Aggregation‐Disruption‐Induced Multi‐Scale Mediating Strategy for Anticoagulation in Blood‐Contacting Devices

Abstract Minimally invasive blood‐contacting interventional devices are increasingly used to treat cardiovascular diseases. However, the risk of device‐related thrombosis remains a significant concern, particularly the formation of cycling thrombi, which pose life‐threatening risks. To better understand the interactions between these devices and blood, the initial stages of coagulation contact activation on extrinsic surfaces are investigated. Direct force measurements reveals that activated contact factors stimulate the intrinsic coagulation pathway and promote surface crosslinking of fibrin. Furthermore, fibrin aggregation is disrupted by surface‐grafted inhibitors, as confirmed by ex vivo coagulation tests. An engineered serum protein with zwitterion grafts to resist the deposition of biological species such as fibrin, platelets, and red blood cells is also developed. Simultaneously, a protease inhibitor‐based coacervate is incorporated into the coating to inhibit the intrinsic pathway effectively. The loaded coacervate can be released and reloaded through modulation of catechol‐amine interactions, facilitating material regeneration. The strategy offers a novel multi‐scale mediation strategy that simultaneously inhibits nanoscale coagulation factors and resists microscale thrombus aggregation, providing a long‐term solution for anticoagulation in blood‐contacting devices.