Abstract
Arterial thrombosis remains a leading cause of cardiovascular morbidity and mortality despite widespread use of dual antiplatelet therapy (DAPT) with aspirin and P2Y12 inhibitors. Although these agents reduce ischemic events, their efficacy is counterbalanced by dose-dependent bleeding and their inability to distinguish pathological platelet activation from physiological hemostasis. Recent advances in platelet biology have shifted therapeutic development toward hemostasis-sparing antiplatelet strategies- approaches designed to selectively inhibit thrombosis while preserving baseline hemostatic function. These strategies target upstream adhesion receptors (GPVI, GPIb-vWF, CLEC-2) and receptor-proximal intracellular signaling nodes (SYK, BTK, PI3Kβ, PLCγ2, NADPH oxidases) that are preferentially engaged under high-shear or strongly prothrombotic conditions. Early-phase clinical and translational studies of such agents demonstrate antithrombotic efficacy with minimal impact on bleeding time, supporting their mechanistic selectivity. In parallel, contemporary clinical practice increasingly utilizes individualized risk assessment, platelet function testing, and genetic profiling to tailor treatment intensity. This integration of mechanism-selective agents with patient-specific risk evaluation forms the basis of precision-based thrombosis prevention, a framework aimed at aligning the duration and depth of platelet inhibition with the dynamic balance between ischemic and bleeding risk. Together, these developments mark a paradigm shift from broad platelet suppression toward rational, context-adaptive, and safer antiplatelet therapy.