines on vascular and platelet function.     

Platelet hyperreactivity and stent thrombosis in patients undergoing coronary stenting

Stent thrombosis (ST) is a rare but very serious event complicating percutaneous coronary intervention (PCI) procedures. Both procedure- and patient-related factors, including inadequate platelet inhibition are well known predictors of ST. According to the present guidelines, a dual antiplatelet treatment regimen consisting of aspirin and a P2Y12 receptor inhibitor such as clopidogrel, prasugrel or ticagrelor is routinely administered to ACS patients and to patients undergoing PCI in order to prevent thrombotic vessel occlusions. In recent years, evidence has grown that patients showing high on-treatment platelet reactivity (HPR) under clopidogrel intake exhibit a higher risk for the occurrence of ischemic events including ST. For assessing HPR, different platelet function assays are currently available and have already found their way into routine clinical practice in several centers. Along with this development, more potent P2Y12 receptor inhibitors like prasugrel and ticagrelor are substitutes for clopidogrel in specific circumstances such as in ACS patients or in patients who do not adequately respond to standard clopidogrel treatment. Utilizing platelet function monitoring, patients showing HPR can be identified and an optimized antiplatelet treatment regime can be tailored for these patients. This review paper aims to summarize the important facts in relation to ST and antiplatelet therapy with a particular focus on P2Y12 receptor inhibition and its ex vivo assessment in patients undergoing coronary stent placement.     

Cangrelor in percutaneous coronary intervention

Cangrelor is a novel, intravenous P2Y₁₂ receptor antagonist in development for use in percutaneous coronary intervention. Currently in Phase III testing, the reversible platelet inhibitor provides several inherent advantages over other P2Y₁₂ receptor antagonists in this setting for the prevention of adverse cardiac events. Unlike the class of thienopyridines (ticlopidine, clopidogrel and potentially soon to be available, prasugrel), cangrelor has nearly immediate onset after a bolus dose and a short half-life, and achieves maximal inhibition of ADP-mediated platelet function. Cangrelor’s distinct mechanism of action allows for intravenous administration and avoids both hepatic and renal metabolism. These unique characteristics make cangrelor a promising agent for use in cardiovascular patients undergoing percutaneous coronary intervention.     

Impact of genetic polymorphisms and drug-drug interactions on clopidogrel and prasugrel response variability

Thienopyridine antiaggregating platelet agents (clopidogrel and prasugrel) act as irreversible P2Y12 receptor inhibitors. They are used with aspirin to prevent thrombotic complications after an acute coronary syndrome or percutaneous coronary intervention. A large interindividual variability in response to clopidogrel and to a lesser extent to prasugrel is observed and may be related to their metabolism. Clopidogrel and prasugrel are indeed prodrugs converted into their respective active metabolites by several cytochromes P450 (CYPs). Besides clopidogrel inactivation (85%) by esterases to the carboxylic acid, clopidogrel is metabolized by CYPs to 2-oxo-clopidogrel (15%) and further metabolized to an unstable but potent platelet-aggregating inhibitor. Prasugrel is more potent than clopidogrel with a better bioavailability and lower pharmacodynamic variability. Prasugrel is completely converted by esterases to an intermediate oxo-metabolite (R-95913) further bioactivated by CYPs. Numerous clinical studies have shown the influence of CYP2C19 polymorphism on clopidogrel antiplatelet activity. Moreover, unwanted drug-drug pharmacokinetic interactions influencing CYP2C19 activity and clopidogrel bioactivation such as with proton pump inhibitors remain a matter of intense controversy. Several studies have also demonstrated that CYP3A4/5 and CYP1A2 are important in clopidogrel bioactivation and should also be considered as potential targets for unwanted drug-drug interactions. Prasugrel bioactivation is mainly related to CYP3A4 and 2B6 activity and therefore the question of the effect of drug-drug interaction on its activity is open. The purpose of this review is to critically examine the current literature evaluating the influence of genetic and environmental factors such as unwanted drug-drug interaction affecting clopidogrel and prasugrel antiplatelet activity.     

Direct formation of thienopyridine-derived nitrosothiols--just add nitrite!

Thienopyridines (ticlopidine, clopidogrel and prasugrel) are pro-drugs that require metabolism to exhibit a critical thiol group in the active form that binds to the P2Y?? receptor to inhibit platelet activation and prevent thrombus formation in vivo. We investigated whether these thienopyridines participate in S-nitrosation (SNO) reactions that might exhibit direct anti-platelet behaviour. Optimum conditions for in vitro formation of thienopyridine-SNO formation were studied by crushing ticlopidine, clopidogrel or prasugrel into aqueous solution and adding sodium nitrite, or albumin-SNO. Ozone-based chemiluminescence techniques were utilised to specifically detect NO release from the SNO produced. Effect on agonist-induced platelet aggregation was monitored using light transmittance in a 96 well microplate assay. Pharmaceutical grade preparations of ticlopidine, clopidogrel and prasugrel were found to exhibit significant free thiol and formed SNO derivatives directly from anionic nitrite in water under laboratory conditions without the need for prior metabolism. Thienopyridine-SNO formation was dependent on pH, duration of mixing and nitrite concentration, with prasugrel-SNO being more favourably formed. The SNO moiety readily participated in trans-nitrosation reactions with albumin and plasma. Prasugrel-SNO showed significantly better inhibition of platelet aggregation compared with clopidogrel-SNO, however when compared on the basis of SNO concentration these were equally effective (IC??=7.91 ± 1.03 v/s 10.56 ± 1.43 μM, ns). Thienopyridine-derived SNO is formed directly from the respective base drug without the need for prior in vivo metabolism and therefore may be an important additional contributor to the pharmacological effectiveness of thienopyridines not previously considered.     

新型P2Y12受体抑制剂替格瑞洛临床研究进展

抗血小板药物是急性冠脉综合征（Acute Coronary Syndrome,ACS）治疗的基石,对防治心肌缺血和介入并发症是有益的。目前治疗ACS和经皮冠状动脉介入治疗（percutaneous coronary intervention,PCI）指南推荐使用的口服抗血小板药物包括氯吡格雷、替格瑞洛、普拉格雷联合阿司匹林双重抗血小板治疗预防复发性缺血事件。本文对新型P2Y12受体抑制剂替格瑞洛的药代动力学和药效学特点以及在ACS患者中的循证医学证据作一介绍。     

Comparative pharmacokinetics and pharmacodynamics of platelet adenosine diphosphate receptor antagonists and their clinical implications

Over the last two decades or more, anti-platelet therapy has become established as a cornerstone in the treatment of patients with ischaemic cardiovascular disease, since such drugs effectively reduce arterial thrombotic events. The original agent used in this context was aspirin (acetylsalicylic acid) but, with the advent of adenosine diphosphate (ADP) receptor antagonists, the use of dual anti-platelet therapy has resulted in further improvement in cardiovascular outcomes when compared with aspirin alone. The first group of platelet ADP receptor antagonists to be developed was the thienopyridine class, which comprise inactive pro-drugs that require in vivo metabolism to their active metabolites before exerting their inhibitory effect on the P2Y(12) receptor. Clopidogrel has been the principal ADP receptor antagonist in use over the past decade, but is limited by variability in its in vivo inhibition of platelet aggregation (IPA). The pharmacokinetics of clopidogrel are unpredictable due to their vulnerability to multiple independent factors including genetic polymorphisms. Expression of the 3435T/T genetic variant encoding the MDR1 gene for the P-glycoprotein efflux transporter results in a significantly reduced maximum drug concentration and area under the plasma concentration-time curve as intestinal absorption of clopidogrel is reduced; and the expression of the mutant *2 allele of CYP2C19 results in similar pharmacokinetic effects as the two cytochrome P450 (CYP)-mediated steps required for the production of the active metabolite of clopidogrel are impaired. These variable pharmacokinetics lead to erratic pharmacodynamics and cannot reliably be overcome with increased dosing. Both prasugrel, a third-generation thienopyridine, and ticagrelor, a cyto-pentyl-triazolo-pyrimidine, have more predictable pharmacokinetics and enhanced pharmacodynamics than clopidogrel. Neither appears to be affected by the same genetic polymorphisms as clopidogrel; prasugrel requires only a single CYP-mediated step to produce its active metabolite and ticagrelor is not a pro-drug. Enhanced IPA by both prasugrel and ticagrelor is achieved at the expense of increased major bleeding, although this is partially mitigated in the case of ticagrelor due to its reversible IPA. However, the reversible binding of ticagrelor to the P2Y(12) receptor requires a twice-daily dosing regimen. Due to limited data from clinical studies, the use of prasugrel is currently restricted to individuals undergoing percutaneous coronary intervention who are ≤75 years old and have a body weight ≥60 kg. The clinical data for ticagrelor are more comprehensive and this drug therefore has a place in the management of patients with acute coronary syndrome at moderate-to-high risk of ischaemic events, irrespective of treatment strategy. Here we review in detail the pharmacokinetics and pharmacodynamics of clopidogrel, prasugrel and ticagrelor, and explore the implications of the differences in these parameters for their clinical use.