Biomedical Engineering

Description

The biomedical engineering program prepares students to solve important human health-related scientific problems through the application of engineering principles, ideas, methods, and inventions. The program emphasizes critical and creative thinking in addition to technical skills and knowledge and provides students with opportunities to apply these skills and knowledge to the solution of real world problems. A strong foundation in basic sciences and math, including biology, chemistry, physics, and data analysis, coupled with specific biomedical engineering coursework provides students with a broad interdisciplinary background for careers in a wide variety of fields including biomechanics, biotechnology, rehabilitation, medicine, and more.

In addition to science and engineering coursework that emphasizes teamwork and problem-solving, students in this program are immersed in the professional setting and gain practical experience through a required clinical immersion and a two-semester design capstone experience that is tailored to their career interests. As a result, students in biomedical engineering are prepared to play a key role in the research, design, and development of innovations in biomedical procedures and devices. Graduates are also well-positioned to pursue continuing education in the health professions , graduate studies in engineering or science or other professional programs.

Program Educational Objectives

The Biomedical Engineering program at Stevenson University nurtures students to become competent professionals and caring citizens who improve the health and well-being of others by:

1. Making substantive progress in post-graduate training in biomedical and related fields or other professional programs and/or transitioning into professional practice in their chosen career path.

2. Making purposeful and substantive contributions to their organizations, communities, and the biomedical field through creative problem solving, demonstrating compassion and empathy, and reflecting an understanding of social, environmental, and economic considerations.

3. Succeeding in a broad spectrum of professional careers, such as research and development, medicine, and engineering, including fields such as medical devices and diagnostic systems, biomechanics, biotechnology, or rehabilitation.

Outcomes

Upon successful completion of the Bachelor of Science in Biomedical Engineering, graduates will be able to:

1.  Apply knowledge of mathematics, science, and engineering principles to the description and analysis of living systems.

2.  Design and conduct experiments, including the analysis and interpretation of data.

3.  Design a system, component, or process that meets desired needs within relevant constraints such as economic, environmental, ethical, safety, sustainability and others.

4.  Collaborate effectively to formulate, test and refine an engineering solution to a biomedical problem or issue.

5.  Evaluate scientific issues and findings using primary research literature.

6.  Communicate scientific and engineering findings or conclusions in written and oral formats appropriate to the audience.

7.  Conduct oneself in a manner consistent with the ethical and professional standards of the discipline.

8.  Apply academic preparation to professional experiences outside the classroom.

Upon successful completion of the Bachelor of Science in Biomedical Engineering, graduates will be able to demonstrate the following learning outcomes defined by the Accreditation Board for Engineering and Technology (ABET):

1 - an ability to identify, formulate, and solve complex engineering problems by applying principles of engineering, science, and mathematics

2 - an ability to 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

3 - an ability to communicate effectively with a range of audiences

4- an ability to recognize ethical and professional responsibilities in engineering situations and make informed judgements, which must consider the impact of engineering solutions in global, economic, environmental, and societal contexts

5 - an ability to function effectively on a team whose members together provide leadership, create a collaborative and inclusive environment, establish goals, plan tasks, and meet objectives

6 - an ability to develop and conduct appropriate experimentation, analyze and interpret data, and use engineering judgment to draw conclusions

7 - an ability to acquire and apply new knowledge as needed, using appropriate learning strategies

Policies

Students must earn a minimum GPA of 2.00 in the major. The lowest acceptable grade is a "C" in all courses listed in the catalog under "Program Requirements" for the major, including both courses in the major and SEE courses required by the major. No student, regardless of major, will be permitted to take a science or math course* unless they earn a grade of "C" or better in all prerequisite courses.

A student must maintain a science and math GPA of 2.0 or better in each semester in order to remain in good standing within the major. Grades are reviewed each semester and students are notified in writing of their academic status in the major, as appropriate:

• Probation: The student who earns a science and math GPA less than 2.0 in one semester will be notified, in writing, by the Department Chair that they are on probation in the Fine School of the Sciences. Students who are on probation will be required to meet regularly with their Success Coach/Academic Advisor for at least one full semester after being put on probation.
• Dismissal: The student who earns a science and math GPA less than 2.0 for a second semester will be notified, in writing, by the Department Chair that they are dismissed from the applied mathematics, biochemistry, biology, biomedical engineering, chemistry, or environmental science major.

* Science and mathematics courses are defined as courses with the designation: BIO, BIOCH, BME, CHEM, ENV, FSCI, MATH, PHYS, or SCI. 

Requirements

The courses listed below are required for completion of the bachelor's degree in biomedical engineering. Students must also complete the requirements for the Stevenson Educational Experience (SEE). Specific pre- and co-requisities are listed in the course descriptions.

Major Requirements:

Basic Science Electives:

Select one from the following list:

Biomedical Engineering Electives:

Select two from the following list:

Suggested Course Sequence

2023-24 SCS Biomedical Engineering

Minor in Biomedical Engineering

A minor in biomedical engineering is not available.

Other Options

Other options are not available at this time.

Course Descriptions

See Biomedical Engineering Course Descriptions