| Relevance of Course Objectives and Core Learning Outcomes(%) |
Teaching and Assessment Methods for Course Objectives |
| Course Objectives |
Competency Indicators |
Ratio(%) |
Teaching Methods |
Assessment Methods |
| 使修習者熟悉生醫微系統之微製造技術、基本原理、構造、操作方式,能應用微製造技術設計製作生醫微元件 |
| 1.The ability to apply the knowledge of math, science, and mechanical engineering. |
| 2.The ability to design and conduct experiments, as well as to analyze the data obtained. |
| 3.The ability to work with others as a team to design and manufacture products of mechanical engineering systems. |
| 4.The ability humanities awareness and a knowledge of contemporary issues, and to understand the impact of science and engineering technologies, environmental, societal, and global context. |
| 5.The ability of continuing study and self-learning. |
| 6.The knowledge of professional ethics and social responsibilities of a mechanical engineer. |
|
|
| Exercises |
| Discussion |
| Lecturing |
|
| Oral Presentation |
| Assignment |
| Quiz |
| Other |
|
| Course Content and Homework/Schedule/Tests Schedule |
| Week |
Course Content |
| Week 1 |
Chapter 0. Review of biosystem
|
| Week 2 |
Chapter 1. Introduction of bio NEMS/MEMS
1.1 Learning from the Experiences of Microelectronics
1.2 The Advantages of Miniaturizing Systems for Chemical Analysis
1.3 From Concept to TAS |
| Week 3 |
Chapter2. Microfludics-Theoretical aspects
2.1 Fluids and Flows
2.2 Transport Processes |
| Week 4 |
Chapter2. Microfludics-Theoretical aspects
2.3 System Design
2.4 An Application : Biological Fluids
Chapter 3. Microfludics-Components
3.1 Valves and Pumps |
| Week 5 |
Chapter 3. Microfludics-Components
3.2 Injection, Dosing, and Metering
3.3 Temperature Measurement in Microfuidics |
| Week 6 |
Chapter 4. Silicon and Cleanroom Processing
4.1 Substrate Fabrication
4.2 Optical Lithography |
| Week 7 |
Chapter 4. Silicon and Cleanroom Processing
4.3 Additive Techniques
4.4 Subtractive Techniques |
| Week 8 |
Chapter 5. Polymer Micromachining
5.1 Thick Resist Lithography
5.2 Polymeric Surface Micromachining |
| Week 9 |
Chapter 5. Polymer Micromachining
5.3 Soft Lithography
5.4 Micromolding |
| Week 10 |
Chapter 5. Polymer Micromachining
5.5 Laser Micromachining
5.6 3D Bioprinting
5.7 Examples |
| Week 11 |
Midterm Examination |
| Week 12 |
Chapter 6. MEMS for biosensors
6.1 In-vitro diagnostics
6.2 Biosensors |
| Week 13 |
Chapter 6. MEMS for biosensors
6.3 Biosensors based on a nanostructured electrode |
| Week 14 |
Chapter 6. MEMS for biosensors
6.4 Glucose biosensors
6.5 Molecular detections using Raman spectroscopy |
| Week 15 |
Chapter 7. MEMS for tissue engineering
7.1 Introduction of Tissue Engineering
7.2 Tissue scaffold design |
| Week 16 |
Chapter 7. MEMS for tissue engineering
7.3 Tissue scaffold fabrication using MEMS approaches
7.4 Applications of MEMS fabricated tissue scaffold |
| Week 17 |
Chapter 8. MEMS for clinical applications
8.1 Drug delivery devices
8.2 Minimally invasive medical devices. |
| Week 18 |
Final Project Presentation |
|
| Evaluation |
作業:25%
期中考試:40%
期末報告 (1)Oral presentation(10%) (2)Writing (25%)
|
| Textbook & other References |
教科書:
1.Tuhin S. Santra, Microfluidics and Bio-MEMS Devices and Applications, 2020, Stanford Publishing
2.Class handout
|
| Teaching Aids & Teacher's Website |
| 數位教學平台i-Learning |
| Office Hours |
| 星期一 下午 |
| Sustainable Development Goals, SDGs |
| 03.Good Health and Well-Being 04.Quality Education 05.Gender Equality | include experience courses:N |
|