Content Blocks
2a
P-H800
2b
MSc
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1 year full-time
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3 October 2022
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University of Warwick
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The MSc in Biomedical Engineering delivers state-of-the-art knowledge and understanding of Biomedical Engineering at postgraduate level. At Warwick's School of Engineering you will develop expertise across a range of topics.
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The MSc in Biomedical Engineering delivers advanced modules informed by the active research expertise and industrial links of our academic staff.
The course prepares students for careers in advanced biomedical engineering. This includes biomedical engineering research institutions, medical device manufacturing, agencies for health technology assessment and medical device regulatory affairs, and clearly hospitals, where biomedical engineers oversee medical device clinical trials, purchasing and maintenance as responsible for clinical engineering services.
The Warwick Biomedical Engineering MSc spans the whole School of Engineering incorporating predictive modelling, medical device design, health technology assessment, signal processing, electronics, communication, software, hardware, systems thinking and machine intelligence.
Warwick has a unique systems approach to research and teaching and so modules are developed across disciplines in parallel to our research. This approach culminates in a group design project in which you will design a medical device. This, in the past two years included, a defibrillator, a pulmonary ventilator, an ECGph and wearable devices for SpO2 monitoring. Beyond that, you will be assigned an in-depth individual project which will allow you to work closely with an academic on state-of-the art biomedical engineering research and innovation, often linked with industry.
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The degree comprises eight taught modules and a project. The individual project entails an in-depth experimental, theoretical or computational investigation on a topic chosen by the student in conjunction with an academic supervisor.
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Class sizes for lectures, practical laboratory sessions and seminars vary depending on the number of students taking the module.
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The MSc degree (totalling 180 credits) comprises:
- Eight taught modules (15 credits each)
- A research project (60 credits)
The typical workload for a 15-credit module is as follows:
- 20-30 hours of lectures/seminars
- 5 hours of laboratory work
- 45 hours of private/directed study
- 70 hours of assessed work
The research project is valued at 60 credits and students should plan to execute around 600 hours of work towards the completion of the project dissertation.
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A combination of coursework and written examinations.
Reading lists
Most departments have reading lists available through Warwick Library. If you would like to view reading lists for the current cohort of students you can visit our Warwick Library web page.
Your timetable
Your personalised timetable will be complete when you are registered for all modules, compulsory and optional, and you have been allocated to your lectures, seminars and other small group classes. Your compulsory modules will be registered for you and you will be able to choose your optional modules when you join us.
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A 2:ii undergraduate degree (or equivalent) in a relevant branch of engineering or science degree.
Maths requirement
All applicants will be expected to know the prescribed mathematical concepts, please visit shown on this Engineering web page. The onus is on the individual to ensure that they understand the required material in order to cope easily with the course.
We are looking for competence in the majority of mathematics that is taught in the first and second year of an undergraduate Engineering or Physics course. We reserve the right to request that you undertake a short online test assessment.
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- Band A
- IELTS overall score of 6.5, minimum component scores not below 6.0.
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There are no additional requirements for this course.
5a
Biomedical Imaging and Medical Devices
This module will introduce you to the fundamental principles and applications of medical imaging in the human body, and to imaging and sensing in the brain. Techniques include Magnetic Resonance Imaging (MRI), X-ray Computed Tomography (CT), Positron Emission Tomography (PET), Electroencephalography (EEG), Magnetoencephalography (MEG), and Ultrasound. The module will provide you with a firm grounding in the basic theory underpinning the core methods in clinical practice, as well as an awareness of emerging technologies and their applications.
Medical Device: Design, Maintenance and Assessment
On this module you will develop a firm understanding of the principles of modern design, maintenance and assessment of healthcare technologies, including: medical devices, novel treatment and therapeutic technologies, technologies for a healthy life-course, systems and environments for care delivery. This module will provide you with a firm grounding in methods and tools for design, management and assessment of health technologies for prevention, diagnosis, treatment and rehabilitation.
Biomedical Systems Modelling
This module gives you the opportunity to demonstrate that you have independently contributed primary data and/or a new analysis of secondary data, within your chosen advanced research topic. Projects will be highly variable in nature to reflect the range of topics within the programmes of study but all will provide you with an opportunity to achieve the learning outcomes. Thus, projects may entail experimentation, modelling, analysis and literary survey skills to develop advanced skills in the discovery and occasionally creation of new knowledge. The module also offers the chance for you to pursue curiosity driven work guided by an academic supervisor.
Individual Project
Research and Professional Skills in Biomedical and Clinical Engineering
This is an introduction to Biomedical Engineering for MSc students on this course. This module is held at the beginning of the term one and aims to quickly give you an overview of the biomedical various topics to help you choose an appropriate MSc project. The module will also equip you with the required background knowledge and skills for the MSc course.
5b
- Biomechanics
- Biomedical Signal Processing
- Biomedical Materials, Tissue Engineering and Regenerative Medicine
- Computational Synthetic and Systems Biology
- Computational Intelligence in Biomedical Engineering
- Systems Modelling and Control
- Affective Computing
- Signal Processing
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