MRes Leadership and Strategy
The University of Greater Manchester offers a wide array of undergraduate and postgradu...
MSc Biomedical Engineering
Bolton
INTAKE: January
Program Overview
The 18-month MSc Biomedical Engineering program offers an in-depth study of the engineering principles that underpin modern medicine and healthcare technologies. The extended timeframe allows for a more detailed exploration of key subject areas and often includes a more substantial research project or opportunities for practical experience compared to a standard one-year program. The program is structured to cater to graduates seeking a specialization in biomedical engineering, providing them with a robust theoretical framework and the practical skills needed to contribute to the design, development, and application of biomedical solutions. The curriculum typically integrates lectures, seminars, laboratory work, and independent study to facilitate a comprehensive learning experience.
Curriculum: The curriculum of the 18-month MSc Biomedical Engineering program is designed to provide a thorough grounding in both fundamental and advanced topics. Core modules typically cover areas such as advanced engineering modeling and analysis, biomedical devices and implants, biotechnology and regenerative medicine, and research skills and project management. The extended duration may allow for more specialized elective modules or a more extensive individual major project, enabling students to delve deeper into areas of particular interest, such as smart engineering systems or product innovation in the biomedical context. The program emphasizes a blend of theoretical knowledge and practical application, often incorporating case studies and hands-on projects.
Research Focus: A significant component of the 18-month MSc Biomedical Engineering program is its emphasis on research. The extended duration provides students with more time to develop their research skills and undertake a more in-depth individual major project. This project allows students to apply the knowledge and skills gained from the taught modules to investigate a specific problem within biomedical engineering, conduct independent research, and critically analyze their findings. The program is often delivered by faculty active in research, ensuring that students are exposed to current research trends and methodologies within the field, potentially in areas like advanced materials, medical device innovation, or regenerative therapies.
Industry Engagement: Recognizing the importance of translating academic learning into real-world impact, the 18-month MSc Biomedical Engineering program often incorporates strong links with industry. This may include opportunities for guest lectures from industry professionals, visits to medical device companies or research facilities, and potentially longer internships or industry-based projects. The extended duration can facilitate more meaningful engagement with industrial partners, providing students with valuable insights into the practical challenges and opportunities within the biomedical engineering sector and enhancing their employability.
Global Perspective: The field of biomedical engineering is inherently global, addressing healthcare challenges and driving innovation worldwide. The 18-month MSc program may integrate a global perspective by examining international regulations for medical devices, exploring global healthcare needs and the role of biomedical engineering in addressing them, and considering international collaborations in research and development. The diverse student body, including international students, can further enrich the learning environment by bringing different perspectives on healthcare systems and technological solutions from around the world.
Location
Bolton
Score
IELTS 6.5
Tuition Fee
£ 15950
Postgraduate Entry Requirements
Academic Qualifications: Applicants should have successfully completed a bachelor's degree or its equivalent from a recognized institution with a minimum overall score of 60% or equivalent.
English language proficiency:
- IELTS: A minimum overall score of 6.5 or 7.0 with no individual component below 6.0.
- TOEFL: A minimum overall score of 79.
- PTE Academic: A minimum overall score of 59.
- Some postgraduate programs may have specific subject prerequisites or additional requirements.
The University of Greater Manchester offers a variety of scholarships to support international students in financing their education. These scholarships are designed to reward academic excellence and assist students in pursuing their studies in the UK.
Global Futures Scholarships: The university provides the Global Futures Scholarships, which offer financial support to international students. These scholarships are available to both undergraduate and master's students holding an offer for full-time study on campus in Manchester.
Equity and Merit Scholarships: The university offers Equity and Merit Scholarships to academically excellent international students. These scholarships are available to postgraduate taught students commencing their studies. The scholarships aim to support students who demonstrate strong academic performance and their chosen field of study.
Engineering the Future Scholarships: The School of Engineering at the University of Greater Manchester provides scholarship awards to academically excellent international students commencing their postgraduate taught studies. These scholarships aim to support students pursuing careers in engineering and related fields.
The extended 18-month MSc in Biomedical Engineering at the University of Greater Manchester provides graduates with an even more specialized and in-depth skillset, enhancing their career prospects in the rapidly evolving healthcare technology sector.
Advanced Biomedical Engineer (R&D Focus): The extended program often allows for deeper research experience, positioning graduates for advanced roles in research and development within medical device companies, biotechnology firms, and academic institutions, focusing on innovative solutions.
Specialized Clinical Engineer: With a more comprehensive understanding of medical technologies, graduates can take on specialized roles in hospitals and healthcare systems, managing complex medical equipment, leading technology adoption, and ensuring optimal patient care.
Biomaterials and Tissue Engineering Specialist: The in-depth study of biomaterials and tissue engineering in the extended program prepares graduates for specialized roles in developing and testing novel materials for implants, prosthetics, and regenerative medicine applications.
Medical Imaging Technology Developer: Graduates can contribute to the advancement of medical imaging techniques (MRI, CT, ultrasound, etc.), working on developing new algorithms, hardware, and software for improved diagnostics and treatment monitoring.
Regulatory Affairs Manager (Complex Devices): The extended program can provide a more thorough understanding of the regulatory landscape, preparing graduates to manage the complex approval processes for innovative medical devices and technologies in global markets.
Medical Device Innovation and Entrepreneurship: With a deeper understanding of the technology and market needs, graduates may be well-suited to identify opportunities and launch their own ventures in the medical device or biotechnology space.
Computational Biomedical Engineer: Focusing on modeling and simulation of biological systems and medical devices, graduates can contribute to the design and optimization of healthcare technologies using advanced computational techniques.
Rehabilitation Technology Lead: The extended program can allow for specialization in rehabilitation engineering, leading to roles in developing and implementing advanced assistive technologies and robotic systems for rehabilitation.
Pharmaceutical Engineering (Drug Delivery Systems): Graduates with a strong understanding of biomaterials and drug delivery can work in the pharmaceutical industry, designing innovative drug delivery systems and devices.
Project Manager (Large-Scale Biomedical Projects): The enhanced research and project management skills gained in the extended program equip graduates to manage complex, large-scale biomedical engineering projects in industry or research settings.
