Department of Biomedical Engineering
Department of
Biomedical Engineering
Breadcrumb
- RIT/
- College of Engineering/
- Academics/
- Departments/
- Biomedical Engineering
Contact
Jennifer Bailey, Undergraduate Program Director
585-475-4964, jlbbme@rit.edu
Overview
Biocompatibility testing, engineering artificial organs and tissues, developing new drug delivery systems, creating or modifying innovative medical devices, enhancing medical imaging techniques, or designing procedures to meet regulatory requirements are just a few examples of the work performed by a biomedical engineer to improve the health and well-being of others. Biomedical engineers combine their knowledge of engineering with biology, anatomy, and physiology to create devices and systems for a variety of healthcare issues. The need for sophisticated diagnostic and therapeutic equipment and solutions has fueled the demand for biomedical engineers who commonly work in multidisciplinary teams to develop devices, equipment, and procedures for a number of medical applications. The multidisciplinary nature of biomedical engineering requires professionals to develop an expertise in both engineering and biological sciences.
Biomedical engineering applies the principles and theories of engineering to solve problems in the wide-ranging field of medicine. Biomedical engineers can be found working alongside scientists, other engineering professionals, and medical practitioners to evaluate the complex, interdependent systems of the human body to develop effective solutions to enhance the quality of life for all patients. Biomedical engineers play a key role in developing and defining the engineering requirements and specifications necessary to actually bring these devices and protocols to fruition. It is a rapidly growing field with a variety of career opportunities for students with an interest in combining engineering with medicine.
Biomedical engineers are first and foremost engineers. Biomedical engineering is the branch of engineering that uniquely leverages the vast knowledge base of biology and medicine to solve problems focused on health care and the human body. Biomedical engineers can be found working in a variety of settings depending on the type of work they do. Positions are available in academia, hospital laboratories, manufacturing settings as well as commercial offices. Biomedical engineers are employed to:
- Design systems and products, such as artificial internal organs, artificial devices that replace body parts, and machines for diagnosing medical problems
- Work with life scientists, chemists, and medical scientists to research the engineering aspects of biological systems of humans and animals
- Work with pharmaceutical companies to develop new drug therapies
- Evaluate the safety, efficiency, and effectiveness of biomedical equipment
Learn more about the biomedical engineering BS program at RIT
Mission Statement
To educate and train graduates who are technically competent and are prepared to apply knowledge in traditional and modern application domains. Additionally, they will possess a broad education and knowledge of contemporary issues that enable them to anticipate change and continually update their skills. They will also be able to communicate and work effectively with others in a professional and ethical manner to function as a biomedical engineer in a globally-connected society.
Vision
To prepare graduates to either enter directly into the work force as technically competent and sought-after professionals with reinforcement from experiential learning, or to prepare them with the fundamental knowledge to continue their education in graduate programs.
Values
Student Centered: Our department makes decisions and behaves in a manner that demonstrates the primary importance of the students’ needs and interests.
Community: The department is a close-knit community characterized by respect for its differences, inclusion of a diverse set of ideas and people, and friendly collaboration among the faculty, staff, and students.
Teaching Excellence: To demonstrate continuous excellence and innovation in how we deliver classes to our students, and the support we provide our students outside of class.
Experiential Learning: To provide experiential learning throughout the undergraduate curricula via cooperative education, relevant projects, and practical experiences in state-of-the-art labs.
Research: Faculty members will conduct studies that encompass a vast spectrum of the biomedical field, allowing students to engage in innovative research opportunities.
Accreditation
The BS degree in biomedical engineering is accredited by the Engineering Accreditation Commission of ABET, www.abet.org. For enrollment and graduation data, program educational objectives, and student outcomes, please visit the college’s accreditation page.
Industrial Advisory Board
To help ensure that industry needs are satisfied through the proper training and education of biomedical engineering students, an annual meeting is held with the members of the industrial advisory board. The board is comprised of professionals from all areas of biomedical engineering, and also includes some RIT alumni as well.
52/48
Ratio of Men to Women
98%
Outcomes Rate
290
companies have hired biomedical engineering co-op students
Undergraduate Degrees
A biomedical engineering BS combines engineering with biology and medicine to create innovative solutions that improve human health.
Learn more about the Biomedical Engineering BS programGraduate Degrees
Advance the frontiers of science with a Ph.D. program in Biomedical and Chemical Engineering. Explore groundbreaking research.
Learn more about the Biomedical and Chemical Engineering Ph.D. programRIT’s biomedical engineering master’s degree produces professionals who can innovate solutions for today’s most pressing health care challenges.
Learn more about the Biomedical Engineering MS programConduct research in nano-engineering, design methods, and technologies for micro- and nano-scaled systems. This microsystems engineering doctorate is a multidisciplinary program that addresses the technical challenges of micro- and nano-systems.
Learn more about the Microsystems Engineering Ph.D. programResearch
Biological Fluid Mechanics
We analyze and design blood contacting medical devices and study the science and engineering methods used to minimize cell damage.
Biomechanical Imaging
We develop medical imaging techniques to study the mechanical nature of a variety of human pathologies.
Intelligent Interaction Research (I2R)
We develop interactive technologies to help people with cognitive disabilities and mental disorders.
Biological Microsystems
We use microengineering techniques to design 3D extracellular matrix (ECM) environments to study cell and tissue-scale phenomena.
Microscale Bioseparations
We develop rapid microfluidic-based techniques to offer an alternative to traditional bench scale separation & purification processes.
NanoBio Materials
We design and use nanomaterials to solve biomedical problems at the cellular and molecular level.
Tissue Regeneration & Mechanobiology
We use cells, biomaterials, genome engineering, biologics and mechanical cues to promote tissue regeneration.
Latest News
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July 3, 2024
Engineering researchers receive NSF funding to develop computational tools to monitor ablation therapy on cardiac tissue
Researchers at RIT are developing non-invasive technology that will better assess cardiac tissue response to thermal energy, a common therapy approach for both cancer and cardiac arrhythmia treatments.
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June 3, 2024
Engineering faculty and cardiologist collaborate to design heart pump assessment prototype
Researchers at RIT are developing technology that will be able to determine the lifespan of a heart valve with more precision.
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May 13, 2024
Students will ‘live, learn, and explore’ abroad thanks to international fellowships and scholarships
Throughout the course of the academic year, hundreds of RIT students prepare to compete for some of the most prestigious international fellowships and scholarships available. Intensive research projects, applications, essays, and interviews all play a critical role in their selection.
Featured Profiles
2024 Fulbright Scholar: Mikkael Lamoca
Lamoca, who earned a BS in biomedical engineering and an MS in science, technology, and public policy, will spend a 10-month research experience in the BioIonic Currents Electromagnetic...
Biomedical Engineering Students Create Innovative Prototype for Blood Pressure Cuffs
Students in the Senior Multidisciplinary Design are working on a prototype to provide doctors with more accurate equipment to measure blood pressure.
Graduate to Design Prosthetic Devices in the UK as a Fulbright Scholar
Maggie Brooks will complete a Fulbright experience at the University of Southampton in its Amputation and Prosthetic Rehabilitation graduate degree program.
Student Organizations
The mission of the RIT BioPrint club is to provide an interdisciplinary environment geared toward bringing together students from different fields of interest and expertise with the overall goal of learning from one another in a real world, hands-on application environment.
The Biomedical Engineering Society is the professional society for biomedical engineering and bioengineering. Founded in early 1968, the society now boasts more than 7,000 members and is growing rapidly.
Engineering World Health inspires, educates, and empowers young engineers, scientists, and medical professionals from more developed parts of the world to use their engineering skills to improve global health.
Student Resources
The Biomedical Engineering Department offers a variety of resources for our students that vary from academic support to handbooks and more. Visit our Student Resources page for more information.