Masters Degrees in Medical Physics - Radiation, United Kingdom

Our Physics MSc is highly flexible, giving you the opportunity to structure your course to meet your individual career aspirations.

The course gives you the opportunity to broaden and deepen your knowledge and skills in physics, at the forefront of research in the area. This will help to prepare you to progress to PhD study, or to work in an industrial or other business related area.

A key feature of the course is that you can choose to study a wide range of optional modules or focus on a particular area of research expertise according to your interests and future career aspirations.

Under the umbrella of an MSc in physics, you can specialise in astrophysics, bionanophysics, soft matter physics, condensed matter physics, quantum technology, optical materials or medical imaging. Or you can take a diverse range of modules to suit your interests and keep their options open.

Course content

The course offers you a very wide range of optional modules, giving you the opportunity to specialise in areas such as astrophysics, bionanophysics, soft matter physics, condensed matter physics, quantum technology, optical materials or medical imaging.

Modules studied may include: quantum field theory; superconductivity; general relativity; medical image analysis; cosmology; bionanophysics; magnetism in condensed matter; statistical mechanics; star and planet formation; elementary particle physics; quantum matter; and photonics.

Alongside your optional modules, you will undertake an advanced and extensive research project in one of the School of Physics and Astronomy’s internationally recognised research groups. This will enable you to develop advanced skills in research planning, execution and reporting, possibly leading to publication of your work in an international journal.

Course structure

Compulsory modules

• MSc Project 75 credits
• Advanced Literature Review 15 credits
• Current Research Topics in Physics 15 credits

Optional modules

• Cardiovascular Medical Imaging 10 credits
• Digital Radiography and X-ray Computed Tomography 10 credits
• Magnetic Resonance Imaging 10 credits
• Ultrasound Imaging 10 credits
• Radionuclide Imaging 10 credits
• Medical Image Analysis 10 credits
• Digital Radiography and X-ray Computed Tomography 15 credits
• Ultrasound Imaging 15 credits
• Radionuclide Imaging 15 credits
• Medical Image Analysis 15 credits
• Cosmology 15 credits
• Photonics 15 credits
• Molecular Simulation: Theory and Practice 15 credits
• Star and Planet Formation 15 credits
• Advanced Quantum Mechanics 15 credits
• Quantum Photonics 15 credits
• Quantum Matter 15 credits
• Magnetism in Condensed Matter 15 credits
• Statistical Mechanics 15 credits
• Advanced Mechanics 15 credits
• Bionanophysics 1 15 credits
• Theoretical Elementary Particle Physics 15 credits
• Soft Matter Physics: Liquid Crystals 15 credits
• Quantum Many-Body Physics 15 credits
• Winds, Bubbles and Explosions 15 credits
• Bionanophysics 2: Advanced Bionanophysics Research 15 credits
• Advanced Group Industrial Project 15 credits
• Superconductivity 15 credits
• Soft Matter Physics: Polymers, Colloids and Glasses 15 credits
• Quantum Transport in Nanostructures 15 credits
• Quantum Field Theory 15 credits
• General Relativity 15 credits
• Quantum Information Science 15 credits
• Advanced Physics in Schools 15 credits

For more information on typical modules, read Physics MSc in the course catalogue

Learning and teaching

Teaching methods include a combination of lectures, seminars, supervisions, problem solving, presentation of work, independent research, and group work (depending on the modules you choose to study).

Assessment

Assessment of modules are by problem solving exams and research assignments. The project is assessed on the ability to plan and conduct research and communicate the results in written and oral format.

Career opportunities

The specialist pathways offered by this course (in astrophysics, bionanophysics, soft matter physics, condensed matter physics, quantum technology, optical materials or medical imaging) allow you to tailor your course and focus on a particular area of research expertise according to your interests and future career aspirations.

Physicists are highly employable due to their high level of numeracy and mathematical competence, their computer skills, and their high level of technical academic scientific knowledge. They are employed by: industry, financial sector, defence, education, and more.

This course is also a clear route to PhD level study.

Careers support

We encourage you to prepare for your career from day one. That’s one of the reasons Leeds graduates are so sought after by employers.

The Careers Centre and staff in your faculty provide a range of help and advice to help you plan your career and make well-informed decisions along the way, even after you graduate. Find out more at the Careers website.

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The MSc Medical Imaging programme is intended to provide a Masters-level postgraduate education in the knowledge, skills and understanding of engineering design of advanced medical and biotechnology products and systems. Students will also acquire a working knowledge of the clinical environment to influences their design philosophy.

Why study Medical Imaging at Dundee?

With biotechnology replacing many of the traditional engineering disciplines within the UK, this programme will allow you to develop the skills to apply your engineering or scientific knowledge to technologies that further the developments in this field. As a result, employment opportunities will be excellent for graduates, both in research and in industry.

We have an active research group, and you will be taught by leading researchers in the field.

What's so good about Medical Imaging at Dundee?

The MSc in Medical Imaging at the University of Dundee will:

Provide knowledge, skills and understanding of medical imaging technologies, particularly in modern biomedical, radiological and surgical imaging instrumentation, biomaterials, biomechanics and tissue engineering

Enhance your analytical and critical abilities, competence in multi-disciplinary research & development

Provide broad practical training in biology and biomolecular sciences sufficient for you to understand the biomedical nomenclature and to have an appreciation of the relevance and potential clinical impact of the research projects on offer

Allow you to experience the unique environment of clinical and surgical aspects in medical imaging in order to provide an understanding of the engineering challenges for advanced practice

Provide core training in electrical, microwave, magnetic, acoustic and optical techniques relevant to the life sciences interface and

Provide broad experience of analytical and imaging techniques relevant for biology, biomolecular and clinical sciences
provide core training in acoustic ultrasound technologies.

Who should study this course?

This course is suitable for students who are recent graduates of mechanical engineering courses or other related programmes.

This course has two start dates - January & September, and lasts for 12 months.

How you will be taught

The programme will involve a variety of teaching formats including lectures, tutorials, seminars, hands-on imaging classes, laboratory exercises, case studies, coursework, and an individual research project.

The teaching programme will include visits to and seminars at IMSaT and clinical departments at Ninewells Hospital and Medical School and Tayside University Hospitals Trust, including the Clinical Research Centre, the Departments of Medicine, Surgery, Dentistry and ENT, the Vascular Laboratory and Medical Physics.

A high degree of active student participation will be encouraged throughout. Taught sessions will be supported by individual reading and study. You will be guided to prepare your research project plan and to develop skills and competence in research including project management, critical thinking and problem-solving, project report and presentation.

What you will study

The course is divided into two parts:

Part I has 60 credits:

Biomechanics (20 Credits)
Biomaterials (20 Credits)
Bioinstrumentation (10 Credits)
Introduction to Medical Sciences (10 Credits)

Part II has one taught module and a research project module. It starts at the beginning of the University of Dundee's Semester 2, which is in mid-January:

Taught module: Advanced Biomedical Imaging Technologies (30 Credits).
Research project (30 Credits for diploma or 90 Credits for MSc)

How you will be assessed

The taught modules will be assessed by a combination of written examinations and coursework. The research project will be assessed by a written thesis and oral presentation.

Careers

This Master's programme provides you with the skills to continue into research in areas such as biomedical and biomaterials engineering as well as progression into relevant jobs within the Mechanical Engineering and Mechatronics industries.

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As a practising therapeutic radiographer, this unique programme allows you to quickly and easily obtain a full masters qualification.

Having an MSc Radiotherapy will enable you to meet the standards expected by the profession and greatly enhance your career prospects.

To apply you must already have the Postgraduate Diploma in Radiotherapy from the University of Liverpool, or a pre-registration Postgraduate Diploma from a different UK university that confers eligibility to apply for registration as a therapeutic radiographer with the Health and Care Professions Council (HCPC). You should also have 12 to 18 months clinical work experience.

The MSc consists of one 60 credit dissertation. Your learning starts with a four day block workshop, which runs in September and January each year. You then complete your independent research project under the guidance of an appropriate supervisor. You can liaise with your research supervior to develop a study plan that works for you both e.g. face to face meetings, online meetings or a combination.

The Directorate staff have a very wide range of expertise including medical physics in radiotherapy, computer treatment planning, imaging in radiotherapy, general cancer care and strategic planning of cancer services locally and nationally. The Directorate also has its own CTSim, treatment planning system, a patient management information system and a virtual environment in radiotherapy (VERT) system. These facilities will allow supervisors to support students on the MSc in Radiotherapy in a diverse range of dissertations.

Completion of the MSc must be achievable within 6 years of the start of your pre-registration Postgraduate Diploma programme.

Why Radiotherapy?

Unique programmes

We are the only Russell Group University delivering Radiotherapy education programmes.

Clinical Placement Sites

Our clinical palcement sites are second to none. We have three Internationally renowned cancer centres: The Christie NHS Foundation Trust, the Clatterbridge Cancer Centre and Rosemere Cancer Centre.

Clinical and Academic experience

We use real, 21st century radiotherapy technologies.

State of the art facilities

Our state-of-the-art facilities include a CT scanner, Virtual Reality Radiotherapy Suite, Human Anatomy Resource Centre, Oncology Management System and Eclipse Treatment Planning System.

Successful students present work at national and international conferences

The best poster award at the annual Society and College of Radiographers Conference in 2015 went to a recent graduate of the MSc Radiotherapy. The poster was also accepted for the multi-disciplinary annual conference of the European Society for Radiotherapy and Oncology in 2015.

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Our programme will give you a thorough grounding in the radiation and environmental protection aspects of nuclear physics.

This includes in-depth knowledge of radiation protection and showing you how the technical and organisational procedures of the discipline may be applied to the broader concept of environmental protection.

The substantial practical element of this programme enables you to relate taught material to real-world applications. Formal lectures are complemented with work in specialist radiation laboratories that were recently refurbished as part of a £1m upgrade to our facilities.

Here you will work with a wide range of radioactive sources and radiation detectors. There is also an extended project in the spring and an eleven-week MSc dissertation project in the summer.

Programme structure

This programme is studied full-time over one academic year and part-time students must study at least two taught technical modules per academic year. It consists of eight taught modules and a dissertation.

Example module listing

The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.

• Radiation Physics 
• Radiation Measurement
• Nuclear Metrology
• Introduction to Biology and Radiation Biology
• Nuclear Reactor and Health Physics
• Environment and Legislation
• Extended Group Project 
• Radiation Laboratory Skills 
• Research Project and Dissertation

Research-led teaching

The programme material is taught by a combination of academics from the Department of Physics at Surrey and specialists provided by industrial partners. The Surrey academics are part of the Centre for Nuclear and Radiation Physics which houses the largest academic nuclear physics research group in the UK.

In addition to the formal lectures for taught modules, the programme provides a wide range of experimental hands-on training. This includes a nine-week radiation physics laboratory which takes place in the specialist radiation laboratories within the Department of Physics at the University of Surrey.

These were recently refurbished as part of a £1 million upgrade to the departmental teaching infrastructure. Within the Department, we also have a common room and a departmental library, which contains copies of earlier MSc dissertations.

As well as the laboratory training, you will also undertake a research project at the beginning of the Spring semester as a precursor to the eleven-week research dissertation project which makes up the final part of the MSc.

There are many opportunities for both the spring research project and summer dissertation project to be taken in an external industrial environment.

Careers

The programme has produced over 500 UK and overseas graduates, many of whom have gone on to well-paid positions in companies in the nuclear and radiation sectors. In the UK we need to decommission old reactors and build new ones to provide a low-carbon source of energy.

This, together with, for example, the importance of radioisotopes in fields such as medicine, means that the career prospects of our graduates are excellent.

Educational aims of the programme

The programme integrates the acquisition of core scientific knowledge with the development of key practical skills with a focus on professional career development within medical physics and radiation detection, and related industries.

The principle educational aims and outcomes of learning are to provide participants with advanced knowledge, practical skills and understanding applied to medical physics, radiation detection instrumentation, radiation and environmental practice in an industrial or medical context.

This is achieved by the development of the participants’ understanding of the underlying science and technology and by the participants gaining an understanding of the legal basis, practical implementation and organisational basis of medical physics and radiation measurement.

Programme learning outcomes

Knowledge and understanding

• A systematic understanding of Radiation and Environmental Protection in an academic and professional context together with a critical awareness of current problems and / or new insights
• A comprehensive understanding of techniques applicable to their own research project in Radiation and / or Environmental Protection
• Originality in the application of knowledge, together with a practical understanding of radiation-based, experimental research projects
• An ability to evaluate and objectively interpret experimental data pertaining to radiation detection
• Familiarity with generic issues in management and safety and their application to Radiation and Environmental Protection in a professional context

Intellectual / cognitive skills

• The ability to plan and execute under supervision, an experiment or investigation and to analyse critically the results and draw valid conclusions from them. Students should be able to evaluate the level of uncertainty in their results, understand the significance of uncertainty analysis and be able to compare these results with expected outcomes, theoretical predictions and/or with published data. Graduates should be able to evaluate the significance of their results in this context
• The ability to evaluate critically current research and advanced scholarship in the discipline of radiation protection
• The ability to deal with complex issues both systematically and creatively, make sound judgements in the absence of complete data, and communicate their conclusions clearly to specialist and non- specialist audiences

Professional practical skills

• The ability to communicate complex scientific ideas, the conclusions of an experiment, investigation or project concisely, accurately and informatively
• The ability to manage their own learning and to make use of appropriate texts, research articles and other primary sources
• Responsibility for personal and professional development. Ability to use external mentors for personal / professional purposes

Key / transferable skills

• Identify and resolve problems arising from lectures and experimental work
• Make effective use of resources and interaction with others to enhance and motivate self-study
• Make use of sources of material for development of learning and research such as journals, books and the internet
• Take responsibility for personal and professional development

Global opportunities

We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.

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Your programme of study

If you want to study Medical Physics with applications in nuclear medicine, radiotherapy, electronics and MRI University of Aberdeen has an world renowned historic reputation within major global innovation in this health area. Did you know the first MRI (Magnetic Resonance Imaging) scanner was invented at Aberdeen over 30 years ago? Major innovations to this technology are still being researched at Aberdeen today. You learn everything you need to know as an advanced grounding in medical physics such as understanding anatomy and how cells are altered by disease. You look at the engineering behind MRI and other visual scanning techniques to understand how applications are made in areas such as nuclear, Positron, Tomography, Radio diagnosis (X-ray), MRI and Ultrasound. You understand radiation and you apply electronics and computing to medical physics. The degree ensures plenty of practical understanding and application and you learn MRI within the department that built it.

If you want to work within imaging and medical physics to pursue a medical career in hospitals, industry and healthcare and diagnose disease by different methods of imaging the degree in Medical Physics will help you towards this goal. You can also develop your own research portfolio and PhD from this MSc and work within academia to pursue innovation in the discipline.

You receive a thorough academic grounding in Medical Physics, are exposed to its practice in a hospital environment, and complete a short research project. Many graduates take up careers in health service medical physics, either in the UK or their home country. The MSc programme is accredited by the Institute of Physics & Engineering in Medicine as fulfilling part of the training requirements for those wishing to work in the NHS. You can also work as a researcher, risk manager, radiation physics specialist and within the medical device industry in product development and innovation.

Courses listed for the programme

Semester 1

Biomedical and Professional Topics in Healthcare Science

Imaging in Medicine

Radiation in Medicine

Computing and Electronics in Medicine

Generic Skills

Semester 2

Radiation and Radiation Physics

Nuclear Medicine and Post Emission Tomography

Magnetic Resonance Imaging

Medical Electronics and Instrumentation

Medical Image Processing and Analysis

Diagnostic Radiology and Radiation Protection

Semester 3

Project Programmes in Medical Physics and Medical Imaging

Find out more detail by visiting the programme web page

https://www.abdn.ac.uk/study/postgraduate-taught/degree-programmes/180/medical-physics/

Why study at Aberdeen?

• You are taught by renowned researchers with opportunity to contribute to the expanding research portfolio
• You learn in a cutting edge medical facility adjacent to the teaching hospital including a PET-CT scanner, radiotherapy centre and linac treatment machines, plus MRI scanners
• The MRI scanner was invented and developed at University of Aberdeen

Where you study

• University of Aberdeen
• 12 months or 24 months
• Full time or Part Time
• September start

International Student Fees 2017/2018

Find out about fees:

https://www.abdn.ac.uk/study/international/tuition-fees-and-living-costs-287.php

*Please be advised that some programmes have different tuition fees from those listed above and that some programmes also have additional costs.

Scholarships

View all funding options on our funding database via the programme page

https://www.abdn.ac.uk/study/postgraduate-taught/finance-funding-1599.php

https://www.abdn.ac.uk/funding/

Living in Aberdeen

Find out more about:

• Your Accommodation
• Campus Facilities
• Aberdeen City
• Student Support
• Clubs and Societies

Find out more about living in Aberdeen:

https://abdn.ac.uk/study/student-life

Living costs

https://www.abdn.ac.uk/study/international/finance.php

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For health care professionals from diverse backgrounds who wish to expand their knowledge of theoretical and practical aspects of oncology, including:

medical and clinical oncology SpRs
nurses
pharmacists
radiographers
vets
clinical trial co-ordinators
dieticians

A full-time programme is also available.

This programme aims to give you a scientific understanding of the cellular and molecular biology of cancer, its epidemiology and pathology, and to place this in a clinical context. You will then address how this knowledge effects therapeutic approaches and disease management.

It aims to allow you to understand the research process by drawing on examples within the department and its associated clinical trials unit. A key part of this Masters programme is the planning, execution and reporting of a piece of independent study leading to submission of a dissertation.

At all levels we aim to encourage interactive rather than didactic learning and lecturing. Therefore, in addition to assembling and learning facts you will also to consider some of the philosophical challenges which underlie the treatment of cancer.

The programme is studied part time over 2 years and includes a taught element plus a work place based dissertation. This is made up of 4 residential taught modules per year (8 in total). Taught modules consist of one or two 5 day blocks Monday to Friday approximately 9am - 5.30pm. The total taught element consists of 45-55 days of attendance over the whole programme depending on your choice of optional modules.

You can opt for a Postgraduate Diploma on completion of the core modules and 40 credits of optional modules, or an MSc on successful completion of the taught programme and an independently researched dissertation.

About the College of Medical and Dental Sciences

The College of Medical and Dental Sciences is a major international centre for research and education, make huge strides in finding solutions to major health problems including ageing, cancer, cardiovascular, dental, endocrine, inflammatory diseases, infection (including antibiotic resistance), rare diseases and trauma.
We tackle global healthcare problems through excellence in basic and clinical science, and improve human health by delivering tangible real-life benefits in the fight against acute and chronic disease.
Situated in the largest healthcare region in the country, with access to one of the largest and most diverse populations in Europe, we are positioned to address major global issues and diseases affecting today’s society through our eight specialist research institutes.
With over 1,000 academic staff and around £60 million of new research funding per year, the College of Medical and Dental Sciences is dedicated to performing world-leading research.
We care about our research and teaching and are committed to developing outstanding scientists and healthcare professionals of the future. We offer our postgraduate community a unique learning experience taught by academics who lead the way in research in their field.

Funding and Scholarships

There are many ways to finance your postgraduate study at the University of Birmingham. To see what funding and scholarships are available, please visit: http://www.birmingham.ac.uk/postgraduate/funding

Open Days

Explore postgraduate study at Birmingham at our on-campus open days.
Register to attend at: http://www.birmingham.ac.uk/postgraduate/visit

Virtual Open Days

If you can’t make it to one of our on-campus open days, our virtual open days run regularly throughout the year. For more information, please visit: http://www.pg.bham.ac.uk

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Medical imaging is a rapidly-growing discipline within the healthcare sector, involving clinicians, physicists, computer scientists and those in IT industries.

This programme delivers the expertise you'll need to forge a career in medical imaging, including radiation physics, image processing, biology, computer vision, pattern recognition, artificial intelligence and machine learning.

Programme structure

This programme is studied full-time over 12 months and part-time over 48 months. It consists of eight taught modules and an extended project.

Example module listing

The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.

• Image Processing and Vision
• Professional Skills for Clinical Science and Engineering 
• Introduction to Biology and Radiation Biology 
• Radiation Physics 
• AI and AI Programming 
• Computer Vision and Pattern Recognition 
• Diagnostic Apps of Ionising Radiation 
• Non-Ionising Radiation Imaging
• Engineering Professional Studies 1
• Engineering Professional Studies 2
• Extended Project

Facilities, equipment and support

To support your learning, we hold regular MSc group meetings where any aspect of the programme, technical or non-technical, can be discussed in an informal atmosphere. This allows you to raise any problems that you would like to have addressed and encourages peer-based learning and general group discussion.

We provide computing support with any specialised software required during the programme, for example, Matlab.

The Department’s student common room is also covered by the university’s open-access wireless network, which makes it a very popular location for individual and group work using laptops and mobile devices. There is also a Faculty quiet room for individual study.

We pride ourselves on the many opportunities that we provide to visit collaborating hospitals. These enable you to see first-hand demonstrations of medical imaging facilities and to benefit from lectures by professional practitioners.

To support material presented during the programme, you will also undertake a selection of ultrasound and radiation detection experiments, hosted by our sister MSc programme in Medical Physics.

Educational aims of the programme

The taught postgraduate Degree Programmes of the Department are intended both to assist with professional career development within the relevant industry and, for a small number of students, to serve as a precursor to academic research.

Our philosophy is to integrate the acquisition of core engineering and scientific knowledge with the development of key practical skills (where relevant).

To fulfil these objectives, the programme aims to:

• Attract well-qualified entrants, with a background in Electronic Engineering, Physical Sciences, Mathematics, Computing & Communications, from the UK, Europe and overseas
• Provide participants with advanced knowledge, practical skills and understanding applicable to the MSc degree
• Develop participants' understanding of the underlying science, engineering, and technology, and enhance their ability to relate this to industrial practice
• Develop participants' critical and analytical powers so that they can effectively plan and execute individual research/design/development projects
• Provide a high level of flexibility in programme pattern and exit point
• Provide students with an extensive choice of taught modules, in subjects for which the Department has an international and UK research reputation

Technical characteristics of the pathway

Medical Imaging is a rapidly growing discipline within the healthcare sector, incorporating engineers, physicists, computer scientists and clinicians. It is driven by the recent rapid development of 3-D Medical Imaging Systems, fuelled by an exponential rise in computing power.

New methods have been developed for the acquisition, reconstruction, processing and display of digital medical-image data with unprecedented speed, resolution and contrast.

This programme in Medical Imaging is aimed at training graduates for careers in this exciting multi-disciplinary area, and our graduates can expect to find employment in the medical imaging industry or the public health care sector.

It represents a blend of fundamental medical physics topics concerned with image acquisition and reconstruction coupled with imaging science and image engineering topics such that graduates understand how images are formed and how advanced machine-based methods can be bought to bare to provide new diagnostic information.

Global opportunities

We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.

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Why Surrey?

Our Medical Physics MSc programme is well-established and internationally renowned. We are accredited by IPEM (Institute of Physics and Engineering in Medicine) and we have trained some 1,000 medical physicists, so you can look forward to high-quality teaching during your time at Surrey.

Programme overview

The syllabus for the MSc in Medical Physics is designed to provide the knowledge, skills and experience required for a modern graduate medical physicist, placing more emphasis than many other courses on topics beyond ionising radiation (X-rays and radiotherapy).

Examples of other topics include magnetic resonance imaging and the use of lasers in medicine.

You will learn the theoretical foundations underpinning modern imaging and treatment modalities, and will gain a set of experimental skills essential in a modern medical physicist’s job.

These skills are gained through experimental sessions in the physics department and practical experiences at collaborating hospitals using state-of-the-art clinical facilities.

Why not discover more about our programme in our video?

Programme structure

This programme is studied full-time over one academic year. It consists of eight taught modules and a dissertation project. Part-time studemts study the same content over 2 academic years.

Example module listing

The following modules are indicative, reflecting the information available at the time of publication. Please note that all modules are compulsory, there are no optional modules, and may be subject to change.

• Radiation Physics 
• Radiation Measurement 
• Experimental and Professional Skills for Medical Physics
• Introduction to Biology and Radiation Biology
• Therapy Physics 
• Diagnostic Applications of Ionising Radiation Physics
• Non-ionising Radiation Imaging 
• Extended Group Project 
• Research Project and Dissertation

Facilities, equipment and academic support

Common room

A student common room is available for the use of all Physics students.

Computers

The University has an extensive range of PC and UNIX machines, full internet access and email. The University has invested in resources to allow students to develop their IT skills. It also has an online learning environment, SurreyLearn. Computers are located in dedicated computer rooms. Access to these rooms is available 24 hours per day.

Prizes

Hounsfield Prize

A prize of £200 is awarded annually for the best dissertation on the Medical Physics programme. Sir Hounsfield was jointly awarded the Nobel Prize for Medicine in 1979 for his work on Computed Tomography.

Mayneord Prize

A prize of £200 in memory of Professor Valentine Mayneord will be awarded to the student with the best overall performance on the Medical Physics course. Professor Mayneord was one of the pioneers of medical physics, who had a long association with the Department and encouraged the growth of teaching and research in the field.

Knoll Prize

A prize of £300 in memory of Professor Glenn Knoll is awarded annually to the student with outstanding performance in Radiation Physics and Radiation Measurement on any of the department's MSc programmes. Professor Knoll was a world-leading authority in radiation detection, with a long association with the department

IPEM Student Prize (MSc Medical Physics)

A prize of £250 is awarded annually to a student with outstanding performance in their dissertation.

Educational aims of the programme

The programme integrates the acquisition of core scientific knowledge with the development of key practical skills with a focus on professional career development within medical physics and related industries. The principle educational aims and outcomes of learning are to provide participants with advanced knowledge, practical skills and understanding applied to medical physics, radiation detection instrumentation, radiation and environmental practice in an industrial or medical context. This is achieved by the development of the participants’ understanding of the underlying science and technology and by the participants gaining an understanding of the legal basis, practical implementation and organisational basis of medical physics and radiation measurement.

Global opportunities

We give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities and through our international research collaboration. Hence, it may be possible to carry out the dissertation project abroad.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.

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This one-year full-time taught MSc programme (or up to six years part-time) will equip you for a career in any industry involving radiation and radiation detectors.

We cover basic radiation principles, the use of detection systems and associated instrumentation applications, and modelling. There’s a strong focus on practicals and laboratory-based techniques.

You’ll be able to carry out a project, often in industry, making you even more employable in sectors such as nuclear power, medicine, environmental protection, oil and mining, and health and safety.

The programme consists of a number of one-week modules which you can select to best meet your needs. These modules are organised into four groups:-

Foundation
Basic
Applied
Project and Dissertation.

For your MSc you must complete your chosen modules and one major project to a value of 180 credits. Diploma (120 credits) and Certificate (60 credits) may also be available if you don’t want to submit a dissertation.

Key Facts

REF 2014
We're 15th in UK for 4* and 3*research (world leading and internationally excellent), and we achieved 100% excellence in a research environment.

Why Department of Physics?

Excellent facilities

We're a major centre for research and recieve around £35m of funding per year from the research councils, the University and other sources.

Exciting, rigorous research environment

Study for a Physics PhD, MPhil, MRes or pursue one of our taught MSc programmes.

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The Department offers an MSc course with four separate streams:

Biomedical Engineering with Medical Physics

Biomedical Engineering with Biomechanics

Biomedical Engineering with Neurotechnology

Biomedical Engineering with Biomaterials

The Medical Physics stream trains graduates in the physical understanding required for healthcare and medical research, focusing on human physiology, and the use of radiation in treatment and in clinical imaging (especially MRI, ultrasound, X-ray and optical techniques), as well as the signal and image processing methods needed for the design and optimal use of such systems in diagnosis and research.

The Biomechanics stream is focused on bioengineering problems related to major diseases associated with an ageing population, such as cardiovascular disease, glaucoma, and bone and joint disease (osteoarthritis, osteoporosis).

These are major causes of mortality and morbidity, and this stream prepares engineers for a career in these key growth areas.

The Neurotechnology stream covers the development of new technology for the investigation of brain function, focusing on the application of this to benefit society—for example the development of neuroprosthetic devices, new neuroimaging techniques, and developing drugs and robotic assistive devices for those with central nervous system disorders, as well as in biologically-inspired control engineering.

The Biomaterials stream is offered jointly with the Department of Materials.

It addresses the selection and use of biomaterialsin medical and surgical devices, including their application, properties, interaction with tissues and drawbacks. Existing and new biomaterials are studied, including bioactive and biodegradable materials, implants and dental materials.

Modules also cover the development of materials for new applications, the response of cells and the design of materials as scaffolds for tissue engineering, which involves tailoring materials so that they guide stem cells to produce new tissue.

You will be required to choose your stream at the time of application. All four streams lead to the award of the MSc in Biomedical Engineering. The Medical Physics and Biomechanics streams are accredited by the Institute of Physics and Engineering in Medicine (IPEM).

The course is full-time for one calendar year, starting in October. It currently has an annual intake of about 60 students.

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This programme pathway is designed for students with an interest in the engineering aspects of technology that are applied in modern medicine. Students gain an understanding of bioengineering principles and practices that are used in hospitals, industries and research laboratories through lectures, problem-solving sessions, a research project and collaborative work.

Degree information

Students study in detail the engineering and physics principles that underpin modern medicine, and learn to apply their knowledge to established and emerging technologies in medical imaging and patient monitoring. The programme covers the engineering applications across the diagnosis and measurement of the human body and its physiology, as well as the electronic and computational skills needed to apply this theory in practice.

Students undertake modules to the value of 180 credits.

The programme consists of six core modules (90 credits), two optional modules (30 credits), and a research project (60 credits). A Postgraduate Diploma (120 credits) is offered.

Core modules
-Imaging with Ionising Radiation
-Clinical Practice
-Magnetic Resonance Imaging and Optics
-Medical Electronics and Control
-Professional Skills module

Optional modules
-Aspects of Biomedical Engineering
-Biomedical Engineering
-Computing in Medicine

Dissertation/report
All MSc students undertake an independent research project within the broad area of physics and engineering in medicine which culminates in a written report of 10,000 words, a poster and an oral examination.

Teaching and learning
The programme is delivered through a combination of lectures, demonstrations, practicals, assignments and a research project. Lecturers are drawn from UCL and from London teaching hospitals including UCLH, St. Bartholomew's, and the Royal Free Hospital. Assessment is through supervised examination, coursework, the dissertation and an oral examination.

Careers

Graduates from the Biomedical Engineering and Medical Imaging stream of the MSc programme have obtained employment with a wide range of employers in healthcare, industry and academia sectors.

Employability
Postgraduate study within the department offers the chance to develop important skills and acquire new knowledge through involvement with a team of scientists or engineers working in a world-leading research group. Graduates complete their study having gained new scientific or engineering skills applied to solving problems at the forefront of human endeavour. Skills associated with project management, effective communication and teamwork are also refined in this high-quality working environment.

Why study this degree at UCL?

The spectrum of medical physics activities undertaken in UCL Medical Physics & Biomedical Engineering is probably the broadest of any in the United Kingdom. The department is widely acknowledged as an internationally leading centre of excellence and students receive comprehensive training in the latest methodologies and technologies from leaders in the field.

The department operates alongside the NHS department which provides the medical physics and clinical engineering services for the UCL Hospitals Trust, as well as undertaking industrial contract research and technology transfer.

Students have access to a wide range of workshop, laboratory, teaching and clinical facilities in the department and associated hospitals. A large range of scientific equipment is available for research involving nuclear magnetic resonance, optics, acoustics, X-rays, radiation dosimetry, and implant development, as well as new biomedical engineering facilities at the Royal Free Hospital and Royal National Orthopaedic Hospital in Stanmore.

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This programme pathway is designed for students with a developing interest in radiation physics, both ionising and non-ionising, that underpins many of the imaging and treatment technologies applied in modern medicine. Students gain an understanding of scientific principles and practices that are used in hospitals, industries and research laboratories through lectures, problem-solving sessions, a research project and collaborative work.

Degree information

Students study the physics theory and practice that underpins modern medicine, and learn to apply their knowledge to established and emerging technologies in medical science. The programme covers the applications of both ionising and non-ionising radiation to the diagnosis and treatment of human disease and disorder, and includes research project, workplace skills development and computational skills needed to apply this theory into practice.

Students undertake modules to the value of 180 credits.

The programme consists of seven core modules (105 credits), one optional module (15 credits), and a research project (60 credits). A Postgraduate Diploma of eight modules (120 credits) is offered.

Core modules
-Clinical Practice
-Medical Imaging (Ionising)
-Ultrasound in Medicine
-Magnetic Resonance Imaging and Biomedical Optics
-Research Project
-Professional Skills module
-Treatment with Ionising Radiation
-Ionising Radiation Physics: Interactions & Dosimetry

Optional modules
-Biomedical Engineering
-Computing in Medicine
-Programme Foundations for Medical Image Analysis

Dissertation/report
All MSc students undertake an independent research project within the broad area of Physics and Engineering in Medicine which culminates in a report up to 10,000 words, a poster and an oral examination.

Teaching and learning
The programme is delivered through a combination of lectures, demonstrations, tutorials, assignments and a research project. Lecturers are drawn from UCL and from London teaching hospitals including UCLH, St. Bartholomew's, and the Royal Free Hospital. Assessment is through supervised examination, coursework and assignments, a research dissertation and an oral examination.

Careers

A large percentage of graduates from the MSc continue on to PhD study, often in one of the nine research groups within the department, as a reult of the skills and knowledge they acquire on the programme. Other graduates commence or resume training or employment within the heaalthcare sector in hospitals or industry, both within the UK and abroad.

Employability
Postgraduate study within the department offers the chance to develop important skills and acquire new knowledge through involvement with a team of scientists or engineers working in a world-leading research group. Graduates complete their study having gained new scientific or engineering skills applied to solving problems at the forefront of human endeavour. Skills associated with project management, effective communication and teamwork are also refined in this high-quality working environment.

Why study this degree at UCL?

The spectrum of medical physics activities undertaken in UCL Medical Physics & Biomedical Engineering is probably the broadest of any in the United Kingdom. The department is widely acknowledged as an internationally leading centre of excellence and students on this programme receive comprehensive training in the latest methodologies and technologies from leaders in the field.

The department operates alongside the NHS department which provides the medical physics and clinical engineering services for the University College London Hospitals NHS Foundation Trust, as well as undertaking industrial contract research and technology transfer. The department is also a collaborator in the nearby London Proton Therapy Centre, currently under construction.

Students have access to a wide range of workshop, laboratory, teaching and clinical facilities in the department and associated hospitals. A large range of scientific equipment is available for research involving nuclear magnetic resonance, optics, acoustics, X-rays, radiation dosimetry, and implant development.

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This programme pathway is identical to the campus-delivered radiation physics stream but is designed for students who are unable to travel to London because of their work duties or international location. Teaching is delivered for each module via video lectures, top-up online tutorials and additional e-learning resources, with coursework and supervised examinations which are arranged across the world by the British Council.

Degree information

Students study in detail the physics theory and practice that underpins modern medicine, and learn to apply their knowledge to established and emerging technologies in medical science. The programme covers the applications of both ionising and non-ionising radiation to the diagnosis and treatment of human disease and disorder, and includes a research project and the development of computational skills needed to apply this theory into practice.

Students undertake modules to the value of 180 credits.

The programme consists of eight core modules (120 credits) and the research dissertation (60 credits).

A Postgraduate Diploma, eight core modules (120 credits), is offered. There are no optional modules for this programme.

Core modules
-Clinical Practice
-Computing in Medicine
-Ionising Radiation Physics: Interactions & Dosimetry
-Magnetic Resonance Imaging and Biomedical Optics
-Medical Imaging (Ionising)
-Research Project
-Treatment with Ionising Radiation
-Ultrasound in Medicine
-Professional Skills Module

Dissertation/report
All students undertake an independent research project which culminates in a research report of up to 10,000 words, a poster and an oral presentation.

Teaching and learning
The programme is delivered through a combination of lectures, demonstrations, tutorials, assignments and a research project. Lecturers are drawn from UCL and from London teaching hospitals including UCLH, St. Bartholomew's, and the Royal Free Hospital. Assessment is through supervised examination, coursework and assignments, a research dissertation and an oral examination.

Careers

A large percentage of graduates from the online Master's programme commence or continue training or employment within the healthcare sector, mostly in UK and overseas hospitals. Online learning offers the ability to up-skill or re-skill in physics disciplines applied to medicine while also training or practising in the field.

Employability
Postgraduate study within the department offers the chance to develop important skills and acquire new knowledge through involvement with a team of scientists or engineers working in a world-leading research group. Graduates complete their study having gained new scientific or engineering skills applied to solving problems at the leading-edge of human endeavour. Skills associated with project management, effective communication and teamwork are also refined in this high-quality working environment. The department has a recognised track record for producing excellent graduates that go on to hold leading roles in universities, companies and hospitals around the world.

Why study this degree at UCL?

The spectrum of medical physics activities undertaken in UCL Medical Physics & Biomedical Engineering is probably the broadest of any in the United Kingdom. The department is widely acknowledged as an internationally leading centre of excellence and students receive comprehensive training in the latest methodologies and technologies from leaders in the field.

The department operates alongside the NHS department which provides the medical physics and clinical engineering services for the University College London Hospitals NHS Foundation Trust, as well as undertaking industrial contract research and technology transfer. The department is also a collaborator in the nearby London Proton Therapy Centre currently under construction.

Students have access to an exceptionally wide range of expertise, laboratory, teaching and clinical facilities in the department and associated hospitals. A large range of scientific equipment is available for research involving nuclear magnetic resonance, optics, acoustics, X-rays physics, radiation dosimetry, and implant and interventional device development.

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For health care professionals from diverse backgrounds who wish to expand their knowledge of theoretical and practical aspects of oncology, this full-time programme is particularly suitable for medical professionals with an interest in clinical, medical, surgical and translational oncology. Unique to this programme is the exciting opportunity to gain clinical observership status and log your hours observing in a UK based hospital.

The aim of this programme is to give you a scientific understanding of the cellular and molecular biology of cancer, its epidemiology and pathology, and to place this in a clinical context. We will then address how this knowledge effects therapeutic approaches, and disease management.

Aiming to allow you to understand the research process, this programme draws on examples within the department and its associated clinical trials unit. A key part of the Masters programme is the planning, execution and reporting of a piece of independent study leading to submission of a dissertation.

At all levels we aim to encourage interactive rather than didactic learning and lecturing. Therefore, as well as assembling and learning facts you will also consider some of the philosophical challenges which underlie the treatment of cancer.

You can opt for a Postgraduate Diploma on completion of the core modules and 40 credits of optional modules, or a Masters on successful completion of the taught programme and an independently researched dissertation.

About the College of Medical and Dental Sciences

The College of Medical and Dental Sciences is a major international centre for research and education, make huge strides in finding solutions to major health problems including ageing, cancer, cardiovascular, dental, endocrine, inflammatory diseases, infection (including antibiotic resistance), rare diseases and trauma.
We tackle global healthcare problems through excellence in basic and clinical science, and improve human health by delivering tangible real-life benefits in the fight against acute and chronic disease.
Situated in the largest healthcare region in the country, with access to one of the largest and most diverse populations in Europe, we are positioned to address major global issues and diseases affecting today’s society through our eight specialist research institutes.
With over 1,000 academic staff and around £60 million of new research funding per year, the College of Medical and Dental Sciences is dedicated to performing world-leading research.
We care about our research and teaching and are committed to developing outstanding scientists and healthcare professionals of the future. We offer our postgraduate community a unique learning experience taught by academics who lead the way in research in their field.

Funding and Scholarships

There are many ways to finance your postgraduate study at the University of Birmingham. To see what funding and scholarships are available, please visit: http://www.birmingham.ac.uk/postgraduate/funding

Open Days

Explore postgraduate study at Birmingham at our on-campus open days.
Register to attend at: http://www.birmingham.ac.uk/postgraduate/visit

Virtual Open Days

If you can’t make it to one of our on-campus open days, our virtual open days run regularly throughout the year. For more information, please visit: http://www.pg.bham.ac.uk

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This taught Masters is designed to provide you with an advanced programme of study in Medical Physics. It provides an understanding of the application of physics and technology to a range of disciplines within medical physics at a level appropriate for a professional physicist. We have expertise in traditional areas like ionising radiation, but also specialist sections in PET Scanning, Ophthalmology, Urology, Informatics and leading researchers in MRI.

Why this programme

◾A key strength of this programme is that you will be taught mostly by physicists working in the NHS. It will quip you for employment in a clinical environment.
◾Due to the large size of the NHS medical physics department in Glasgow, all mainstream areas of medical physics are covered along with some specialised fields.
◾The programme is accredited with the Institute of Physics & Engineering in Medicine (IPEM), the UK professional body for medical physicists.
◾The department has access to 1.5, 3 and 7 Tesla MRI, Pet Scanning, a cyclotron, dedicated SPECT and has its own radiosotope dispensary.
◾Your lecturers are operating at the forefront of the profession with a balance of research and clinical practice, perfect for studying Medical Science.
◾The research component of this programme allows you to develop valuable skills for practising and interpreting research.
◾We draw on expert resources within the wider university for anatomy, statistics and the two optional courses.

Programme structure

You will attend lectures, seminars and tutorials, take part in e-learning and undertake a research project.

Core courses
◾Radiation physics
◾Anatomy and physiology
◾Statistics and experimental techniques
◾Medical imaging physics
◾Programming
◾Scientific management
◾Clinical medical imaging
◾Radiotherapy
◾Clinical measurement
◾Research dissertation.

Optional courses
◾Advanced data analysis
◾Problem solving.

Career prospects

Career opportunities include positions in the NHS, private healthcare and equipment manufacturers. This is the course followed by the NHS trainees in Scotland so it is highly attuned to preparing the successful student for employment.

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