The endothelium is a critical mediator of homeostasis on blood-contacting surfaces in the body, serving as a selective barrier to regulate processes such as clotting, immune cell adhesion, and cellular response to fluid shear stress. Implantable cardiovascular devices, including stents, vascular grafts, heart valves, and left ventricular assist devices, are in direct contact with circulating blood and carry a high risk for platelet activation and thrombosis without a stable endothelial cell (EC) monolayer. Development of a healthy endothelium on the blood-contacting surface of these devices would help ameliorate risks associated with thrombus formation and eliminate the need for long-term antiplatelet or anticoagulation therapy. Although ECs have been seeded onto or recruited to these blood-contacting surfaces, most ECs are lost upon exposure to shear stress due to circulating blood. Many investigators have attempted to generate a stable EC monolayer by improving EC adhesion using surface modifications, material coatings, nanofiber topology, and modifications to the cells. Despite some success with enhanced EC retention in vitro and in animal models, no studies to date have proven efficacious for routinely creating a stable endothelium in the clinical setting. This review summarizes past and present techniques directed at improving the adhesion of ECs to blood-contacting devices. Impact statement Clinical success of blood-contacting devices such as vascular grafts, stents, and heart valves has remained limited by postimplantation problems, including thrombosis and loss of patency. Without a stable endothelial cell (EC) monolayer, blood-contacting devices are at risk for platelet activation and thrombosis. Methods to improve EC adhesion on these devices have not translated to long-term in vivo success, as many ECs are lost after exposure to circulating blood. In this study, we summarize methods to improve EC adhesion and retention. Successful endothelialization of blood-contacting devices may improve patient outcomes after device implantation and limit the need for long-term antiplatelet or anticoagulation therapy.
Keywords: biomaterial; cell adhesion; cell retention; endothelial cell; shear stress.