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.
Our MSc in Medical Imaging Science covers a multidisciplinary topic of central importance in diagnosis, treatment monitoring and patient management.
It is also a key tool in medical research and it is becoming increasingly possible to relate imaging studies to genetic traits in individuals and populations. Novel imaging biomarkers of disease can enable more rapid and precise diagnosis and inform decision making in drug discovery programmes.
As medical imaging involves knowledge of anatomy, physiology, pathology, physics, mathematics and computation, our course is suitable if you want to expand your disciplinary horizons and pursue a career in an image-related field in clinical medicine, medical research, or technological research or development.
You will cover the basic science and technology behind the principal imaging modalities currently used in medicine and medical research, as well as advanced imaging methods, clinical and research applications, imaging biomarkers and computational methods.
You will learn how advanced imaging techniques are applied in medical research and drug discovery with an emphasis on magnetic resonance (MR) and positron emission tomography (PET) imaging. You will also receive training in computational and quantitative methods of image analysis or in the interpretation of clinical images from different imaging modalities.
This course comprises both a taught component and a research project, giving you the skills and knowledge required for a career in an image-related field in clinical practice, clinical or scientific research, or technical development.
We aim to provide you with:
Benefit from research-dedicated imaging facilities at several hospital sites and a dedicated molecular imaging centre co-located with the Christie Hospital.
Learn from experts
Manchester has an imaging and image computing research group with a strong international reputation. Our research groups and facilities are staffed by scientists conducting research in novel imaging and image analysis methods, and clinicians who apply these methods in clinical practice.
Learn when it suits you thanks to options for either full-time or part-time study.
Study alongside physicists, engineers, mathematicians, computer scientists, chemists, biologists and clinicians working in hospitals and research-dedicated imaging facilities.
As this course aims to produce graduates equipped to pursue either clinically or technically-focused careers in imaging, it is important to provide an adequate knowledge base. For this reason, much of the teaching takes the form of lectures.
However, in most course units, this is supplemented by group discussions and practical exercises. Other than the introductory units, most course units provide you with an understanding of research methods by requiring submission of a critical review of appropriate research literature or clinical material, either as a report or presentation.
Where appropriate, practical imaging exercises are provided, requiring you to cooperate in acquiring images and analysing results.
All units require a considerable component of independent research and study.
Assessment will occur in a variety of forms.
Summative assessment takes the form of written assignments, examinations, oral presentations and online quizzes. Written assignments and presentations, as well as contributing to summative assessment, have a formative role in providing feedback, particularly in the early stages of course units.
Online quizzes provide a useful method of regular testing, ensuring that you engage actively with the taught material. As accumulation of a knowledge base is a key aim of the course, examinations (both open-book and closed-book) form an important element of summative assessment.
In addition, formal assessment of your research and written communication skills is achieved via the dissertation. This is a 10,000 to 15,000-word report, written and organised to appropriate scientific standards, describing the design, execution and results of the research project.
The MSc requires students to pass 180 credits composed of eight course units of 15 credits each and a 60-credit research project.
We provide course units in Human Biology and Introductory Mathematics and Physics to bring students up to the required level in these topics.
Semester 1: Compulsory units
Semester 2: Compulsory units
Semester 2: Elective units (select one)
You will benefit from research-dedicated imaging facilities at several hospital sites and a dedicated molecular imaging centre co-located with the Christie Hospital.
Each student will have an identified personal tutor who can provide advice and assistance throughout the course. During the research project, you will be in regular contact with your research supervisor.You will also be able to access a range of other library and e-learning facilities throughout the University.
Practical support and advice for current students and applicants is available from the Disability Advisory and Support Service. Email: [email protected]
Graduates will be in an excellent position to pursue careers in image-related fields in healthcare and research. This MSc will also form a sound basis for students who wish to proceed to PhD research in any aspect of medical imaging.
Intercalating medical students may use this qualification as a platform to pursue a clinical career in radiology.
Physical science/engineering graduates may see this as a route to imaging research or development in an academic or commercial environment.
Our MRes Experimental Cancer Medicine master's course will give nurses, doctors and clinical researchers the skills needed to work in early phase clinical studies.
You will learn how to master experimental cancer through a combination of traditional teaching and hands-on learning, spending a year as a member of the Experimental Cancer Medicine Team at The Christie while also taking four structured taught units.
The taught units will see you learn the details of designing and delivering Phase 1 clinical studies, understanding the pre-clinical data required before a clinical programme can commence, and how to optimise early clinical studies to provide evidence for progressing a promising drug into Phase II/III clinical testing.
Alongside the taught elements, you will be allocated to one or more clinical trials that are being conducted by The Christie experimental cancer medicine team. You will have a named trainer and be exposed to tasks required in the setup, delivery, interpretation and audit of a clinical study.
Nursing and physician students will be expected to participate in patient care, including new and follow-on patient clinics, treatment and care-giving episodes with patients.
For clinical trials coordinators, no direct patient contact is envisaged and duties will involve clinical trial setup, protocol amendments, database setup, data entry, costing and billing for clinical research.
You will be able to choose two aspects of your direct clinical trial research experience to write up for your two research projects in a dissertation format. This will give you the skills and knowledge required to critically report medical, scientific and clinically related sciences for peer review.
The primary purpose of the MRes in Experimental Cancer Medicine is to provide you with the opportunity to work within a premier UK Phase 1 cancer clinical trials unit and, through a mix of taught and experiential learning, master the discipline of Experimental Cancer Medicine.
Extensive practical experience
You will spend most of your time gaining hands-on experience within The Christie's Experimental Cancer Medicine Team.
Meet the course team
Dr Natalie Cook is a Senior Clinical Lecturer in Experimental Cancer Medicine at the University and Honorary Consultant in Medical Oncology at The Christie. She completed a PhD at Cambridge, investigating translational therapeutics and biomarker assay design in pancreatic cancer.
Professor Hughes is Chair of Experimental Cancer Medicine at the University and Strategic Director of the Experimental Cancer Medicine team at The Christie. He is a member of the research strategy group for Manchester Cancer Research Centre. He serves on the Biomarker evaluation review panel for CRUK grant applications.
Professor Hughes was previously Global Vice-President for early clinical development at AstraZeneca, overseeing around 100 Phase 0/1/2 clinical studies. He was previously Global Vice-President for early phase clinical oncology, having been involved in over 200 early phase clinical studies.
Dr Matthew Krebs is a Clinical Senior Lecturer in Experimental Cancer Medicine at the University and Honorary Consultant in Medical Oncology at The Christie.
He has a PhD in circulating biomarkers and postdoctoral experience in single cell and ctDNA molecular profiling. He is Principal Investigator on a portfolio of phase 1 clinical trials and has research interests in clinical development of novel drugs for lung cancer and integration of biomarkers with experimental drug development.
Our course is structured around a 2:1 split between clinical-based research projects and taught elements respectively.
Taught course units will predominantly use lectures and workshops.
For the research projects, teaching and learning will take place through one-to-one mentoring from a member of the Experimental Cancer Medicine team.
The clinical and academic experience of contributors to this course will provide you with an exceptional teaching and learning experience.
You will be assessed through oral presentations, single best answer exams, written reports and dissertation.
For each research project, you will write a dissertation of 10,000 to 15,000 words. Examples of suitable practical projects include the following.
Publication-based/dissertation by publication
Service development/professional report/ report based dissertation
Adapted systematic review (qualitative data)
Full systematic review that includes data collection (quantitative data)
Qualitative or quantitative empirical research
Qualitative secondary data analysis/analysis of existing quantitative data
Quantitative secondary data analysis/analysis of existing qualitative data/theoretical study/narrative review
Teaching will take place within The Christie NHS Foundation Trust , Withington.
Practical support and advice for current students and applicants is available from the Disability Advisory and Support Service. Email: [email protected]
This course is relevant to physician, nursing and clinical research students who are considering a career in Phase 1 clinical studies.
The course provides a theoretical and experiential learning experience and offers a foundation for roles within other experimental cancer medicine centres within the UK and EU, as well as careers in academia, the pharmaceutical industry, clinical trials management and medicine.
The MRes is ideal for high-calibre graduates and professionals wishing to undertake directly channelled research training in the clinical and medical oncology field.
The Cancer MSc reflects the depth and breadth of research interests, from basic science to translational medicine, within the UCL Cancer Institute. The programme, taught by research scientists and academic clinicians, provides students with an in-depth look at the biology behind the disease processes which lead to cancer.
This programme offers a foundation in understanding cancer as a disease process and its associated therapies. Students learn about the approaches taken to predict, detect, monitor and treat cancer, alongside the cutting-edge research methods and techniques used to advance our understanding of this disease and design better treatment strategies.
Students undertake modules to the value of 180 credits.
The programme consists of two core modules (60 credits), four specialist modules (60 credits) and a research project (60 credits).
A Postgraduate Diploma (120 credits, full-time nine months) is offered.
A Postgraduate Certificate (60 credits, full-time 12 weeks) is offered.
All MSc students undertake a laboratory project, clinical trials project or systems biology/informatics project, which culminates in a 10,000–12,000 word dissertation and an oral research presentation.
Teaching and learning
Students develop their knowledge and understanding of cancer through lectures, self-study, database mining, wet-lab based practicals, clinical trial evaluations, laboratory training, assigned reading and self-learning. Each taught module is assessed by an unseen written examination and/or coursework. The research project is assessed by the dissertation (75%) and oral presentation (25%).
Further information on modules and degree structure is available on the department website: Cancer MSc
The knowledge and skills developed will be suitable for those in an industrial or healthcare setting, as well as those individuals contemplating a PhD or medical studies in cancer.
Skills include critical evaluation of scientific literature, experimental planning and design interpretation of data and results, presentation/public speaking skills, time management, working with a team, working independently and writing for various audiences.
UCL is one of Europe's largest and most productive centres of biomedical science, with an international reputation for leading basic, translational and clinical cancer research.
The UCL Cancer Institute brings together scientists from various disciplines to synergise multidisciplinary research into cancer, whose particular areas of expertise include: the biology of leukaemia, the infectious causes of cancer, the design of drugs that interact with DNA, antibody-directed therapies, the molecular pathology of cancer, signalling pathways in cancer, epigenetic changes in cancer, gene therapy, cancer stem cell biology, early phase clinical trials, and national and international clinical trials in solid tumours and blood cancers.
The Research Excellence Framework, or REF, is the system for assessing the quality of research in UK higher education institutions. The 2014 REF was carried out by the UK's higher education funding bodies, and the results used to allocate research funding from 2015/16.
The following REF score was awarded to the department: Cancer Institute
80% rated 4* (‘world-leading’) or 3* (‘internationally excellent’)
Learn more about the scope of UCL's research, and browse case studies, on our Research Impact website.