Whether you are a new graduate or already employed and seeking to further your career prospects, this course offers a solid career development path. You can also choose this course if you wish to pursue research in biotechnology at PhD level.
Biotechnology is the application of biological processes and is underpinned by • cell biology • molecular biology • bioinformatics • structural biology. It encompasses a wide range of technologies for modifying living organisms or their products according to human needs.
Applications of biotechnology span medicine, technology and engineering.
Important biotechnological advances including
The course is led by academics who are actively involved in biotechnology research and its application to the manipulation of proteins, DNA, mammalian cells and plants. Staff also have expertise in the use of nanoparticles in drug delivery and the manipulation of microbes in industrial and environmental biotechnology.
You are supported throughout your studies by an academic advisor who will help you develop your study and personal skills.
What is biotechnology
Biotechnology is the basis for the production of current leading biopharmaceuticals and has already provided us with the 'clot-busting' drug, tissue plasminogen activator for the treatment of thrombosis and myocardial infarction. It also holds the promise of new treatments for neurodegeneration and cancer through recombinant antibodies.
Genetically modified plants have improved crop yields and are able to grow in a changing environment. Manipulation of cellular organisms through gene editing methods have also yielded a greater understanding of many disease states and have allowed us to understand how life itself functions.
You begin your studies focusing on the fundamentals of advanced cell biology and molecular biology before specialising in both molecular and plant biotechnology. Practical skills are developed throughout the course and you gain experience in molecular biology techniques such as PCR and sub cloning alongside tissue culture.
Core to the program is the practical module where you gain experience in a range of techniques used in the determination of transcription and translational levels, for example.
All practicals are supported by experienced academic staff, skilled in the latest biotechnological techniques.
Research and statistical skills are developed throughout the program. Towards the end of the program you apply your skills on a two month research project into a current biotechnological application. Employability skills are developed throughout the course in two modules.
The masters (MSc) award is achieved by successfully completing 180 credits.
The postgraduate certificate (PgCert) is achieved by successfully completing 60 credits.
The postgraduate diploma (PgDip) is achieved by successfully completing 120 credits.
Optional modules :
As students progress through the course they are exposed to a wide range of teaching and learning activities. The assessment strategy of the postgraduate course considers diverse assessment methods. Some modules offer dedicated formative feedback to aid skills development with assessments going through several rounds of formative tutor and peer feedback. Summative assessment methods are diverse, with examinations present in theory-based modules to test independent knowledge and data analysis. Several modules are entirely coursework-based, with a portfolio of skills such laboratory practical's and research proposals generated throughout the course forming the summative tasks. In all cases, the assessment criteria for all assessed assignments are made available to student prior to submission.
The course is suitable for people wishing to develop their knowledge of molecular and cell biotechnology and its application to solving health and industrial problems.
You can find career opportunities in areas such as
Students on this course have gone on to roles including experimental officers in contract research, research and development in scientists, diagnostics specialists and applications specialists. Many of our graduates also go on to study for PhDs and continue as academic lecturers.
This study course is for students who wish to become specialised graduates with an advanced biomedical knowledge concerning the links between the structure and the purpose of biomolecules and bio-systems operating at cellular and tissue level of the human body, in both physiological and pathological conditions. The wide knowledge of the techniques is based on a solid practical activity in laboratories during the internship.
Subject to the educational aims of Class LM-9, the acquired knowledge allows specialized graduates to assist physicians in the diagnostic and therapeutic tasks involving the manipulation of cells, genes, and other biosystems requiring applicants to learn special skills in experimental biotechnology (e.g. Diagnosis and gene therapy; therapy through the use of genetically engineered cells; rational design and development of new medicines based on models of molecular targets known or derived from pharmacogenomic knowledge; preparation of nano-biotechnological tools for advanced diagnostics imaging and drug delivery; modulation of the immune response; diagnostics based on innovative processes of science and medical laboratory techniques; immunotherapy to targeted cells); organize and coordinate laboratory activities for advanced research or for diagnostic examinations requiring the use of biotechnological methods and the manipulation of cells or biotechnological materials; organize and coordinate the experimental protocols of clinical research involving the use of materials or biotechnology techniques; design and perform with autonomy research in biotechnology applied to medicine; lead and coordinate, also in governance, development programs and surveillance of biotechnology applied to human beings, taking into account the ethical, technical, environmental and economic implications.
First year: Advanced Biomedical Technologies Or Laboratory Activities 1: Cellular And Molecular Therapies Or Laboratory Activities 2: Molecular And Systems Biology, Laboratory Medicine Technologies And Molecular Diagnostics, Pharmaceutical Biotechnology: Design And Analysis Of Biopharmaceuticals, Seminar
Molecular Medicine Curriculum: 6 Months At Ulm University: Glp/Gsp Bioethics, Molecular Oncology, Trauma Research And Regenerative Medicine
Traditional Curriculum: Proteomics And Bioinformatics, Cell And Organ Physiology And Medical Pathophysiology, Genetics, Immunology And General Pathology, Nanobiotechnology
Second year: Experimental Models In Vivo And Vitro, Pharmacology And Molecular Therapies, Stem Cell Biology And Molecular Biology Of Development, Thesis Work
Molecular Medicine Curriculum + Proteomics And Bioinformatics
Biotechnology physicians will be able to head research laboratories in a predominantly technological and pharmacological environment and coordinate, as well as in terms of management and administration, program development and the monitoring of biotechnology applied on human beings with emphasis on the development of pharmaceutical products and vaccines, taking into account the ethical, technical, and legal implications and environmental protection.
Graduates will be able to assist doctors in the diagnostic and in the therapeutic phases when those imply the manipulation of cells, genes and other bio systems and when specific biotechnological experimental competences are required.
The University of Padova, the Veneto Region and other organisations offer various scholarship schemes to support students. Below is a list of the funding opportunities that are most often used by international students in Padova.
You can find more information below and on our website here: http://www.unipd.it/en/studying-padova/funding-and-fees/scholarships
You can find more information on fee waivers here: http://www.unipd.it/en/fee-waivers
Looking to further your career within the creative industries? Southampton Solent’s innovative and transmedia MA Critical Creative Practice programme focuses on individual student-centred learning and encourages critical creative practice across the creative spectrum, including art, design, fashion, photography, media arts and technology, helping to enhance employability and leaving you well-prepared to progress within your chosen creative field.
Taught by both creative industry professionals and academic practitioners, the course enables students to develop ideas and engage with the emerging material and digital cultures of the future, as well as the fast-changing demands of the creative industries and the associated changes to cultural production, consumption and interpretation.
The course structure is theory and practice based. The theoretical element consists of critical core units which reference visual culture, cultural theory, critical theory, art and design history, media culture, and material and digital culture. The interdisciplinary practice element relates to creative practice in the fields of art, design, fashion, photography, media arts and technology.
The integration of theory and practice is central to the course and learning is carefully structured through these interdependent units to develop a broad base of interrelated experiences, whilst also providing the opportunity to specialise through the professional practice unit and the choice of final dissertation or final project.
Students will also have the opportunity to take optional technician-supported introductory workshops which could include contemporary arts practice, photography, new media practice, 3D printing and laser cutting, material manipulation, performance, beauty and the body, film editing, and sound and image production. To complement their studies, students may be able to take part in international and European study exchange opportunities through the University's study abroad programmes.
The unique approach of this course can enhance employability, enabling students to progress into the workplace equipped with valuable critical thinking and practice-based skills required for working in the creative industries and forming innovative hybrid engagements.
Graduates from this course will be well-placed for careers in a broad range of the creative industries, such as art, design, media, film, fashion, photography, education, culture and heritage, and curation.
This course is well-suited to graduates who wish to further their career within the creative industries by gaining a solid understanding of creative practice and critical thinking across a broad range of disciplines.
Optional technician supported introductory workshops to be run in both semester one and two: Contemporary Arts Practice, Photography, New Media Practice, 3D Printing and Laser Cutting, Material Manipulation, Performance, Beauty and the Body, Film Editing, and Sound and Image Production.
Solent University provides a well-resourced environment to help students develop and harness enterprising and entrepreneurial practice. Students on this course have access to dedicated studio space to develop their individual creative practice. Other creative spaces and equipment available to students include photographic studios, fashion studios, Mac rooms, recording equipment, editing suites, and performance and exhibition space.
Solent is also home to a 24-hour library, modern IT facilities and a range of expert learning and employability support services.
The course team has strong industry links and students may have the opportunity to benefit from relevant industry contacts and academic links including John Hansard Gallery, V&A Museum, ICA Education and Events Programme, Solent Showcase exhibition space, Solent Research and Innovation Office, Solent Learning and Teaching Institute, Solent Material and Digital Archive.
Students may also benefit from internship and partnership collaboration opportunities with Hampshire Cultural Trust (Arts Council England-funded South East Museum Development Programme.
Students studying on courses within the School of Art, Design and Fashion may also have the opportunity to gain additional industry insights through an excellent guest speaker programme which has included internationally acclaimed artists, designers, photographers, curators, stylists, writers, musicians, performers, filmmakers and Oscar and Bafta award-winning film editors.
This 1 year course leads to an internationally recognised MRes qualification that provides training in transferable skills essential for those wishing to pursue post-graduate PhD, commercial or industrial research opportunities. Focusing on parasites and the diseases that they cause, you will gain expert knowledge in the detection, prevention and control of protozoan as well as metazoan animal and human pathogens. You will be trained in specialisms including biochemistry, molecular biology, whole organism/cell culture and manipulation, bioinformatics, proteomics, transcriptomics, genomics, functional genomics, drug discovery, vaccinology, biomarker discovery, genetics/epigenetics, epidemiology, vector/intermediate host biology and ecology.
At the end of the course you will understand how interdisciplinary methods can be brought to bear on controlling some of the deadliest infectious organisms on the planet and be ready to pursue your career in parasitology.
Parasitism is the most successful lifestyle on the planet and leads to diverse and highly-damaging infectious diseases of agricultural, veterinary and biomedical significance. Therefore, a greater understanding of the parasite species responsible for these conditions and the means by which they are controlled remain a priority for scientists, health care professionals and farmers in this 21st Century. For example, it is recognised that parasitic worms infect greater than 1 billion people worldwide with some species causing between $700 million-$1 billion USDs in economic losses per annum. The development of novel, creative and integrated control strategies are urgently needed to combat the growing threat of changing parasite distributions due to climate change, human migration, animal transportation and farming practices. This MRes course will provide you with a range of vocational skills and prepare you for professional employment or further post-graduate PhD studies in Parasitology or related disciplines (i.e. infectious diseases, public health, epidemiology, etc.).
IBERS continuously maintained an excellent internationally-recognised reputation in parasitological research since the 1930s. One of the British Society of Parasitology’s founding members and two of its past presidents were IBERS Parasitologists. More recently, IBERS appointments and University investments have increased critical mass in Parasitology leading to the formation of the Parasitology and Epidemiology Research Group (in 2007) as well as the Barrett Centre for Helminth Control (in 2016). The creation of both research groupings has facilitated greater interactions with animal health and pharmaceutical/biotech companies as well as increased research grant capture derived from government, research council and charitable funding bodies.
With 360 members of staff (principle investigators, technicians and post-doctoral fellows), 1350 undergraduate students and more than 150 postgraduate students, IBERS is the largest research and teaching institute within Aberystwyth University. Excellence in teaching was recognised by outstanding scores in the National Student Satisfaction Survey (NSS 2017) and being awarded University of the Year for Teaching Quality by the Times and Sunday Times Good University Guide 2018. Employability data from the Recent Destinations of Leavers from Higher Education (DLHE, 2017) shows that 97% of IBERS graduates were in work or further study six months after leaving Aberystwyth University. The economic and social impact of IBERS research was recognised in 2011 when IBERS won the national BBSRC Excellence with Impact Award.
An aspect of this course that uniquely positions itself from other Masters level Parasitology courses in the UK is the 12-month dissertation project (Semesters 1-3). Working under the supervision of active researchers in the field, you will collaboratively develop a research project on diverse topics such as (but not inclusive) intermediate host and vector control, anthelmintic drug and target discovery, biomarker identification, visual cue selection for arthropod vectors, mathematical modelling of disease transmission, host responses to parasite biomolecules, parasite and host population studies and functional genomics manipulation of parasites. A list of available projects and supervisors will be advertised closer to the start of each academic year. Your supervisor/supervisory team will mentor you in hypothesis and discovery driven experimental design, provide training in lab-based and computer-assisted methodologies, arrange instruction in analytical techniques, aid in the trouble-shooting of experimental challenges, assist you in the interpretation of results and prepare you for successful oral presentations. You will also be guided in how to most efficiently communicate your results during the dissertation write-up. It is expected that during this year long research project you will become an expert in your topic.
Please refer to our couse web pages for full details of course modules.
This course is an ideal training programme for those wishing to:
- Pursue PhD studies;
- Work in industry, charities or funding bodies;
- Improve animal and human health;
- Influence governmental policies.
Throughout this course you will:
· Develop strong data collection/analysis, fieldwork and laboratory skills;
· Enhance your scientific communication and team work skills;
· Write for a range of audiences including academics and the wider public;
· Enhance your analytical abilities, critical thinking and problem solving skills;
· Develop study and research skills;
· Direct and sustain a self-initiated programme of study underpinned by good time management skills;
· Work effectively and independently;
· Hone your project management skills to deliver a demanding combination of research, analysis, communication and presentation
During the one year of full-time study students complete 40 60 credits of core modules centred on parasitology, parasite control and a further 20 credits focusing on laboratory techniques & research methodologies. The taught modules are assessed by scientific writing assignments (such as reports, critical reviews, essays and journalistic articles), presentations, contribution to group discussions in seminars and online assignments. The core element of this course is the 120 credit MRes Dissertation, during which students will have supervision meetings to give them guidance before undertaking a prolonged period of experimental work/data gathering, research, and writing up of the dissertation. All postgraduate students in IBERS also have a named personal tutor, with whom they can discuss personal or domestic concerns that impact on their studies. Subsequent successful submission of your dissertation leads to the award of an MRes.
The benefits of GIS are increasingly recognised within government, business, education and the voluntary sector, and the applications of geospatial data technologies are steadily growing. Using GIS, it is possible to combine data from a broad range of sources and in a variety of formats, such as paper and digital maps, routinely collected administrative data, censuses and population surveys, satellite imagery, aerial photography, GPS tracking and surveys, LiDAR and crowd-sourcing. The uses of GIS are very diverse, and include mapping, spatial analysis, planning and decision-making within a wide range of disciplines and sectors – common examples include environmental management and conservation, resource management, emergency service planning and humanitarian assistance, health care provision, land use planning and urban development, the utilities, transport, geo-demographics, mineral extraction and retail analysis. Increasing uptake of GIS and associated techniques and technologies means that there is a growing demand for qualified personnel who have the skills to manage spatial data effectively. Strong industry links help ensure that our course is relevant to the needs of employers.
The course is designed to help people gain understanding and experience of GIS concepts, functionality and applications. Content focuses on the representation, acquisition, management, manipulation and analysis of spatial data. It also includes modules on remote sensing, spatial databases, web-GIS and GIS in the commercial environment. Additional optional modules include GIS work experience, spatial analysis and modelling, GIS for environmental management, and Customising GIS.
After successfully completing the PgDip modules, you may transfer to the Masters part of the programme. This requires the completion of a substantial independent research project, written in the form of a research journal article (which may, with agreement of your supervisor, be submitted for publication).
As part of the course resources, you will be provided with a free copy of ArcGIS, the remote sensing package ERDAS Imagine, and the data analysis package SPSS.
Gaining experience in the workplace and being able to apply academic learning within that context is very beneficial for students preparing to enter the workplace, so we offer the option of undertaking a GIS Work Experience module to full-time students. This entails working within an organisation for 2.5 days per week over a six-week period. Placements (which are unpaid) may be in the public sector, private companies, charities or education. Students who take this module find it extremely helpful for both their professional and personal development and refer particularly to benefits such as broadening their technical skills, gaining experience of team-working and of independent problem-solving, improved confidence and of learning about the geospatial industry and employment through exposure to real-world applications of GIS.
Part-time students who are in GI-related employment may opt to undertake the GIS Workplace Project.
GIS and geospatial technologies underpin a rapidly growing, multi-billion dollar industry, and are becoming increasingly mainstream within both the public and private sectors, resulting in a need for graduates who have a combination of theoretical knowledge and practical skills.
Graduates of this course have secured employment in a variety of GIS-related roles worldwide, in GIS positions including technicians, analysts, scientists, surveyors, data specialists, mapping officers, consultants, project managers, development, sales and marketing, customer support, GIS training, lecturing and research (including funded PhD projects). The breadth of potential uses of GIS ensures a great diversity of job opportunities; for example, our graduates have found employment with mapping agencies, GIS and SatNav companies, environmental consultancies, ecological and marine resource management and environmental agencies, renewable energy companies, forestry, fisheries, town planning departments, heritage agencies, health and emergency services, housing authorities, local government, aid agencies, countryside recreation, rural development, retail analysis, utilities and infrastructure, Further and Higher Education, mining and mineral exploitation and the oil industry, among others. Knowledge and understanding of geo-spatial data is also increasingly required in a variety of jobs outside of the GI profession, making a GIS qualification a valuable asset enhancing employability in a range of fields.
This course increases your knowledge and skills in pharmacology and biotechnology to increase your competitiveness in the job market or complete research at PhD level. If you are already employed, this course can help you to further your career prospects.
The course is delivered by internationally recognised academics who are involved in biotechnology and pharmacology research. Research projects include studying the manipulation of proteins and their application to Alzheimer's disease, epilepsy, ion channels and the development of novel drugs from natural products.
You learn in detail how drugs act at the molecular and cellular level and then how biotechnological techniques are used to produce new drugs. Examples include developing new and effective treatments for diseases, such as Alzheimer’s and rheumatoid arthritis.
You also gain experience of the latest techniques used by the pharmaceutical industry to produce and study the effects of novel drugs.
The course gives you
The masters (MSc) award is achieved by successfully completing 180 credits.
The postgraduate certificate (PgCert) is achieved by successfully completing 60 credits.
The postgraduate diploma (PgDip) is achieved by successfully completing 120 credits.
Assessment is mostly by written examination and coursework including problem solving exercises, case studies and input from practical laboratory work. Research project assessment includes a written report and viva voce.
The course improves your career prospects in areas of • biomedical sciences • medical research in universities and hospitals • the pharmaceutical industry • biotechnology companies • government research agencies.
You also develop the skills to carry out research to PhD level in pharmacology and biotechnology.
Recent MSc Pharmacology and Biotechnology graduates jobs include • project specialist at PAREXEL • quality assurance documentation assistant at Vifor Pharma • PhD at the University of Manchester • clinical research associate at AstraZeneca • workplace services analyst at Deloitte India (Offices of the US) • regulatory compliance specialist for Selerant • senior product executive at PlasmaGen BioSciences.
This programme provides practical, career-orientated training in social science research methods, including research design, data collection and data analysis relating to both qualitative and quantitative modes of inquiry.
Students will have the opportunity to specialise in particular methodologies and to learn more about the application of these methodologies to illuminate important issues and debates in contemporary society.
The programme is designed to provide a fundamental grounding in both quantitative and qualitative research skills, along with the opportunity to specialise in more advanced training in quantitative research, qualitative research or in practical applications of research techniques.
This module offers an introduction to the different styles of social science research as well as guidance and illustrations of how to operationalize research questions and assess them empirically. Students will be shown how to conduct systematic literature searches and how to manage empirical research projects. The module will also explore issues around the ethics of social science research as well as the connection between social science research and policy concerns. It is designed as preparation for undertaking postgraduate research and dissertation work.
This module aims to deepen students' understanding of key debates in social theory and research, providing advanced level teaching for those building upon basic knowledge and undertaking postgraduate research. It is designed to demonstrate and explore how social theory is utilised, critiqued and developed through the pursuit of social science research.
The purpose of this module is to illuminate the theoretical underpinnings of qualitative research. The module will discuss the impact of various theories on the nature and conduct of qualitative research particularly around questions of epistemology and ontology. The role of different types of interviewing in qualitative research will be utilised in order to explore the relationship between theory and methods.
The aim of the module is to provide a comprehensive overview of the theory and practice of measurement and constructing quantitative data in the social sciences. Through lectures and practical exercises, this module will provide students with relevant knowledge of secondary data sources and large datasets, their respective uses and usefulness, and their relevance for the study of contemporary social issues
The module will provide students with an overview of different approaches to qualitative data analysis. It will include introductory training to this skill that includes such techniques as thematic analysis and discourse analysis, as well as computer assisted qualitative data analysis. It will provide the knowledge necessary for the informed use of the qualitative data analysis software package NVivo. The module gives students a base level introduction to the analytical and technical skills in qualitative data analysis appropriate to the production of a Master's dissertation and/or use of CAQDAS software for social science research purposes.
This module provides an introduction to the basics of quantitative data analysis. The module will begin with a brief review of basic univariate and bivariate statistical procedures as well as cover data manipulation techniques. The module is taught through a series of seminars and practical workshops. These two strands are interwoven within each teaching session. Please note that students may be granted an exemption from this module if they have already successfully completed a module that has the equivalent learning outcomes.
This module advances students' confidence and knowledge in the use of SPSS. The module focuses on multivariate regression models, including the appropriate use and awareness of statistical assumptions underlying regression and the testing and refinement of such models.
A dissertation of no more than 15,000 words on a topic relevant to social science research methods training. The thesis will involve either carrying out and reporting on a small social science research project which includes a full and considered description and discussion of the research methods employed or the discussion of a research issue or technique to a level appropriate for publication.
We offer a range of advanced modules in quantitative and qualitative research methods, for example, logistic regression, internet-based research and visual research methods. We also provide specialist modules which reflect the teaching team’s diverse research interests, from the social logic of emotional life to conflict and change in divided societies. Optional modules generally run during the Spring semester and are offered subject to sufficient student demand and staff availability. Students will be able to choose a maximum of three to four option modules (depending on whether they need to complete Quantitative Data Analysis: Foundational). Please note that it is unlikely that all the following modules will be available for 2017/8. Please check with the Programme Director for queries about specific modules.
The MA in Healthcare Ethics & Law course aims to provide the highest quality of training in health care ethics and health care law in a flexible and interdisciplinary way. There is an emphasis on the application of bioethical and legal theory to real world scenarios, thus catering to the practical needs of health care and legal professionals and those in related fields. Students gain an expert knowledge and understanding of bioethical and medico-legal theories, and the skills needed to apply them to real world scenarios in a diverse range of contexts. They will also develop the ethical and medico-legal knowledge and research skills required for writing a Masters-level dissertation, and will be well prepared for further research if they so desire.
You study a wide variety of ethical and legal subjects including autonomy, consent, refusal of treatment, confidentiality, the moral status of the foetus, resource allocation, genetic testing, HIV testing, medical malpractice, clinical negligence, organ and tissue transplantation, fertility treatment, genetic manipulation, research ethics, stem cell research and euthanasia.
Teaching tends to defy the traditional boundaries associated with lectures and seminars. Generally, each class in a course unit has a duration of 2 or 3 hours per week, and is split roughly equally between a formal, didactic period and a structured discussion period (most often based on the so-called challenge-response model). Nevertheless, each class is considered a seminar or lecture, and attendance of all classes of a course unit for which a student is enrolled is thus compulsory . For course units of 15 credit value there will generally be 15 hours of face-to-face teaching throughout the semester in which the unit is delivered, and twice that amount for 30 credit units.
Assessment of all taught course units (to a total of 120 credits) is by assessed coursework in the form of essays of 4,000 words per 15 credit course unit and up to 7,000 words for the two 30 credit core course units. In addition, students who wish to complete the MA must submit a 12,000 to 15,000 word dissertation by independent research (60 credits); no dissertation is required for the PGDip or PGCert. Part-time students undertake a supervised dissertation in the summer months of year two. Please note that the part-time students can extend their registration for extra 3 months to submit their dissertations in December of their second year, instead of September (you will be advised of the exact date on the second year of the course).
Those who do not successfully complete the MA you may be considered for the award of the Postgraduate Diploma.
Those who do not successfully complete the Postgraduate Diploma may be considered for the award of the Postgraduate Certificate.
The awards of the MA or Postgraduate Diploma are classified according to Pass/Merit/Distinction. The Postgraduate Certificate is awarded unclassified.
Students will be required to complete 180 credits: 120 credits comprised of taught course units (each of 15 or 30 credits value), and an independent research element of the course worth 60 credits by way of a Masters dissertation of between 12,000 and 15,000 words, which is undertaken over the summer months of the course. The dissertation should be predominantly law-based.
On the full time course, the 120 taught credits can be split in one of two ways: (1) 60 credits in each of the two semesters; or (2) 75 credits in semester one and 45 credits in semester two.
Students registered on the MA in Healthcare Ethics and Law would need to select a majority of their optional courses from the 'ethics' list (Ethics, Genetics and Genomics; Research Ethics). Global Health Law and Bioethics can count as an ethics or law course.
Details of all current course units available in the School of Law can be found on the Faculty of Humanities website.
The School is offering a number of awards for students applying for masters study. To find out more please visit our Master's funding opportunity search page .
Practical support and advice for current students and applicants is available from the Disability Advisory and Support Service. Email: [email protected]
Successful graduates are able to progress within a wide variety of roles in both medical, legal and ethical fields. Graduates from previous years have, for example, proceeded to specialise in medico-legal practice and academic careers, and the degrees have enhanced the careers of healthcare professionals.