| 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
Chapter 8. MEMS for clinical applications
8.1 Drug delivery devices
8.2 Minimally invasive medical devices.
Final Project Presentation |
self-directed
learning |
|
|
| 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(Link URL) |
| include experience courses:N |
|