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Human tissue repair after injury and in disease and the development of effective treatments are the focus of all biomedical research. Read more
Human tissue repair after injury and in disease and the development of effective treatments are the focus of all biomedical research. This MSc programme, taught by leading scientists and clinicians, provides an integrated approach to human tissue repair focusing on inflammation, immunotherapy and transplantation science, and preparation for PhD study and a career in biomedicine.

Degree information

The MSc will provide knowledge of the fundamentals of inflammation and immune response in human health and disease, cellular and molecular mechanisms of human tissue repair, the development of therapies designed to repair and restore tissue function, and treatments including immunotherapy, transplantation, tissue constructs and medical devices. Students will obtain additional practical, analytic and transferable skills essential in biomedical research.

Students undertake modules to the value of 180 credits. This programme consists of six core modules (90 credits), two specialisation optional modules (30 credits) and a research project (60 credits).

Core modules
-Principles of Immunology
-Practical Research Skills
-Principles of Inflammation
-Research Methodologies for Human Tissue Repair
-Tissue Repair and Regeneration
-Practical Cell Culture Analysis
-Students choose one of the following specialisation modules depending on the route they wish to follow: Inflammation; Immunotherapy; Transplantation Science:
-Immunological Basis of Disease
-Inflammation and Disease
-Transplantation Science

Optional modules - students choose two optional modules from their chosen specialisation route below:
-Inflammation specialisation
-Biological Molecules as Therapies
-Ethics, Translation & Commercialisation
-Immunological Basis of Disease
-Stem Cell Therapy
-Transplantation
-Immunotherapy specialisation
-Cell & Gene Therapy: Molecular and Clinical Aspects
-Ethics, Translations & Commercialisation
-Immunological Basis of Disease
-Stem Cell Therapy
-Transplantation
-Transplantation Science specialisation
-Applied Biomaterials
-Ethics, Translation & Commercialisation
-Immunological Basis of Disease
-Stem Cell Therapy
-Tissue Engineering

Dissertation/report
Students undertake a research project culminating in a dissertation.

Teaching and learning
The programme is delivered through a combination of seminars, lectures, e-learning, laboratory work and tutorials. Assessment is through examination, presentations, essays, practical reports and dissertation.

Careers

The programme will prepare students for further academic study and to work at the highest levels within the biomedical sciences. It will also provide the foundation for careers in the public healthcare sector and the NHS, in industry and biopharma, government and research councils, biomedical charities and stakeholders, sports medicine, and scientific media and publishing houses.

Employability
Students will gain awareness of the commercial opportunities and diverse funding mechanisms for the development of new ideas, technologies and applications. Our learning methods will prepare students for careers in academic or industrial biomedical sciences, as well as equipping them with transferable skills in presentation, writing, organisation and team work.

Why study this degree at UCL?

UCL offers a world-class research and teaching environment in biomedical sciences.

The UCL Divisions of Medicine and Surgery & Interventional Science jointly offer this MSc within the new Institute of Immunity and Transplantation (IIT) based at the Royal Free Campus, to deliver the only programme with an integrated multidisciplinary approach to learning about human tissue repair, regeneration and therapy.

The programme aims to harness basic, biomedical and clinical expertise and research strengths assembled from across UCL institutes and divisions and UCL partner hospitals, and together with industrial colleagues will provide world-leading cohesive teaching and training in inflammation, immunology, tissue engineering, transplantation, drug discovery and in understanding and treating human disease.

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Human tissue repair after injury and in disease and the development of effective treatments is the focus of all biomedical research. Read more
Human tissue repair after injury and in disease and the development of effective treatments is the focus of all biomedical research. This MRes, taught by leading research scientists and clinicians, offers specialised training and provides a foundation year for a biomedical research career.

Degree information

The programme will provide knowledge of the fundamentals of inflammation and the immune response in human health and disease, cellular and molecular mechanisms of human tissue repair, and the development of therapies designed to repair and restore tissue function, treatments including immunotherapy, transplantation, tissue constructs and medical devices. Students will obtain additional practical, analytical and transferable skills essential in biomedical research.

Students undertake modules to the value of 180 credits. This programme consists of five core modules (75 credits), one specialisation optional module (15 credits) and a research project (90 credits).

Core modules
-Principles of Inflammation
-Principles of Immunology
-Tissue Repair and Regeneration
-Research Methodologies for Human Tissue Repair
-Practical Cell Culture Analysis
-Students choose one of the following specialisation modules depending on the route they wish to follow: Inflammation; Immunotherapy; Transplantation Science
-Immunological Basis of Disease
-Inflammation and Disease
-Transplantation Science

Dissertation/report
Students undertake a 6 month research project in a research laboratory.

Teaching and learning
The programme is delivered through a combination of seminars, lectures, e-learning, laboratory work, and practicals. Assessment is through examination, presentations, essays, practical reports and dissertation.

Careers

The programme will prepare students for further academic study and to work at the highest levels within the biomedical sciences. It will also provide the foundation and links for careers engaged in the public healthcare sector and the NHS, in industry and biopharma, government and research councils, biomedical charities and stakeholders, sports medicine, and scientific media and publishing houses.

Employability
Students will gain awareness of the commercial opportunities and diverse funding mechanisms for the development of new ideas, technologies and applications. Our learning methods will prepare students for careers in academic or industrial biomedical sciences, as well as equipping them with transferable skills in presentation, writing, organisation and team work.

Why study this degree at UCL?

UCL offers a world-class research and teaching environment in biomedical sciences.

The UCL Divisions of Medicine and Surgery & Interventional Science jointly offer an MRes within the new Institute of Immunity and Transplantation (IIT) based at the Royal Free Campus, to deliver the only programme with an integrated multidisciplinary approach to learning about human tissue repair, regeneration and therapy.

The programme aims to harness basic, biomedical and clinical expertise and research strengths assembled from across UCL institutes and divisions and UCL partner hospitals, and together with industrial colleagues will provide world-leading cohesive teaching and training in inflammation, immunology, tissue engineering, transplantation, drug discovery and in understanding and treating human disease.

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As well as giving a solid scientific understanding, the course also addresses commercial, ethical, legal and regulatory requirements, aided by extensive industrial contacts. Read more
As well as giving a solid scientific understanding, the course also addresses commercial, ethical, legal and regulatory requirements, aided by extensive industrial contacts.

Students who successfully complete the course will have acquired skills that are essential to the modern biomedical and healthcare industry, together with the expertise required to enter into management, product innovation, development and research.

Programme Structure

The MSc programmes in Biomedical Engineering are full-time, one academic year (12 consecutive months). The programmes consist of 4 core (compulsory) taught modules and two optional streams. Biomedical, Genetics and Tissue Engineering stream has 3 modules, all compulsory (see below). The second option, Biomedical, Biomechanics and Bioelectronics Engineering stream consists of 5 modules. Students choosing this option will be required to choose 60 credit worth of modules. See individual course pages.

The taught modules are delivered to students over two terms; Term 1 (September – December) and Term 2 (January – April) of each academic year. The taught modules are examined at the end of each term, and the students begin working on their dissertations on a part-time basis in term 2, then full-time during the months of May to September.

Core Modules
Biomechanics and Biomaterials (15 credit)
Design and Manufacture (15 credit)
Biomedical Engineering Principles (15 credit)
Innovation, Management and Research Methods (15 credit)

Additional Compulsory Programme Modules
Tissue Engineering and Regenerative Medicine (15 credit)
Genomic Technologies (15 credit)
Molecular Mechanisms of Human Disease (30 credit)
Dissertation (60 credit)

Module Descriptions

Biomechanics and Biomaterials

Main topics include: review of biomechanical principles; introduction to biomedical materials; stability of biomedical materials; biocompatibility; materials for adhesion and joining; applications of biomedical materials; implant design.

Biomedical Engineering Principles

Main topics include: bone structure and composition; the mechanical properties of bone, cartilage and tendon; the cardiovascular function and the cardiac cycle; body fluids and organs; organisation of the nervous system; sensory systems; biomechanical principles; biomedical materials; biofluid mechanics principles, the cardiovascular system, blood structure and composition, modelling of biofluid systems.

Design and Manufacture

Main topics include: design and materials optimisation; management and manufacturing strategies; improving clinical medical and industrial interaction; meeting product liability, ethical, legal and commercial needs.

Genomic Technologies

Main topics: General knowledge of genomic and proteomic technology; Microarrary technology; Transgenic technology. Drug discovery technology; Translational experiment-design and interpretation; Sequencing in microbiology research

Innovation and Management and Research Methods

Main topics include: company structure and organisation will be considered (with particular reference to the United Kingdom), together with the interfacing between hospital, clinical and healthcare sectors; review of existing practice: examination of existing equipment and devices; consideration of current procedures for integrating engineering expertise into the biomedical environment. Discussion of management techniques; design of biomedical equipment: statistical Procedures and Data Handling; matching of equipment to biomedical systems; quality assurance requirements in clinical technology; patient safety requirements and protection; sterilisation procedures and infection control; failure criteria and fail-safe design; maintainability and whole life provision; public and environmental considerations: environmental and hygenic topics in the provision of hospital services; legal and ethical requirements; product development: innovation in the company environment, innovation in the clinical environment; cash flow and capital provision; testing and validation; product development criteria and strategies.

Molecular Mechanisms of Human Disease

Main topics: The module will focus on the following subject material with emphasis on how these processes are altered in a variety of human diseases. Where appropriate, therapeutic intervention in these processes will be highlighted. Signalling pathways resulting from activation of membrane, intracellular or nuclear receptors will be discussed. Examples include: Mammalian iron, copper and zinc metabolism, G-Protein coupled receptor signalling, Wnt signalling, JAK/STAT signalling and cytokine signalling, Steroid signalling

Tissue Engineering and Regenerative Medicine

Main topics: Fundamentals of tissue structure, function and pathology. Tissue regeneration. Tissue engineering substitutes. Cells, cell culture, stem cells, cell and gene therapy. Extracellular matrix, structure, scaffolds. Cell signalling, growth factors, cytokines, neurotransmitters, receptors and other signalling molecules. Bioreactors, ex-vivo and in-vivo. Engineering host tissue responses.

Dissertation

The choice of Dissertation topic will be made by the student in consultation with academic staff and (where applicable) with the sponsoring company. The topic agreed is also subject to approval by the Module Co-ordinator. The primary requirement for the topic is that it must have sufficient scope to allow the student to demonstrate his or her ability to conduct a well-founded programme of investigation and research. It is not only the outcome that is important since the topic chosen must be such that the whole process of investigation can be clearly demonstrated throughout the project. In industrially sponsored projects the potential differences between industrial and academic expectations must be clearly understood.

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This unique research-led masters course provides laboratory training to future scientists in drug screening and gene discovery using the latest automated genomics techniques. Read more

About the course

This unique research-led masters course provides laboratory training to future scientists in drug screening and gene discovery using the latest automated genomics techniques. Students will also gain training in the pharmaceutical industry practices through direct contact with industry leaders from a wide range of companies.

Your research project will be undertaken in conjunction with the internationally renowned Sheffield RNAi Screening Facility, providing you with world-class training and professional skills in the use of pharmaco-genomics. You’ll also benefit from our modern research laboratories and equipment, including purpose-built facilities for drug screening, laboratory automation, cellular assays, imaging and processing.

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

Practical Approaches to Small Molecule and Functional Genomic Screening; 3D Tissue Culture and Genome Editing; Genomic Approaches to Drug Discovery; The Biotech and Pharmaceutical Industry; Modelling Human Disease

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- https://www.kent.ac.uk/locations/medway/. Start. At any time but preferably in September. Our research programme in Pharmacy gives you the integrated, broad-based research training needed to exploit current advances in pharmaceutical and biological sciences and pharmacy practice. Read more

This course will be held at the Medway Campus

- https://www.kent.ac.uk/locations/medway/

Start: At any time but preferably in September

Our research programme in Pharmacy gives you the integrated, broad-based research training needed to exploit current advances in pharmaceutical and biological sciences and pharmacy practice.

Within the school we have a number of home, EU and international postgraduate students who are undertaking doctoral research degrees. Graduates who obtain their PhD from Kent or Greenwich are highly sought after by prospective employers, both within the UK and overseas. Destinations for doctoral graduates include university academic departments, research institutes and leading pharmaceutical and biotechnological companies.

Visit the website https://www.kent.ac.uk/courses/postgraduate/171/pharmacy

About Medway School of Pharmacy

Medway School of Pharmacy is one of the few regional schools of pharmacy in the UK, a collaboration between the University of Kent and the University of Greenwich.

The impetus for the formation of the Medway School of Pharmacy came from the local community, who recognised the shortage of qualified pharmacists in all branches of the pharmacy profession in Kent.

The School is now recognised as an established school with accreditation from the General Pharmaceutical Council (GPhC) and the Health and Care Professions Council (HCPC). Graduates are employed in health disciplines in Kent and the south-east and more broadly across the UK.

Study support

- Postgraduate resources

Postgraduate students have access to all the facilities at the Medway School of Pharmacy, including clinical skills labs and a ‘simulation man’. As the School of Pharmacy is a joint venture between the two universities, students have access to facilities at Kent’s Medway and Canterbury campuses, and the University of Greenwich.

- Dynamic publishing culture

Medway School of Pharmacy has a research culture and as such postgraduate students publish regularly and widely in journals, conference proceedings and books. Among others, they have recently contributed to: International Journal of Pharmacy Practice; Nephron Physiology; Acta Physiologica; Purinergic Signalling; and European Journal of Pharmacology.

- Researcher Development Programme

Kent's Graduate School co-ordinates the Researcher Development Programme for research students, which includes workshops focused on research, specialist and transferable skills. The programme is mapped to the national Researcher Development Framework and covers a diverse range of topics, including subjectspecific research skills, research management, personal effectiveness, communication skills, networking and teamworking, and career management skills

Research areas

The Medway School of Pharmacy houses strong and vibrant research groups that span a range of pharmacy-related areas. Staff have a wealth of research experience, and UK and international links with both industry and academic institutions.

- Chemistry and drug delivery

This group has laboratories with dedicated state-ofthe art drug delivery, nanotechnology, spectroscopy, chromatography and organic synthesis facilities. It brings together researchers in medicinal chemistry and drug design, nanotechnology and materials science, drug delivery and pharmaceutics encouraging a multidisciplinary approach to research. Research covers synthesis and biological evaluation of potential anti-cancer agents, structurebased drug design, QSAR predication of ADMET properties, controlled release, particle engineering, powder technology, pharmaceutical technology, and novel drug delivery systems, with a focus on respiratory drug delivery.

- Biological sciences

This group is housed in recently refurbished laboratories with dedicated state-of-the-art molecular biological, electrophysiological, tissue culture and microscopy facilities. The research is divided into four main themes; infectious diseases and allergy; neuroscience; renal and cardiovascular physiology; and pharmacology. Examples of current work include: investigation of the use of non-pathogenic virus ‘pseudotypes’ to study pathogenic RNA, study of the properties of neuronal potassium channels and their modulation and the development of new therapies for patients that have developed acute kidney injury in collaboration with a major pharmaceutical company.

- Pharmacy practice

This group conducts research in two areas: public health and medicines optimisation, with a particular focus on cardiovascular diseases and mental health. Work in public health includes studies in physical exercise, alcohol, cardiovascular screening and spirometry testing, plus pharmacovigilance. Studies in medicines optimisation include work in dementia, bipolar disorder and stroke, with an emphasis on the patient perspective.

Careers

Graduates who obtain their PhD from Kent or Greenwich are highly sought after by prospective employers, both within the UK and overseas. Destinations for doctoral graduates include university academic departments, research institutes and leading pharmaceutical and biotechnological companies.

Find out how to apply here - https://www.kent.ac.uk/courses/postgraduate/apply/

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This innovative degree offers a fascinating opportunity to study modern and topical research areas in Cell Biomedicine. You will gain the essential skills required to prepare for your career in either biomedical research, a clinical setting or within the health industry. Read more

Summary

This innovative degree offers a fascinating opportunity to study modern and topical research areas in Cell Biomedicine. You will gain the essential skills required to prepare for your career in either biomedical research, a clinical setting or within the health industry.

This postgraduate degree will provide you with advanced research training in medical aspects of cell biology and pathology and you will conduct your own lab based research project. With a focus on research methods, you will take you research methods to the next level in producing your own research design, understanding ethics in research projects and best practice in handling statistical data-sets. The programme includes a variety of subject-specific lectures, seminars, tutorials and practical work that will give keep you up-to-date with the current advances in the field. You will learn the theoretical and technological aspects of cellular biomedicine and their practical applications within industry.

You will be taught by enthusiastic, research active experts in the field who conduct research in a diverse range of topics that you can choose to study such as cellular and molecular mechanisms of cancer, microbial resistance to antibiotics, immune mechanisms of disease, stem cell research and molecular modelling in cell biology.

You will conduct your research project in our state-of-the-art laboratories equipped with microscopy analysers, autoradiography, flow cytometry, high sensitivity HPLC and LC-MS, and neural stem cell and tissue culture facilities.

You will automatically be a part of our Health Sciences Research Centre, a community of leading experts who are currently investigating a range of topical issues. You will participate in engaging discussions within research seminars on the latest developments within neuroscience and the health sciences.

Content

In this postgraduate programme, you will be trained in medical aspects of cell biology and pathology with a focus on the lab based research project. The programme has a strong focus on research methods and will provide you with necessary skills in research design, ethics and statistical methods.

You will learn the most recent advances in cellular biomedicine by being part of engaging subject-specific lectures, seminars, tutorials and conducting your own research. You will study the theoretical and technological and their practical applications in cellular biomedicine.

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MPhil - full time. minimum 12 months, part time. minimum 24 months. PhD - full time. minimum 36 months, part time. minimum 72 months. Read more

Course Description

MPhil - full time: minimum 12 months, part time: minimum 24 months
PhD - full time: minimum 36 months, part time: minimum 72 months

MPhil and PhD supervision covers a number of research topics supported by research active academic staff. Our range of research areas relate to animal health and welfare, environmental impact of livestock systems, and safety and quality of livestock products.

The school of Agriculture, Food and Rural Development has an internationally recognised centre of excellence in Animal Sciences, drawing on fundamental research and applying it to areas of societal, industrial and policy importance.

Our research primarily involves:
•farm livestock, domesticated animal and wildlife applied research
•integrated livestock system development and evaluation
•animal behaviour, health and welfare
•survival, health and efficiency of nutrient utilisation

Opportunities are available for postgraduate research in the following areas:

Animal health and welfare:
Work ranges from understanding animal behaviour and behavioural problems, through development of practical on-farm monitoring and assessment methods to mechanistic studies of health and disease at the molecular level.

Environmental impact of livestock systems:
Our work examines the consequences of modifications in nutrition and husbandry and alterations in breeding strategies to improve the efficiency of resource use.

Safety and quality of livestock products, including milk, meat and eggs:
Our 'field to fork' expertise allows us to study the relationships between husbandry systems and nutritional inputs of animals and the composition of their products, with further implications for human diet and health.


Delivery

We offer a number of different routes to a research degree qualification, including full-time and part-time supervised research projects. We attract postgraduates via non-traditional routes, including mature students and part-time postgraduates undertaking study as part of their continuing professional development. Off-campus (split) research is also offered, which enables you to conduct trials in conditions appropriate to your research programme.

Facilities:

Farms:
Our multi-purpose farms provide demonstration facilities for teaching purposes, land-based research facilities (especially in the area of organic production) and they are viable farming businesses.

Cockle Park Farm is a 262ha mixed farm facility that includes the Palace Leas Plots hay meadow experiment and an anaerobic digestion plant that will generate heat, electricity and digestate - an organic fertiliser - from pig and cattle manure.

Nafferton Farm is a 300ha farm with two main farm units covering conventional and organic farming systems. The two systems are primarily focussed upon dairying and arable cropping. Both also operate beef production enterprises as a by-product of their dairy enterprises, although the organic system is unique in maintaining a small-scale potato and vegetable production enterprise.

Laboratories:
Our modern laboratories provide important teaching and research environments and are equipped with analytical equipment such as HPLCs, GCs, CNS analyser, centrifuges, spectrophotometers and molecular biology equipment. Our specialist research facilities include:
•tissue culture laboratory
•plant growth rooms
•class II laboratory for safe handling of human biological samples
•taste panel facilities and test kitchen
•thin section facility for soils analysis

We operate closely with other schools, institutes and the University's Central Scientific Facilities for access to more specialist analytical services. For work with human subjects we use a purpose built Clinical Research Facility which is situated in the Royal Victoria Infirmary teaching hospital and is managed jointly by us and the Newcastle upon Tyne Hospitals NHS Foundation Trust.

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This programme is the only one of its kind in the UK. It is designed for high-calibre, veterinary graduates from clinical backgrounds who want to explore and benefit from veterinary research, perhaps with a view to pursuing a PhD or a career in research. Read more

Research profile

This programme is the only one of its kind in the UK. It is designed for high-calibre, veterinary graduates from clinical backgrounds who want to explore and benefit from veterinary research, perhaps with a view to pursuing a PhD or a career in research.

The programme offers you the opportunity to undertake a research project in a laboratory or department relevant to your speciality. The choice of research projects carried out is wide, and ranges from bench research to clinical research.

Admission to this programme is subject to identifying a suitable research project and appropriate supervisor before starting the degree. Examples of projects completed in session 2015-2016 were:

1. Interactions of natural killer cells and dendritic cells in bovine tuberculosis immunity.
2. Defining correlates of protective immunity against Mycobacterium bovis.

Subjects include:

epidemiology
gene delivery
genetics
immunology
microbiology
neuroscience
parasitology
pathology
welfare and zoo animals.

The programme begins with a month of teaching to give you an overview of the whole range of techniques used in medical research. The first two weeks comprise lectures on subjects from stem cell biology to ethics and clinical trials and statistics training. This will follow with two weeks of practical workshops in cell biology and molecular medicine and learning practical techniques, including basic tissue culture, how to do PCRs and run Western Blots. After the first month of teaching you will move to a laboratory most relevant to your own speciality.

Career opportunities

Most MVetSci graduates go on to study for a PhD. Those who choose to return to clinical practice go back with a broader experience of research than is afforded by the undergraduate clinical veterinary curriculum.

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In the last 10-15 years the study of plant sciences has been revolutionised by the development of new tools and technologies which have allowed unprecedented progress in the study of plant biology - knowledge which is being applied to develop sustainable solutions to some of the major challenges of the 21st century. Read more
In the last 10-15 years the study of plant sciences has been revolutionised by the development of new tools and technologies which have allowed unprecedented progress in the study of plant biology - knowledge which is being applied to develop sustainable solutions to some of the major challenges of the 21st century.

This programme provides training in modern molecular aspects of plant science. Teaching is delivered by academics from the University’s Centre for Plant Sciences (CPS) and is often related to their areas of expertise and current research projects.

You’ll benefit from the research of international experts in DNA recombination and repair mechanisms and explore the wide range of approaches used in bio-imaging alongside the range of modern techniques and methodologies that underpin contemporary biomolecular sciences. You’ll explore the key topic areas of molecular biology; structural biology; cell imaging and flow cytometry; high throughput techniques; and transgenic organisms.

Our Facilities

You’ll study in a stimulating environment which houses cutting-edge facilities. The CPS laboratories feature a state-of-the-art plant growth unit, including tissue culture suites with culture rooms, growth rooms and cabinets alongside glass-houses to meet a range of growth requirements.

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This course introduces you to the principles of experimental pathology applied to oral disease. It is provides a grounding in experimental method for dental graduates who plan to follow either a career in academic dentistry or one of the clinical specialities. Read more
This course introduces you to the principles of experimental pathology applied to oral disease. It is provides a grounding in experimental method for dental graduates who plan to follow either a career in academic dentistry or one of the clinical specialities. It also provides an opportunity for science graduates to learn about oral disease, in preparation for a career in dental research.

We offer you a fundamental training in the principles of laboratory research methods and the range of techniques used to study the behaviour of oral tissues in health and disease.

Programme outline
Your programme will be modular, focused on acquiring laboratory skills and knowledge. The taught modules provide the basic understanding to help with the research component. There is a structured course of seminars with associated practical work, dealing with the structure and behaviour of cells and tissues in health and disease. This core begins with fundamental and general concepts of cell biology and continues with the application of these concepts to a consideration of oral and dental disease. Related disciplines such as oral microbiology and immunology are also covered.

Throughout the programme, emphasis is placed on the evidence upon which the concepts are based and the way in which such evidence is obtained by observation and experiment. You are actively encouraged to take part in the seminars.

Running in parallel with the core programme are several related series of seminars dealing with research methods, statistics and techniques of fundamental importance to experimental pathology such as tissue culture, molecular biological techniques, immunocytochemistry, light and electron microscopy. You will undertake a laboratory-based research project in the final module of the programme, exploring any aspect of oral disease.

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The Masters in Medical Sciences programme is the only one of its kind in the UK and is proven to give graduates the competitive edge in the job market. Read more
The Masters in Medical Sciences programme is the only one of its kind in the UK and is proven to give graduates the competitive edge in the job market. It is designed for high-calibre medicine graduates who want to explore and benefit from medical research, perhaps with a view to pursuing a PhD or a career
 in research.

We offer you the opportunity to undertake a research project in a laboratory or department relevant to your speciality. The choice of research projects carried out is wide and ranges from bench research to clinical research. Examples of completed projects are:

1. Therapeutic Hypothermia Decreases Intracranial Pressure in Severe Traumatic Brain Injury
2. Renal Function in the 11β-Hydroxysteroid Dehydrogenase Type 1 Null Mouse
3. Immune cell populations in the mouse lung during RSV infection
4. Salt Appetite in Stable Heart Disease and Healthy Volunteers

You will need to secure a supervisor and project before starting the degree.

Programme Structure

The programme begins with a month of teaching, providing you with an overview of the whole range of techniques used in medical research. In the first two weeks you will attend lectures on subjects ranging from stem cell biology to ethics and clinical trials. You will also receive statistics training and practical workshops in cell biology and molecular medicine. You will be taught practical techniques, including basic tissue culture, how to do PCRs and run Western Blots.

Around 20 per cent of the course will consist of taught classes and seminars. The rest is spent in your host department.

To consider your research interests and opportunities we advise you to visit Edinburgh’s Clinical Academic Training Centre (ECAT) or speak to the Programme Director.

Career opportunities

Around a quarter of our students continue on to a PhD. Those who choose to return to clinical practice go back with a broader experience of research than is afforded by the undergraduate clinical medicine curriculum.

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Our Masters of Research (MRes) in Translational Medicine provides high-quality research and training skills for students who want to use state-of-the-art biotechnologies to rapidly translate disease research into improved clinical healthcare. Read more
Our Masters of Research (MRes) in Translational Medicine provides high-quality research and training skills for students who want to use state-of-the-art biotechnologies to rapidly translate disease research into improved clinical healthcare.

With advances in technology, graduates are now faced with heightened expectations to conduct effective bioscience research.
Employers demand skillsets comprising biological, medical, physical and computational characteristics and this Masters is designed to provide this breadth of training.

The core aim is to train the next generation of scientists able to 'fast-track' biological and scientific data into advanced therapies and diagnostics tools.

Our understanding of the molecular basis of disease and drug mechanisms has improved dramatically in recent years, yet there is a distinct shortage of individuals able to apply this knowledge into effective clinical benefit.

Our MRes in Translational Medicine (Interdisciplinary Molecular Medicine) provides intense training in 'omics' skills and techniques such as genetics, genomics, transcriptomics, proteomics and metabolomics.

The training in metabolomic techniques is novel for a UK course, and teaching on the integration of different omic platforms and data in a systems medicine strategy is unique.

With its extended 35-week research project and broad training in biotechnology for medical healthcare, this MRes provides an excellent platform to progress into PhD research, or for a career in academia or the pharmaceutical or biotechnology industries, or as a clinical academic.

The MRes has substantial interdisciplinary focus; training comprises four taught modules before you undertake an extended 35-week research project within The University of Manchester, Waters or one of the Greater Manchester teaching hospitals.

A wide choice of projects are available (view the list of example projects), allowing individuals to focus on areas of interest such as the use of gene expression profiling, proteomics, metabolomics, stem cell research, tissue culture or pharmacogenetics in the biology of cancer, cardiovascular disease, infectious diseases, stroke or diabetes.

The MRes lasts for one year full-time, so it provides the ideal opportunity to experience the challenges of multidisciplinary research first-hand before committing to further training.

Over 85% of our graduates secure further research (PhD), pharmaceutical or biotechnology industry, or medical training posts upon completion.

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First established in the early 1950s, the MMet course has produced over 700 graduates, with many now working in senior positions within metallurgical companies across the globe. Read more

About the course

First established in the early 1950s, the MMet course has produced over 700 graduates, with many now working in senior positions within metallurgical companies across the globe.

You’ll receive an in-depth and up-to-date understanding of current developments in metallurgy and metallurgical engineering. You’ll learn the fundamentals of thermodynamics, structure and mechanical behaviour. As well as the option to study the more advanced courses on engineering alloys, processing, modelling and performance in service.

Fully accredited by the IoM3 graduates will have the underpinning knowledge for later professional registration as a Chartered Engineer (CEng).

A welcoming department

A friendly, forward-thinking community, our students and staff are on hand to welcome you to the department and ensure you settle into student life.

Your project supervisor will support you throughout your course. Plus you’ll have access to our extensive network of alumni, offering industry insight and valuable career advice to support your own career pathway.

Your career

Prospective employers recognise the value of our courses, and know that our students can apply their knowledge to industry. Our graduates work for organisations including Airbus, Rolls-Royce, the National Nuclear Laboratory and Saint-Gobain. Roles include materials development engineer, reactor engineer and research manager. They also work in academia in the UK and abroad.

90 per cent of our graduates are employed or in further study 6 months after graduating, with an average starting salary of £27,000, the highest being £50,000.

Equipment and facilities

We have invested in extensive, world-class equipment and facilities to provide a stimulating learning environment. Our laboratories are equipped to a high standard, with specialist facilities for each area of research.

Materials processing

Tools and production facilities for materials processing, fabrication and testing, including wet chemical processing for ceramics and polymers, rapid solidification and water atomisation for nanoscale metallic materials, and extensive facilities for deposition of functional and structural coatings.

Radioactive nuclear waste and disposal

Our £3million advanced nuclear materials research facility provides a high-quality environment for research on radioactive waste and disposal. Our unique thermomechanical compression and arbitrary strain path equipment is used for simulation of hot deformation.

Characterisation

You’ll have access to newly refurbished array of microscopy and analysis equipment, x-ray facilities, and surface analysis techniques covering state-of-the-art XPS and SIMS. There are also laboratories for cell and tissue culture, and facilities for measuring electrical, magnetic and mechanical properties.

The Kroto Research Institute and the Nanoscience and Technology Centre enhance our capabilities in materials fabrication and characterisation, and we have a computer cluster for modelling from the atomistic through nano and mesoscopic to the macroscopic.

Stimulating learning environment

An interdisciplinary research-led department; our network of world leading academics at the cutting edge of their research inform our courses providing a stimulating, dynamic environment in which to study.

Teaching and assessment

Working alongside students and staff from across the globe, you’ll tackle real-world projects, and attend lectures, seminars and laboratory classes delivered by academic and industry experts.

You’ll be assessed by formal examinations, coursework assignments and a dissertation.

Core modules

Metals; Metallurgical Processing; Science of Materials; Materials Processing and Characterisation; Materials Selection, Properties and Applications; Technical Skills Development; Heat and Materials with Application; Advanced Materials Manufacturing; Deformation, Fracture and Fatigue; Research Project in an area of your choice.

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Solid State Chemistry covers the latest advances in advanced inorganic materials with applications ranging from energy storage systems, electronic materials and sensors to the more traditional, but increasingly hi-tech materials and industries that include glass, cement and refractories. Read more

About the course

Solid State Chemistry covers the latest advances in advanced inorganic materials with applications ranging from energy storage systems, electronic materials and sensors to the more traditional, but increasingly hi-tech materials and industries that include glass, cement and refractories.

This course is specifically designed to give students a broad overview of the synthesis, structure and properties of inorganic materials together with in-depth coverage of the main groups of ceramic materials and allows you further specialisation when it comes to choosing your personal research project.

A welcoming department

A friendly, forward-thinking community, our students and staff are on hand to welcome you to the department and ensure you settle into student life.

Your project supervisor will support you throughout your course. Plus you’ll have access to our extensive network of alumni, offering industry insight and valuable career advice to support your own career pathway.

Your career

Prospective employers recognise the value of our courses, and know that our students can apply their knowledge to industry. Our graduates work for organisations including Airbus, Rolls-Royce, the National Nuclear Laboratory and Saint-Gobain. Roles include materials development engineer, reactor engineer and research manager. They also work in academia in the UK and abroad.

90 per cent of our graduates are employed or in further study 6 months after graduating, with an average starting salary of £27,000, the highest being £50,000.

Equipment and facilities

We have invested in extensive, world-class equipment and facilities to provide a stimulating learning environment. Our laboratories are equipped to a high standard, with specialist facilities for each area of research.

Materials processing

Tools and production facilities for materials processing, fabrication and testing, including wet chemical processing for ceramics and polymers, rapid solidification and water atomisation for nanoscale metallic materials, and extensive facilities for deposition of functional and structural coatings.

Radioactive nuclear waste and disposal

Our £3million advanced nuclear materials research facility provides a high-quality environment for research on radioactive waste and disposal. Our unique thermomechanical compression and arbitrary strain path equipment is used for simulation of hot deformation.

Characterisation

You’ll have access to newly refurbished array of microscopy and analysis equipment, x-ray facilities, and surface analysis techniques covering state-of-the-art XPS and SIMS. There are also laboratories for cell and tissue culture, and facilities for measuring electrical, magnetic and mechanical properties.

The Kroto Research Institute and the Nanoscience and Technology Centre enhance our capabilities in materials fabrication and characterisation, and we have a computer cluster for modelling from the atomistic through nano and mesoscopic to the macroscopic.

Stimulating learning environment

An interdisciplinary research-led department; our network of world leading academics at the cutting edge of their research inform our courses providing a stimulating, dynamic environment in which to study.

Teaching and assessment

Working alongside students and staff from across the globe, you’ll tackle real-world projects, and attend lectures, seminars and laboratory classes delivered by academic and industry experts.

You’ll be assessed by formal examinations, coursework assignments and a dissertation.

Core modules

Solid State Chemistry; Functional and Structural Ceramics; Glasses and Cements; Science of Materials; Materials Processing and Characterisation; Materials Selection, Properties and Applications; Technical Skills Development; Heat and Materials; Research project in an area of your choice.

Read less
A fantastic time to be a specialist in aerospace materials, Sheffield is in the heartland of the UK aerospace industry, meaning many international aerospace companies look to the Department to discover ways to improve both materials and processes for use in their products. Read more

About the course

A fantastic time to be a specialist in aerospace materials, Sheffield is in the heartland of the UK aerospace industry, meaning many international aerospace companies look to the Department to discover ways to improve both materials and processes for use in their products.

You’ll develop knowledge of the manufacturing, processing and properties of the metals and composite materials used in airframes and aeroengines. You’ll also be trained in the fundamentals of thermodynamics, structure and mechanical behaviour.

A welcoming department

A friendly, forward-thinking community, our students and staff are on hand to welcome you to the department and ensure you settle into student life.

Your project supervisor will support you throughout your course. Plus you’ll have access to our extensive network of alumni, offering industry insight and valuable career advice to support your own career pathway.

Your career

Prospective employers recognise the value of our courses, and know that our students can apply their knowledge to industry. Our graduates work for organisations including Airbus, Rolls-Royce, the National Nuclear Laboratory and Saint-Gobain. Roles include materials development engineer, reactor engineer and research manager. They also work in academia in the UK and abroad.

90 per cent of our graduates are employed or in further study 6 months after graduating, with an average starting salary of £27,000, the highest being £50,000.

Equipment and facilities

We have invested in extensive, world-class equipment and facilities to provide a stimulating learning environment. Our laboratories are equipped to a high standard, with specialist facilities for each area of research.

Materials processing

Tools and production facilities for materials processing, fabrication and testing, including wet chemical processing for ceramics and polymers, rapid solidification and water atomisation for nanoscale metallic materials, and extensive facilities for deposition of functional and structural coatings.

Radioactive nuclear waste and disposal

Our £3million advanced nuclear materials research facility provides a high-quality environment for research on radioactive waste and disposal. Our unique thermomechanical compression and arbitrary strain path equipment is used for simulation of hot deformation.

Characterisation

You’ll have access to newly refurbished array of microscopy and analysis equipment, x-ray facilities, and surface analysis techniques covering state-of-the-art XPS and SIMS. There are also laboratories for cell and tissue culture, and facilities for measuring electrical, magnetic and mechanical properties.

The Kroto Research Institute and the Nanoscience and Technology Centre enhance our capabilities in materials fabrication and characterisation, and we have a computer cluster for modelling from the atomistic through nano and mesoscopic to the macroscopic.

Stimulating learning environment

An interdisciplinary research-led department; our network of world leading academics at the cutting edge of their research inform our courses providing a stimulating, dynamic environment in which to study.

Teaching and assessment

Working alongside students and staff from across the globe, you’ll tackle real-world projects, and attend lectures, seminars and laboratory classes delivered by academic and industry experts.

You’ll be assessed by formal examinations, coursework assignments and a dissertation.

Core modules

Aerospace Metals; Design and Manufacture of Composites; Science of Materials; Materials Processing and Characterisation; Materials Selection, Properties and Applications; Technical Skills Development; Heat and Materials with Application; Advanced Materials Manufacturing; Deformation, Fracture and Fatigue; Research project in an area of your choice.

Read less

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