Seminar & Event

2012년도 제 18차 WCU Seminar 공지 - 2012년 9월 25일

Author
관리자
Date
2012-09-18
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1020
1.  제목 :  Experimental and Computational Analysis of Cell Mechanics during


              Spreading and Migration 


2.  연사 :  Sangyoon Han, Ph.D (Mechanical Engineering, University of Washington)


3.  일시 :  2012년 09월 25일 (화) 오후 4시 30분


4.  장소 :  301동  1512-2호


5.  내용 : 


The processes of cell migration and spreading are critical for wound healing and cancer metastasis. Cells use their ability to generate mechanical forces to probe the mechanical resistance of their environment and move forward. Biomechanical explanations for how mechanical factors in their environment affect these forces and how cells use their forces to migrate are still unclear. Here, using patterned micropost arrays, the effects of substrate stiffness, cell adhesive area, and adhesion density on contractile forces of endothelial cells were investigated. Each of these traits was found to play a fundamentally different role in contributing to overall cellular contractility. By quantifying the size of individual focal adhesions on each post, it was also found that focal adhesion area responds to each parameter in the same way that traction forces do. A computational model was then adopted to predict, using ordinary differential equations, the traction forces produced during cell migration. To validate the results from these simulations, NIH 3T3 fibroblasts were seeded onto arrays of posts, but allowed to migrate only in one dimension by patterning the tips of the posts with lines of extracellular matrix (ECM) proteins. Experimentally measured development of force at their leading edge and loss in force at their trailing edge matched closely with the computational simulations. Moreover, the increase in force at the leading edge caused a decrease in force at the adjacent post, but did not affect the rest of the forces at the interior or trailing edge of the cell. To match these experimental results, the model requires the elasticity of the cell to be lower than the elasticity of its substrate. The significance of this work is that it provides biophysical relationship and mathematical model involving mechanical properties of a substrate, a cell and traction force generation during spreading and migration.



6. 약력


학력: 2012 Ph.D. in Mechanical Engineering at University of Washington


        2004 M.S. in Mechanical Engineering at Seoul National University, Korea


        2002 B.S. in Mechanical Engineering at Seoul National University, Korea


경력: 2006-2007 Project Manager at Korea Institute of Industrial Technology, Applied Robotics


        2004-2006 Research Engineer at Daewoo Electronics Corp, Digital Multimedia R&D Center


 


7. 문의: 기계항공공학부 서갑양 교수 (880-9103)