
Center for Medical Physics and Biomedical Engineering, Department of Cardiac and Thoracic Aortic Surgery, (Division of Cardiology)
Position: PHD Student
ORCID: 0000-0003-3667-0965
T +43 1 40400-61074
marta.bonora@meduniwien.ac.at
Keywords
Blood Platelets; Heart-Assist Devices; In Vitro; Microfluidics
Research group(s)
- Additive Manufacturing for Medical Research
Head: Francesco Moscato
Research Area: The research group investigates physical and digital 3D modeling and engineering for improving medical implants and devices, surgical procedures and training.
Members:
Research interests
My research is focused on blood platelets and their behavior in the presence of mechanocirculatoy pumps. Contact with artificial surfaces and abnormal blood flow are two factors acting as platelet activation agonists. These may result in severe consequences for patients implanted with biomedical devices, such as thrombi and thromboembolic events. My thesis project aims to develop a novel artificial surface modified via micropatterning of specific microstructures intended to reduce the adhesion of platelets. Further, it has been necessary to design an assay ad hoc for testing these peculiar surfaces. The assay is a microfluidic system in which blood is perfused with the same shear stress levels experienced in the pump and with analog conditions to the realistic ones.
Techniques, methods & infrastructure
This project is a collaboration between the Cardiac Surgery Research Laboratory and the Center for Medical Physics and Biomedical Engineering and with other partners involved in the manufacturing process: UpNano GmbH, Profactor GmbH and Lithoz GmbH, BST (Bionic Surface Technologies) GmbH. All the microstructures have been firstly printed via 2-Photon Polymerization printer at the UpNano and at our center where we own such technology. Then, the microstructures were replicated via Nano Imprinting Lithography (NIL) at Profactor and finally imprinted on the surface by employing a high-quality ceramic material provided by Lithoz. At our center and the at BST have been run the microfluidic computational simulation of this system.