Holiday
ENG I工一 211 W2W3W4
Microfluidics is rapidly emerging as an enabling technology, with applications ranging from unmanned aerial vehicles to biomedical applications to drug discovery and delivery. Given the importance of micro/nano mechanical and fluidic phenomena, it is necessary to understand the fluid mechanics, heat and mass transfer, chemistry, biochemistry and engineering principles on which the design of devices is ba<x>sed. These courses are essential in understanding the behavior of fluid flow (droplet) through nano/micro scales for bio-applications.
Course keywords: 微流體系統(microfluidics), 微全分析系統(MicroTAS), 生醫晶片(Bio Chip or Lab on a Chip), 微閥及微幫浦(Microvalve and Micropump), and 微製程(Microfabrication). Course: 生醫微熱流 Thermo-fluidics in Bio-MEMS When: 112年度2nd semester, Wed 9:00-12:00 Course Description: Microfluidics is rapidly emerging as an enabling technology, with applications ranging from unmanned aerial vehicles to biomedical applications to drug discovery and delivery. Given the importance of micro/nano mechanical and fluidic phenomena, it is necessary to understand the fluid mechanics, heat and mass transfer, chemistry, biochemistry and engineering principles on which the design of devices is based. These courses are essential in understanding the behavior of fluid flow (droplet) through nano/micro scales for bio-applications. Handouts: may be downloaded by the student. Textbook: 1. “Fundamentals and applications of Microfluidics”, N.-T. Nguyen and S. T. Wereley, Artech House, 2nd edition, 2008. 2. “Introduction to BioMEMS”, Albert Folch, CRC press, 2012. Textbook (reference): 1. “Micro- and Nanoscale Fluid Mechanics”, Brian J. Kirby, Cambridge, 2010. 2. “Fluid Power with Applications”, Anthony Esposito, 5th Edition, Prentice Hall, 2000. Assignments and Grading (subject to revision): ◆ Class participation: 10% ◆ Report: 10% ◆ Midterm exam: 30% ◆ Final presentation (or final exam): 50% Contact: 森川響二朗 助理教授 / Kyojiro Morikawa, Assistant Professor (morikawa@pme.nthu.edu.tw) Contents: 1. Introduction to BioMEMS 2. Introduction to microfluidics – basic principles 3. Introduction to microfluidics – applications 4. Microfluidic device fabrication – fabrication method 5. Microfluidic device fabrication – material (silicon, glass, polymers …) 6. Microfluidic device fabrication – summary 7. Flow control method – pump 8. Flow control method – valve 9. Surface modification and patterning – method 10. Surface modification and patterning – application (cell, electrode, chemical …) 11. Mid-term exam 12. Biosensors 13. Molecular Biology on a chip 14. Cell-based Chips for Biotechnology 15. BioMEMS for Cell Biology 16. Implantable Microdevices 17. Summary and future perspectives for BioMEMS technology 18. Final presentation or final exam
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20:30c21:20 |
Average Percentage 82
Std. Deviation 6.16
動機系碩士班生醫系統組課程
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