Biomedical Engineering is an interdisciplinary field that combines the principles of engineering, biological and medical sciences to develop technologies and devices that improve health care and treatment. This specialty aims to improve human life through innovation in medical devices, diagnostic tools, treatments, and health systems. Here’s a comprehensive look at the main aspects of the bioengineering major:

Biological and medical basics:

• The study of anatomy and physiology to understand the structures and functions of the human body.
• Understand the basic principles of biochemistry and molecular biology.

Engineering basics:

• Apply mechanical and electrical engineering principles to medical problems.
• Study thermodynamics, biomechanics, and medical electronics.

Medical device design:

• Develop and design medical devices such as implantable devices, biosensors, and diagnostic equipment.
• Use computer-aided design (CAD) techniques to design prototypes.

Medical electrical and electronic engineering:

• Design and maintenance of electronic devices used in medicine such as magnetic resonance imaging (MRI) and computed tomography (CT) machines.
• Developing technologies for sensing and electronic processing of vital signals.

Tissue engineering and stem cells:

• Developing cell and tissue culture techniques for use in regenerative medicine.
• Study tissue engineering techniques to repair and replace damaged tissue.

Diagnostic and therapeutic tools:

• Design and develop innovative diagnostic tools for early detection of diseases.
• Developing drug delivery systems and improving treatment techniques such as radiotherapy and chemotherapy.

Systems bioengineering:

• Study and analyze complex biological systems such as the circulatory and nervous systems.
• Use mathematical and computer models to simulate and analyze these systems.

Environmental Bioengineering:

• The application of bioengineering to solve environmental problems such as water treatment and air purification.
• Developing techniques to utilize biological resources in a sustainable manner.

Research and development:

• Participate in research to develop new technologies and products in the field of bioengineering.
• Publishing research and participating in scientific conferences to share results and innovations.

Ethics and safety:

• Understand the ethical issues related to the development and use of biomedical technologies.
• Commitment to safety and quality standards to ensure the safety of patients and users.

Practical training and clinical applications:

• Obtain practical experience through training in hospitals, research centers and medical companies.
• Apply theoretical knowledge in practical settings to develop effective medical solutions.

Project management and innovation:

• Learn how to manage research and development projects in the field of bioengineering.
• Develop innovation and critical thinking skills to solve complex medical problems.

The Bioengineering major provides broad opportunities to work in diverse fields such as medical device development, medical research, textile engineering, and medical electronics. This specialty contributes significantly to improving health care and providing innovative solutions to contemporary medical challenges, which enhances the quality of life for patients and contributes to the advancement of modern medicine.