Cătălin Popa
Dr. Cătălin Popa is a Professor in the Department of Materials Science and Engineering, Head of the Biomaterials Research Group in the Technical University of Cluj-Napoca (TUCN). He is an Engineer since 1986 and, after working as a design engineer in several companies, he has become a member of the academic staff of TUCN since 1990. From the very early stages of his career, he worked in the field of Biomaterials and, later, he created the Biomaterials Research Group. Doctor of Engineering since 1997, Professor Popa was awarded a NATO / Royal Society Fellowship in the University of Nottingham (2000). He was a recognized researcher in numerous research projects in the UK, in the IRC in Biomedical Materials, Queen Mary, University of London, and Rutherford Appleton Laboratory, STFC, as well as director in 29 research grants awarded by Romanian public funding bodies. The Biomaterials Research Group he leads focuses on optimisation of medical implants / devices, Tissue Engineering applications, drug delivery systems and Medical Microfluidics. Fundamental or developmental research for industry, in Romania, Germany, UK or Japan is, also, a key topic for the group he leads. Prof. Cătălin Popa is member of the Materials Engineering and Science Commission in The National Commission for the Attestation of Titles, Diplomas and University Certificates (CNATDCU), Romania.
Abstract
SYNERGISIC PHYSICAL / CHEMICAL / BIOLOGIC EFFECTS IN MEDICAL MICROFLUIDIC DEVICES
Cătălin POPA
Technical University of Cluj-Napoca, ROMANIA
Medical Microfluidics became in recent years a very dynamic domain, both due to advances in Engineering Science and Manufacturing Technology, and to the new demands after the recent pandemic. Fields such as Capillary Force Microfluidics, using cost – effective devices prone to high – scale production, or 3D printing of microfluidic devices with cheap raw materials, emerged very strongly in the recent years. The applications in this presentation useseveral types of action upon target – components in biologic / biologically inspired fluids, ranging from simple flow effects, to synergistic physical – chemical ones, and refer either to diagnostic, therapy or theranostic, microfluidic bioreactors, difficult wounds dressing,biosensing or fast accurate point-of-care blood analysis, drug testing etc. Rigid microfluidic devices manufactured through 3D printing, as well as capillary force ones, on paper or thread, with electrodes / chemical agents’ integration, were conceived, manufactured and tested, in view of medical or forensic applications.
BioReMed 2025
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