Several treatments of cardiovascular diseases involve artificial heart valves, ventricular assist devices, grafts, or stents, which are all blood-contacting medical devices. The haemocompatibility of medical devices remains the major challenge in their development. An insufficient haemocompatibility may lead to thrombus formation, failure of the device and in the worst case to the patient’s death. When a foreign material comes in contact with blood, a foreign body reaction is initiated: proteins adsorb on the surfaces and in consequence, the coagulation cascade is triggered, circulating platelets are activated and recruited, possibly leading to clotting and thrombus formation at the foreign material. Although an anticoagulation therapy can counteract these adverse events, it bears the risk of severe bleeding complications. Hence, improving the haemocompatibility of blood-contacting artificial materials is the key for better and safer medical devices. To manipulate thrombotic adverse reaction and increase haemocompatibility, surface topographies in the nano/micrometre range have gained attention as a promising biomimetic approach. However, only incomplete, and inconsistent results regarding effective structure geometries and dimension were published so far, leaving the full potential and impact of surface structures unclear. ThromboSurf investigates the relation between platelets and microstructured surfaces with a special emphasize on the hemodynamic effects of surface topographies. The hypothesis is to reduce the artificial surface thrombogenicity by controlling the capability of the platelets to adhere to the surface by adjusting the flow above the surface. The aim of the project is thus to investigate the interaction between platelet adhesion and microstructured surfaces, specifically designed to alter the near-wall flow, through in silico and in vitro approaches. We will use intensive computational fluid dynamics and particle-based platelets models, high-throughput real-time cell imaging and in-vitro blood tests to derive a correlation between alterations in haemodynamics by surface structure and the resulting platelet activation and adhesion. The in-silico model will first be improved and tuned iteratively, until the prediction of platelet-surface interactions is precise. Then, the model will be applied to many different surface structures to create a database including surface properties and platelet responses. This broad physical cross-analysis will be unique and provide a base for distinct surface topography research in the light of thrombogenicity reduction. A subset of promising topographies will be selected and investigated experimentally in vitro to confirm the thrombogenicity outcome. Additionally, the impact of complex flow conditions such as pulsatility and turbulence effects, which occur in medical devices regularly, will be considered, paving the way for future breakthroughs in the use of haemocompatible artificial surfaces.

DFG Programme Research Grants

International Connection France

Co-Investigator Dr. Michael Neidlin

Cooperation Partner Professor Dr. Franck Nicoud