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Bachelor of Science in Engineering, Biomedical Engineering

• Emphases
• Mechanical Emphasis
• Product Design and Manufacturing Emphasis
• Suggested Order of Coursework for the Biomedical Engineering Major - Electrical Emphasis

By applying engineering methods to solve medical and biological problems, biomedical engineers aim to improve our quality of life. The National Institute of Health's working definition of biomedical engineering adopted on July 24, 1997, states:

• "Biomedical engineering integrates physical, chemical, mathematical, and computational sciences and engineering principles to study biology, medicine, behavior, and health. It advances fundamental concepts; creates knowledge from the molecular to the organ systems level; and develops innovative biologics, materials, processes, implants, devices and informatics approaches for the prevention, diagnosis, and treatment of disease for patient rehabilitation and for improving health."

A biomedical engineer applies the design, analytical, and problem-solving skills acquired in engineering training to improve health and quality of human life. Biomedical engineers are able to collaborate with health care professionals such as physicians and nurses to apply advanced technological solutions to clinical problems. Their abilities to apply mathematical models and computational simulation to the study of complex physiologic systems are invaluable to the medical science and research community.

Biomedical engineering is a broad discipline with many areas of specialization. Grand Valley offers programming in three emphasis areas:

Electrical Emphasis: Students who elect this emphasis will be prepared to apply fundamental electrical engineering principles to health care. Examples include modeling cardiac physiology to understand arrhythmogenesis, or developing better measurement and diagnostic devices like cardioverter-defibrillators and MRI scanning systems.

Mechanical Emphasis: Students who elect this emphasis will be prepared to apply fundamental engineering mechanics to understanding musculoskeletal systems and transport phenomena in vasculature. Biomechanical engineers help develop better rehabilitation and therapeutic devices like prosthetic limbs, artificial hips, and wheelchairs.

Product Design and Manufacturing Emphasis: Students who elect this emphasis will research and develop ideas and processes for new medical products, improve the performance and design of existing medical products, plan production, and manage production facilities.

Integral to all four years of the program is a "design and build" educational philosophy incorporated through extensive laboratory and project activities as preparation for professional practice. Students engage in design at all levels of the curriculum. At each level, they must realize their designs and proceed with testing, validation, and redesign. This approach allows students to experience many real-world constraints, such as project economics, project planning and scheduling, environmental considerations, manufacturability/producibility of the designs, laboratory and product safety, and product reliability.

Program Educational Objectives

Graduates of the biomedical engineering program are expected within a few years of graduation to

• demonstrate technical competency in their careers;
• function effectively in an industrial or academic environment;
• engage in professional development; and
• shape their professions and societies.

Student Outcomes and Assessment

Graduates will demonstrate an ability to

• identify, formulate, and solve complex engineering problems by applying principles of engineering, science, and mathematics;
• apply engineering design to produce solutions that meet specified needs with consideration of public health, safety, and welfare, as well as global, cultural, social, environmental, and economic factors;
• communicate effectively with a range of audiences;
• recognize ethical and professional responsibilities in engineering situations and make informed judgments, which must consider the impact of engineering solutions in global, economic, environmental, and societal contexts;
• function effectively on a team whose members together provide leadership, create a collaborative and inclusive environment, establish goals, plan tasks, and meet objectives;
• develop and conduct appropriate experimentation, analyze and interpret data, and use engineering judgment to draw conclusions; and
• acquire and apply new knowledge as needed, using appropriate learning strategies.

Degree Requirements

Biomedical engineering students must complete all requirements for the B.S.E. degree including the general education and basic skills requirements, the foundations of engineering courses, cooperative education, the engineering design Capstone, and the following courses.

Required courses for all biomedical engineering emphases:

• BMS 202 - Anatomy and Physiology (4 credits)
• CHM 230 - Introduction to Organic and Biochemistry (4 credits)
• EGR 403 - Medical Device Design (3 credits)
• EGR 435 - Mathematical Modeling of Physiologic Systems (3 credits)

Students must also complete an emphasis from the three options outlined as follows.

Emphases

Three emphases to choose from include: electrical, mechanical, and product design and manufacturing. Each emphasis has required courses and elective courses that are chosen from an approved list.

Electrical Emphasis

Students choosing the electrical emphasis should complete the foundations course for the electrical engineering major.

Required Courses:

• EGR 314 - Circuit Analysis II (4 credits)
• EGR 315 - Electronic Circuits I (4 credits)
• EGR 323 - Signals and Systems Analysis (3 credits)
• EGR 326 - Embedded System Design (4 credits)
• EGR 434 - Bioelectric Potentials (3 credits)

Elective Courses (choose three):

• EGR 343 - Applied Electromagnetics (4 credits)
• EGR 418 - Radio Frequency Systems (4 credits)
• EGR 432 - Biomedical Imaging and Image Processing (3 credits)
• EGR 433 - Electronic Instrumentation for Biomedical Applications (3 credits)
• EGR 436 - Embedded Systems Interface (4 credits)
• EGR 455 - Automatic Control (4 credits)
• EGR 457 - Fundamentals of Nanotechnology (4 credits)

Mechanical Emphasis

Students choosing the mechanical emphasis should complete the foundations course for the mechanical engineering major.

Required Courses:

• EGR 250 - Materials Science and Engineering (4 credits)
• EGR 346 - Mechatronic Systems Dynamics and Control (4 credits)
• EGR 362 - Thermal and Fluid Systems (4 credits)
• EGR 447 - Engineering Mechanics of Human Motion (3 credits)
• EGR 453 - Biomedical Materials (3 credits)

Elective Courses (choose two):

• EGR 329 - Introduction to Finite Element Analysis (3 credits)
• EGR 409 - Machine Design II (4 credits)
• EGR 445 - Robotic Systems Engineering (4 credits)
• EGR 465 - Computational Fluid Dynamics (CFD) (4 credits)
• EGR 468 - Heat Transfer (4 credits)

Product Design and Manufacturing Emphasis

Students choosing the product design and manufacturing emphasis should complete the foundations course for the product design and manufacturing engineering major.

Required Courses:

• EGR 301 - Analytical Tools for Product Design (4 credits)
• EGR 345 - Dynamic System Modeling and Control (4 credits)
• EGR 362 - Thermal and Fluid Systems (4 credits)
• EGR 367 - Manufacturing Processes (4 credits)
• EGR 453 - Biomedical Materials (3 credits)

Elective Courses (choose two):

• EGR 440 - Introduction to Production (3 credits)
• EGR 445 - Robotic Systems Engineering (4 credits)
• EGR 450 - Manufacturing Control Systems (4 credits)
• EGR 465 - Computational Fluid Dynamics (CFD) (4 credits)

Suggested Order of Coursework for the Biomedical Engineering Major - Electrical Emphasis

Junior and Senior Years

First Co-op Semester

Spring/Summer:

• General education World Perspectives (3 credits)
• EGR 290 - Engineering Co-op 1 (3 credits)

Fifth Academic Semester

Fall:

• EGR 314 - Circuit Analysis II (4 credits)
• EGR 315 - Electronic Circuits I (4 credits)
• EGR 326 - Embedded System Design (4 credits)
• CHM 230 - Introduction to Organic and Biochemistry (4 credits)

Second Co-op Semester

Winter:

• General education Issues (3 credits)
• EGR 390 - Engineering Co-op 2 (3 credits)

Sixth Academic Semester

Spring/Summer:

• General education History (3 credits)
• General education Philosophy and Literature (3 credits) PHI 102 is recommended.
• General education Issues (3 credits)
• BMS 202 - Anatomy and Physiology (4 credits)
• EGR 323 - Signals and Systems Analysis (3 credits)

Third Co-op Semester

Fall:

• EGR 434 - Bioelectric Potentials (3 credits)
• EGR 490 - Engineering Co-op 3 (3 credits)

Seventh Academic Semester

Winter:

• Electrical emphasis elective
• Electrical emphasis elective
• EGR 403 - Medical Device Design (3 credits)
• EGR 435 - Mathematical Modeling of Physiologic Systems (3 credits)
• EGR 485 - Senior Engineering Project I (Capstone) (1 credit)

The prerequisites for EGR 485 are acceptance into the B.S.E. degree program and completion of the prerequisite courses listed under the student's engineering major. For the biomedical engineering major with electrical emphasis, the prerequisite courses are: EGR 315, EGR 323, EGR 326, EGR 434, and EGR 390.

Eighth Academic Semester

Spring/Summer:

• Electrical emphasis elective
• General education Social and Behavioral Sciences (3 credits)

• ECO 210 - Introductory Macroeconomics (3 credits) OR ECO 211 - Introductory Microeconomics (3 credits)
• EGR 486 - Senior Engineering Project II (Capstone) (2 credits)

Engineering Program Description

Click here for the program description.