Course details
- Full-time: 12 months
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Discover the principles and technologies that have led to biomedical engineering becoming essential in healthcare, medicine and human biology. Suitable for intercalating medical students and graduates in life sciences, this master's degree combines knowledge of biomechanics and fluid mechanics in the human body with engineering design innovations and a modern management toolkit.
Biomedical engineering, the application of engineering knowledge and skills to healthcare, medicine and human biology, is the fastest growing engineering discipline worldwide.
Contributing to the future development of artificial organs, medical devices and novel treatments, the School of Engineering is home to internationally recognised, ground-breaking research in biomedical engineering. This programme harnesses this expertise in key areas around biomechanics, cardiovascular fluid mechanics, tissue engineering, biomaterials, engineering design and manufacturing.
You’ll discover how to measure and analyse human movement, learn the principles of blood flow and the role of different bio-fluids in the human body, and gain an understanding of the structures and properties of materials used in medical devices.
Immersing you in computer aided design and engineering product design, we’ll introduce the latest 3D tools and techniques and task you with the development of innovative products and creative solutions. We’ll also focus on modern management, including examining organisational behaviour and enhancing your project management skills.
Accredited by the Institution of Mechanical Engineers, the programme includes a supervised independent research project. This provides the opportunity to enhance your skills and knowledge in an area of biomedical engineering of your choice, supported by our specialist research facilities.
This programme is designed for intercalating medical students and graduates in life science subjects who want to develop specialist skills and knowledge in biomedical engineering. You’ll combine this expertise with insights into effective leadership and management.
This programme is accredited by the Institute of Mechanical Engineering (IMechE), the professional body for mechanical engineers in the UK. This means that successful completion of the programme will put you on track to gain Chartered Engineer (CEng) status in the UK.
Discover what you'll learn, what you'll study, and how you'll be taught and assessed.
This modules covers topics related to the structure and properties of materials that are used in medical devices, including metals and alloys, polymers and ceramics. Corrosion and polymer degradation is also covered.
To introduce the student to the latest 3D tools and techniques used by designers.
To develop a wider knowledge and understanding of integrated systems design.
To stimulate an appreciation of modern design and development methodologies.
Project Management is a core skill for professional engineers of all types and a sound education in this subject area is required by the professional accrediting bodies. The knowledge and skills developed in this module will equip students for their future UG project work and for their careers ahead.
This module teaches students the theory of fundamental techniques in project management, risk management, and cost management.
In this modules student undertake a group "virtual project" in which they undertake all stages of project management involved n a major construction projects. The five virtual project tasks require students to apply their theoretical learning; and they provide an opportunity to develop key professional skills.
The Aims of this module are as follows:
To introduce the student to various aspects of advanced modern management.
To develop a knowledge and understanding of modern management tools.
To stimulate an appreciation of management and its importance in organisational success.
To present the fundamental principles of Engineering Product Design according to the Total design methodology.
To engage students in a multi-disciplinary group project to develop and justify an innovative engineering solution/product that is part of a grand challenge which is formulated from complex and uncertain factors.
To develop students team working, communication, project management, problem solving and critical evaluation skills.
To formulate a theoretical novel solution that is supported by valid evidence and meets an authentic need.
To develop technical writing skills for engineers. English Language Centre deliver the module for non-native English speakers, Engineering staff deliver identical syllabus, assessments and learning outcomes for other students.
This module will commence with an introduction to cardiovascular anatomy and physiology. The module will then progress to cover the behaviour of biofluids under flow will be studied with particular emphasis placed on the flow of blood ("haemodynamics"). In particular blood flow in relation to cardiovascular prostheses and devices, including heart valves, cardiac assist devices, and arterial bypass grafts, will be explored.
This module aims to understand advanced engineering materials, focusing on non-ferrous alloys and composite materials. It covers the processing, heat treatment, microstructure and properties of Al, Ti and Ni alloys. It introduces constituent materials, manufacturing methods, test methods and mechanical response of composite materials.
This module introduces the relationships between materials properties and the influence of processing on them. A range of manufacturing processes is considered for ceramics, polymers, metals and composites. The Granta – Cambridge Engineering Selector software is used to inform the selection of materials processing and the inter-relationships with design.
To provide an overview on the role of additive manufacturing in new product development.
To develop a generic understanding on the principles and the complete process chain of additive manufacturing processes.
To provide an awareness on recent developments in additive manufacturing and associated technologies.
This module will give students an understanding of the biomechanics of the musculoskeletal system and will cover techniques used to measure and analyse body movements as mechanical systems.
The module will explore the understanding for the need for enhanced control of material induced biological interactions and how we can utilise novel material development and engineering techniques to control biological responses from the “bottom-up” (controlled biological interactions), developing the next generation of smart-implantable medical devices. As well as presenting fundamental concepts that are relevant to real clinical situations the module will also explore the need for cost effective solutions and viable routes for scale up and translation.
The module teaches the concepts of Entrepreneurship, Intrapreneurship, Company Infrastructure and Investment Proposals. It is taught using lectures, class questions, case studie sand a comprehensive coursework assignment. Successful students will have acquired knowledge and understanding at mastery level of the process and how itis executed in a modern industrial environment.
To present the fundamental principles of Engineering Product Design according to the Total design methodology.
To engage students in a multi-disciplinary group project to develop and justify an innovative engineering solution/product that is part of a grand challenge which is formulated from complex and uncertain factors.
To develop students team working, communication, project management, problem solving and critical evaluation skills.
To formulate a theoretical novel solution that is supported by valid evidence and meets an authentic need.
This module will commence with an introduction to cardiovascular anatomy and physiology. The module will then progress to cover the behaviour of biofluids under flow will be studied with particular emphasis placed on the flow of blood ("haemodynamics"). In particular blood flow in relation to cardiovascular prostheses and devices, including heart valves, cardiac assist devices, and arterial bypass grafts, will be explored.
This modules discusses energy generation and usage, and how they complement each other. The topics are introduced in lectures that then lead onto a case study on a specific topic.
This module provides an understanding of the principles of advanced manufacturing techniques using lasers and how these are being explored through current/recent research and adopted by industry.
This module introduces students to the facilitating world of ‘Smart Materials’. The term ‘Smart Materials’ is used to define a broad collection of materials that have the in-built ability to ‘actuate’ in some way in response to external stimulus. Examples of ‘Smart materials’ include piezoelectrics, electrostrictive materials, shape memory alloys, ferrofluids, various biomimetic materials plus a host of others. This module looks at a selection of smart materials and considers the underlying reasons for the actuating behavior, key performance indicators that aid materials selection, aspects of manufacturing associated with the exploitation of the materials, plus engineering applications of these facilitating and highly useful materials.
The purpose of the project is to provide students with the opportunity to plan, carry out and control a research project at the forefront of their academic discipline, field of study or area of professional practice. The student will report findings both orally and in writing. Detailed instructions are provided in the PG handbook distributed at the outset of the programme.
You’ll be taught through a combination of traditional lectures and practical classes, benefitting from research-led teaching and active learning methods.
There will be a mixture of lectures, seminars, tutorials, laboratory work, demonstrations, problem-solving exercises, group projects and independent study.
You’ll be assessed through a combination of written exams, class tests and coursework.
Coursework-based assignments include essays, reports, oral presentations, mini-project work, key skills exercises and a dissertation.
We have a distinctive approach to education, the Liverpool Curriculum Framework, which focuses on research-connected teaching, active learning, and authentic assessment to ensure our students graduate as digitally fluent and confident global citizens.
Studying with us means you can tailor your degree to suit you. Here's what is available on this course.
You’ll study in the School of Engineering, which hosts modern, world-class teaching and learning facilities. This includes the Active Learning Laboratories, which feature lab space, manufacturing robots and prototyping facilities so you can learn, build and test. You’ll also have access to high-spec workstations featuring industry-standard engineering software.
The University of Liverpool will open the doors to an international career!
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Whether you’re seeking a career designing medical devices or assistive technologies, focusing on research and development, or working in engineering management or consultancy, this MSc will prepare you for a variety of opportunities in the UK and abroad.
The programme includes a strong practical element and incorporates the latest academic and industry research, preparing you to work effectively at the forefront of engineering.
Our professional accreditation with the Institution of Mechanical Engineers means you’ll graduate with a recognised qualification on the route to Chartered Engineer status.
You’ll graduate from this MSc ready for a career in medical device design and manufacture, academic research, and engineering management or consultancy.
Previous biomedical engineering graduates have gone onto careers working for medical device companies, pharmaceutical companies, and the National Health Service and other healthcare providers.
Their career destinations include working for companies such as:
You’ll also be well placed to pursue PhD study. Some of our previous graduates have secured fully-funded PhD studentships.
Your tuition fees, funding your studies, and other costs to consider.
UK fees (applies to Channel Islands, Isle of Man and Republic of Ireland) | |
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Full-time place, per year | £13,300 |
International fees | |
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Full-time place, per year | £29,900 |
Tuition fees cover the cost of your teaching and assessment, operating facilities such as libraries, IT equipment, and access to academic and personal support.
If you're a UK national, or have settled status in the UK, you may be eligible to apply for a Postgraduate Loan worth up to £12,167 to help with course fees and living costs. Learn more about fees and funding.
We understand that budgeting for your time at university is important, and we want to make sure you understand any course-related costs that are not covered by your tuition fee. This could include buying a laptop, books, or stationery.
Find out more about the additional study costs that may apply to this course.
We offer a range of scholarships and bursaries that could help pay your tuition and living expenses.
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The qualifications and exam results you'll need to apply for this course.
We've set the country or region your qualifications are from as United Kingdom. Change it here
Your qualification | Requirements |
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Postgraduate entry requirements |
We accept a 2:2 honours degree from a UK university, or an equivalent academic qualification from a similar non-UK institution. This degree should be in Life Sciences, Biomedical Sciences, Optometry, Anatomy or a closely related subject. A level Mathematics or A level Physics is desirable. |
International qualifications |
If you hold a bachelor’s degree or equivalent, but don’t meet our entry requirements, you could be eligible for a Pre-Master’s course. This is offered on campus at the University of Liverpool International College, in partnership with Kaplan International Pathways. It’s a specialist preparation course for postgraduate study, and when you pass the Pre-Master’s at the required level with good attendance, you’re guaranteed entry to a University of Liverpool master’s degree. |
You'll need to demonstrate competence in the use of English language, unless you’re from a majority English speaking country.
We accept a variety of international language tests and country-specific qualifications.
International applicants who do not meet the minimum required standard of English language can complete one of our Pre-Sessional English courses to achieve the required level.
English language qualification | Requirements |
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IELTS | 6.5 overall, with no component below 6.0 |
TOEFL iBT | 88 overall, with minimum scores of listening 19, writing 19, reading 19 and speaking 20. TOEFL Home Edition not accepted. |
Duolingo English Test | 120 overall, with no component below 105 |
Pearson PTE Academic | 61 overall, with no component below 59 |
LanguageCert Academic | 70 overall, with no skill below 65 |
PSI Skills for English | B2 Pass with Merit in all bands |
INDIA Standard XII | National Curriculum (CBSE/ISC) - 75% and above in English. Accepted State Boards - 80% and above in English. |
WAEC | C6 or above |
Do you need to complete a Pre-Sessional English course to meet the English language requirements for this course?
The length of Pre-Sessional English course you’ll need to take depends on your current level of English language ability.
Find out the length of Pre-Sessional English course you may require for this degree.
Discover more about the city and University.
Liverpool bursts with diversity and creativity which makes it ideal for you to undertake your postgraduate studies and access various opportunities for you and your family.
To fully immerse yourself in the university experience living in halls will keep you close to campus where you can always meet new people. Find your home away from home.
Discover what expenses are covered by the cost of your tuition fees and other finance-related information you may need regarding your studies at Liverpool.
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Last updated 20 December 2024 / / Programme terms and conditions