Biomedical Engineering
Biomedical engineers use science, engineering, and mathematics to understand and solve medical problems. We focus on improving people’s quality of life. Biomedical engineers who specialize in biomechanics design and analyze biological systems or medical devices that have to do with forces, stresses, and strains. This includes studying the motions of bodies or joints, fluid flow, the deformation of tissues or materials, and the transport of molecules and chemicals through tissues and across membranes.
Biomedical engineers who specialize in bioinstrumentation use electronics and signal analysis to take measurements from and deliver stimuli to living cells and tissues. Examples include cochlear implants, pacemakers, and patient monitoring equipment. Biomedical engineers who specialize in biomaterials design and study materials to replace, repair, and interact with cells and tissues in the body. Examples include metal, ceramic, polymer, or tissue-engineered implants; these implants can be permanent or biodegradable. The United States Bureau of Labor Statistics has projected that jobs for biomedical engineers will increase by 23% between the years 2014 and 2024.
The biomedical engineering program at Rose-Hulman produces engineers with the medical and biological expertise needed to solve health care problems during careers in technical and health-related industries, as well as in government or industrial laboratories. Alumni wishing to continue their studies in graduate/professional school or health professions programs will be well-qualified to do so.
Biomedical Engineering Program Educational Objectives
Objectives are defined as "expected accomplishments of graduates during
the first several years following graduation from the program."
- Graduates will apply the theories and concepts of biology, mathematics, physical science and engineering science essential to being a successful biomedical engineer.
- Graduates will apply practical and technical skills required for biomedical engineering practice.
- Graduates will work and communicate effectively with all of the people around them.
- Graduates will exercise their professional responsibilities towards society.
- Graduates will apply design principles to open-ended problems subject to technical, practical and societal constraints.
Biomedical Engineering Student Outcomes
By the time students graduate with an undergraduate Biomedical Engineering degree from Rose-Hulman, they will have:
- An ability to apply knowledge of mathematics, science, and engineering.
- An ability to design and conduct experiments, as well as to analyze and interpret data.
- An ability to design a system, component, or process to meet desired needs within realistic constraints such as economic, environmental, social, political, ethical, health and safety, manufacturability, and sustainability.
- An ability to function on multidisciplinary teams.
- An ability to identify, formulate, and solve engineering problems.
- An understanding of professional and ethical responsibility.
- An ability to communicate effectively.
- The broad education necessary to understand the impact of engineering solutions in a global, economic, environmental, and societal context.
- A recognition of the need for, and an ability to engage in life-long learning.
- A knowledge of contemporary issues.
- An ability to use the techniques, skills, and modern engineering tools necessary for engineering practice.
The biomedical engineering program is accredited by the Engineering Accreditation Commission of ABET, www.abet.org.
Biomedical Engineering Areas of Concentration
To receive the B.S. Degree Program in Biomedical Engineering, each student must satisfy the requirements of one of three Biomedical Engineering Areas of Concentration: Biomaterials, Biomechanics or Biomedical Instrumentation. The course options for each of these Areas are given below. A total of 16 credits (including required courses) from one of the lists must be taken.
It is not permissible to "mix and match" courses from different area lists without written permission from the BBE department head.
Biomedical courses that are offered as special topics courses (e.g. BE491 or BE597) may be used with the written permission of the department head. Students should work out their schedule in advance to ensure that all graduation requirements are met.
BIOMATERIALS CONCENTRATION
Course | Title | |
---|---|---|
BE 516 | Introduction to MEMS | |
BE 539 | Multiscale Biomechanics | |
BE 560 | Tissue-Biomaterial Interactions | |
BE 570 | Introduction to Tissue Engineering | |
CHE 315* | Materials Science and Engineering | |
CHE 441 | Polymer Engineering | |
ME 317 | Design for Manufacturing | |
ME 328* | Materials Engineering |
*CHE 315 OR ME 328 may be used, but not both
BIOMEDICAL INSTRUMENTATION CONCENTRATION
Course | Title | |
---|---|---|
BE 340 | Biomedical Instrumentation and Signal Processing | |
BE 350 | Biocontrols | |
BE 435/535 | Biomedical Optics | |
BE 516 | Introduction to MEMS | |
BE 520 | Introduction to Brain-Machine Interfaces | |
BE 541 | Medical Imaging | |
BE 543 | Neuroprosthetics | |
BE 555 | Electrophysiology | |
ECE 230 | Introduction to Embedded Systems | |
ECE 480 | Introduction to Image Processing | |
ME 430 | Mechatronic Systems |
BIOMECHANICS CONCENTRATION
Course | Title | |
---|---|---|
ME 317 | Design for Manufacturing | |
BE 525 | Biomedical Fluid Mechanics | |
BE 531 | Biomechanics II | |
BE 534 | Soft Tissue Mechanics | |
BE 539 | Multiscale Biomechanics | |
BE 545 | Orthopaedic Biomechanics | |
BE 550 | Research Methods in Biomechanics | |
EM 403 | Advanced Mechanics of Materials | |
ME 422 | Finite Elements for Engineering Applications | |
ME 520 | Computer-Aided Design and Manufacturing | |
ME 522 | Advanced Finite Element Analysis |
Biomedical Engineering Thesis Option:
The biomedical engineering thesis option is intended for students who complete a substantive research project in this field. In order to complete this thesis option a student must:
- Pass a minimum of 8 credit hours of BE 492.
- Perform research in BE492 that involves the same research project and is completed under the direction of a departmental faculty mentor. None of these credits may be used to fulfill the biomedical engineering area elective requirement.
- Complete the course, BE 499 Thesis Research, in which the thesis is written and submitted to the department, and an oral research presentation is given to a minimum of three departmental faculty members, including the student’s advisor. Successful completion of the biomedical engineering thesis will be noted on the student’s transcript.
The biomedical engineering minor is intended to provide a biomedical engineering background to undergraduate students who are interested in pursuing careers in the biomedical industry and healthcare related fields.
In order to complete the requirements of the biomedical engineering minor, a student must complete either BIO 110-Cell Structure & Function or BIO 120-Comparative Anatomy & Physiology AND complete four courses from the list shown below. Other BE courses may be substituted with approval by the BBE Department Head. At least three of the courses must have a BE prefix.
Course |
Title |
---|---|
BIO411 |
Genetic Engineering |
BE310 |
Analysis of Physiological Systems I |
BE320 |
Analysis of Physiological Systems II |
BE331 and BE352 |
Biomechanics and Biomechanics Lab |
BE340 * |
Biomedical Signal Processing * |
BE350 ** |
Biocontrol Systems ** |
BE361 and BE353 |
Biomaterials and Biomaterials Lab |
BE435/535 |
Biomedical Optics |
BE/MA482 |
Bioengineering Statistics |
BE520 |
Introduction to Brain Machine Interfaces |
BE525 |
Biomedical Fluid Mechanics |
BE531 |
Biomechanics II |
BE534 |
Soft Tissue Mechanics |
BE539 |
Multiscale Biomechanics |
BE543 |
Neuroprosthetics |
BE545 |
Orthopaedic Biomechanics |
BE560 |
Tissue-Biomaterial Interactions |
BE570 |
Introduction to Tissue Engineering |
* BE340 cannot be used for a BE minor by students majoring in electrical or computer engineering.
** BE350 cannot be used for a BE minor by students who have taken ECE320 or ME406.
In addition to courses in the above area concentration, students are required to have completed at least 12 credits of basic engineering courses. These courses may be chosen from the list below:
Course |
Title |
---|---|
BE201 |
Biomedical Instrumentation and Measurements |
EM121 |
Statics & Mechanics of Materials I |
EM204 |
Statics & Mechanics of Materials II |
EM301 |
Fluid Mechanics |
ECE180 |
Introduction to Signal Processing |
ECE203 * |
DC Circuits |
ECE204 ES201 |
AC Circuits Conservation & Accounting Principles |
ES202 |
Fluid Systems |
ES203 * |
Electrical Systems |
ES204 |
Mechanical Systems |
CHE201 |
Conservation Principles and Balances |
CHE202 |
Basic Chemical Process Calculations |
CHE301 |
Fluid Mechanics |
* Students may use either ECE203 or ES203 for a BE minor, but not both of these courses.
Successful completion of an area minor is indicated on the student’s transcript. A student interested in pursuing an area minor in biomedical engineering should consult with the head of the Department of Biology and Biomedical Engineering.