BSc (Hons) Biomedical Engineering

The BSc (Hons) Biomedical Engineering program at the University of Surrey offers a comprehensive curriculum designed to equip students with the essential knowledge and practical skills needed to innovate and advance healthcare technologies. This multidisciplinary course seamlessly integrates engineering principles with biomedical sciences, preparing graduates to address complex challenges in the medical device industry, healthcare provision, and medical research. Throughout their studies, students explore core topics such as biomechanics, biomaterials, medical instrumentation, and biological systems, gaining a deep understanding of how engineering solutions can improve patient outcomes. The program emphasizes hands-on learning through state-of-the-art laboratories, collaborative projects, and industry placements, providing real-world experience and fostering critical problem-solving abilities. Students also have opportunities to engage with cutting-edge topics like regenerative medicine, imaging technologies, and wearable health devices, ensuring they stay at the forefront of technological advancements. The curriculum is designed to develop both technical expertise and transferable skills such as teamwork, communication, and project management. Upon graduation, students are well-prepared for careers in medical device development, healthcare technology consultancy, clinical engineering, or further postgraduate research. The University of Surrey’s strong links with industry partners and research institutions ensure that students benefit from up-to-date industry insights and networking opportunities. Graduates of this program are positioned to contribute meaningfully to the evolving field of biomedical engineering, supporting innovations that enhance healthcare delivery and patient care worldwide.

The BSc Biomedical Engineering program at the University of Surrey offers a comprehensive curriculum designed to equip students with the essential knowledge and practical skills necessary to innovate and excel in the rapidly evolving field of biomedical technology. Throughout the course, students will explore the fundamental principles of engineering, biology, and medicine, integrating them to develop advanced medical devices, diagnostic equipment, and healthcare solutions. The program emphasizes both theoretical understanding and practical application, ensuring graduates are well-prepared to address real-world challenges in healthcare and biomedical industries.

Students begin their studies by gaining a solid foundation in mathematics, physics, and engineering principles, which are essential for understanding complex biomedical systems. As they progress, they delve into specialized modules covering areas such as biomechanics, biomaterials, medical imaging, digital health, and biomechanics. The curriculum also includes training in programming, data analysis, and machine learning, reflecting the growing importance of digital technologies in biomedical research and healthcare delivery.

A key feature of the program is the emphasis on hands-on experience. Students participate in laboratory classes, design projects, and industry-focused workshops that foster practical skills in system design, prototyping, and testing. The program incorporates opportunities for work placements and industry collaborations, providing students with valuable real-world experience and networking opportunities within the biomedical sector.

Research-led teaching is a hallmark of the program, with faculty members at the University of Surrey engaged in cutting-edge biomedical research. This ensures that course content remains current and relevant, incorporating the latest advances in medical technology and healthcare innovations. Students also have access to state-of-the-art laboratories and facilities, supporting their development as skilled engineers capable of contributing to medical device development, healthcare improvement, and biomedical research.

Graduates of the BSc Biomedical Engineering program are prepared for careers in medical device companies, healthcare providers, research institutions, and regulatory agencies. They are equipped to work in multidisciplinary teams, applying engineering solutions to improve patient care and health outcomes. Additionally, the program provides a solid foundation for those interested in postgraduate studies or research careers in biomedical engineering and related disciplines. With a focus on innovation, practical skills, and industry relevance, the program at the University of Surrey aims to produce highly qualified professionals ready to make significant contributions to the biomedical field.

A minimum of 112 UCAS tariff points from your overall qualifications, including at least two A-levels or equivalent, is typically required for entry. Applicants are expected to have achieved at least grade C/4 or above in GCSE Mathematics and Science (Physics, Chemistry, or Biology). Relevant work experience or knowledge of engineering principles can be advantageous but is not mandatory. Applicants whose first language is not English must demonstrate proficiency through tests such as IELTS with an overall score of 6.5 or higher, including a minimum of 6.0 in each component, or equivalent qualifications. The program also considers applicants with other qualifications or work experience that demonstrate their ability to undertake higher education learning in this field. The selection process may include an interview or aptitude test, especially for applicants without traditional academic qualifications but with relevant skills or experience. The university values applicants who show enthusiasm for biomedical engineering and an understanding of the field’s interdisciplinary nature, combining principles from engineering, biology, and medicine. A strong background in mathematics and sciences is essential for success in this programme, as it forms the foundation of the coursework and practical applications. Additionally, students should be prepared to undertake coursework that involves significant laboratory work, projects, and potential placements or industry collaborations. The programme aims to develop technical expertise, problem-solving skills, and innovative thinking in areas such as medical device design, diagnostics, and healthcare technology. Finally, applicants are advised to review the specific entry requirements for each intake year on the university’s official admissions pages, as these can be updated or adjusted based on applicant pool and academic policies.

The University of Surrey offers a range of financial support options for students pursuing the Biomedical Engineering undergraduate program. The program's tuition fees vary depending on the student's domicile. For UK students, the annual tuition fee is approximately £9,250, while international students can expect to pay around £20,500 per year. These fees cover the costs of lectures, laboratory work, access to university facilities, and support services. To assist students in financing their studies, the university provides various scholarships and bursaries based on academic excellence, financial need, or specific criteria related to the program. Notable scholarships include the Surrey Undergraduate Scholarships, which offer partial tuition fee waivers to eligible students. Additionally, students may be eligible for government-funded loans such as the Student Loan Company (SLC) loans for UK residents, which can cover tuition fees and living costs. International students are encouraged to explore scholarships offered directly by the university or through external funding agencies in their home countries. Part-time work opportunities are also available on campus, enabling students to gain work experience while earning additional income. The university provides comprehensive financial guidance services to help students understand their options and apply for suitable funding. Furthermore, prospective students are advised to check the university's official website regularly for updated information on tuition fees and financial support schemes. Studying Biomedical Engineering at Surrey is an investment in a high-demand field, and the university's support system aims to make education accessible through a combination of scholarships, loans, and employment opportunities.

The BSc (Hons) Biomedical Engineering program at the University of Surrey is designed to provide students with a comprehensive understanding of the integration of engineering principles with biological and medical sciences. This interdisciplinary course aims to equip students with the technical skills and scientific knowledge necessary to develop innovative solutions for healthcare and medical technology. The program covers various aspects of biomedical engineering, including biomechanics, medical imaging, biomaterials, instrumentation, and rehabilitation engineering. Students will gain practical experience through laboratory work, project-based learning, and opportunities for industry placements, fostering both theoretical understanding and hands-on skills.

The curriculum emphasizes a multidisciplinary approach, encouraging students to collaborate with experts from different fields such as medicine, engineering, and biology. Throughout the course, students are introduced to emerging technologies like biomedical sensors, drug delivery systems, and artificial organs, preparing them for careers in medical device design, research, and development, or further postgraduate study. The university’s state-of-the-art laboratories and research facilities support experiential learning, enabling students to work on real-world problems and contribute to ongoing research projects.

The program aims to produce graduates who are competent in designing, analyzing, and improving healthcare systems and devices, with a solid foundation in engineering principles and biological sciences. Graduates of the Biomedical Engineering course at Surrey are well-prepared for employment in medical technology companies, healthcare providers, research institutions, or to pursue postgraduate studies. The university maintains strong links with the biomedical industry, offering networking opportunities, internships, and collaborative projects, which enhance employability prospects. Overall, the program combines rigorous academic content with practical application to foster innovative problem solvers dedicated to advancing healthcare technology and improving patient outcomes.