MSci Medical Sciences (Human Genomics)
|Typical offer||AAB-ABB; IB: 34-32; BTEC DDD-DDM|
Dr Anna Murray describes Genomic Medicine at the University of Exeter Medical School.
• Study genes, their action and how they are passed on through generations
• Learn how powerful technologies in genomics allow us to sequence a person’s entire genetic code: the genome, giving insight into the mechanisms of normal and pathological states, as well as the identification, diagnosis
• Help contribute to the latest research in human / medical genomics and gain higher level insight into bioinformatics, ethics and counselling, new generation sequencing, genetics of cancer and infectious diseases, and epigenetics by studying modules and carrying out research at Masters level
At present many scientific discoveries never leave the laboratories in which they are made. At the same time the needs of frontline clinicians – and their patients – often go unheard by those doing research. This career-focused degree prepares you to be able to fill these gaps, and thereby enhance the lives of patients.
Our Medical Sciences degrees offer an innovative approach to learning that includes lectures from world-leading experts; supportive small-group learning; internationally renowned e-learning resources; hands-on sessions in research laboratories and clinical settings; inspirational clinician-scientist-patient sessions; and worldwide professional training placements. The curriculum combines contemporary medical science with the training required to undertake cutting-edge research.
This four-year programme that mirrors the BSc Medical Sciences (Human Genomics) and includes an additional fourth year at Masters level.
Genomics is the study of the structure and function of our genome. Genes are regulated to produce the RNAs and proteins needed for life, and these factors may be influenced by internal factors (such as genetic variation or disease states) or external factors (such as our environment).
Powerful technologies in genomics allow us to sequence a person’s entire genetic code, giving insight into the mechanisms of normal and pathological states, as well as the identification, diagnosis and treatment of genetic disorders.
• Medical Genetics
• Medical Genomics
• Genomics and Introductory Bioinformatics
• Microbiology of the Gene
• Final Year Project in Human Genomics
You’ll develop an integrated, scientific knowledge that you can put into practice in a clinical setting and robust research skills, plus creative and inquisitive communication, leadership, critical appraisal and problem-solving skills. These key skills will prepare you for a career helping to progress scientific discovery into clinical and medical practice, ultimately to improve human health.
Join us at one of our Open Days.
The modules we outline here provide examples of what you can expect to learn on this degree course based on recent academic teaching. The precise modules available to you in future years may vary depending on staff availability and research interests, new topics of study, timetabling and student demand.
Our Medical Sciences degree prioritises the science that underpins medicine and clinical practice, preparing you to translate scientific discoveries and technological advances into improved healthcare. To achieve this, the first part of the programme gives you a wide-ranging insight into how the human body normally works. We study this through small-group sessions, lectures and hands-on laboratory practicals.
We then build upon this foundation to see how things can go wrong in the body due to disease and trauma and how normal function might be restored. We are keen that you develop a holistic understanding of human health. For example, whilst pharmaceutical intervention may be appropriate in some conditions, other conditions might be helped more by using technology or engineering. You will be able to see this for yourself, thanks to the wide range of placements that run throughout the programme.
Your final year will be spent specialising in the area that interests you most, tailoring your degree to match your specific career ambitions. You’ll also undertake a two-term long independent research project under the supervision of an academic.
In your first year you will explore the science that underpins the advancement of modern medical practice. The emphasis is on understanding the normal functioning of the human body, from enzymes through to whole biological systems. Without this core knowledge of how the body works, it would be impossible for us, as scientists, to devise the new diagnostic tests, drugs or treatments that will best benefit patients.
Alongside traditional lectures, tutorials and laboratory practicals, you will engage in small group work where you are given the freedom to explore a scientific topic under the expert guidance of one of our tutors (in the Integrated Human Physiology and Fundamental Skills for Medical Scientists modules). Further tutor-guided learning occurs within our Life Science Resource Centre, supported by state-of-the-art technology-enhanced learning resources (the Integrated Human Physiology module). Your core laboratory skills will be developed through laboratory-based practicals that run alongside and support your other sessions. Some sessions also involve a doctor, scientist and patient to explore key clinical cases from three different perspectives.
You will begin to compile your Personal Development and Professionalism Portfolio, in which you chart your progress from a new student to a professional individual ready for the world of employment. You will do this by analysing your academic performance and the frequent feedback offered by the school to identify opportunities for personal and professional development to help you achieve your career goals. Support for your academic progress and career planning is provided by your Academic Tutor and through various workshops and training sessions.
Integrated Human Physiology
|CSC1004||Fundamental Skills for Medical Scientists||30|
|BIO1341||Biochemistry and Genetics||30|
|BIO1342||Microbiology and Cells 1||30|
|CSC1905||Academic and Professional Support||0|
The second year focuses on the scientific basis of important diseases, beginning with some fundamental insights into the ways in which human biology goes awry in disease. This knowledge is then used to explore how cutting-edge scientific technologies can be exploited to advance disease diagnosis and treatment.
Within a variety of learning environments, including lectures, tutorials, workshops, laboratory practicals and small group learning, you will have opportunities to investigate and debate how disease develops and how healthcare can be improved. Key aspects of applied research are explored, including clinical research methods and its design and setting within healthcare environments. Your understanding of these areas develops through a variety of hands-on learning opportunities which enhance your practical research skills and knowledge of contemporary medical research issues.
|CSC2012||Disease, Diagnostics and Therapeutics||30|
|CSC2014||Principles of Medical Research||30|
|CSC2905||Academic and Professional Support||0|
You must take 45 credits of optional modules, at least 15 credits of which must be from the Biosciences options.
|CSC2013||Medical Research Evaluation||15|
|CSC2004||Medical Genetics (core module for Genomics pathway)||15|
|CSC2006||Foundations in Neuroscience (core module for Neuroscience pathway)||15|
|CSC2005||Introduction to Pharmacology (core module for Pharmacology and Therapeutics pathway)||15|
|CSC2017||Ethical Issues in Health Research (core module for Health Research Pathway)||15|
|CSC2007||Introduction to Health Research (core module for Health Research Pathway)||15|
|CSC2016||Measurement & Evaluation in Health Research||15|
|BIO2078||Medical and General Microbiology||15|
|BIO2092||Genomics and Introductory Bioinformatics||15|
|BIO2089||Molecular Biology of the Gene||15|
|BIO2088||Advanced Cell Biology||15|
|BIO2090||Analytical Techniques in Biochemistry||15|
In your final year you have opportunities to study and undertake research to help improve current medical knowledge and practice. In addition to the core modules, you can select from a range of optional specialist advanced modules, enabling you to tailor your degree to match your own specific interests and career ambitions.
You will look at authentic and complex clinical case scenarios and, working as a team, apply evidence-based scientific theory and explore emerging new health technologies to help improve patient health. During this year, you will undertake a clinical/medical research project, closely supervised by an expert research professional.
You will complete your Personal Development and Professionalism Portfolio. Support will be provided to help you consider your career options and help consolidate your CV and interview technique.
120 credits at Stage 4, made up of 90 credits of compulsory modules and 30 credits of optional modules (at least 15 credits must be taken from the recommended optional modules listed below)
|CSC3905||Academic and Professional Support||0|
|CSC4019||Translational Medical Science||30|
*For credits from your Research Project to count towards the specialism, your focus of study in this module must be in the field of human genomics.
The final year provides the opportunity to work at Masters level, accruing 120 credits. You may be permitted to work in the same area of research at Masters level in year 4, as you do in the 3rd year.
You must complete 4 taught modules.
|HPDM036||"Omics" Techniques and their Application to Genomic Medicine||15|
|HPDM037||Genomics of Common and Rare Inherited Diseases||15|
|HPDM041||Bioinformatics, Interpretation, Statistics and Data Quality Assurance*||15|
*If you have taken BIO3092 Bioinformatics in year 3 you do not need to complete HPDM041 Bioinformatics, Interpretation, Statistics and Data Quality Assurance.
If you have taken BIO3092 Bioinformatics in year 3 you must choose 2 optional modules. Those that complete HPDM041 Bioinformatics, Interpretation, Statistics and Data Quality Assurance must choose 1 optional module.
|HPDM038||Molecular Pathology of Cancer and Application in Cancer Diagnosis, Screening, and Treatment||15|
|HPDM039||Pharmacogenomics and Stratified Healthcare||15|
|HPDM044||Ethical, Legal and Social Issues||15|
|HPDM045||Counselling Skills for Genomics||15|
|BIOM567||Application of Genomics in Infectious Disease||15|
Entry requirements 2019
AAB-ABB; IB: 34-32; BTEC DDD-DDM
At least one grade A and one grade B in GCE AL science subjects, one of which must be Biology. At least one HL6 and one HL5 in IB science subject, one of which must be Biology.
GCE AL/AS science includes: Biology/Human Biology*; Chemistry; Computing; Design and Technology; Electronics; Environmental Studies; Geography; Geology; Maths/Pure Maths/Further Maths*; Physical Education; Physics; Psychology; Science (applied); Statistics.
*If more than one of these is taken they would only count as one ‘science’ but could count as two A levels towards our general requirements.
Applicants studying a BTEC Extended Diploma will also require one grade A and one grade B in GCE AL science subjects, one of which must be Biology.
Students joining the three-year programme will have the option to transfer to the four-year programme, and vice versa.
Please read the important information about our Typical offer.
For full and up-to-date information on applying to Exeter and entry requirements, including requirements for other types of qualification, please see the Applying section.
Learning and teaching
Throughout the programme, you benefit from a careful blend of innovative and traditional teaching methods employed by both the Medical School and the Biosciences department. A variety of stimulating, cutting-edge resources are also available to support your learning.
Structured small group learning sessions
In tutor-led groups of 8-12 students you will investigate key scientific concepts and systems presented in the form of triggers. The style of trigger varies week by week but will include patient-based clinical case studies, current media-worthy medical science breakthroughs and extracts from research papers.
Within your group, you will discuss the trigger and report back your individual research findings, coming to a shared understanding of the medically relevant scientific knowledge important to fully understand the trigger. Throughout your degree you will have the opportunity to apply your increasing knowledge to new triggers and build on the depth of your understanding.
These small group sessions will also develop your critical thinking, problem design and solving, teamwork, presentation and lifelong learning skills which are essential for your career development.
Life Sciences Resource Centre activities
You’ll be supported in your exploration of the human biomedical science that is presented in your small group sessions by the rich variety of state-of-the-art resources available in the Life Sciences Resource Centre. These resources include anatomical models, multimedia and IT resources, and a well-stocked library. Tutor-led activities will drive your engagement with selected resources in order to increase your understanding of the small group triggers.
Lectures and seminars
Large group lectures and cutting-edge research seminars delivered by academics as well as external speakers will complement your studies. Lectures may contain students from a variety of different programmes for which the lecture content is relevant.
Practical laboratory sessions
You will develop your laboratory skills in the biosciences teaching laboratory on the Streatham Campus and the new teaching lab at the St Luke’s campus, which are equipped with instruments for observational, experimental and numerical aspects of biosciences including a range of biochemical, molecular, physiological and electronic apparatus.
Computer-based practical sessions are held in the IT suite on the St Luke’s Campus. Helpful and friendly technicians and demonstrators are always available during practical sessions to ensure that you get the most out of your training sessions.
Your learning will be supported by the University’s virtual learning environment. You will have individual access to electronic journals, content-rich study guides, and interactive online learning materials covering various science disciplines, formative online assessments and group discussion forums.
Regular assessment is used to help provide you with frequent feedback, enabling you to identify your strengths, as well as areas for improvement. Feedback is provided in a number of different ways including online written feedback and self, peer, tutor or small group feedback.
Assessment in the early stages of the degree tends to be more knowledge-based to ensure a strong and broad grounding in the subject area, with some opportunities for essay writing and critical analysis.
Assessment in the later degree stages tends to assess your critical appraisal skills, depth of understanding and your ability to think independently. Some assessments take place in groups, focusing on the team product or how well you lead your team to complete a task.
A variety of assessment methods are employed across the programme, each aligned to the intended learning outcomes of the modules. Assessment formats include multiple-choice tests, essays, structured practical exams, reflective essays, oral and poster presentations, scientific report writing, short-answer question tests and independent project work.
This programme is designed to prepare you for employment in a wide variety of professional careers and helps to develop the key transferable skills valued by employers.
These skills range from identifying and solving problems, to efficient communication, leadership and management. Key vocational skills, such as advanced laboratory training within molecular biology, also enhance your employability.
Science graduates compete well in the wider graduate employment market, as they offer strong analytical and problem-solving skills valued highly across all sectors.
You would acquire the knowledge, understanding and skills that should help you gain employment or PhD positions especially in the expanding fields of genomics, bioinformatics, or other medically-related research and development in either academia, pharmaceutical or biotech industries.
All students are assigned an academic tutor by the Medical School for the duration of your programme. Your academic tutor is there to help and support you in any areas related to your academic progress including providing advice on careers, employability and training events.
In addition to your academic tutor in the Medical School, you’ll be assigned a programme adviser from Biosciences who will provide you with extra academic support for your Biosciences modules.
Pastoral Support and Wellbeing
We offer a friendly and supportive environment from your first day with us. Our Pastoral Tutor team can provide assistance with non-academic issues and there is a designated Student Welfare Officer (SWO) for the Medical School. Prospective students can contact the SWO on email@example.com for student support enquiries.
The University also provides extensive wellbeing support through a range of services including counselling services, advice units, chaplaincy, childcare facilities and student health centres. Find out further information about our Wellbeing services.