报告题目:Multi-head 3D Bio-Printing System for Artificial Organ Fabrication
报 告 人:Junhee Lee. Principle Researcher, Department of 3D printing, Korea Institute of Machinery and Materials, Daejeon, Rep. of Korea
报告时间:2019年4月18日(周四) 11:00
报告地点:南岭校区机械材料馆529会议室
报告人简历
Education
PhD in Dep. of Mechanical Engineering, Korea Advanced Institute of Science and Technology, Korea (2005)
MS in Dep. of Mechanical Engineering, Korea Advanced Institute of Science and Technology, Korea (1999)
BSc in Dep. of Mechanical Engineering, Korea Advanced Institute of Science and Technology, Korea (1997)
Institute
2015 ~ present: Principal Research in Korea Institute of Machinery and Materials (KIMM)
Academia and Society
2013~present: Associate Professor in University of Science and Technology
2010: Post Doc. Drexel University (USA)
Award and Fellowship
Minister prize: Ministry of Trade, Industry and Energy of Korea (2017)
100 Technologies for the Year 2025 and their 238 Key Engineers: The National Academy of Engineering of Korea (2017)
Academic Director of Korea Society of Mechanical Engineers (2018 - Present)
报告内容:
3D printing technology can create a three-dimensional object using 3D CAD model by printing successive layers of various materials under computer control. The 3D printing technology can be applied to the biomedical field to produce tissue engineered constructs imitating complex organ or tissue structure. 3D bio-printing technology makes it possible to not only fabricate 3D shape, but also precisely place various cell in a single structure. In this talk, I will introduce 3D bio-printing system (3DBP) and its bio-applications. The 3DBP can fabricate the 3D polymer scaffold which serves a 3D supporting structure for cell adhesion and proliferation for artificial organ. The system has data conversion software which can convert 3D CT/MRI files into the NC code. And the system composes of multi-dispensing module, high precision multi-axis stages and controller. It can control the shape, size, pore size and porosity of the scaffold. I will also present the cell printing system which can fabricate 3D hydrogel scaffold. The greatest advantage of the cell printing system is that it can fabricate the cell-laden hydrogel scaffolds. Homogenous encapsulation of the cells can be done using the cell printing system. Both systems can fabricate 3D scaffolds with interconnected porous structures to increase the efficiency of the transport of the nutrient and waste. The mechanical properties of the scaffold, proliferation and differentiation of the cells are compared with different biocompatible polymers and hydrogels. Finally, I will discuss about the potential of 3D printing technology for artificial organ fabrication.
