MRes Leadership and Strategy
The University of Greater Manchester offers a wide array of undergraduate and postgradu...
MSc Biomedical Engineering
Bolton
INTAKE: September
Program Overview
The MSc Biomedical Engineering program provides a thorough grounding in the fundamental principles of engineering and their application to biological and medical systems. It aims to develop graduates who can design, analyze, and develop innovative biomedical devices, materials, and therapies. The program typically covers core areas such as biomechanics, biomaterials science, medical imaging modalities (e.g., MRI, CT, ultrasound), biomedical instrumentation and signal processing, and the principles of tissue engineering and regenerative medicine. A significant emphasis is placed on understanding the physiological context of medical problems and the engineering solutions that can address them. The curriculum often incorporates practical laboratory work, computer simulations, and design projects to reinforce theoretical learning and develop hands-on skills.
Curriculum: The curriculum of the MSc Biomedical Engineering program is carefully structured to provide a strong interdisciplinary foundation. Core modules generally cover topics such as advanced biomechanics, biomaterials and their clinical applications, medical imaging principles and analysis, biomedical instrumentation and measurement, and tissue engineering and regenerative medicine. Students may also have opportunities to specialize through elective modules in areas like rehabilitation engineering, biosensors, or computational modeling in biomedicine. A substantial component of the program is typically an individual research project or dissertation, allowing students to delve into a specific area of biomedical engineering, conduct independent research, and develop their analytical and problem-solving abilities.
Research Focus: The MSc Biomedical Engineering program is delivered by faculty actively engaged in cutting-edge research across various domains of biomedical engineering. This ensures that the curriculum is informed by the latest scientific advancements and technological innovations. The program emphasizes the importance of research in driving progress in the field and encourages students to engage with research methodologies and contribute to the knowledge base through their projects and dissertations. Research areas within the program may include the development of novel biomaterials for implants, advanced medical imaging techniques, biomechanical analysis of human movement, and the engineering of tissues and organs for therapeutic applications.
Industry Engagement: Recognizing the strong connection between biomedical engineering research and its industrial applications, the University of Greater Manchester often incorporates industry engagement into its MSc program. This may include guest lectures from professionals in the medical device and biotechnology industries, opportunities for industry-based projects or internships, and visits to relevant companies and research facilities. The program aims to equip graduates with an understanding of the regulatory pathways for medical devices, the challenges of commercializing biomedical technologies, and the skills needed to thrive in industrial research and development settings.
Global Perspective: The field of biomedical engineering is inherently global, with research collaborations, technological advancements, and healthcare challenges transcending national borders. The MSc Biomedical Engineering program at the University of Greater Manchester often incorporates a global perspective by exploring international research trends, regulatory frameworks for medical devices in different regions, and the global market for biomedical technologies. The curriculum may include case studies and examples from various countries and consider the challenges of addressing global health issues through biomedical engineering solutions. The diverse student body, including international students, also contributes to a broader understanding of global perspectives within the field.
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.
Graduates from the MSc Biomedical Engineering program at the University of Greater Manchester possess a unique interdisciplinary skillset, making them highly sought after in a rapidly growing sector focused on advancing healthcare through engineering innovation.
Biomedical Engineer: Graduates can work in research and development, designing and creating medical devices, artificial organs, and diagnostic tools for companies, hospitals, and research institutions.
Clinical Engineer: Working directly in healthcare settings, graduates can manage, maintain, and troubleshoot complex medical equipment, ensuring patient safety and the effective use of technology in diagnosis and treatment.
Rehabilitation Engineer: Graduates can design and develop assistive technologies and rehabilitation devices to improve the quality of life for individuals with disabilities, focusing on mobility, communication, and daily living aids.
Biomaterials Scientist/Engineer: Specializing in the development and testing of biocompatible materials, graduates can contribute to the creation of implants, prosthetics, and drug delivery systems.
Medical Imaging Specialist: Graduates can work on the development, application, and maintenance of medical imaging technologies such as MRI, CT, and ultrasound, contributing to improved diagnostics.
Regulatory Affairs Specialist: Ensuring the safety and efficacy of medical devices and technologies, graduates can work with regulatory bodies to navigate approval processes and ensure compliance with international standards.
Product Development Engineer: Graduates can lead the design, prototyping, and testing phases of new medical devices and technologies, bringing innovative healthcare solutions to the market.
Biomechanical Engineer: Applying principles of mechanics to biological systems, graduates can analyze human movement, design orthopedic implants, and improve sports equipment.
Research Scientist: Graduates can pursue research careers in academia, government agencies, or private companies, contributing to advancements in areas like tissue engineering, regenerative medicine, and nanomedicine.
Sales and Marketing Engineer (Medical Devices): Combining their technical knowledge with business acumen, graduates can work in the commercial aspects of the medical device industry, promoting and selling advanced medical technologies.
