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Biological Sciences×

Full Time MSc Degrees in Biological Sciences, Sheffield, United Kingdom

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This MSc gives students excellent postgraduate training, and leads to exciting careers in research, industry, the NHS and other clinical institutions. Read more

About the course

This MSc gives students excellent postgraduate training, and leads to exciting careers in research, industry, the NHS and other clinical institutions. Many of our graduates have also gone on to study bioscience at PhD level.

You’ll develop an in-depth knowledge of medical and molecular genetics, and receive clinical genetics training to prepare you for a research project in a modern research facility. You’ll have the chance to collaborate with top genetics research laboratories and clinical partners.

This MSc was developed in partnership with the Sheffield Diagnostic Genetics Service (NHS), which is a world-renowned clinical genetics facility. This relationship is unique to this course and gives you the opportunity to be taught by the Director of the Sheffield Diagnostic Genetics Service, Sheffield Children’s Hospital NHS Foundation Trust, 
and their Head of Pharmacogenetics.

Where your masters can take you

Our graduates work in health care, pharmaceuticals, food safety and production, brewing and agrochemicals. Many of our masters students go on to do a PhD then pursue a career in research; others have gained entry to the prestigious NHS Scientist Training Programme (STP).

An international reputation

The 2014 Research Excellence Framework (REF) ranks Sheffield No 1 for biomedical research and in the UK top five for biological sciences generally. We have regular seminars from distinguished experts, and our motivated staff undertake collaborative research ranging from biotechnology to medicine.

Teaching and assessment

Our masters courses give you a solid grounding in experimental science, with personal supervision and tutorials by experienced scientists, based in modern and well-equipped labs, leading on to a research project in which you design and conduct your own research. You will learn cutting edge science from research leaders, and gain practice in reading the scientific literature and writing reports. Assessment is based on a combination of coursework, project work, formal examinations and a dissertation.

Modules

Genome Stability and Genetic Change; Human Genetics I; Human Genetics II; Advanced Research Topics; Laboratory Techniques in Molecular Bioscience; Literature Review; Research Project.

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The biotechnological applications of molecular biology underpin major industries in the medical and agricultural sectors. Insights from the study of genetic material are already benefitting the development of new diagnostic tests, therapeutic agents, bioenergy production systems, improved crops and more. Read more

About the course

The biotechnological applications of molecular biology underpin major industries in the medical and agricultural sectors. Insights from the study of genetic material are already benefitting the development of new diagnostic tests, therapeutic agents, bioenergy production systems, improved crops and more. The range and value of these developments is rapidly increasing.

This exciting MSc Molecular Biology and Biotechnology program provides training for bioscience graduates to develop confidence and independence in their practical skills and knowledge relevant to careers in this area. Successful graduates will be ready to undertake further study at PhD level or to enter employment in the biotechnology sector.

You’ll learn essential practical skills; study the relevant theory in the Departments of Molecular Biology and Biotechnology (MBB) and Chemical and Biological Engineering (CBE); and carry out an individual research project, in which you’ll learn how to design and conduct research, keep records and present the research in different styles.

Where your masters can take you

Our graduates work in health care, pharmaceuticals, food safety and production, brewing and agrochemicals. Many of our masters students go on to do a PhD then pursue a career in research; others have gained entry to the prestigious NHS Scientist Training Programme (STP).

An international reputation

The 2014 Research Excellence Framework (REF) ranks Sheffield No 1 for biomedical research and in the UK top five for biological sciences generally. We have regular seminars from distinguished experts, and our motivated staff undertake collaborative research ranging from biotechnology to medicine.

Teaching and assessment

Our masters courses give you a solid grounding in experimental science, with personal supervision and tutorials by experienced scientists, based in modern and well-equipped labs, leading on to a research project in which you design and conduct your own research. You will learn cutting edge science from research leaders, and gain practice in reading the scientific literature and writing reports. Assessment is based on a combination of coursework, project work, formal examinations and a dissertation.

Core modules

Laboratory Skills in Molecular Bioscience; Principles of Biochemical Engineering; Advanced Research Topics; Literature Review; Research Project (typical research areas include plant genetic engineering, engineering of proteins of commercial importance, or genetic studies by random mutagenesis).

Examples of optional modules

Choose two from: The RNA World, Cells as Factories, Plant Biotechnology, Microbiology of Extreme Environments.

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Advance your knowledge of analytical chemistry, your practical skills and professional and organisation skills on this course. You learn the fundamentals of analytical chemistry and how it is applied to pharmaceutical, environmental and materials analyses. Read more
Advance your knowledge of analytical chemistry, your practical skills and professional and organisation skills on this course. You learn the fundamentals of analytical chemistry and how it is applied to pharmaceutical, environmental and materials analyses. The course is taught by researchers with an international reputation in advanced analytical techniques, such as the application of mass spectrometry to the analysis of biological matrices. Tutors also have expertise in production and detection of nanoparticles and detection of pollutants, particularly in soil.

This course is suitable if you wish to increase your knowledge and skills and increase your competitiveness in the job market or pursue a PhD. It will also suit you if you work in a chemistry-related profession and are seeking to further your career prospects.
You gain experience and understanding of:
-Key techniques in separation sciences, including liquid and gas chromatography.
-Atomic and molecular spectroscopy, such as atomic absorption and emission, NMR and IR.
-Analytical technologies applied in process control and solving complex biological problems.

This is a multi-disciplinary course where you learn about various topics including statistics, laboratory quality assurance and control, environmental analysis and fundamentals of analytical instrumentation.

You also gain the transferable skills needed to continue developing your knowledge in science, such as data interpretation and analysis, experimental design and communication and presentation skills.

You complete a research project to develop your research skills and their application to real world situations. You are supported by a tutor who is an expert in analytical chemistry.

Your laboratory work is carried out in our teaching laboratories which are extensively equipped with the latest models of analytical instruments such as HPLCs and GCs. This is supplemented by access to our research facilities where you have access to more sophisticated equipment, such as NMR and a suite of various types of mass spectrometers.

Professional recognition

This course is accredited by the Royal Society of Chemistry (RSC). Applicants should normally have a degree (bachelors or equivalent) in chemistry that is accredited by the RSC. Applicants whose first degree is not accredited by the RSC, or with overseas degrees or degrees in which chemistry is a minor component will be considered on a case by case basis on submission of their first degree transcript.

Candidates who do not meet the RSC criteria for accreditation will be awarded a non-accredited masters qualification on successful completion of the programme.

Applicants will be informed in writing at the start of the programme whether or not they possess an acceptable qualification and, if successful on the masters programme, will receive an RSC accredited degree. If you do not meet the RSC criteria for accreditation, you will be awarded a non-accredited masters after successfully completing the programme.

For more information, see the website: https://www.shu.ac.uk/study-here/find-a-course/mscpgdippgcert-analytical-chemistry

Course structure

Full time – 14 months to Masters. Part time – typically 2 years to Masters. The diploma and certificate are shorter. Starts September.

Course structure
The Masters (MSc) award is achieved by successfully completing 180 credits.

Core modules
-Quality issues, laboratory accreditation and the analytical approach (15 credits)
-Separation, detection and online techniques (15 credits)
-Surface analysis and related techniques (15 credits)
-Drug detection and analysis (15 credits)
-Methods for analysis of molecular structure (15 credits)
-Process analytical technology (15 credits)
-Professional development (15 credits)
-Research methods and statistics (15 credits)
-Research project (60 credits)

The Postgraduate Certificate (PgCert) is achieved by successfully completing 60 credits.
The Postgraduate Diploma (PgDip) is achieved by successfully completing 120 credits.

Assessment
Assessment methods include written examinations and coursework including:
-Problem-solving exercises.
-Case studies.
-Reports from practical work.
-Research project assessment includes a written report and viva voce.

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If you’re an international fee-paying student you could be eligible for a £3,000 discount when you start your course in January 2017. Read more
If you’re an international fee-paying student you could be eligible for a £3,000 discount when you start your course in January 2017.
http://www.shu.ac.uk/VCAwardJanuary2017

This course is suitable if you:
-Wish to pursue research into molecular and cell biology or disease mechanisms at PhD level.
-Want to improve your knowledge and skills to be competitive in the life science jobs market.
-Are currently employed and seeking to improve your career prospects.

Most of your practical work is carried out in our teaching laboratories which contain industry standard equipment for cell culture, quantitative nucleic acid and protein analysis and a sophisticated suite of analytical equipment such as HPLC and gas chromatography. In addition many of our research facilities such as flow cytometry, confocal microscopy and mass spectrometry are used in taught modules and research projects and our tutors are experts in these techniques.

You gain:
-A detailed and up-to-date understanding of molecular biology and cell biology.
-Knowledge of how alterations or defects in cellular processes may lead to disease, such as cellular dysfunction leading to degenerative diseases, cell cycle dys-regulation in cancer, and how mutations result in genetic diseases.
-Hands-on expertise in the latest techniques including cell culture, flow cytometry, real-time PCR, immuno-histochemistry and recombinant DNA technology.
-Professional skills to further your career in research or the life science industry.

The teaching on the course is split between formal lectures and tutorials, and laboratory-based work. A third of the course is a laboratory-based research project, where students are assigned to a tutor who is an active researcher in the biomedical research centre. Typically, taught modules have a mixture of lectures and tutorials and involve a significant amount of laboratory time. Other modules are tutorial-led with considerable input from the course leader who acts as personal tutor.

Tutors complete research within the Biomolecular Sciences Research Centre into cancer, musculoskeletal diseases, human reproduction, neurological disease, medical microbiology and immunological basis of disease. Their work is regularly published in international peer-reviewed journals, showing that the course is underpinned by relevant quality research.

For more information, see the website: https://www.shu.ac.uk/study-here/find-a-course/mscpgdippgcert-molecular-and-cell-biology

Course structure

Full time – 14 months to Masters. Part time – typically 2 years to Masters. The diploma and certificate are shorter. Starts September and January.

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.

Core modules
-Biomedical laboratory techniques (15 credits)
-Cell biology (15 credits)
-Cellular and molecular basis of disease (15 credits)
-Molecular biology (15 credits)
-Professional development (15 credits)
-Research methods and statistics (15 credits)
-Research project (60 credits)

Options (two from)
-Applied biomedical techniques (15 credits)
-Cellular and molecular basis of cancer (15 credits)
-Molecular biotechnology (15 credits)

Assessment
Assessment methods include written examinations and coursework including: problem-solving exercises; case studies; reports from practical work. Research project assessment includes a written report and viva voce.

Read less
If you’re an international fee-paying student you could be eligible for a £3,000 discount when you start your course in January 2017. Read more
If you’re an international fee-paying student you could be eligible for a £3,000 discount when you start your course in January 2017.
http://www.shu.ac.uk/VCAwardJanuary2017

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:
-Up-to-date knowledge of cellular and molecular pathology of various human diseases.
-The basis of therapeutic rationales for treating diseases and their development.
-An advanced understanding of recombinant DNA technology and how it is used to produce drugs.
-Experience of the latest practical techniques, such as cell culture, quantitative PCR analysis, cloning, western blotting, and analytical techniques such as HPLC and mass spectrometry.
-The transferable and research skills to enable you to continue developing your knowledge and improve your employment potential.

For more information, see the website: https://www.shu.ac.uk/study-here/find-a-course/mscpgdippgcert-pharmacology-and-biotechnology

Course structure

Full time – 14 months to Masters. Part time – typically 2 years to Masters. The certificate and diploma are shorter. Starts September and January.

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.

Core modules
-Cell biology (15 credits)
-Fundamentals of pharmacology (15 credits)
-Molecular biology (15 credits)
-Biotechnology (15 credits)
-Professional development (15 credits)
-New approaches to pharmacology (15 credits)
-Research methods and statistics (15 credits)
-Research project (60 credits)

Optional modules (one from)
-Applied biomedical techniques (15 credits)
-Cellular and molecular basis of cancer (15 credits)
-Pharmaceutical drug development (15 credits)
-Human genomics and proteomics (15 credits)

Assessment
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.

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University of Sheffield School of Medicine
Distance from Sheffield: 0 miles
Lead academic 2016. Dr Martin Nicklin. This flexible course focuses on the molecular and genetic factors of human diseases. Understanding those factors is crucial to the development of therapies. Read more

About the course

Lead academic 2016: Dr Martin Nicklin

This flexible course focuses on the molecular and genetic factors of human diseases. Understanding those factors is crucial to the development of therapies. Core modules cover the fundamentals. You choose specialist modules from the pathway that interests you most. We also give you practical lab training to prepare you for your research project. The project is five months of invaluable laboratory experience: planning, carrying out, recording and reporting your own research.

Recent graduates work in academic research science, pharmaceuticals and the biotech industry.

Our study environment

You’ll be based in teaching hospitals that serve a population of over half a million people and refer a further two million. We also have close links with the University’s other health-related departments.

Our research funding comes from many sources including the NIHR, MRC, BBSRC, EPSRC, the Department of Health, EU, and prominent charities such as the Wellcome Trust, ARC, YCR, Cancer Research UK and BHF. Our partners and sponsors include Novartis, GlaxoSmithKline, Pfizer, Astra Zeneca and Eli Lilly.

You’ll also benefit from our collaboration with the Department of Biomedical Sciences.

How we teach

Classes are kept small (15–20 students) to make sure you get the best possible experience in laboratories and in clinical settings.

Our resources

We have a state-of-the-art biorepository and a £30m stem cell laboratory. The Sheffield Institute of Translational Neuroscience (SITraN) opened in November 2010. We also have microarray, genetics, histology, flow cytometry and high-throughput screening technology, and the latest equipment for bone and oncology research.

At our Clinical Research Facility, you’ll be able to conduct studies with adult patients and volunteers. The Sheffield Children’s Hospital houses a complementary facility for paediatric experimental medical research.

Hepatitis B policy

If your course involves a significant risk of exposure to human blood or other body fluids and tissue, you’ll need to complete a course of Hepatitis B immunisation before starting. We conform to national guidelines that are in place to protect patients, health care workers and students.

Core modules

From Genome to Gene Function; Human Gene Bioinformatics; Research Literature Review; Human Disease Genetics; Modulating Immunity; Laboratory Practice and Statistics.
You choose: six optional pathways

1. Genetic Mechanisms pathway:


Modelling Protein Interactions; Gene Networks: Models and Functions.

2. Microbes and Infection pathway:


Virulence Mechanisms of Viruses, Fungi and Protozoa; Mechanisms of Bacterial Pathogenicity; Characterisation of Bacterial Virulence Determinants.

3. Experimental Medicine pathway:


Molecular and Cellular Basis of Disease; Model Systems in Research; Novel Therapies.

4. Cancer pathway:

Molecular Basis of Tumourigenesis and Metastasis; Molecular Techniques in Cancer Research; Molecular Approaches to Cancer Diagnosis and Treatment.

5. Cardiovascular pathway:

Vascular Cell Biology; Experimental Models of Vascular Disease; Vascular Disease Therapy and Clinical Practice.

6. Clinical Applications pathway:

Apply directly to this pathway. Available only to medical graduates. Students are recruited to a specialist clinical team and pursue the taught programme (1-5) related to the attachment. They are then attached to a clinical team for 20 weeks, either for a clinical research project or for clinical observations. See website for more detail and current attachments.

Teaching and assessment

Lectures, seminars, tutorials, laboratory demonstrations, computer practicals and student presentations. Assessment is continuous. Most modules are assessed by written assignments and coursework, although there are some written exams. Two modules are assessed by verbal presentations.

Your research project is assessed by a thesis, possibly with a viva.

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On this established and well respected course, you gain the knowledge, skills and attributes needed to be an effective sport and exercise science practitioner. Read more
On this established and well respected course, you gain the knowledge, skills and attributes needed to be an effective sport and exercise science practitioner. You develop strong technical, analytical, practical and professional skills, alongside specialist skills in biomechanics and performance analysis, physiology and nutrition, and strength and conditioning.

The course enables you to:
-Develop your understanding of science.
-Develop your ability to apply theory to practice in sport and exercise.
-Work towards British Association of Sport and Exercise Science (BASES) accreditation, (at the discretion of BASES, graduates are able to apply for exemption from some elements of the BASES supervised experience accreditation scheme).
-Conduct independent research.
-Gain experience as a sport or exercise science consultant.

We offer a first-class suite of research and teaching laboratories alongside excellent facilities offered by our partnership venue at the English Institute of Sport, Sheffield. Our laboratories are all British Association of Sport and Exercise Science (BASES) accredited.
The four overarching study themes are:
-Analysis of performance.
-Improving performance.
-Research methods and data analysis in both research and applied practice.
-Professional practice.

Many of the teaching staff support elite athletes as part of their work in the Centre for Sport and Exercise Science (CSES). The team for sport performance have worked successfully with athletes competing at the Olympics, Paralympics, and Winter Olympics. They have provided, or are currently providing, sport science research and consultancy services at elite level for the
-Amateur Boxing Association
-Amateur Swimming Association (diving and swimming)
-British Cycling
-British Speed Skating Association
-British Skeleton-Bob Team
-English Bowls Association
-English Golf Union
-Royal Yachting Association
-GB table tennis
-GB volleyball

You benefit from CSES' activities as they allow us to keep course content at the cutting edge, based on our knowledge and experience of sport and exercise science delivery. You can also benefit from a work-based learning programme to help develop your experience of working in multidisciplinary teams, supporting athletes and coaches.

During the course you use a mix of traditional and online learning resources to ensure the course is flexible and can fit in with your existing commitments. The quality of our provision was rated 24/24 by the Higher Education Council.

Sheffield Hallam are a Skills Development Partner of the Chartered Institute for Managing Sport and Physical Activity.

For more information, see the website: https://www.shu.ac.uk/study-here/find-a-course/mscpgdippgcert-applied-sport-and-exercise-science

Course structure

Full time – 1 year
Part time – typically 2 years
Starts September

The masters award is achieved by successfully completing 180 credits.

Core modules
-Analysis and evaluation of performance: technical and tactical (15 credits)
-Analysis and evaluation of performance: functional and metabolic (15 credits)
-Inter-professional practice in sport and exercise science (15 credits)
-Work-based learning in sport and exercise science (15 credits)
-Research methods (15 credits)
-Data analysis (15 credits)
-Project (60 credits)

Optional modules
30 credits from:
-Improving performance: strength and conditioning (15 credits)
-Improving performance: physiology and nutrition (15 credits)
-Applied performance analysis (15 credits)
-Applied movement analysis (15 credits)
-Human factors in sports engineering (15 credits)

Assessment
Assessments may include:
-Laboratory reports
-Project/ethics proposal
-Needs analysis
-Qualitative data analysis
-Managing projects
-Problem solving exercises
-Group work
-Oral presentations
-Poster presentations
-Case study defence or report
-Quantitative data analysis examination
-Project file
-Abstract writing
-Article prepared for publication (MSc only)
-Action plan
-Organisational report
-Technology-based communication package

Other admission requirements

We designed this course to continue specialist studies at masters level for students who already possess a relevant first degree. You may also have an appropriate combination of other subject specific qualifications and relevant practical experience.

The course leader interviews applicants with non-standard qualifications.

If English is not your first language you will need an IELTS score of 6.0 with a minimum of 5.5 in all skills, or a recognised equivalent. If your level of English language is currently below IELTS 6.0 we recommend you consider an appropriate Sheffield Hallam University Pre-sessional English course which will enable you to achieve the required level of English.

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This unique specialist course gives you practical experience in human embryonic stem cell techniques, helping you develop the professional skills employers want. Read more

About the course

This unique specialist course gives you practical experience in human embryonic stem cell techniques, helping you develop the professional skills employers want. You’ll also spend time in seminars considering the ethical and legal issues associated with the field.

Where your masters can take you

Graduates with skills in stem cell and regenerative medicine are in demand. Your degree will prepare you for a career in research in academia or industry, or in a clinical-related field. Our graduates are working all over the world – from the UK to China, India and the USA – and over half go on to doctoral study.

Learn from the experts

The 2014 Research Excellence Framework (REF) rates us No 1 in the UK for research in this field. Our international reputation attracts highly motivated staff and students. Sheffield is a vibrant place to take a masters based on pioneering research.

Regular seminars from distinguished international experts help you to connect your studies to the latest developments. We’re also part of collaborative research groups for developmental biology, cell biology, physiology, pharmacology, neuroscience, models of human disease, stem cell science and regenerative medicine.

Our three research centres focus on translating laboratory research to the clinical environment: Bateson Centre, the Centre for Stem Cell Biology, and the Centre for Membrane Interactions and Dynamics.

Leaders in our field

We have a long track record of groundbreaking discoveries. These include breakthroughs in human stem cells for hearing repair, and the generation of animal models for Parkinson’s disease, schizophrenia, muscular dystrophies and their use for therapeutic studies.

Labs and equipment

We have purpose-built facilities for drosophila, zebrafish, chick and mouse genetics and for molecular physiology. Other facilities provide all the tools you’ll need to examine and analyse a range of cellular structures. We have an electron and a light microscopy centre, a PCR robotics facility, a flow cytometry unit and an RNAi screening facility.

Teaching and assessment

There are lectures, practical classes, tutorials and seminars. In small group teaching classes you’ll discuss, debate and present on scientific and ethical topics. Laboratory placements within the department provide you with one-to-one attention, training and support to do your individual research project. Assessment is by formal examinations, coursework assignments, debates, poster presentations and a dissertation.

Our teaching covers ethics, practical scientific skills and an overview of the current literature. You’ll also develop useful career skills such as presentation, communication and time management.

Core modules

Literature Review; Practical Research Project; Analysis of Current Science; Ethics and Public Understanding.

Examples of optional modules

Stem Cell Techniques; Practical Cell Biology; Practical Developmental Genetics; Bionanomaterials; Modelling Human Diseases; Stem Cell Biology.

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This course blends theory and practice to help you develop the skills required for a career in molecular and cellular biology. Our teaching focuses on integrated mammalian biology and animal models of human disease, drawing on our pioneering biomedical research. Read more

About the course

This course blends theory and practice to help you develop the skills required for a career in molecular and cellular biology. Our teaching focuses on integrated mammalian biology and animal models of human disease, drawing on our pioneering biomedical research.

Where your masters can take you

Graduates with skills in stem cell and regenerative medicine are in demand. Your degree will prepare you for a career in research in academia or industry, or in a clinical-related field. Our graduates are working all over the world – from the UK to China, India and the USA – and over half go on to doctoral study.

Learn from the experts

The 2014 Research Excellence Framework (REF) rates us No 1 in the UK for research in this field. Our international reputation attracts highly motivated staff and students. Sheffield is a vibrant place to take a masters based on pioneering research.

Regular seminars from distinguished international experts help you to connect your studies to the latest developments. We’re also part of collaborative research groups for developmental biology, cell biology, physiology, pharmacology, neuroscience, models of human disease, stem cell science and regenerative medicine.

Our three research centres focus on translating laboratory research to the clinical environment: Bateson Centre, the Centre for Stem Cell Biology, and the Centre for Membrane Interactions and Dynamics.

Leaders in our field

We have a long track record of groundbreaking discoveries. These include breakthroughs in human stem cells for hearing repair, and the generation of animal models for Parkinson’s disease, schizophrenia, muscular dystrophies and their use for therapeutic studies.

Labs and equipment

We have purpose-built facilities for drosophila, zebrafish, chick and mouse genetics and for molecular physiology. Other facilities provide all the tools you’ll need to examine and analyse a range of cellular structures. We have an electron and a light microscopy centre, a PCR robotics facility, a flow cytometry unit and an RNAi screening facility.

Teaching and assessment

There are lectures, practical classes, tutorials and seminars. In small group teaching classes you’ll discuss, debate and present on scientific and ethical topics. Laboratory placements within the department provide you with one-to-one attention, training and support to do your individual research project. Assessment is by formal examinations, coursework assignments, debates, poster presentations and a dissertation.

Our teaching covers ethics, practical scientific skills and an overview of the current literature. You’ll also develop useful career skills such as presentation, communication and time management.

Core modules

Literature Review; Practical Research Project; Analysis of Current Science; Ethics and Public Understanding.

Examples of optional modules

Integrated Mammalian Biology; Practical Cell Biology; Practical Developmental Genetics; Cancer Biology; Modelling Human Diseases; Epithelia in Health and Disease.

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Study at the cutting edge of sports engineering and learn how to apply advanced engineering techniques to the research and development of sports technologies. Read more
Study at the cutting edge of sports engineering and learn how to apply advanced engineering techniques to the research and development of sports technologies. This course is taught by the Centre for Sports Engineering Research, one of the largest hubs of sports engineering research in the world.

If you are a high-achieving graduate in engineering and the physical sciences, learn to develop and apply your technical knowledge to the world of sport. The course gives you the skills and knowledge to work at the cutting edge of research and development in the sports equipment industry.

More than ever, the world of sport is intimately connected to new technologies. The global sports equipment industry is valued at £200 billion annually and is driven by new research and innovation. In addition professional and national teams are increasingly reliant on technological solutions to monitor and assess the performance of their elite athletes.

Throughout this course you enhance your technical, problem solving and engineering skills and learn to apply them to the sporting environment. You also develop a biomechanical and physiological understanding of athletes, enabling you to analyse the athlete-equipment interactions in sport.

You complete a major industry linked research project to develop your practical understanding of sports engineering, to gain vital real world experience as well as improve your employability. Recent student projects have been partnered to organisations such as:
-Adidas
-Ping
-Prince Sports
-Mitre
-Gunn and Moore
-Eley
-International Tennis Federation
-International Rugby Board
-D3o
-English Institute of Sport
-UK Sport

The course is delivered by the Centre for Sports Engineering Research an internationally renowned centre of excellence for research and consultancy with over 200 years of cumulative experience. The Centre for Sports Engineering Research has 35 research staff and PhD students making it one of the world’s largest centres for sports engineering research. The group has close ties to many different sports companies and organisations and works extensively to enhance elite performance across many sports through its role as an English Institute of Sport research and innovation partner.

We assign you an academic and professional advisor, whose role is to support your academic and professional development, and career planning. You can also attend a free four day leadership award, that explores different perspectives on leadership.

The course is led by Dr Simon Choppin, a fellow of the research centre and an associate editor of the Sports Engineering Journal.

For more information, see the website: https://www.shu.ac.uk/study-here/find-a-course/msc-sports-engineering

Course structure

Full time – 1 year
Part time – 2 years (the part-time route is only available to home and EU students)
Starts September

The course is made up of nine taught modules, plus a major industry linked research project. All modules are mandatory and have been tailored to match the previous experience of a graduate engineer/ physical scientist. The vast majority of teaching is in small groups (typically less than 20) allowing for bespoke delivery.

Modules
-Industry linked research project (45 credits)
-Mechanics of sports equipment (15 credits)
-Measurement techniques in sports engineering and biomechanics (15 credits)
-Computer simulation of sports equipment (15 credits)
-Numerical programming in sports engineering (15 credits)
-Innovation and enterprise in sports engineering (15 credits)
-Human factors in sports engineering (15 credits)
-Physiology of sport and exercise (15 credits)
-Research methods (15 credits)

Assessment: examinations, coursework, presentations, research project thesis.

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If you’re an international fee-paying student you could be eligible for a £3,000 discount when you start your course in January 2017. Read more
If you’re an international fee-paying student you could be eligible for a £3,000 discount when you start your course in January 2017.
http://www.shu.ac.uk/VCAwardJanuary2017

Enhance your knowledge and skills in biosciences with an emphasis on biotechnology and increase your competitiveness in the job market. 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 production of therapeutic proteins using cloned DNA, for example insulin and clotting factors.
-The application of stem cells to treat human disease.
-The enhancement of crop yields and plants with increased nutritional value.
-Herbicide and insect resistant plants.
-Production of recombinant antibodies for the treatment of disease.
-Edible vaccines, in the form of modified plants.
-Development of biosensors for the detection of biological and inorganic analytes.

You gain:
-Up-to-date knowledge of the cellular and molecular basis of biological processes.
-An advanced understanding of DNA technology and molecular biotechnology.
-Knowledge of developing and applying biotechnology to diagnosis and treatment of human diseases.
-Practical skills applicable in a range of bioscience laboratories.
-The transferable and research skills to enable you to continue developing your knowledge and improving your employment potential.

The course is led by internationally recognised 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 a personal tutor.

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.

For more information, see the website: https://www.shu.ac.uk/study-here/find-a-course/mscpgdippgcert-biotechnology

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. Recombinant proteins are also found throughout everyday life from washing powders to cheese as well as many industrial applications.

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.

Course structure

Full time – 14 months to Masters. Part time – typically 2 years to Masters. The Diploma and Certificate are shorter. Starts September and January.

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.

Core modules
-Cell biology (15 credits)
-Biotechnology (15 credits)
-Plant biotechnology (15 credits)
-Molecular biology (15 credits)
-Applied biomedical techniques (15 credits)
-Professional development (15 credits)
-Research methods and statistics (15 credits)
-Research project (60 credits)

Options (choose one from)
-Human genomics and proteomics (15 credits)
-Cellular and molecular basis of disease (15 credits)
-Cellular and molecular basis of cancer (15 credits)

Assessment
Assessment methods include written examinations and coursework including: problem-solving exercises; case studies; reports from practical work; in-depth critical analysis; oral presentations. Research project assessment includes a written report and viva.

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University of Sheffield School of Medicine
Distance from Sheffield: 0 miles
Lead academic 2016. Dr Jonathan Wood. Translational Neuroscience looks at how laboratory research relating to brain structure and function informs the development of new therapies for diseases of the nervous system. Read more

About the course

Lead academic 2016: Dr Jonathan Wood

Translational Neuroscience looks at how laboratory research relating to brain structure and function informs the development of new therapies for diseases of the nervous system.

Combining the research strengths from the Faculty of Medicine, Dentistry and Health and the Faculty of Science, leading international basic and clinical scientists will provide an innovative and progressive programme. You’ll study basic neurobiology and molecular biology through to neuroimaging and applied clinical practice.

The MSc will provide you with up-to-date knowledge of advances in the field, research experience with internationally renowned research groups and transferable skills to provide a springboard for your future career.

Our study environment

You’ll be based in teaching hospitals that serve a population of over half a million people and refer a further two million. We also have close links with the University’s other health-related departments.

Our research funding comes from many sources including the NIHR, MRC, BBSRC, EPSRC, the Department of Health, EU, and prominent charities such as the Wellcome Trust, ARC, YCR, Cancer Research UK and BHF. Our partners and sponsors include Novartis, GlaxoSmithKline, Pfizer, Astra Zeneca and Eli Lilly.

You’ll also benefit from our collaboration with the Department of Biomedical Sciences.

How we teach

Classes are kept small (15–20 students) to make sure you get the best possible experience in laboratories and in clinical settings.

Our resources

We have a state-of-the-art biorepository and a £30m stem cell laboratory. The Sheffield Institute of Translational Neuroscience (SITraN) opened in November 2010. We also have microarray, genetics, histology, flow cytometry and high-throughput screening technology, and the latest equipment for bone and oncology research.

At our Clinical Research Facility, you’ll be able to conduct studies with adult patients and volunteers. The Sheffield Children’s Hospital houses a complementary facility for paediatric experimental medical research.

Hepatitis B policy

If your course involves a significant risk of exposure to human blood or other body fluids and tissue, you’ll need to complete a course of Hepatitis B immunisation before starting. We conform to national guidelines that are in place to protect patients, health care workers and students.

Core modules

Molecular Neuroscience; CNS Structure and Function; Genetics and Modelling of Neurodegenerative Disease; Mechanisms of Neurodegenerative Disease; Applied Neuroimaging; Neurophysiology and Psychiatry. A 20 week Research Project will be undertaken in the Summer Term.

Examples of optional modules

Option one: Literature Review and Critical Analysis of Science; Ethics and Public Awareness of Science.

Option two: Computational Neuroscience: Neurons and Neuronal Codes; Mathematical Modelling and Research Skills.

Teaching and assessment

Lectures, seminars, tutorials, laboratory demonstrations, computer practicals and student-led group work. Assessment is primarily by written assignments and coursework, although there are some written examinations and oral presentations. The research project is assessed by a thesis 
and presentation.

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Lead academic 2016. Dr Mark Fenwick. The course provides training in reproductive and developmental medicine for scientists, clinicians and others, for instance ethical advisers or lawyers looking to specialise. Read more

About the course

Lead academic 2016: Dr Mark Fenwick

The course provides training in reproductive and developmental medicine for scientists, clinicians and others, for instance ethical advisers or lawyers looking to specialise. It’s a good platform for a research career or a career in clinical laboratory training for IVF or embryology.

Through the taught modules you’ll develop a solid understanding of reproductive science relevant to clinical applications. We cover the breadth of processes from gonadal development and production of gametes through to pregnancy and parturition. Each module is taught by leading scientists and clinicians in that field.

You’ll also have the opportunity to learn about the ethical issues and international laws regulating reproductive medicine. Finally, you’ll undertake a research project to develop a depth of knowledge in a specialist topic.

Our study environment

You’ll be based in teaching hospitals that serve a population of over half a million people and refer a further two million. We also have close links with the University’s other health-related departments.

Our research funding comes from many sources including the NIHR, MRC, BBSRC, EPSRC, the Department of Health, EU, and prominent charities such as the Wellcome Trust, ARC, YCR, Cancer Research UK and BHF. Our partners and sponsors include Novartis, GlaxoSmithKline, Pfizer, Astra Zeneca and Eli Lilly.

You’ll also benefit from our collaboration with the Department of Biomedical Sciences.

How we teach

Classes are kept small (15–20 students) to make sure you get the best possible experience in laboratories and in clinical settings.

Our resources

We have a state-of-the-art biorepository and a £30m stem cell laboratory. The Sheffield Institute of Translational Neuroscience (SITraN) opened in November 2010. We also have microarray, genetics, histology, flow cytometry and high-throughput screening technology, and the latest equipment for bone and oncology research.

At our Clinical Research Facility, you’ll be able to conduct studies with adult patients and volunteers. The Sheffield Children’s Hospital houses a complementary facility for paediatric experimental medical research.

Hepatitis B policy

If your course involves a significant risk of exposure to human blood or other body fluids and tissue, you’ll need to complete a course of Hepatitis B immunisation before starting. We conform to national guidelines that are in place to protect patients, health care workers and students.

Core modules

Research Skills in Reproductive Medicine; Gonads to Gametes: fundamentals of reproduction; Fertilisation, Implantation and Embryology; Fetal Development, Pregnancy and Parturition; Reproductive Technology and Infertility; Law, Ethics and Policy in Reproductive Medicine.

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This course blends biochemical engineering with business management to prepare you for a career in biopharmaceuticals or industrial biotechnology. Read more

About the course

This course blends biochemical engineering with business management to prepare you for a career in biopharmaceuticals or industrial biotechnology. We also cover:

Industrial applications
Industry-relevant applications of engineering analysis
Working in teams
Independent working and learning

The bioscience industries have a huge role to play in the search for sustainable energy, food production and medicine. They need managers who understand the science, the technology and the business. Our MSc is designed to produce graduates who are up to the challenge.

Take advantage of our expertise

Our teaching is grounded in specialist research expertise. Our reputation for innovation secures funding from industry,
UK research councils, the government and the EU. Industry partners, large and small, benefit from our groundbreaking work addressing global challenges.

You’ll have access to top facilities, including modern social spaces, purpose-built labs, the Harpur Hill Research Station for large-scale work, extensive computing facilities and a modern applied science library. There are high-quality research facilities for sustainable energy processes, safety and risk engineering, carbon capture and utilisation, and biological processes and biomanufacturing.

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University of Sheffield School of Medicine
Distance from Sheffield: 0 miles
Lead academics 2016. Dr Janine Kirby and Professor Winston Hide. This course draws on expertise from three University faculties – Medicine, Dentistry and Health, Science and Social Sciences – and the Sheffield Genetics Diagnostic Service (Sheffield Children’s Hospital NHS Foundation Trust). Read more

About the course

Lead academics 2016: Dr Janine Kirby and Professor Winston Hide

This course draws on expertise from three University faculties – Medicine, Dentistry and Health, Science and Social Sciences – and the Sheffield Genetics Diagnostic Service (Sheffield Children’s Hospital NHS Foundation Trust). It’s aimed at professionals and students from health care and science backgrounds. The syllabus, as outlined by Health Education England (HEE), covers the scope and application of genomics in medicine and biomedical research as well as the ethical, social and legal issues relating to this field.

The course is taught by academics, scientists and clinicians. Techniques range from lectures and tutorials to laboratory workshops and online learning packages. You’ll get first-hand experience of hypothesis-driven research by carrying our your own project in Genomic Medicine.

Our study environment

You’ll be based in teaching hospitals that serve a population of over half a million people and refer a further two million. We also have close links with the University’s other health-related departments.

Our research funding comes from many sources including the NIHR, MRC, BBSRC, EPSRC, the Department of Health, EU, and prominent charities such as the Wellcome Trust, ARC, YCR, Cancer Research UK and BHF. Our partners and sponsors include Novartis, GlaxoSmithKline, Pfizer, Astra Zeneca and Eli Lilly.

You’ll also benefit from our collaboration with the Department of Biomedical Sciences.

How we teach

Classes are kept small (15–20 students) to make sure you get the best possible experience in laboratories and in clinical settings.

Our resources

We have a state-of-the-art biorepository and a £30m stem cell laboratory. The Sheffield Institute of Translational Neuroscience (SITraN) opened in November 2010. We also have microarray, genetics, histology, flow cytometry and high-throughput screening technology, and the latest equipment for bone and oncology research.

At our Clinical Research Facility, you’ll be able to conduct studies with adult patients and volunteers. The Sheffield Children’s Hospital houses a complementary facility for paediatric experimental medical research.

Hepatitis B policy

If your course involves a significant risk of exposure to human blood or other body fluids and tissue, you’ll need to complete a course of Hepatitis B immunisation before starting. We conform to national guidelines that are in place to protect patients, health care workers and students.

Core modules

An Introduction to Human Genetics and Genomics; Omics Techniques and Application to Genomic Medicine; Genomics of Common and Rare Inherited Diseases; Molecular Pathology of Cancer; Pharmacogenomics and Stratified Health Care; Application of Genomics in Infectious Disease; Bioinformatics and Interpretation in Genomics; Ethical, Legal and Social Issues in Applied Genomics.

Examples of optional modules

Option one: Research Project.

Option two: Literature Review; Workplace-Based Genomic Medicine; Professional and Research Skills.

Teaching and assessment

The MSc Genomic Medicine offers a wide range of delivery methods for providing theoretical knowledge, from lectures, laboratory sessions and tutorials to computer-based analysis workshops as well as the opportunity to gain input from internationally renowned experts in their fields. The inclusion of problem-based learning is embedded within the course and features in combinations of online and in person interpretive class formats. Tutorials, seminars and individual meetings with staff provide opportunities for discussion and feedback. Each of the departments delivering the programme fosters an environment that provides many opportunities for individual and group learning. However, the primary responsibility for learning lies with the student, who must be organised and self-motivated to make the most of the programme.

PG Diploma and PG Certificate options available as entry options both full time and part time

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