Prothrombotic determinants of coronary atherothrombosis

An acute coronary syndrome (ACS) is the clinical manifestation of a thrombotic event occurring within a coronary artery narrowed by atherosclerosis. This atherothrombotic event is thought to occur following destabilizing changes within the atherosclerotic plaque, rendering it a surface on which thrombus can develop. The development and progression of this thrombus are determined by deleterious perturbations in the hemostatic equilibrium within the local environment of the plaque that favor thrombosis. Major risk factors for the development of atherosclerotic disease have been clearly established and are targets of aggressive modification in an effort to impede the development or slow the progression of disease. While conferring an increased risk for plaque development, these and other risk factors also establish a prothrombotic milieu within the microenvironment of the atherosclerotic plaque that favors thrombosis. This review seeks to address these traditional and emerging risk factors from the context of their pathologic effects on local hemostatic balance. Aggressive risk factor modification not only reduces atherosclerotic disease development and progression, but also ameliorates the prothrombotic state, and ultimately serves to reduce atherothrombotic events.     

Pathogenesis and early management of non-ST-segment elevation acute coronary syndromes

NSTE ACS is a clinically significant problem. Endothelial dysfunction triggered by traditional cardiovascular risk factors (and perhaps by other as yet unidentified risks) in the susceptible host leads to the formation and development of atherosclerotic plaque. Inflammatory mediators and mechanical stresses contribute to plaque rupture by disrupting the protective fibrous cap. In about 25% of patients who have ACS, typically those who are younger, female, or smokers, plaque erosion seems to be the main underlying pathologic mechanism. Endothelial alteration, inflammation,or exposure of the lipid core results in the release of TF, vWF, and PAF. The release of these factors leads to platelet activation and aggregation as well as to the formation of a fibrin clot, resulting in arterial thrombosis that occludes the vessel. A variety of factors, including circulating catecholamines, LDL levels, blood glucose levels, and systemic thrombogenic factors, can affect the extent and stability of the thrombus, thereby determining whether the occlusion is complete and fixed, labile and nonocclusive (NSTE ACS),or clinically silent resulting in a mural thrombus and plaque growth. The acute treatment of NSTEACS is directed at interrupting the prothrombotic environment surrounding the ruptured plaque; thus, antiplatelet agents such as aspirin, clopidogrel, and glycoprotein IIb/IIla receptor antagonists,as well as anticoagulants such as heparin, are the mainstays of early therapy.     

Physiopathology of unstable angina

The major risk of atherosclerotic disease is the occurrence of an acute coronary syndrome. The pathogenesis of instable angina involves the formation of an arterial thrombus as a consequence of the rupture of an atheromatous plaque. This risk of plaque rupture appears to depend on plaque morphology rather than plaque size or severity of stenosis. Ratio of lipid core to fibrous determined by the balance between smooth muscle cells proliferation and extracellular matrix synthesis stabilizing the plaque and macrophages which degrade collagen, determine the plaque vulnerability. The fibrous cap weakness leads to the plaque activation, plaque fissure or erosion activating a thrombotic cascade. A general inflammation or prothrombotic states are probably involved suggesting the need for a systemic therapeutic in addition with the treatment of the culprit lesion.     

Thrombosis formation on atherosclerotic lesions and plaque rupture

Atherosclerosis is a silent chronic vascular pathology that is the cause of the majority of cardiovascular ischaemic events. The evolution of vascular disease involves a combination of endothelial dysfunction, extensive lipid deposition in the intima, exacerbated innate and adaptive immune responses, proliferation of vascular smooth muscle cells and remodelling of the extracellular matrix, resulting in the formation of an atherosclerotic plaque. High‐risk plaques have a large acellular lipid‐rich necrotic core with an overlying thin fibrous cap infiltrated by inflammatory cells and diffuse calcification. The formation of new fragile and leaky vessels that invade the expanding intima contributes to enlarge the necrotic core increasing the vulnerability of the plaque. In addition, biomechanical, haemodynamic and physical factors contribute to plaque destabilization. Upon erosion or rupture, these high‐risk lipid‐rich vulnerable plaques expose vascular structures or necrotic core components to the circulation, which causes the activation of tissue factor and the subsequent formation of a fibrin monolayer (coagulation cascade) and, concomitantly, the recruitment of circulating platelets and inflammatory cells. The interaction between exposed atherosclerotic plaque components, platelet receptors and coagulation factors eventually leads to platelet activation, aggregation and the subsequent formation of a superimposed thrombus (i.e. atherothrombosis) which may compromise the arterial lumen leading to the presentation of acute ischaemic syndromes. In this review, we will describe the progression of the atherosclerotic lesion along with the main morphological characteristics that predispose to plaque rupture, and discuss the multifaceted mechanisms that drive platelet activation and subsequent thrombus formation. Finally, we will consider the current scientific challenges and future research directions.     

Platelet function in intravascular device implant-induced intimal injury

Platelets are involved in the rapid response to intimal injury in which the underlying thrombogenic subendothelial matrix is exposed, leading to platelet adhesion, secretion, aggregation, and initiation of arterial thrombus formation. The platelet activation pathway involves a multistep process of distinct receptors, adhesive ligands, release of mediators, receptor-ligand interactions, and recruitment of more platelets to the site of injury. The balance between blood fluidity and intimal injury-induced arterial thrombosis is maintained by an intact endothelium that controls vessel tone, synthesizes inhibitors and activators of platelet function, and thereby allows the free flow of blood cell elements. An intravascular device implant causes intimal injury, which is accompanied by decreased antithrombotic potential of the endothelial cells and increased release of prothrombotic substances. A trigger for the formation of intimal injury-induced thrombus formation may be due to endothelial dysfunction and/or the loss of endothelial cell barrier between the subendothelial matrix and flowing blood, which allows initiation of platelet activation. A thorough understanding of the platelet regulatory mechanisms is necessary to develop effective antiplatelet therapy to prevent the complications of thrombosis following revascularization procedures using percutaneous coronary intervention. This review summarizes the temporal events following intravascular device implants, including endothelial cell injury, platelet activation, receptor-mediated signaling events, platelet-rich thrombus formation, and the redundant platelet pathways, all of which may be potential therapeutic targets.     

Evolving Concepts in the Triad of Atherosclerosis,Inflammation and Thrombosis

Recent developments into antherothrombosis, the leading cause of morbidity and mortality in Western Society, may help to change our treatment strategy to a more casual approach. The composition of the atherosclerotic plaque, rather than the percent stenosis, appears to be a critical predictor for both risk of plaque rupture and subsequent thrombogenicity. A large lipid core, rich in tissue factor (TF) and inflammatory cells including macrophages, and a thin fibrous cap with compromise of its structural integrity by matrix degrading enzymes, such as metalloproteinases (MMPs), render a lesion susceptible to rupture and subsequent acute thrombosis. Thrombosis may lead to a complete occlusion or, in the case of mural thrombus or intraplaque hemorrhage, to plaque progression. Disruption of a vulnerable or unstable plaque (type IV and Va lesions of the AHA classification) with a subsequent change in plaque geometry and thrombosis may result in an acute coronary syndrome. The high-risk plaque tend to be relatively small, but soft or vulnerable to "passive" disruption because of high lipid content. Inflammatory processes are important components of all stages of atherosclerotic development, including plaque initiation and disruption. As such the early steps in atherosclerotic lesion formation are the over expression of endothelial adhesive protein (i.e. selectins, VCAM and ICAM), chemotactic factors (MCP-1), growth factors (M-CSF), and cytokines (IL-2) that will facilitate the recruitment, internalization and survival of blood-borne inflammatory cells into the vascular wall. Macrophages, following what appears to be a defense mission by protecting the vessel wall from excess lipid accumulation, may eventually undergo apoptosis with release of MMPs and TF. Specific cell recruitment in the vessel wall and build-up of the extracellular matrix are coordinated by a wide variety of stimulators and inhibitors. Active interaction of immune competent cells within the atherosclerotic lesions appears to play a pivotal role in the control of atherosclerotic plaque evolution and, therefore, deserves particular attention from the research community with the ultimate goal of improving preventive and therapeutic medical approaches. Inflammation, thrombosis and atherosclerosis are interdependent and define a triad within the complex pathogenic process of atherothrombosis.     

Tissue factor in acute coronary syndromes

Thrombosis at the site of atherosclerotic plaque disruption is the principal cause of acute coronary syndromes. The severity of the clinical consequences is determined by the extent and the progression of the thrombus that are caused by local and systemic factors. In atherosclerotic lesions mediators induce tissue factor (TF) in macrophages, smooth muscle cells, and endothelial cells. Procoagulant microparticles in the lipid core further enhance the thrombogenicity of the plaque. In addition, in acute coronary syndromes circulating monocytes and microparticles express TF and, thereby, contribute to systemic procoagulant activity. As a regulatory mechanism surface-bound, endogenous tissue factor pathway inhibitor-1 (TFPI) inhibits TF activity by translocation of the quaternary complex TF-FVIIa-FXa-TFPI into glycosphingolipid-rich microdomains more efficiently than exogenously added TFPI. This inhibition occurs not only in endothelial cells but also on circulating monocytes and presumably microparticles. Because therapeutic thrombolysis in acute myocardial infarction degrades TFPI, a prothrombotic state due to unopposed TF activity may occur. Several studies have demonstrated a contribution of local and bloodborne TF to thrombus formation; a direct relationship with the clinical outcome, however, awaits further studies. This article discusses the current understanding of the role of TF and its regulation by TFPI in acute coronary syndromes.     

Thrombus formation on atherosclerotic plaques: pathogenesis and clinical consequences

PURPOSE: To describe the characteristics of thrombus formation on atherosclerotic plaques, the clinical expression of atherothrombosis in vascular disease, and some of the most recent therapeutic approaches in cardiovascular disease. DATA SOURCES: MEDLINE search for English-language articles on thrombosis and atherosclerosis published up to January 2000. Abstracts of recent international meetings on new aspects of thrombus formation and new therapeutic options were reviewed, and references from identified articles were selected and reviewed. STUDY SELECTION: Experimental, basic, clinical, and epidemiologic studies related to the pathophysiology of thrombosis on atherosclerotic lesions. Therapeutic approaches were obtained from experimental studies and large clinical investigations. DATA EXTRACTION: Arterial vessel wall substrate, rheologic conditions, and blood thrombogenicity influence the process of thrombus formation in arteries. Thrombus formation on disrupted atherosclerotic plaques or arterial erosions frequently causes acute coronary syndromes. Severe atherosclerosis of the aorta has been identified as an important morphologic indicator of an increased risk for thromboembolism. Current antithrombotic therapies available as long-term treatment for patients with cardiovascular disease are often not effective enough to prevent acute thrombotic events and deterioration of atherosclerosis. DATA SYNTHESIS: Improved understanding of the pathophysiology of thrombus formation on atherosclerotic plaques has led to the development of new therapeutic approaches. Glycoprotein IIb/IIIa, tissue factor, factor Xa, and thrombin inhibitors as well as combined antithrombotic therapy, such as aspirin plus a thienopyridine plus warfarin, are being evaluated as new possible options for the treatment of arterial thrombosis. CONCLUSIONS: Long-term treatment with potent antithrombotic drugs, such as tissue factor or factor Xa inhibitors, that effectively block thrombosis without causing bleeding complications could help reduce death from cardiovascular disease.     

Hyperlipidemia promotes thrombosis after injury to atherosclerotic vessels in apolipoprotein E-deficient mice

The increased risk of hyperlipidemia on the development of complications of atherosclerosis is well established. Cholesterol-lowering therapies lead to a decrease in the incidence of vascular thrombotic events that is out of proportion to the reduction in plaque size. This suggests that the occurrence of acute thrombosis overlying a disrupted plaque is influenced by changes in lipid levels. The influence of acute hyperlipidemia on the development of thrombosis overlying an atherosclerotic plaque in vivo has not been extensively studied. We used a murine model of vascular injury induced by a photochemical reaction to elicit thrombus formation overlying an atherosclerotic plaque. Fifteen apolipoprotein E-deficient mice were maintained on normal chow until the age of 30 weeks. Five days before the induction of thrombosis, 6 mice were started on a high fat diet, and 9 mice were continued on normal chow. Mice then underwent photochemical injury to the common carotid artery immediately proximal to the carotid bifurcation, where an atherosclerotic plaque is consistently present. Mice maintained on normal chow developed occlusive thrombi, determined by cessation of blood flow, 44+/-5 minutes (mean+/-SEM) after photochemical injury, whereas mice fed a high fat chow developed occlusive thrombosis at 27+/-3 minutes (P<0.02). Histological analysis confirmed the presence of acute thrombus formation overlying an atherosclerotic plaque. These studies demonstrate a useful model for assessing the determinants of thrombosis in the setting of atherosclerosis and show that acute elevations in plasma cholesterol facilitate thrombus formation at sites of atherosclerosis after vascular injury.     

Current perspectives in the treatment of thrombotic disorders

New trends in antithrombotic therapy should reside in a better adaptation, both in potency and in target to the involved thrombogenic mechanism. Thrombogenesis as hemostasis is the result of cooperation between plasma coagulation factors and platelet functions, and these two systems are themselves in equilibrated antagonism with the vessel wall, mainly endothelial cells. These triangular relations between coagulation factors, platelet functions, and endothelial cell reactivity are quantitatively regulated by flow conditions. The relative importance of each of these protagonists in the genesis of vascular thrombosis varies along the vascular tree, mainly due to changes in flow characteristics, and explain the usual separation between venous and arterial thrombosis: venous thrombosis involves mainly coagulation factors and the vascular fibrinolytic response whereas arterial thrombosis involves the thromboresistant characteristics of the endothelial cell membrane and platelet functions. The real blood flow characteristics may be altered by local disease and influences the relative involvement of coagulation and fibrinolytic factors, platelet functions, and endothelial cells. Prevention of thrombosis must take into account all these phenomena and must be targeted to the predominant factor or factors. Depending on the local conditions, the therapeutical goal can be: (1) limitation of platelet functions or coagulation factors; (2) stimulation of thromboresistant properties of the endothelium (mainly its profibrinolytic characteristics); and (3) modification of the flow conditions. Several targets can be associated: the level of inhibition or stimulation of a function depends on the dysequilibrium, and efficient prevention does not always require complete inhibition of a function. Once a thrombus has developed, antithrombotic treatment will prevent its extension, and thrombolytic therapy will try to restore vascular patency. Once patency has been restored antithrombotic therapy is still needed to prevent recurrence of the thrombus. Even if the main targeting is on platelets, the choice in the molecule to be clinically used must be defined by the function of the platelet involved: thrombogenesis or vasospasm, and even by the metabolic pathway predominantly activated. In coagulation strategy, differences must be drawn between antithrombotic therapy directed against thrombin formation, complexes of coagulation, free enzymes or activation phases. In thrombolytic therapy all procedural uses of extrinsic thrombolytic agents (natural, modified, or artificial), increase of susceptibility to endogenous thrombolytic systems, and stimulation of endogenous thrombolytic activity do not bear the same efficiency. As a consequence, the responsibility for clinical use of new molecules with more specific activity can allow more efficient antithrombotic therapy directed at the condition of an indication targeted at the exact mechanisms involved.(ABSTRACT TRUNCATED AT 400 WORDS)     

组织因子与急性冠脉综合征研究进展

组织因子作为FⅦ/FⅦa的细胞膜表面受体,是外源性凝血系统的关键因子,组织因子通过介导凝血激活形成血栓。动脉粥样硬化斑块破裂处血栓形成是急性冠脉综合征的主要原因,其临床后果的严重性决定于血栓的范围和进展。急性冠脉综合征时循环单核细胞和微颗粒表达组织因子,促进全身的促凝活性。动脉粥样硬化斑块中巨噬细胞、平滑肌细胞、血管内皮细胞表达组织因子,不稳定性斑块中组织因子表达和活性较稳定性斑块更高。组织因子通路抑制物是内源性组织因子抑制物,对调剂血栓形成有重要作用。现就目前组织因子与急性冠脉综合征研究进展作一综述。     

Morphologic features of unstable atherothrombotic plaques underlying acute coronary syndromes

Unstable angina appears to be a good clinical marker for rapidly progressing coronary artery disease. Pathologically, an unstable atherothrombotic coronary lesion, represented by a raised atherosclerotic plaque with ruptured surface causing variable degree of hemorrhage into the plaque and luminal thrombosis (rapid plaque progression), usually is present in patients at autopsy after a period of unstable angina. The thrombus at the rupture site may be mural and limited (just sealing the rupture) or occlusive, depending on the degree of preexisting atherosclerotic stenosis. An occlusive thrombus is seldom seen over ruptured plaques causing less than 75% stenosis (histologic cross-sectional area reduction), but it is found with increasing frequency when severity of stenosis increases beyond 75%. Most occlusive thrombi have a layered structure with thrombus material of differing age indicating an episodic growth by repeated mural deposits, and microemboli/microinfarcts are frequently found in the myocardium downstream to coronary thrombi, indicating intermittent thrombus fragmentation with peripheral embolization. Such a "dynamic thrombosis" (with or without a concomitant focal vasospastic phenomenon) at the site of an unstable (ruptured) atherosclerotic lesion obviously may lead to the other thrombus-related acute coronary events: myocardial infarction or sudden death. Accordingly, progression of unstable angina to myocardial infarction or sudden death should, in principle, be preventable by the correct timing of current available therapies aimed to prevent or eliminate (1) the chronic atherosclerotic obstruction, (2) the acute plaque disruption, (3) luminal thrombosis, and (4) vasospasm.     

T cells and cytokines in atherogenesis

Recent findings suggest that inflammation plays a key role in atherosclerosis from the earliest stage of lesion initiation, to the ultimate complication of thrombosis. In patients who died because of acute coronary syndromes (ACS), coronary atherosclerotic plaques are characterized by the presence of macrophages, and to a lesser extent T-lymphocytes, at the immediate site of either plaque rupture or superficial erosion. The rupture-related inflammatory cells are activated, indicating ongoing inflammation. ACS patients are also characterized by activated circulating lymphocytes, monocytes and neutrophils, and by increased concentrations of proinflammatory cytokines and of the highly sensitive acute phase reactant C-reactive protein. Interestingly, an unusual subset of T cells, CD4+ CD28null T cells, involved in vascular complication of rheumatoid arthritis because of their functional profile predisposing for vascular injury, are expanded in the peripheral blood and infiltrate the coronary lesions of ACS patients. The presence of activated T lymphocytes implies antigenic stimulation, but the nature of such antigen(s) remains to be investigated. Several autoantigens expressed in the atherosclerotic plaque, including oxidized LDL and heat shock proteins, and infectious agents are able to elicit an immune response. The inflammatory component is not localized to the 'culprit' plaque, but it is diffused to the entire coronary vascular bed, and involves also the myocardium.     

Regulation of microvascular thromboembolism in vivo

Atherothrombosis and embolization are main causes of morbidity and mortality in the Western world. To optimize treatment, better understanding of the factors involved in thromboembolism in vivo is needed. The course and outcome of a thromboembolic process are determined by the local balance between anti and prothrombotic factors. In healthy vessels, endothelial antithrombotic properties prevent blood platelets from interacting with the vessel wall. Upon vessel wall damage or endothelial activation, however, prothrombotic factors temporarily overrule the antithrombotic factors, leading to thrombus formation and embolization. According to this concept, thromboembolism ends when the balance is restored. Animal models on microvascular thromboembolism have provided evidence that the endothelium is eminently involved in the regulation of thromboembolism, and that shear forces are an important determinant of endothelial function. Therefore, in this review focus is on the endothelial regulation of platelet-vessel wall interactions during thromboembolism in vivo. Anti- and prothrombotic properties of vascular endothelium will be discussed, paying special attention to the endothelium-derived platelet inhibiting substances nitiric oxide (NO) and prostacyclin (PGl(2)) and to differences between arteriolar and venular endothelium. In addition, the involvement of shear forces in microvascular thromboembolic processes in vivo will be described     

斑块侵蚀在急性冠状动脉综合征中的作用及机制研究进展

急性冠状动脉综合征是世界范围内发病率和死亡率较高的一组临床综合征。目前,越来越多的证据表明,带有完整纤维帽的斑块侵蚀是导致急性冠状动脉综合征的主要原因之一。基础实验已经揭示了斑块侵蚀的独特分子特征,已有研究表明,血流紊乱会引起内皮细胞损伤,从而导致基底膜丧失其完整性以及内皮细胞脱落,继而形成中性粒细胞胞外陷阱和血栓,导致斑块侵蚀。文章将讨论动脉粥样硬化斑块侵蚀的分子特征以及对斑块侵蚀患者未来精准医疗所需的转化研究。     

Leukocyte adhesion and thrombosis

PURPOSE OF THE REVIEW: The consequences of arterial thrombosis such as myocardial infarction, stroke and peripheral vascular occlusion are the leading causes of morbidity and mortality. A high leukocyte count and an elevation in inflammatory markers are identified as significant risk factors for thrombosis. Leukocytes form the front line in defense against infection and are the first cells arriving at the site of inflammation. This review summarizes the cellular and molecular mechanisms by which adherent leukocytes can induce a prothrombotic state. RECENT FINDINGS: Circulating tissue factor has been recognized as a potential prothrombotic factor initiating thrombosis after vascular injury. The tissue factor is present on microvesicles originated from activated leukocytes. Leukocytes generate tissue factor containing microvesicles following stimulation with cytokines and following platelet adhesion via P-selectin. Additionally, activated leukocytes release several mediators, such as cathepsin G and elastase, which can activate both the coagulation cascade and platelets. Furthermore, new roles for leukocytes have been identified in vascular injury in sickle cell anemia, in vascular occlusion following the rupture of atherosclerotic plaque, and in thrombotic complications of myeloproliferative diseases. SUMMARY: Leukocyte adhesion to endothelium and platelets plays an important role in the activation of the coagulation cascade. An excessive activation of leukocytes during the inflammatory process may induce a systemic procoagulant state. Elucidation of critical steps in activation of coagulation by leukocytes may offer a new therapeutic target for antithrombotic therapy based on blocking leukocyte adhesion.     

Pathophysiology of coronary thrombosis.

Detailed knowledge of the pathophysiology as well as the dynamic nature of coronary thrombus formation provides a valuable tool for correct management and proper adjunctive therapy in patients with acute coronary syndromes. Coronary thrombosis is in the majority of cases caused by disruption or fissuring of an atherosclerotic plaque. At the lesion thrombogenic material will be exposed to the flowing blood leading to activation of platelets and the formation of a platelet clot. Simultaneously, the coagulation system is activated resulting in increased thrombin formation. Thrombin is a key mediator in arterial thrombosis, due to its effect on both platelets and fibrin generation. Thrombin contributes to the stabilization of an initially loose platelet clot by generating cross-bound fibrin within the thrombus. During the course of an acute coronary syndrome, the patient presents changing chest pain and dynamic ischaemic ECG findings. This is likely to be related to the dynamic nature of the pathophysiology. The presence of a non-occlusive coronary thrombus may deprive the myocardium its normal blood flow and oxygen supply, leading to ischaemic pain. During lysis or embolization, blood supply may be restored, but the presence of thrombus fragments in the microcirculation holds the potential to sustained interference with myocardial metabolism. The emboli contain activated platelets which release vasoconstrictors that may compromise the microcirculation. Recurrent thrombus formation at the lesion site may result in occlusion of the artery adding to the dynamic nature of the clinical presentation. In conclusion, platelets, the coagulation system, and the endothelium cause a dynamic process of intermittent occlusion, vasospasm and embolization of thrombus material.     

Intracoronary ultrasound in acute coronary syndromes: from characterization of vulnerable plaques to guidance of percutaneous treatment of complex stenoses

Our current knowledge on the substrate and genesis of acute coronary syndromes (ACS) results from the integration of pathological, angiographic, and intracoronary imaging techniques. To summarize briefly the current paradigm, eight differentiated stages of development of atherosclerotic lesions are currently accepted, defined not only by the cellular elements involved, but also by the appearance of sudden alterations of plaque structure and coronary thrombosis. The latter constitutes not only the dominant substrate for the most devastating manifestations of coronary artery disease, but also accelerates plaque size at a faster pace than in earlier stages. The composition of atherosclerotic plaque varies significantly along the different evolutive stages, and thus includes cellular (macrophage, smooth muscle cells) and noncellular elements (glicosaminglycan or collagen-rich cellular matrix, extracellular lipid deposits, calcification, fresh, or organized thrombus) in a varying proportion. Furthermore, a dynamic process of vessel remodeling occurs along the atherosclerotic process, resulting, in most cases, in a protective mechanism against myocardial ischemia by preserving luminal dimensions during plaque enlargement. Intravascular ultrasound (IVUS) is one of the intracoronary imaging techniques that has contributed to the understanding of these changes in man. In addition, IVUS has the potential of being a useful clinical tool for predicting the chances of future acute coronary events by identifying vulnerable plaques, of characterizing which is the culprit lesion in ACS, and in guiding revascularization procedures in the treacherous field of thrombotic coronary syndromes. In this article, we review the current evidence on the potential of IVUS imaging for fulfilling these purposes.     

Lipid-lowering therapies in the management of acute coronary syndromes

Despite the significant advances made in the treatment of acute coronary syndromes (ACS) with antiplatelet and antithrombotic therapy, the risk of serious complications remains high, especially in the first few months following an acute coronary event. Although lipid-lowering therapy in patients with significant risk factors (primary prevention) or stable coronary disease (secondary prevention) is known to improve long-term survival, patients with a recent ACS were specifically excluded from the early statin trials. However, the use of lipid-lowering agents (principally statins) during hospitalization or in the period immediately following an acute coronary event has recently been studied. Statin therapy in this setting has been shown to reduce angina, rehospitalization, and mortality. Improved outcomes associated with lipid-lowering therapy in ACS may be mediated through beneficial effects on plaque stabilization, endothelial function, inflammation, and thrombus formation. This paper reviews the evidence supporting the potential benefits and mechanisms of statin therapy in the management of ACS. Clinical guidelines to achieve optimal lipid management are also discussed.