Professor

y major focuses on the development of next-generation biosensors and integrated bioengineering platforms. Magnetic-based biochips utilize magnetic nanoparticles and microstructures to precisely separate and detect biological targets such as cells and proteins, offering higher sensitivity and simpler signal processing compared to conventional optical sensors. In parallel, cells-on-chip technology enables the culture and analysis of cells within microfluidic systems, allowing the simulation of physiological environments and facilitating studies on drug response and intercellular interactions. These approaches are supported by fabrication methods such as PPW (Prototype Process Wafer), which provide efficient and cost-effective prototyping of biochips. Finally, biosignal analysis plays a key role in converting electrical and magnetic signals obtained from chip platforms into meaningful biological information, forming the foundation for advanced diagnostics and personalized medicine. This convergence of technologies contributes to the progress of precision healthcare and bioelectronics.