FACULTY OF ENGINEERING
Department of Biomedical Engineering
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BME 317 | Course Introduction and Application Information
| Course Name |
Biomedical Mass Transport and Chemical Reactions
|
|
Code
|
Semester
|
Theory
(hour/week) |
Application/Lab
(hour/week) |
Local Credits
|
ECTS
|
|
BME 317
|
Fall
|
2
|
2
|
3
|
6
|
| Prerequisites |
None
|
|||||
| Course Language |
English
|
|||||
| Course Type |
Required
|
|||||
| Course Level |
First Cycle
|
|||||
| Mode of Delivery | - | |||||
| Teaching Methods and Techniques of the Course | - | |||||
| Course Coordinator | ||||||
| Course Lecturer(s) | ||||||
| Assistant(s) | ||||||
| Course Objectives | The objective of this course is to introduce fundamentals of mass transport in biomedical environment. This course will cover chemical thermodynamic, chemical kinetics, mass transport, fluid mechanics and biomedical applications. |
| Learning Outcomes |
The students who succeeded in this course;
|
| Course Description | The course covers chemical thermodynamic, chemical kinetics, mass transport, fluid mechanics and biomedical applications. |
|
|
Core Courses |
X
|
| Major Area Courses | ||
| Supportive Courses | ||
| Media and Management Skills Courses | ||
| Transferable Skill Courses |
WEEKLY SUBJECTS AND RELATED PREPARATION STUDIES
| Week | Subjects | Related Preparation |
| 1 | Introduction to biological structures and mass transport | James S. Ultman, Harihara Baskaran, Gerald M. Saidel. “Biomedical Mass Transport and Chemical Reaction: Physicochemical Principles and Mathematical Modeling”. (2016) Part I |
| 2 | Thermodynamic of biomedical processes | James S. Ultman, Harihara Baskaran, Gerald M. Saidel. “Biomedical Mass Transport and Chemical Reaction: Physicochemical Principles and Mathematical Modeling”. (2016) Part II |
| 3 | Chemical reactions equilibrium | James S. Ultman, Harihara Baskaran, Gerald M. Saidel. “Biomedical Mass Transport and Chemical Reaction: Physicochemical Principles and Mathematical Modeling”. (2016) Part II Ch 5 |
| 4 | Chemical reactions rates and kinetic models | James S. Ultman, Harihara Baskaran, Gerald M. Saidel. “Biomedical Mass Transport and Chemical Reaction: Physicochemical Principles and Mathematical Modeling”. (2016)Part III Ch8 |
| 5 | Transport Models in Fluids and Membranes | James S. Ultman, Harihara Baskaran, Gerald M. Saidel. “Biomedical Mass Transport and Chemical Reaction: Physicochemical Principles and Mathematical Modeling”. (2016) Part ıV |
| 6 | Mechanism of diffusion | James S. Ultman, Harihara Baskaran, Gerald M. Saidel. “Biomedical Mass Transport and Chemical Reaction: Physicochemical Principles and Mathematical Modeling”. (2016) Part IV Ch 9 |
| 7 | Diffusion process | James S. Ultman, Harihara Baskaran, Gerald M. Saidel. “Biomedical Mass Transport and Chemical Reaction: Physicochemical Principles and Mathematical Modeling”. (2016)Part IV Ch 10 |
| 8 | Midterm | |
| 9 | Multidimensional processes of molecules and cells | James S. Ultman, Harihara Baskaran, Gerald M. Saidel. “Biomedical Mass Transport and Chemical Reaction: Physicochemical Principles and Mathematical Modeling”. (2016) Part V |
| 10 | Fluid mechanics | James S. Ultman, Harihara Baskaran, Gerald M. Saidel. “Biomedical Mass Transport and Chemical Reaction: Physicochemical Principles and Mathematical Modeling”. (2016) Part V Ch 13 |
| 11 | Mass transport | James S. Ultman, Harihara Baskaran, Gerald M. Saidel. “Biomedical Mass Transport and Chemical Reaction: Physicochemical Principles and Mathematical Modeling”. (2016) Part V Ch 15 |
| 12 | Biomedical applications | James S. Ultman, Harihara Baskaran, Gerald M. Saidel. “Biomedical Mass Transport and Chemical Reaction: Physicochemical Principles and Mathematical Modeling”. (2016) Part VII Ch 20 |
| 13 | Drug release and delivery | James S. Ultman, Harihara Baskaran, Gerald M. Saidel. “Biomedical Mass Transport and Chemical Reaction: Physicochemical Principles and Mathematical Modeling”. (2016) Part VII Ch 21 |
| 14 | Diagnostics | James S. Ultman, Harihara Baskaran, Gerald M. Saidel. “Biomedical Mass Transport and Chemical Reaction: Physicochemical Principles and Mathematical Modeling”. (2016) Part VII Ch 22 |
| 15 | Semester Review | |
| 16 | Final Exam |
| Course Notes/Textbooks | James S. Ultman, Harihara Baskaran, Gerald M. Saidel. “Biomedical Mass Transport and Chemical Reaction: Physicochemical Principles and Mathematical Modeling”. 2016. Wiley ISBN: 978-0-471-65632-6 |
| Suggested Readings/Materials |
EVALUATION SYSTEM
| Semester Activities | Number | Weigthing |
| Participation | ||
| Laboratory / Application | ||
| Field Work | ||
| Quizzes / Studio Critiques |
2
|
20
|
| Portfolio | ||
| Homework / Assignments |
1
|
10
|
| Presentation / Jury | ||
| Project | ||
| Seminar / Workshop | ||
| Oral Exams | ||
| Midterm |
1
|
30
|
| Final Exam |
1
|
40
|
| Total |
| Weighting of Semester Activities on the Final Grade |
4
|
60
|
| Weighting of End-of-Semester Activities on the Final Grade |
1
|
40
|
| Total |
ECTS / WORKLOAD TABLE
| Semester Activities | Number | Duration (Hours) | Workload |
|---|---|---|---|
| Theoretical Course Hours (Including exam week: 16 x total hours) |
16
|
2
|
32
|
| Laboratory / Application Hours (Including exam week: '.16.' x total hours) |
16
|
2
|
32
|
| Study Hours Out of Class |
14
|
4
|
56
|
| Field Work |
0
|
||
| Quizzes / Studio Critiques |
2
|
10
|
20
|
| Portfolio |
0
|
||
| Homework / Assignments |
1
|
10
|
10
|
| Presentation / Jury |
0
|
||
| Project |
0
|
||
| Seminar / Workshop |
0
|
||
| Oral Exam |
0
|
||
| Midterms |
1
|
15
|
15
|
| Final Exam |
1
|
25
|
25
|
| Total |
190
|
COURSE LEARNING OUTCOMES AND PROGRAM QUALIFICATIONS RELATIONSHIP
|
#
|
Program Competencies/Outcomes |
* Contribution Level
|
||||
|
1
|
2
|
3
|
4
|
5
|
||
| 1 | To have adequate knowledge in Mathematics, Science and Biomedical Engineering; to be able to use theoretical and applied information in these areas on complex engineering problems. |
X | ||||
| 2 | To be able to identify, define, formulate, and solve complex Biomedical Engineering problems; to be able to select and apply proper analysis and modeling methods for this purpose. |
X | ||||
| 3 | To be able to design a complex system, process, device or product under realistic constraints and conditions, in such a way as to meet the requirements; to be able to apply modern design methods for this purpose. |
|||||
| 4 | To be able to devise, select, and use modern techniques and tools needed for analysis and solution of complex problems in Biomedical Engineering applications. |
X | ||||
| 5 | To be able to design and conduct experiments, gather data, analyze and interpret results for investigating complex engineering problems or Biomedical Engineering research topics. |
X | ||||
| 6 | To be able to work efficiently in Biomedical Engineering disciplinary and multi-disciplinary teams; to be able to work individually. |
|||||
| 7 | To be able to communicate effectively in Turkish, both orally and in writing; to be able to author and comprehend written reports, to be able to prepare design and implementation reports, to present effectively, to be able to give and receive clear and comprehensible instructions. |
|||||
| 8 | To have knowledge about global and social impact of Biomedical Engineering practices on health, environment, and safety; to have knowledge about contemporary issues as they pertain to engineering; to be aware of the legal ramifications of engineering solutions. |
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| 9 | To be aware of ethical behavior, professional and ethical responsibility; to have knowledge about standards utilized in engineering applications. |
|||||
| 10 | To have knowledge about industrial practices such as project management, risk management, and change management; to have awareness of entrepreneurship and innovation; to have knowledge about sustainable development. |
|||||
| 11 | To be able to collect data in the area of Biomedical Engineering, and to be able to communicate with colleagues in a foreign language. |
X | ||||
| 12 | To be able to speak a second foreign language at a medium level of fluency efficiently. |
|||||
| 13 | To recognize the need for lifelong learning; to be able to access information, to be able to stay current with developments in science and technology; to be able to relate the knowledge accumulated throughout the human history to Biomedical Engineering. |
|||||
*1 Lowest, 2 Low, 3 Average, 4 High, 5 Highest
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