Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Medicine and Life Sciences at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).
The MRes in Medicine and Life Sciences is a one year full time programme, which provides an ideal opportunity and environment in which to gain practical training in Research Methods and to join a thriving research team within Swansea University College of Medicine. The Medicine and Life Sciences course has been developed with an emphasis on providing students with a research-oriented approach to their learning. Students are able to tailor their studies towards a career in one of the College’s internationally recognised research themes:
– Biomarkers and Genes,
– Microbes and Immunity,
– Patient & Population Health and Informatics.
The Medicine and Life Sciences programme is committed to supporting the development of evidence within the areas of Health, Medicine and Life Science through the training of researchers whose findings will directly inform their own understanding and that of others. The ethos of this programme is to produce graduates with the research skill and knowledge to become effective researchers, who will contribute to the body of knowledge within their chosen area of interest that will have an impact upon the health and well-being of all.
- The advantage of a MRes over other formats is that it provides a structured yet in-depth approach, taking the taught component of FHEQ Level 7 teaching as a framework for conducting research on the candidates own practice.
- Innovative and integrated curriculum that reflects the various aspects of the research process.
- Multidisciplinary teaching team with vast experience and expertise in conducting high quality research.
- Research informed teaching.
- Teaching is supported by online learning and support.
-Flexibility for you to gain specialist knowledge.
- A one year full-time taught masters programme designed to develop the essential skills and knowledge required for a successful research career.
- This course is also available for two years part-time study.
- The opportunity to conduct an individual research project with an interdisciplinary team within a supportive environment.
- Students will be assigned a research-active supervisory team
The aim of the MRes in Medicine and Life Sciences is to provide students with a broad research training to prepare them for a research career in Medical and Life Science research with emphasis on: Biomarkers & Genes, Devices, Microbes & Immunity, and Patient & Population Health and Informatics. The course has been developed to enable graduates to pursue a variety of research careers in Medical and Life Sciences. The programme comprises both taught and research elements.
By the end of the Medicine and Life Sciences programme students will have:
Developed necessary skills to critically interpret and evaluate research evidence; Gained experience the in analysis and interpretation of research data; Advanced knowledge at the forefront of Medical and Life Science research, with the ability to integrate the theoretical and practical elements of research training; Developed the ability to conceptualise, design and implement a research project for the generation of new evidence that informs Health, Medicine and Life Science; Developed practical research skills by working with an interdisciplinary research team; The ability to confidently communicate research ideas and conclusions clearly and effectively to specialist and non-specialist audiences; Acquired transferable skills which enhance your employability and future research career.
Modules on the Medicine and Life Sciences course may include:
PMRM01 Critical Appraisal and Evaluation
PMRM02 Data Analysis for Health and Medical Sciences
PMRM03 Research Leadership and Project Management OR any topic specific FHEQ Level 7 module from the College of Medicine ’s portfolio
Mode of delivery:
The 60 credits of the taught element will be delivered face-to-face, combining formal lecturing, seminars, and group work in addition to tutor-led practical classes. The remaining 120 credits for the research element will be available as distance learning either off or on-site. Irrespective of the location for conducting the research project, students will supported through monthly online (Skype)/or face-to-face supervisory meetings.
Students must complete 3 modules of 20 credits each and produce a 120 credits thesis on a research project aligned to one the College’s research theme. Each taught module of the programme requires a short period of attendance that is augmented by preparatory and reflective material supplied via the course website before and after attendance.
The Medicine and Life Sciences programme is designed in two phases:
Phase 1 – Training and Application (October – January; 60 credits)
Taught modules in Research Methods and their application to Medicine and Life Science. Personalised education and training relevant to student’s research interests. Identification of research questions and how they might be addressed.Focused on students existing knowledge and research skills.
Phase 2 – Research Project (February – September; 120 credits)
The project is selected by the student in combination with an academic supervisory team. Focussed on one of the College’s four main research themes: Biomarkers and Genes, Devices, Microbes and Immunity, and Patient & Population Health and Informatics. At the end of Part 2 students submit a 40,000 word thesis worth 120 credits leading to the award of Master of Research in Medicine and Life Science.
Students are required to attend the University for 1 week (5 consecutive days) for each module in Phase One. Attendance during Phase Two is negotiated with the supervisor.
You are also encouraged to attend the Postgraduate Taught Induction Event during the induction week and any programme associated seminars, together with Postgraduate research events.
The cell is the building block of life, the smallest unit with the molecular characteristics of living systems. Increased knowledge of the mechanisms of the biomolecular and biochemical processes in the cell can lead to better medicines, new methods for combating diseases.
The basis of the two-year master’s programme in Life Science and Technology is formed by research carried out in the life sciences and chemistry groups of the Leiden Institute of Chemistry (LIC). Researchers take a science-based approach in finding tailored solutions for complex societal problems as encountered in personalized medicine, systems biology and sustainable use of biological sources. Starting from day one, and during the whole master programme you are a member of a research team in the LIC. Guided by a personal mentor, the student assembles a tailor-made educational programme for optimal training to become a life sciences professional.
Read more about our Life Science and Technology programme.
Find more reasons to study Life Science and Technology at Leiden University.
If you are interested in Life Science and you are looking for a programme with ample of opportunities to assemble your own study path, our Life Science and Technology programme is the right choice. The programme addresses societal problems on a molecular and cellular level. You can also choose a specialisation where you combine one year of Life Science and Technology research with one year of training in business, communication or education.
Read more about the entry requirements for Life Science and Technology.
Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Clinical Science (Medical Physics) at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).
Medical physicists fill a special niche in the health industry. The role includes opportunities for laboratory work, basic and applied research, management and teaching, which offers a uniquely diverse career path. In addition there is satisfaction in contributing directly to patient treatment and care.
This three-year programme in Clinical Science (Medical Physics), hosted by the College of Medicine, builds on an existing collaboration with the NHS in providing the primary route for attaining the professional title of Clinical Scientist in the field of Medical Physics.
The Clinical Science (Medical Physics) programme is accredited by the NHS and provides the academic component of the Scientist Training Programme for medical physics trainees, within the Modernising Scientific Careers framework defined by the UK Department of Health, and offers students the chance to specialise in either radiotherapy physics or radiation safety. This Master’s degree in Clinical Science (Medical Physics) is only suitable for trainees sponsored by an NHS or an equivalent health care provider.
The MSc in Clinical Science (Medical Physics) is modular in structure, supporting integration of the trainee within the workplace. Students must obtain a total of 180 credits to qualify for the degree. This is made up of 120 credits of taught-course elements and a project that is worth 60 credits and culminates in a written dissertation.
The Clinical Science (Medical Physics) MSc is accredited by the Department of Health.
Modules on the Clinical Science (Medical Physics) MSc typically include:
• Introduction to Clinical Science
• Medical Imaging
• Nuclear Medicine and Diagnostic Imaging
• Radiation Protection
• Radiotherapy Physics
• Research Methods
• Advanced Radiotherapy
• Specialist Radiotherapy
• Advanced Radiation Safety
• Specialist Radiation Safety
The MSc in Clinical Science (Medical Physics) provides the main route for the professional qualification of Clinical Scientist in Medical Physics.
Additionally, the need for specific expertise in the use of medical radiation is enshrined in law. The Ionising Radiation (Medical Exposure) Regulations (IRMER) 2000 defines the role of Medical Physics Expert, required within any clinical context where radiation is being administered, either a diagnostic or therapeutic.
The close working relationship between Swansea University and the NHS in Wales, through the All-Wales Training Consortium for Medical Physics and Clinical Engineering, provides the ideal circumstances for collaborative teaching and research. The Consortium is recognised by the Welsh Government. A significant proportion of the teaching is delivered by NHS Clinical Scientists and other medical staff.
The close proximity of Swansea University to Singleton Hospital, belonging to one of the largest health providers in Wales, Abertawe Bro Morgannwg University (ABMU) health board, as well as the Velindre NHS Trust, a strongly academic cancer treatment centre, provide access to modern equipment, and the highest quality teaching and research.
The Institute of Life Science (ILS) Clinical Imaging Suite has recently been completed and overlaps the University and Singleton Hospital campuses. It features adjoined 3T MRI and high-resolution CT imaging. ILS has clinical research of social importance as a focus, through links with NHS and industrial partners.
Swansea University offers a vibrant environment in medically-oriented research. The Colleges of Medicine has strong research links with the NHS, spearheaded by several recent multimillion pound developments, including the Institute of Life Science (ILS) and the Centre for NanoHealth (CNH).
The University provides high-quality support for MSc student research projects. Students in turn make valuable progress in their project area, which has led to publications in the international literature or has instigated further research, including the continuation of research at the doctoral level.
The College of Medicine provides an important focus in clinical research and we have the experience of interacting with medical academics and industry in placing students in a wide variety of research projects.
Medical academics have instigated projects examining and developing bioeffect planning tools for intensity modulated radiotherapy and proton therapy and devices for improving safety in radiotherapy. Industry partners have utilised students in the evaluation of the safety of ventricular-assist devices, intense-pulsed-light epilators and in the development of novel MRI spectroscopic methods. The student join teams that are solving research problems at the cutting-edge of medical science.
Working at the interface of Chemistry, Biology and Medical science
In Nijmegen we offer a multidisciplinary Master's programme in Molecular Life Sciences. Working at the interface of chemistry, biology and medical science, you will not only explore the basic principles of molecules and cells, but also their role in health and disease. This combination of scientific topics translated into medical implications and solutions is unique in the Netherlands.
See the website http://www.ru.nl/masters/mls
The Master's programme in Molecular Life Science is closely associated with chemistry and medical biology. You can choose a specialisation in Chemistry or in Medical Biology
- Chemistry for Life
- Clinical Biology
- Medical Epigenomics
Most graduates go on to do a PhD in Nijmegen, at another Dutch university or abroad. Each year our research institutes have a number of PhD vacancies. Some find a job as a researcher or manager in the pharmaceutical industry, in the private commercial sector or in research organisations.
- Top scientists
The programme is closely associated with two institutes that have an excellent international reputation:
- the Institute of Molecules and Materials
- the Nijmegen Centre for Molecular Life Sciences.
You will enter a dynamic research environment, work with top scientists, learn about the latest developments in your discipline and conduct research in state-of-the-art laboratories. Thanks to cooperation with the neighbouring University Medical Centre, there is continuous exchange between Lab and Clinic.
- Great freedom and personal tutor
You will be given considerable freedom to follow your own interests. Two internships are central to the programme. You choose a specialisation and you join a related research group, for example Anthropogenetics, Molecular Biology, Pharmacology, Neurobiology or Bioinformatics. You will have your personal tutor who will help you decide which subjects and research to follow. Your second internship will be with a different research group or related to your variant. You can also choose to follow an internship abroad or within a company. In making your choice, you will be able to benefit from the extensive international networks of our scientists.
- The Nijmegen approach
The first thing you will notice as you enter our Faculty of Science is the open atmosphere. This is reflected by the light and transparent building and the open minded spirit of the working, exploring and studying people that you will meet there. No wonder students from all over the world have been attracted to Nijmegen. You study in small groups, in direct and open contact with members of the staff. In addition, Nijmegen has excellent student facilities, such as high-tech laboratories, libraries and study ‘landscapes'.
Studying by the ‘Nijmegen approach' is a way of living. We will equip you with tools which are valuable for the rest of your life. You will be challenged to become aware of your intrinsic motivation. In other words, what is your passion in life? With this question in mind we will guide you to translate your passion into a personal Master's programme.
See the website http://www.ru.nl/masters/mls
The Master in Molecular and Cellular Life Sciences (MCLS) is research oriented and takes a multidisciplinary approach to study related to health and disease in cells and organisms. By the end of the programme you will gain sufficient fundamental knowledge to start working on applications in the field of medical and biotechnological issues. These applications may include the development of new medicines and vaccines, new strategies for crop improvement, or the development of enzymes to be used in industry.
MCLS is the ideal Master’s programme if you are interested in molecules as the basis of life and disease and if you want to know how chemistry, biology, biomedical sciences, and physics contribute to our understanding of how these molecules work. The interplay of molecules in cells and organisms is the central focus of the programme.
The Dutch Master's Selection Guide (Keuzegids Masters 2017) ranked this programme as the best in the field of Chemistry in the Netherlands.
You will develop extensive knowledge about cellular processes such as cellular signaling, membrane biogenesis and intracellular transport. You will also learn skills and methods to study the molecules involved in these processes by using biochemistry, structural biology, cell biology, biophysics, computational biology, proteomics and genomics. The programme offers you the flexibility to choose any specialisation within the field of molecular and cellular life sciences.
Within this Master’s programme you can choose one of four tracks:
Our multidisciplinary Medical Imaging Sciences MRes offers you the opportunity to undertake research in an exciting and rapidly evolving field. Medical imaging is growing in importance both in patient management and clinical decision making, and also in drug development and evaluation. You will work with a multidisciplinary team of academics directing a wide range of cutting-edge research projects, with an emphasis on putting ideas and theory into practice, literally “from bench to bedside”.
Our Medical Imaging Sciences course aims to provide graduates of chemistry, physics, computing, mathematics, biology, pharmacy or medicine with advanced training in the imaging field.
We have designed this course mainly to prepare you for a PhD, but it also serves as training for employment in hospitals and industry. The key components are two research projects, which may be built around different aspects of a single research area in medical imaging. Medical imaging is a rapidly expanding field that needs input from team members with knowledge and skills in these different areas (chemistry, physics, computing, mathematics, biology, pharmacy, medicine) to achieve its promise in improving patient care.
Our course consists of required and optional taught modules in semesters one and two, and two medical imaging-related research projects in semester two. You will begin with a 30-credit introductory module, which will introduce you to the general area of medical imaging in all its forms and give you a firm grounding in the core elements of the course and preparation for the later research projects. Following this, you will be able to choose optional modules from a range of multidisciplinary modules from other masters’ programmes offered by the School of Biomedical Engineering and Imaging Sciences..
Throughout the course you will be provided with Research Skills training including a dedicated 15-credit module covering the topic in semester two.
We also offer a selection of Cardiovascular Imaging modules, including Cardiovascular Imaging 1: SCMR and Cardiovascular Imaging 4: Introduction to Cardiovascular Physiology. We welcome applications from those with a background in Cardiovascular Imaging, and also from physicians, surgeons, technicians, cardiac physiologists and radiographers.
We use lectures, seminars and group tutorials to deliver most of the modules on the programme. You will also be expected to undertake a significant amount of independent study.
In full-time mode, attendance at lectures, tutorials, laboratory practicals, completing coursework assignments and private study is expected to fill a standard 40 hour week during the semester. The research project requires full time work at least during the months of June, July and August.
Typically, one credit equates to 10 hours of work
The programme is assessed by a variety of mechanisms including: unseen written examinations; practical laboratory work and reports; case studies and oral presentations; workshops; audio-visual presentations; and laboratory- or library-based research projects.
The study time and assessment methods detailed above are typical and give you a good indication of what to expect. However, they may change if the course modules change.
Expected destinations are study for PhD, employment (research or service) in the NHS and commercial nuclear medicine services, the pharmaceutical or medical engineering industry.
Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Medical Radiation Physics at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).
The Medical Radiation Physics course builds on the highly successful research partnerships between the College of Medicine and Abertawe Bro Morgannwg University (ABMU) Health Board, including the Institute of Life Science and Centre for NanoHealth initiatives, and ongoing work in Monte Carlo-based radiotherapy modelling and dosimeter development, body composition, tissue characterisation and novel modes of the detection of disease with state-of-the-art CT and MRI facilities.
On the Medical Radiation Physics MSc, you will gain the necessary knowledge and understanding of fundamental aspects of the use of radiation in medicine, in order that you are conversant in medical terms, human physiology and radiation mechanisms.
A direct link to clinical practice is provided through hands-on instruction with equipment used routinely in the hospital setting, which will prepare you for research in a rapidly changing field, including tuition in computer-based modelling, research methodology and the ethical dimensions associated with medical research.
The Medical Radiation Physics programme is accredited by the Institute of Physics and Engineering in Medicine (IPEM).
The Medical Radiation Physics programme is modular in structure. Students must obtain a total of 180 credits to qualify for the degree. This is made up of 120 credits in the taught element (Part One) and a project (Part Two) that is worth 60 credits and culminates in a written dissertation. Students must successfully complete Part One before being allowed to progress to Part Two.
Part-time Delivery mode
The part-time scheme is a version of the full-time equivalent MSc in Medical Radiation Physics scheme, and as such it means lectures are spread right across each week and you may have lectures across every day. Due to this timetabling format, the College advises that the scheme is likely to suit individuals who are looking to combine this with other commitments (typically family/caring) and who are looking for a less than full-time study option.
Those candidates seeking to combine the part-time option with full-time work are unlikely to find the timetable suitable, unless their job is extremely flexible and local to the Bay Campus.
Timetables for the Medical Radiation Physics programme are typically available one week prior to each semester.
Modules on the Medical Radiation Physics course can vary each year but you could expect to study:
• Introduction to the Practice of Medical Physicists and Clinical Engineers
• Nanoscale Simulation
• Physics of the Body
• Nuclear Medicine and Diagnostic Radiology
• Research Methods
• Radiation Protection
• Radiation Physics
• Radiotherapy Physics
• Medical Imaging
• Advanced Radiotherapy
• MSc Research Project
The Medical Radiation Physics course has been accredited by the Institute of Physics and Engineering in Medicine (IPEM). IPEM is the professional body that works with physical science, engineering and clinical professionals in academia, healthcare services and industry in the UK and supports clinical scientists and technologists in their practice through the provision and assessment of education and training.
The close proximity of Swansea University to two of the largest NHS Trusts in the UK outside of London, as well Velindre NHS Trust (a strongly academic cancer treatment centre), offers the opportunity for collaborative research through student placements.
The academic staff of this discipline have always had a good relationship with industrial organisations, which are the destination of our medical engineering graduates. The industrial input ranges from site visits to seminars delivered by clinical contacts.
The Medical Radiation Physics course will prepare you for research and clinical practise in a rapidly changing field, including tuition in computer modelling, human engineering and the medico-legal issues they imply. It will enable you to develop the potential to become leaders, defining and influencing medical practise.
For a medical physicist career path, the role includes opportunities for laboratory work, basic and applied research, management and teaching, offering a uniquely diverse career. In addition there is satisfaction in contributing directly to patient treatment and care.
Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Life Science and Healthcare Enterprise at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).
The Masters of Research in Life Science and Healthcare Enterprise is a taught research programme portfolio designed to give Health Professionals, Life Scientists, Biomedical Scientists, Medics and Academics the opportunity to conduct masters-level research in a supported environment, with relevant training and application to Life Science-related expert witnesses from Industry and Academia through the provision of a series of master-classes.
We combine a multidisciplinary approach of industrial collaboration and integrated and innovative teaching that promises to bring significant advances in the development of leaders of research and innovation in the Life Science sector:
- The opportunity to specialise in to five different areas of Medical Manufacturing, Medical Technology and Pharmaceutical and -Regenerative Medicine with supervision by experienced academics, leading researchers in the field and experts at the forefront of the life sciences industry
- Develop research skills by working with an interdisciplinary research team
- Comprehend, design and implement business models across life science enterprise and innovation
- Engage with clinicians through new and established links with local hospitals and NHS Health Boards.
Each programme within the Life Science and Healthcare Enterprise portfolio consists of two Phases:
• Phase 1 (October – January): 3 taught modules (compulsory modules) totaling 60 credits, which can lead to the award of a Postgraduate Certificate in Life Science and Healthcare Enterprise
• Phase 2 (February – September): an 8 month research project. At the end of this phase, you will submit a 40,000-words thesis worth 120 credits leading to the award of the MRes in Life Science Healthcare Enterprise
The Life Science and Healthcare Enterprise programme ethos is eclectic, innovative and novel in respect to developing you to be ready for the world of business within the Life Science sector. You will be immersed in and exposed to a learning environment with an open, innovative, global multidisciplinary culture.
By the end of the Life Science and Healthcare Enterprise programme, you will be prepared to be entrepreneurs or a senior employee within large and small business, and capable of leading change to a more entrepreneurial and innovative culture.
During the taught element of this Master's programme in Life Science and Healthcare Enterprise, students are required to attend for 1 week (5 consecutive days) teaching block, followed by 1 week of independent study (i.e. no formal teaching sessions) for the generation of a white paper and ending in the Presentation, Defence and Assessment period in Week 3 for each module.
Attendance during Part Two is negotiated with the supervisor. You are also encouraged to attend the Postgraduate Taught Induction Event during the induction week and any programme associated seminars.
This one-year, full time programme provides an excellent grounding for PhD or other academic study in the Biomedical Sciences. You will learn valuable research skills, biomedical laboratory techniques and a wide range of other transferable skills that will give you an advantage for the rest of your career. You can also choose two themes that best suit your interests and career goals.
The programme includes seminars, taught modules and two research projects in our world-recognised research laboratories. We will also cover a range of valuable transferable skills including critical analysis of research papers, learning how to write a project grant application and literature review, and data presentation and statistical analysis.
The programme includes core skills, seminars, taught modules and laboratory projects in our well-resourced laboratories which are at the cutting-edge of Biomedical research.
Students will carry out two 20-week long research projects selected from the themes available. An assessed research proposal is also required for the second project.
Project 1 (September to February)
Project 2 (April to August)
Students may also be able to undertake projects in Integrative Neuroscience or in other areas of Biomedical Sciences, with the permission of the Programme Director. These students would be required to attend the taught element of one of the above Themes as appropriate.
Students are also required to attend the taught element of another theme as appropriate.
In March, students submit a research proposal based on the work to be performed for Project 2. This takes the form of a grant application, as would be prepared for a research organisation, and is assessed.
This programme is an excellent stepping-stone to a PhD, or a career in Biomedical research or industry.
In addition, every year there are vacancies for PhD studentships in the School of Biomedical Sciences and staff are always on the lookout for the outstanding postgraduate students who are on this Programme to encourage them to apply.
Read testimonials from some of our successful students:
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.
Find out more detail by visiting the programme web page
Find out about fees
*Please be advised that some programmes have different tuition fees from those listed above and that some programmes also have additional costs.
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