Abstract
Platelet aggregation, in fundamental terms, is considered a biological end point that contributes to the occurrence of clinical events among patients with advanced atherosclerotic coronary artery disease. Acute coronary syndrome, including non–ST elevation myocardial infarction (NSTEMI) and ST elevation myocardial infarction (STEMI), accounts for upward of 733 000 hospital admissions yearly in the United States.1 The primary pathophysiological mechanism responsible for the majority of acute coronary syndromes is endothelial plaque disruption with and subsequent platelet adhesion, activation, and thrombus formation.2 The end result is formation of thrombus within a coronary artery, leading to subtotal vessel occlusion with NSTEMI and complete occlusion of the artery with STEMI. In this review, we provide a contemporary view of platelet adhesion as a highly coordinated and teleologically conserved process achieved by surface receptors, protein ligands, and matrix proteins operating at the platelet–subendothelium interface. We also discuss drugs in development, including monoclonal antibodies, inhibitory peptides, and oligonucleotides; preclinical data; and, where available, clinical trial results, highlighting the potential translation of fundamental constructs in platelet biology to patient care. Platelets are derived from a hematopoietic bone marrow stem cell precursor.3 Through a highly conserved program of cellular differentiation, this stem cell precursor becomes a megakaryocyte at a rate of approximately 100 000 000 megakaryocytes produced per day.3 Subsequently, each individual megakaryocyte will give rise to approximately 500 platelets via additional developmental steps within the bone marrow that involve a proplatelet intermediate stage.3 Once released into circulation, a mature platelet has an expected life span of 7 to 10 days.3 Platelet maturation and development involve the expression of receptors on the platelet cell surface. These receptors facilitate platelet adhesion and activation, and they promote thrombus development through receptor–ligand interactions, with several ligands expressed on the surface of endothelial cells, within the …
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