M.S. in Business Analytics & Project Management
UConn's M.S. in Business Analytics & Project Management program is designed for...
B.S.E in Biomedical Engineering
Storrs
INTAKE: August
Program Overview
The Bachelor of Science in Engineering (B.S.E.) in Biomedical Engineering at the University of Connecticut (UConn) is an interdisciplinary program that integrates engineering principles with medical and biological sciences. Designed to equip students with the knowledge and skills needed to develop innovative healthcare technologies, the program focuses on designing medical devices, improving diagnostics, and enhancing treatment methods. Graduates from this program are well-prepared for careers in medical device manufacturing, biotechnology, pharmaceuticals, healthcare research, and more. UConn’s commitment to cutting-edge research and industry partnerships ensures that students receive both theoretical and practical experience in biomedical engineering.
STEM Designated: The B.S.E. in Biomedical Engineering at UConn is STEM-designated, highlighting its focus on science, technology, engineering, and mathematics. This designation not only reflects the program’s strong technical foundation but also offers international students the opportunity to apply for extended Optional Practical Training (OPT) benefits in the U.S. The STEM designation underscores the program’s emphasis on innovation, research, and the application of engineering techniques to solve complex medical challenges.
Curriculum: The curriculum for Biomedical Engineering at UConn provides students with a comprehensive understanding of engineering fundamentals, biological sciences, and medical applications. Core courses include Biomechanics, Biomedical Instrumentation, Biomaterials, Medical Imaging, Systems Physiology, Tissue Engineering, and Bioinformatics. The program also incorporates hands-on laboratory work, computational modeling, and design projects to ensure students gain practical experience. Elective courses allow students to specialize in areas such as neural engineering, regenerative medicine, and medical device design, tailoring their education to align with career aspirations.
Research Focus: UConn is a leader in biomedical engineering research, offering students the opportunity to work on groundbreaking projects that improve healthcare solutions. Faculty and students engage in research areas such as biomechanics, tissue engineering, drug delivery systems, biomedical imaging, and nanomedicine. UConn’s Institute for Regenerative Engineering and Biomedical Engineering Research Centers provide state-of-the-art facilities for students to collaborate on innovative research projects. Through these research initiatives, students gain valuable experience in developing new medical technologies, publishing scientific papers, and contributing to advancements in the biomedical field.
Industry Engagement: The Biomedical Engineering program at UConn maintains strong industry connections with medical device manufacturers, hospitals, and research institutions. Students benefit from internships, cooperative education (co-op) programs, and industry-sponsored projects with leading companies such as Medtronic, Johnson & Johnson, Siemens Healthineers, and Boston Scientific. These partnerships provide students with hands-on experience in designing, testing, and improving biomedical devices and healthcare technologies. UConn also hosts industry networking events, career fairs, and guest lectures from professionals in the biomedical engineering field, ensuring that students are well-prepared for careers after graduation.
Global Perspective: Biomedical engineering is a globally relevant field, and UConn ensures that students develop a broad understanding of international healthcare challenges and solutions. The program offers study abroad opportunities, international research collaborations, and exposure to global medical technology trends. Courses emphasize the ethical considerations of biomedical engineering, regulatory requirements, and the impact of technology on healthcare systems worldwide. Students gain insights into how biomedical engineering innovations can address health disparities and improve patient care across different regions.
Location
Storrs
Score
IELTS 6.5
Tuition Fee
USD 39678
Undergraduate Entry Requirements
Academic Qualifications: Applicants for undergraduate programs typically require a minimum academic achievement of 70% or above in their previous academic qualifications.
English Language Proficiency:
- IELTS: Overall band score of 6.5 or 7.0 with a minimum of 6.0 in each component.
- TOEFL: Overall score of 79 or higher.
- DET (Duolingo English Test): Minimum score of 100.
The University of Connecticut (UConn) offers a range of merit-based scholarships to support international students in their academic journey. These scholarships are designed to recognize exceptional academic achievements and leadership qualities.
Global Excellence Award: This scholarship is awarded to international students who have demonstrated outstanding academic performance and leadership both in and outside the classroom.
Global Distinction Award: Similar to the Global Excellence Award, this scholarship recognizes international students with exceptional academic records and leadership abilities.
Global Leader Award: This award honors international students who have shown exceptional academic achievement and leadership qualities.
Graduates of the B.S.E. in Biomedical Engineering program at the University of Connecticut (UConn) are highly sought after in the healthcare, medical device, and biotechnology industries. With a strong foundation in both engineering and biological sciences, students are equipped to solve complex problems related to human health and medical technologies.
Biomedical Engineer: Biomedical engineers design and develop medical devices, prosthetics, and equipment that improve patient care. They work in medical device companies, hospitals, and research institutions to create solutions for diagnosing, treating, and monitoring various health conditions. Biomedical engineers are essential in areas like prosthetics, imaging systems, surgical robots, and diagnostic equipment.
Medical Device Engineer: Medical device engineers specialize in designing, testing, and improving devices used in medical treatments. These engineers ensure that devices like heart monitors, infusion pumps, pacemakers, and surgical instruments meet safety standards, regulatory requirements, and performance criteria. Medical device engineers often work for companies like Medtronic, Boston Scientific, and Johnson & Johnson.
Clinical Engineer: Clinical engineers work in hospitals and healthcare facilities, where they manage, maintain, and troubleshoot medical equipment. They play a key role in ensuring that healthcare institutions are equipped with properly functioning medical devices, such as radiology machines, ventilators, and surgical instruments. Clinical engineers often collaborate with medical professionals to understand their needs and recommend appropriate technologies.
Tissue Engineer: Tissue engineers work on developing biological tissue substitutes that can be used for medical treatments, organ regeneration, and transplantation. This field combines principles of biology, chemistry, and engineering to create tissue scaffolds and promote the growth of cells. Tissue engineers work in biotechnology firms, research laboratories, and hospitals developing products like artificial organs or wound healing materials.
Biomaterials Engineer: Biomaterials engineers focus on the design and development of materials that are compatible with the human body. These materials are used in medical devices, implants, and prosthetics. Biomaterials engineers ensure that these materials meet biological, mechanical, and ethical standards. They work with companies specializing in implants, drug delivery systems, and wound care products.
Regulatory Affairs Specialist: Regulatory affairs specialists in biomedical engineering manage the approval process for medical devices, ensuring that they meet regulatory requirements for safety and efficacy. They work closely with government agencies like the FDA (Food and Drug Administration) to ensure compliance with regulations. This role is critical in bringing biomedical innovations to market while maintaining safety standards.
Research Scientist in Biomedical Engineering: Research scientists in biomedical engineering engage in the development of new technologies, methodologies, and treatments. They work in universities, research labs, and medical device companies to push the boundaries of biomedical science. Their work can involve developing new imaging techniques, improving diagnostics, or advancing therapeutic technologies.
Biomechanics Engineer: Biomechanics engineers focus on studying the mechanical aspects of the human body. They apply engineering principles to understand movement, posture, and force, which is particularly relevant in areas like orthopedics, rehabilitation engineering, and sports medicine. Biomechanics engineers work in academic research, sports technology, and rehabilitation centers to design orthotic devices or prosthetic limbs.
Healthcare Data Analyst: Healthcare data analysts analyze large sets of health-related data to inform decision-making in medical treatment, hospital administration, and policy development. They work with healthcare providers, insurance companies, and government agencies to derive insights from clinical data, patient records, and health trends. Their work supports the optimization of patient care and healthcare operations.
Bioinformatics Specialist: Bioinformatics specialists apply data science to biological data, including genomic and clinical data. They work with medical professionals to analyze large datasets to improve patient care and guide treatment plans. This role is important for developing personalized medicine and understanding the genetic basis of diseases.
Nanomedicine Engineer: Nanomedicine engineers use nanoscale technologies for diagnosing and treating diseases. They design and develop nanoparticles, drug delivery systems, and nanosensors that can target specific cells in the body, allowing for more effective treatments with fewer side effects. Nanomedicine engineers work at the forefront of the biotechnology and pharmaceutical industries.
Pharmaceutical Engineer: Pharmaceutical engineers work in the development and manufacturing of drugs and medications. They are involved in the formulation, production, and testing of new drugs, focusing on safety, efficacy, and cost-effectiveness. Pharmaceutical engineers may work in drug manufacturing companies or research institutions.
Project Manager in Biomedical Engineering: Project managers in biomedical engineering oversee the development and implementation of biomedical projects, from medical device production to clinical trials. They coordinate teams of engineers, researchers, and healthcare professionals, ensuring that projects are completed on time, within budget, and meet regulatory standards.
Entrepreneur in Medical Technology: For those with an entrepreneurial spirit, the B.S.E. in Biomedical Engineering provides the skills to start a business in the medical technology field. Biomedical engineering graduates can innovate by creating their own medical devices, healthcare apps, or biotechnology solutions. This career option combines engineering expertise with business acumen to develop and market new technologies.
Consultant in Biomedical Engineering: Consultants in biomedical engineering advise companies, healthcare organizations, or government agencies on biomedical technologies, healthcare innovations, and regulatory compliance. They provide specialized knowledge to improve operations, optimize product development, and assess emerging technologies.
