Biomechanical Engineering Department
Vision
The vision of the Biomechanical Engineering Department is to prepare graduates capable of keeping pace with developments in this modern specialty, “Biomechanical Engineering,” to serve stakeholders in the public and private sectors. They are qualified to achieve better health outcomes by applying the principles and tools of physical and engineering sciences to biology, physiology, and medicine. They also aim to translate knowledge and innovations into clinical practice by training biomechanical engineers to work effectively in various settings, from academia to industry and medical institutions.
Mission
The Department of Biomechanical Engineering seeks to bridge engineering with medical science by graduating engineers qualified in biomedical research and development, innovation, and discovery and training the next generation of biomedical engineers to achieve better health outcomes. This department places great emphasis on recent discoveries in research related to design technologies, which will significantly contribute to applications in the human body.
Objectives
- Providing qualified engineering personnel to address the field of biomechanics, achieving excellence through multidisciplinary problem-solving collaboration, creativity, innovation, scientific and ethical rigor, integrity, and a team spirit.
- Preparing biomechanical engineers specializing in prosthetic medical devices, tissue engineering, academic study, and applied research.
- Contributing to building a strong relationship between graduates and the department to develop theoretical and practical curricula in line with the needs of the evolving labor market.
Intended Learning Outcomes
The educational Intended Learning Outcomes of the undergraduate program in the Biomechanical Engineering Department are to produce graduates whom:
1- Graduates will have a strong foundation in the fundamental principles of engineering, mathematics, physics, and chemistry, as well as biology and physiology.
2- Graduates will be able to apply these principles to the design, development, and evaluation of biomedical systems, devices, and processes
3- Graduates will be able to work effectively in interdisciplinary teams, collaborating with scientists, clinicians, engineers, and other professionals to identify and solve complex problems in healthcare and related fields.
4- Graduates will be proficient in the use of modern engineering tools and techniques, including computational modeling, data analysis, and experimental methods, and will be able to apply these tools to solve real-world problems.
5- Graduates will be able to communicate effectively, both orally and in writing, to a range of audiences, including technical and non-technical stakeholders.
6- Graduates will have an understanding of the ethical and societal implications of their work and will be able to apply this understanding to the design of socially responsible and sustainable solutions.
7- Graduates will be prepared for lifelong learning and professional development and will have the skills and knowledge to adapt to new challenges and opportunities in the rapidly evolving field of biomedical engineering.
Lectures
First stage lectures / First semester
First stage lectures / second semester
Second Stage / First Semester Lectures
Second Stage / Second Semester Lectures
Third Stage Lectures / First Semester
| اسم المادة | Topics | Lecture | ||||
|---|---|---|---|---|---|---|
| Engineering Analysis |  | | | | |
|
| Biomechanics I | | | | | |
|
| Mechanical Design | | | | | |
|
| Biology | | | | | |
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| Manufacturing Processes | | | | | |
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| Principles of Medical Electronics | | | | | |
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| Engineering Analysis | | | | | |
|
| Engineering Statistics | | | | | |
Third stage lectures / Second semester
Fourth stage lectures / First semester
Fourth stage lectures / Second semester
| اسم المادة | Topics | Lecture | |||||||
|---|---|---|---|---|---|---|---|---|---|
| Biotribology | | | | | | ||||
| Bones Diseases | | | | | | ||||
| Robotics | | | | | | ||||
| Laser Tissue/ Interaction | | | | | | ||||
| Lower Artificial Limbs | | | | | | | | |
|
| Project Engineering Reports | | | | | |
Fifth stage lectures / Frst semester
| اسم المادة | Topics | Lecture | ||||||
|---|---|---|---|---|---|---|---|---|
| Engineering Economics | | | | | | |||
| Biomodelling and Simulation | | | | | | | |
|
| Tissue engineering | | | | | | |||
| Physiotherapy | | | | | | |||
| Transport phenomena | | | | | |
Fifth stage lectures/second semester
| اسم المادة | Topics | Lecture | ||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Drug Delivery | | | | | | |||||||
| Smart Artificial Limbs | | | | | | |||||||
| Rehabilition | | | | | | |||||||
| Hospital Engineering Management | | | | | | |||||||
| Artificial Organs | | | | | | | | | | | |