Apr 17, 2024  
UofM 2021-2022 Undergraduate Catalog 
    
  Catalog Home
  COVID-19 Statement
  About UofM
  About Catalog
  Course Descriptions
  Undergraduate Catalog Archive
  Academics
  UofM President’s Message
  Academic Program Accreditation
  Academic Regulations
  Academic Year Calendars
  Academic Forms
  Explanation of Course Footnotes
  Academic Programs
  Undergraduate Programs
  Minors
  Degree Type
  Accelerated Programs
  Certificate
  Students
  Apply Now!
  Undergraduate Admissions and Orientation
  Transfer Students
  Military Students
  Dual Enrollment
  Student Aid & Scholarships
  University & Student Business Services (Bursar)
  Services for Students
  Parent & Family Involvement
  Campus Directory
  Campus Map
  Notice to Students
  Graduation from University
  General Education Requirements
  Planning
  General Requirements & Graduation
  College and Degree Requirements
  Colleges and Departments
  University Administration, Faculty and Staff
  College of Arts and Sciences
  College of Communication and Fine Arts
  College of Education
  College of Professional & Liberal Studies
  Fogelman College of Business & Economics
  Helen Hardin Honors College
  Herff College of Engineering
  Kemmons Wilson School of Hospitality and Resort Management
  Loewenberg College of Nursing
  School of Communication Sciences and Disorders
  College of Health Sciences
  School of Public Health
  UofM Global
  My Portfolio
HELP
UofM 2021-2022 Undergraduate Catalog [ARCHIVED CATALOG]

Department of Biomedical Engineering

Facebook this Page (opens a new window)
Tweet this Page (opens a new window)

Return to {$returnto_text} Return to: Herff College of Engineering

Biomedical Engineering is a broad field that encompasses many areas related to improving human health such as implant devices, tissue engineering/regeneration, electrophysiological signaling, and biosensors and imaging technologies for the prevention, detection, diagnosis, and treatment of diseases. The program integrates physical, chemical, mathematical, and computational sciences and engineering with biology and medicine.

The curriculum is designed to prepare graduates for professional practice and to provide a foundation for lifelong learning and professional growth. The course of study begins with a strong foundation in mathematics, physics, chemistry, biology, and engineering sciences. Departmental courses during these years build on these foundations to integrate topics in basic sciences and engineering into knowledge in biomedical engineering. The upper division years include a block of electives (noted as BIOM, Engineering and Technical electives in the typical sequence) to allow students, with advisor’s assistance, the means to tailor study in a focused portion of the discipline and its supporting fields as desired. The elective hours must be upper division courses. Concepts and efforts in engineering design occur throughout the curriculum and culminate in a senior design project.

The Biomedical Engineering program is accredited by the Engineering Accreditation Commission of ABET, http://www.abet.org.

Enrollment and graduation data can be found on the department’s website, https://www.memphis.edu/bme/.

The Biomedical Engineering Program at the University of Memphis aims to produce graduates who demonstrate the following program educational objectives within the first few years after graduation:

  • secure employment in biomedical or related health industries or institutions,
  • pursue professional studies,
  • pursue opportunities for professional growth, development, and service

Graduates of Biomedical Engineering will have demonstrated the following student outcomes:

  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 judgments, 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.

The diversity encountered in the profession requires the successful biomedical engineer to have technical and non-technical skills, especially for communication and team efforts. Courses in the humanities and social sciences enhance non-technical skills, and explore the engineer’s relationship with, and responsibility to, society. Studies in the sciences and other engineering disciplines provide a broad background for applying multidisciplinary knowledge to find solutions for biomedical problems. Materials in engineering ethics and professionalism are essential because our graduates and the field expect to enrich life and provide solutions with known benefits and defined risks.

This curriculum equips typical Biomedical Engineering graduates of the University of Memphis with the skills, knowledge, and perspectives required for success in a variety of professional roles. These include the ability to conduct project design work, to work collaboratively on projects, to interact and communicate successfully across disciplines and with the public, and to pursue professional careers ranging from research and development, testing and quality control, regulatory, sales and marketing, and advanced studies in engineering, business, medicine, law, or other fields if so desired.

GRADUATION: To qualify for the degree of Bachelor of Science in Biomedical Engineering, the student must satisfy University and College requirements, obtain a minimum 2.0 grade point average on all work completed, and obtain a minimum grade of “C-” in all engineering, mathematics, physics, biology, and chemistry courses used to satisfy degree requirements. Waiver of departmental graduation requirements for exceptional circumstances will be granted only upon approval of both the department chair and the Dean of the College of Engineering (or designee).

Honors in Biomedical Engineering
The Biomedical Engineering Honors Program is for highly motivated and high-achieving students, and provides special opportunities to advance the career and professional development of the student. The program aims to develop student talents, interests, and abilities within a curricula, as well as encourage independence and creativity.

Students are eligible for the honors program in biomedical engineering if they have and maintain a cumulative GPA of 3.4 with at least junior standing, and have received approval from the departmental honors committee. The honors program in biomedical engineering requires a minimum of 10 hours of upper-division biomedical engineering honors courses, including both BIOM 4800  BME Honors seminar, and completion of an honors thesis (BIOM 4999 ). Students who complete the honors program and the requirements for the B S in Biomedical Engineering will be recognized at the commencement ceremony by having their degree conferred “With Honors in Biomedical Engineering.” Honors designation will also appear on the student’s diploma and academic transcript.

Programs

    MajorAccelerated Bachelor/Masters

    Return to {$returnto_text} Return to: Herff College of Engineering


    Facebook this Page (opens a new window)
    Tweet this Page (opens a new window)