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This Masters in Cancer Sciences will prepare you for a career in cancer science, whether you aim to pursue a PhD or further medical studies, or seek a career in the health services sector, in the life sciences, biotechnology or pharmaceutical industries. Read more
This Masters in Cancer Sciences will prepare you for a career in cancer science, whether you aim to pursue a PhD or further medical studies, or seek a career in the health services sector, in the life sciences, biotechnology or pharmaceutical industries. Our programme takes a “bench to bedside” approach, enabling graduates to work within a multidisciplinary environment of world-leading scientists and cancer-specialists to address the latest challenges in cancer research.

Why this programme

-University of Glasgow is rated in the UK top five and best in Scotland for Cancer Studies. You will be taught by a multidisciplinary team of world leading cancer scientists and clinicians within the Cancer Research UK Glasgow Centre.
-This MSc in Cancer Science programme is unique in the UK as it delivers integrated teaching in molecular biology, pathology and clinical service.
-The Cancer Research UK Glasgow Centre brings together scientists and clinicians from research centres, universities and hospitals around Glasgow to deliver the very best in cancer research, drug discovery and patient care. The Centre’s world leading teams have made major advances in the understanding and treatment of many cancers. For more information, please visit: http://www.wecancentre.org/
-In the first semester, each week is focused around one of the new Hallmarks of Cancer, with the focus on the molecular/cellular biology of this hallmark. A tutorial session will enable you to discuss and integrate your learning from the week. This will enable you to understand how research into the fundamental principles of cancer cell biology can translate to advances in cancer treatment.
-The aim of this MSc in Cancer Science is to train cancer researchers who can break down the barriers that currently prevent discoveries at the bench from being translated into treatments at the bedside. By understanding the science, methodology and terminology used by scientists and clinicians from different disciplines, you will learn to communicate effectively in a multidisciplinary environment, critically evaluate a wide range of scientific data and research strategies and learn how to make a significant contribution to cancer research.

Semester 1
-Hallmarks of Cancer

Semester 2
-Drug Discovery
-Drug Development and Clinical trials
-Viruses and Cancer
-Diagnostic technologies and devices
-Technology transfer and commercialisation of bioscience research
-Current trends and challenges in biomedical research and health
-Frontiers in Cancer Sciences
-Omic technologies for the biomedical sciences: from genomics to metabolomics
-Designing a research project: biomedical research methodology

Semester 3
-Bioscience Research Project

Programme aims

We will lead you through the molecular and cellular hallmarks of cancer biology, including genetic instability, cancer growth and invasion, tumour-stroma interactions, immune response to cancer, cancer metabolism, and cancer stem cells, and explain how this knowledge is being used in our fight against cancer.

You will experience how to plan and write a project proposal and report, and how to research, evaluate, and critically discuss scientific data and present these to a wider audience. A 14-week long research project will finally allow you to gain in-depth knowledge in a cancer-related area of your interest. This programme will therefore give you an excellent foundation for your future career in cancer science.

We will lead you through the molecular and cellular hallmarks of cancer biology and metastasis formation, including genetic instability, cancer growth and invasion, tumour-stroma interactions, immune response to cancer, cancer metabolism, and cancer stem cells, and explain how this knowledge is being used in our fight against cancer in our clinics by providing a personalised cancer treatment. The programme will allow you to specialize either on the molecular aspects of cancer science, including genome wide data analysis for the characterization and classification of cancers, or learn about cutting edge translational cancer research, and introduce you to drug discovery pipelines and clinical trials.

You will experience how to plan and write a project proposal and report, and how to research, evaluate, and critically discuss scientific data and present these to a wider audience. A 14-week long research project will finally allow you to gain in-depth knowledge in a cancer-related area of your interest. This programme will therefore give you an excellent foundation for your future career in cancer science.

Career prospects

The knowledge and transferable skills developed in this programme will be suitable for those contemplating a PhD or further medical studies; those wishing to work in the health services sector; and those interested in working in the life sciences, biotechnology or pharmaceutical industries, including contract research organisations (CROs). This programme is designed for students with undergraduate degrees in the life sciences, scientists working in the pharmaceutical and biotechnology industries, and clinicians and other healthcare professionals.

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The course will provide a robust and wide-reaching education in fundamental and applied cancer biology, and focused training in laboratory research and associated methodology. Read more
The course will provide a robust and wide-reaching education in fundamental and applied cancer biology, and focused training in laboratory research and associated methodology.

Why study Cancer Biology at Dundee?

The MRes Cancer Biology is a research-centred taught Masters programme providing a focused training in molecular cancer research. It covers both the fundamental and translational science of carcinogenesis, cancer biology, diagnosis and therapy.

The programme delivers outstanding research-focused teaching from internationally-renowned scientists and clinicians.

Dundee University is internationally renowned for the quality of its cancer research and has over 50 cancer research groups: current funding for cancer research is about £40 million from research councils and charities. In 2009 the university became the first Scottish university to be awarded Cancer Centre status by the CRUK.

What's so good about studying Cancer Biology at Dundee?

The MRes Cancer Biology has been developed from the innovative collaboration between the College of Medicine, Dentistry and Nursing and the School of Life Sciences, and it complements the establishment of the Cancer Research UK (CRUK) Centre here in Dundee.

The Dundee Cancer Centre aims to enhance cancer research and apply discoveries to improve patient care. Key to this is training the next generation of cancer researchers.

Areas of particular strength at the University of Dundee are in surgical oncology for breast and colon cancer, radiation biology and clinical oncology, skin cancer and pharmacogenomics. Areas of strength in basic cancer biology are DNA replication, chromosome biology and the cell cycle, cell signalling and targets for drug discovery.

Teaching and Assessment

This course is taught by staff based in the College of Medicine, Dentistry and Nursing and the School of Life Sciences.

The MRes will be taught full-time over one year (September to August).

How you will be taught

The course will be taught through a combination of face-to-face lectures, tutorials, discussion group work and journal clubs, self-directed study and supervised laboratory research.

What you will study

The MRes degree course is taught full-time over three semesters.

The first semester provides in-depth teaching and directed study on the molecular biology of cancer, and covers:

Basic cell and molecular biology, and introduction to cancer biology
Cell proliferation, cell signalling and cancer
Cancer cell biology
Carcinogenesis, cancer treatment and prevention
Specific training in research methodology and critical analysis

Students will also be required to take part in a journal club to further develop their critical review skills.

In semesters two and three students will be individually guided to focus on a specific cancer research topic which will be the subject of a literature review and associated laboratory research project. The research project is based in laboratories with state-of-the-art facilities, and under the leadership of world-class researchers.

How you will be assessed

Exams on the taught element of the programme will be held at the end of semester one. Essays and assignments will also contribute to the final mark, and the dissertation will be assessed through the production of a thesis and a viva exam.

Places on the course are limited, so early applications are strongly encouraged.
Apply early to avoid disappointment.
Follow us on Twitter to keep up with news from the MRes Cancer Biology @Mrescancerbiol

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The Cancer MSc reflects the depth and breadth of research interests, from basic science to translational medicine, within the UCL Cancer Institute. Read more
The Cancer MSc reflects the depth and breadth of research interests, from basic science to translational medicine, within the UCL Cancer Institute. The programme, taught by research scientists and academic clinicians, provides students with an in-depth look at the biology behind the disease processes which lead to cancer.

Degree information

This programme offers a foundation in understanding cancer as a disease process and its associated therapies. Students learn about the approaches taken to predict, detect, monitor and treat cancer, alongside the cutting-edge research methods and techniques used to advance our understanding of this disease and design better treatment strategies.

Students undertake modules to the value of 180 credits. The programme consists of two core modules (60 credits), four specialist modules (60 credits) and a research project (60 credits). A Postgraduate Diploma (120 credits, full-time nine months) is offered. A Postgraduate Certificate (60 credits, full-time 12 weeks) is offered.

Core modules
-Basic Biology and Cancer Genetics
-Cancer Therapeutics

Specialist modules
-Behavioural Science and Cancer
-Biomarkers in Cancer
-Cancer Clinical Trials
-Haematological Malignancies and Gene Therapy

Dissertation/report
All MSc students undertake a laboratory project, clinical trials project or systems biology/informatics project, which culminates in a 10,000–12,000 word dissertation and an oral research presentation.

Teaching and learning
Students develop their knowledge and understanding of cancer through lectures, self-study, database mining, wet-lab based practicals, clinical trial evaluations, laboratory training, assigned reading and self-learning. Each taught module is assessed by an unseen written examination and/or coursework. The research project is assessed by the dissertation (75%) and oral presentation (25%).

Careers

The knowledge and skills developed will be suitable for those in an industrial or healthcare setting, as well as those individuals contemplating a PhD or medical studies in cancer.

Top career destinations for this degree:
-Research Technician, NHS Imperial College Healthcare NHS Trust
-Cancer and Genetics, ETH Zurich
-PhD Cancer Research, University of New South Wales (UNSW)
-Clincial Trial Project Manager, Beijing Lawke Health Laboratory Inc.
-Research Scientist, SporeGen

Employability
Skills include critical evaluation of scientific literature, experimental planning and design interpretation of data and results, presentation/public speaking skills, time management, working with a team, working independently and writing for various audiences.

Why study this degree at UCL?

UCL is one of Europe's largest and most productive centres of biomedical science, with an international reputation for leading basic, translational and clinical cancer research.

The UCL Cancer Institute brings together scientists from various disciplines to synergise multidisciplinary research into cancer, whose particular areas of expertise include: the biology of leukaemia, the infectious causes of cancer, the design of drugs that interact with DNA, antibody-directed therapies, the molecular pathology of cancer, signalling pathways in cancer, epigenetic changes in cancer, gene therapy, cancer stem cell biology, early phase clinical trials, and national and international clinical trials in solid tumours and blood cancers.

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The increasing impact of genetics in healthcare and the development of newer sophisticated technologies requires close collaboration between research scientists, clinical laboratory scientists and clinicians to deliver a high quality service to patients. Read more
The increasing impact of genetics in healthcare and the development of newer sophisticated technologies requires close collaboration between research scientists, clinical laboratory scientists and clinicians to deliver a high quality service to patients. The Medical Genetics MSc covers the delivery of a modern clinical genetics service, including risk analysis and application of modern genetic and genomic technologies in medical genetics research and in diagnostics and population screening.

Why this programme

-This is a fully up-to-date Medical Genetics degree delivered by dedicated, multi-award-winning teaching and clinical staff of the University, with considerable input from hospital-based Regional Genetics Service clinicians and clinical scientists.
-The full spectrum of genetic services is represented, from patient and family counselling to diagnostic testing of individuals and screening of entire populations for genetic conditions: eg the NHS prenatal and newborn screening programmes.
-The Medical Genetics MSc Teaching Staff have won the 2014 UK-wide Prospects Postgraduate Awards for the category of Best Postgraduate Teaching Team (Science, Technology & Engineering). These awards recognise and reward excellence and good practice in postgraduate education.
-The close collaboration between university and hospital staff ensures that the Medical Genetics MSc provides a completely up-to-date representation of the practice of medical genetics and you will have the opportunity to observe during clinics and visit the diagnostic laboratories at the new Southern General Hospital laboratory medicine building.
-The Medical Genetics degree explores the effects of mutations and variants as well as the current techniques used in NHS genetics laboratory diagnostics and recent developments in diagnostics (including microarray analysis and the use of massively parallel [“next-generation”] sequencing).
-New developments in medical genetics are incorporated into the lectures and interactive teaching sessions very soon after they are presented at international meetings or published, and you will gain hands-on experience and guidance in using software and online resources for genetic diagnosis and for the evaluation of pathogenesis of DNA sequence variants.
-You will develop your skills in problem solving, experimental design, evaluation and interpretation of experimental data, literature searches, scientific writing, oral presentations, poster presentations and team working.
-This MSc programme will lay the academic foundations on which some students may build in pursuing research at PhD level in genetics or related areas of biomedical science.
-The widely used textbook “Essential Medical Genetics” is co-authored by a member of the core teaching team, Professor Edward Tobias.
-For doctors: The Joint Royal Colleges of Physicians’ Training Board (JRCPTB) in the UK recognises the MSc in Medical Genetics and Genomics (which was established in 1984) as counting for six months of the higher specialist training in Clinical Genetics.
-The Medical Council of Hong Kong recognises the MSc in Medical Genetics and Genomics from University of Glasgow in it's list of Quotable Qualifications.

Programme structure

-Genetic Disease: from the Laboratory to the Clinic
-Case Investigations in Medical Genetics and Genomics
-Clinical Genomics - Students will take this course OR Omic Technologies for Biomedical Sciences OR Frontiers in Cancer Science.
-Omic technologies for the Biomedical Sciences: from Genomics to Metabolomics - Students will take this course OR Clinical Genomics OR Frontiers in Cancer Science.
-Frontiers in Cancer Science - Students will take this course OR Clinical Genomics OR Omic Technologies for Biomedical Sciences.
-Disease Screening in Populations
-SNP Assay Design and Validation
-Medical Genetics and Genomics Dissertation

Teaching and Learning Methods
A variety of methods are used, including problem-based learning, case-based learning, lectures, tutorials and laboratories. These are supplemented by a wide range of course-specific electronic resources for additional learning and self-assessment. As a result, you will develop a wide range of skills relevant to careers in research, diagnostics or clinical genetics. These skills include team-working, data interpretation and experimental design. You will use the primary scientific literature as an information resource, although textbooks such as our own Essential Medical Genetics will also be useful. You will have the options of: attending genetic counselling clinics and gaining hands-on experience and guidance in using software and online resources for genetic diagnosis and for the evaluation of pathogenesis of DNA sequence variants.

There are weekly optional supplementary tutorials on topics that are selected by students

Electronic Resources
-Access to a continually updated Moodle (virtual learning environment) with extensive additional teaching and self-assessment materials.
-An online web-portal with regularly updated direct links to >70 worldwide genetic databases & online algorithms (plus the latest new genetics discoveries), all easily accessible and grouped into useful categories.

Career prospects

Research: About half of our graduates enter a research career and most of these graduates undertake and complete PhDs; the MSc in Medical Genetics and Genomics facilitates acquisition of skills relevant to a career in research in many different bio-molecular disciplines.

Diagnostics: Some of our graduates enter careers with clinical genetic diagnostic services, particularly in molecular genetics and cytogenetics.

Clinical genetics: Those of our graduates with a prior medical / nursing training often utilise their new skills in careers as clinical geneticists or genetic counsellors.

Other: Although the focus of teaching is on using the available technologies for the purpose of genetic diagnostics, many of these technologies are used in diverse areas of biomedical science research and in forensic DNA analysis. Some of our numerous graduates, who are now employed in many countries around the world, have entered careers in industry, scientific publishing, education and medicine.

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Computer science has a brilliant future! You could help to create new network solutions, build the future digital society, develop secure digital services, or be involved in a ground-breaking international software project. Read more
Computer science has a brilliant future! You could help to create new network solutions, build the future digital society, develop secure digital services, or be involved in a ground-breaking international software project. Perhaps you will develop algorithms for utilising genome data in medicine or optimise bus routes using positioning data. Do you wonder about all the things that can be automated? Or would you like to dig deeper and become a researcher?

In the Master’s programme in computer science you can become an expert in a wide range of fields. You will have access to the focus areas of research in computer science at the University of Helsinki: algorithms, distributed or networked systems, and software engineering. You will gain lasting professional skills for specialist, design, or managerial posts in the corporate world, or for research and doctoral education, since the Master’s programme in computer science gives you the aptitude for both independent working and multidisciplinary teamwork.

This education will give you:
-The ability to advance your knowledge in the different areas of computer science.
-The skill to seek, assess, and analyse scientific information in your own area of expertise, and apply the methods of the field in an ethical and sustainable way.
-The ability to act as expert in the field, and to develop the practices and methods of your field in cooperation with specialists from other fields.
-Oral and written communication skills in an international work environment.

The quality teaching within the computer science programme at the University of Helsinki has been highlighted repeatedly in national and international teaching assessments. The student-centred, in-depth learning gives you a solid basis for life-long learning. Studying at the leading research unit for computer science in Finland offers you constant interaction with current research and insight into the development patterns in the field.

The University of Helsinki will introduce annual tuition fees to foreign-language Master’s programmes starting on August 1, 2017 or later. The fee ranges from 13 000-18 000 euros. Citizens of non-EU/EEA countries, who do not have a permanent residence status in the area, are liable to these fees. You can check this FAQ at the Studyinfo website whether or not you are required to pay tuition fees: https://studyinfo.fi/wp2/en/higher-education/higher-education-institutions-will-introduce-tuition-fees-in-autumn-2017/am-i-required-to-pay-tuition-fees/

Programme Contents

In future, we will increasingly be using intelligent tools, consisting of networked hardware, software, services, and data. They will work based on intelligent, learning algorithms, data streams carried by communication protocols, and global infrastructures.

Within the Algorithms sub-programme, you will study effective algorithms and their application within other disciplines and in corporate life. Future IT systems will contain more and more intelligent components, the function of which will be based on complex mathematical models created automatically with the aid of machine-learning methods. The problems to be solved are computationally challenging, and the ever increasing amounts of data will create their own challenges when it comes to the efficiency of the algorithms needed.

The Networking and services sub-programme educates you to become an expert and strategic leader in the design and management of new global infrastructures. The infrastructures include Internet technologies in fixed networks and mobile environments, as well as the information and service networks built on top of them. Focus areas include the theory, data security, and trust within distributed systems, interactive systems, and the adaptability of services in a changing environment.

The Software systems sub-programme introduces you to the design and implementation of advanced software. The development of a shared software framework or platform for several software products is very demanding both technically and from the development project viewpoint. Developing such software requires technical skills, but also team- and project work, quality assurance, and communication. Within this sub-programme, you can specialise in software engineering, software technology, or information management, and study the current research questions in these areas in depth.

Selection of the Major

The sub-programmes in the Master’s programme for computer science are:
-Algorithms
-Networking and services
-Software systems

You can select any of these programmes according to your preferences at the beginning of your studies. The sub-programme determines which courses you should take.

Programme Structure

The Master’s programme comprises 120 credits, which can be completed in two years, in accordance with an approved personal study plan. The degree includes:
-80 credits of advanced courses, including shared courses within the programme, courses within the programme which support the thesis topic, the Master’s thesis (Pro gradu), 30 credits.
-40 credits of other courses from your own or other programmes. The other courses can include a work-orientation period.

Career Prospects

The employment outlook within the field is excellent. Masters of computer science find varied positions within the ICT field, both as employees and entrepreneurs. The nature of the education is also geared towards giving you an aptitude for managerial posts. All the sub-programmes provide the qualifications to find employment in a wide variety of jobs.

Software-system graduates often start their careers as software developers and designers, while network graduates often start with software at the infrastructure level (such as data communications, computation, or data entry). The skills learned in the algorithms sub-programme enable you to work on challenging tasks in various fields.

As a graduate you can find employment within small or large corporations as well as organisations in the private, public, or third sector. Due to the global nature of the field, you can find employment anywhere in the world. Taking modules from other education programmes will help you apply your computer science skills in other areas. Many jobs are based on these combinations.

Thanks to its strong scientific basis, the degree is also an excellent springboard to a doctoral programme.

Internationalization

There is a very international atmosphere within the programme, as nearly a third of the students come from abroad, and the advanced courses are instructed by international researchers.

In addition, the University of Helsinki and the Faculty of Science offer you many opportunities for international activities:
-Instruction in English within other education programmes.
-International tasks within the students’ organisations or union.
-Language courses at the Language Centre of the University of Helsinki.

You can also get information and counselling about independent international experience, such as:
-Student exchange in one of the exchange locations of the faculty or university.
-Traineeships abroad.

Computer science at the University of Helsinki is a popular exchange location, especially from Germany. Some 5-10 students come annually; exchange students have come from 14 countries in recent years. The students in the department have taken exchange periods in 16 countries in the past few years.

Research Focus

There are several multidisciplinary research projects under way at the Faculty of Science, which are being carried out in cooperation with the research institutes on the science campus and with other faculties, universities, and corporations. The role of computer science within these projects is to develop the basic methods of the discipline in strategic areas and to collaborate in depth with other disciplines.

The sub-programmes within the Master’s programme cover a considerable part of the strategic focus areas of computer science research at the University of Helsinki: algorithms, data analysis and machine learning, networking and services, software systems, bioinformatics, and data science.

Computer science is part of three Finnish Academy centres of excellence: for computational inference, inversion problems, and cancer genetics. These units represent the collaboration between computer science and other disciplines.

Computer science has coordinated the long-lived Algodan centre of excellence, which has been the basis for many current research groups.

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If you're looking for a career in the fight against cancer - this is the course for you. This full-time MRes offers two research projects to give your future career in cancer biology a boost. Read more

Research training at the computational/clinical translational science interface

If you're looking for a career in the fight against cancer - this is the course for you. This full-time MRes offers two research projects to give your future career in cancer biology a boost. With two streams on offer – Cancer Biology, and Cancer Informatics – we have the options available for you to choose the best way for you to use your life-sciences degree to meet your objective. We will provide you with a broad-training in research as well as theoretical and practical skills to help you take the next step in your career.

Streams

There are two streams available:

•Cancer Biology - http://www.imperial.ac.uk/medicine/study/postgraduate/masters-programmes/mres-cancer-biology/
•Cancer Informatics - http://www.imperial.ac.uk/medicine/study/postgraduate/masters-programmes/mres-cancer-biology-cancer-informatics/

Is this programme for you?

You will engage with both theoretical and practical elements. The theoretical elements will include why particular methods are used, assumptions they are based on and understanding the technical limitations and quality control of different data types. The practical elements will include data handling and the computational method employed for each data type.

When you enter your projects, you will perform novel bioinformatics-based research, accumulate experimental findings and exercise critical scientific thought in the interpretation of those findings. The research projects may also include a smaller component of wet-lab experiments to provide some validation of the findings from the bioinformatics research.

You will need to be an independent person, who is looking for a challenge. If you're not afraid of hard work, then we would welcome an application from you.

Application

Decisions on applications are made in batches, with the following deadlines for each batch:
•09:00 GMT (UTC) Tuesday, 31 January 2017
•09:00 BST (UTC+1) Wednesday, 26 April 2017
•09:00 BST (UTC+1) Monday, 31 July 2017

You will receive notification of a conditional offer or rejection in the weeks following these deadlines. If you do not hear from us, it is because you have been placed on the waiting list. We withhold the right to close application early, so ensure that you submit your application sooner, rather than later.

Please note that we are unable to consider your application without at least one academic reference from your most recent institution.

Programme structure

The course comprises an initial four/five week taught component in which the cellular and molecular basis of cancer biology are covered, plus an introduction to the clinical and pathological aspects of carcinogenesis. This information is contained within the lectures which will partly be on the lecturer's own research, making use of the excellent researchers we have within Imperial College London. Within this period will also be a series of workshops covering key transferable skills such as oral presentation of scientific data and grant writing. This is shared with the Cancer Biology stream.

While the Cancer Biology stream move into their first project, you will receive three weeks of specialist training in informatics which is comprised of lectures and workshops. You will then complete an initial assignment before beginning your first research placement of roughly 16 weeks, and then a second project of roughly 20 weeks. These will be within the recently created Imperial College Cancer Research UK Centre, the Faculty of Medicine at the Hammersmith Hospital campus of Imperial College, and other collaborating institutes across London (e.g. Institute of Clinical Sciences, The Francis Crick Institute).

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If you want to pursue a research career in academia or industry, our MSc Cancer Biology will provide you with the essential advanced skills and knowledge for a role in biopharma, healthcare or cancer research. Read more
If you want to pursue a research career in academia or industry, our MSc Cancer Biology will provide you with the essential advanced skills and knowledge for a role in biopharma, healthcare or cancer research. We offer many opportunities for you to explore medically relevant research in the School of Biological Sciences including hospital-based sessions through our collaboration with local cancer specialists and clinicians.

An important and exciting part of your programme is an extensive independent research project, based in one of our academic research groups using advanced laboratories facilities and bioinformatics tools. There are also opportunities for research projects to take place within an industrial or clinical setting.

Throughout the course, you develop your knowledge in the essential areas of molecular and cellular biology which complement your specialist modules in cancer biology. You gain expertise in areas including:
-Specific cancer types (including breast, prostate, pancreatic and colon cancer)
-Clinical aspects of cancer
-Emerging trends in cancer research

You are also trained in modern research methods and approaches which will develop your skills in complex biological data analysis and specific techniques in cancer research.

Within our School of Biological Sciences, two-thirds of our research is rated “world-leading” or “internationally excellent” (REF 2014), and you will learn from and work alongside our expert staff as you undertake your own research.

Our expert staff

We have a very strong research team in the area of cancer biology, who are well placed to deliver the specialist teaching on this course.

The team includes the course leader Professor Elena Klenova (molecular oncology and cancer biomarkers), Dr Ralf Zwacka (apoptotic and survival signalling in cancer), Dr Greg Brooke (steroid hormone receptor signalling in cancer), Dr Metodi Metodiev (clinical proteomics and bioinformatics), Dr Pradeepa Madapura (cancer epigenetics), Dr Vladimir Teif (computational and systems biology), Professor Nelson Fernandez (tumour immunology) and Dr Filippo Prischi (structural biology and biophysics of novel drug targets).

External experts also input to your teaching, including guest speakers from hospitals and research institutions, who deliver classes both on-campus and within the hospital environment.

As one of the largest schools at Essex, we offer a lively, friendly and supportive environment with research-led study and high-quality teaching, and you benefit from our academics’ wide range of expertise and research.

The University of Essex has a Women's Network to support female staff and students and was awarded the Athena SWAN Institutional Bronze Award in November 2013 in recognition of its continuing work to support women in STEM.

Specialist facilities

Recent investment has provided modern facilities for functional genomics, computational biology and imaging biological systems. On our course you have the opportunity to:
-Study in an open and friendly department, with shared staff-student social spaces
-Carry out your research project in shared lab space, alongside PhD students and researchers engaged in cutting-edge cancer research
-Learn to use state-of-the-art research facilities, including an advanced microscopy suite, proteomics laboratory, cell culture, bioinformatics and genomics facilities, modern molecular biology laboratories, and protein structure analysis

Your future

Graduates who are skilled in the research methods embedded into your course are in demand from the biotechnology and biomedical research industries in this area of the UK and beyond.

Many of our Masters students progress to study for a PhD, and there are many opportunities within our school leading to a career in science.

We work with our University’s Employability and Careers Centre to help you find out about further work experience, internships, placements, and voluntary opportunities.

Example structure

-Advanced Cancer Biology
-Practical Skills in Cancer Research
-Gene Technology and Synthetic Biology
-Protein Technologies
-Professional Skills and the Business of Molecular Medicine
-Cancer Biology (optional)
-Research Project: MSc Cancer Biology
-Genomics (optional)
-Cell Signalling (optional)
-Molecular Medicine and Biotechnology (optional)
-Human Molecular Genetics (optional)
-Molecular and Developmental Immunology (optional)
-Creating and Growing a New Business Venture (optional)
-Rational Drug Design (optional)

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This MSc course offers an innovative interdisciplinary perspective on the study of cancer. Three core modules encompass biological and social sciences. Read more
This MSc course offers an innovative interdisciplinary perspective on the study of cancer.

Three core modules encompass biological and social sciences. These equip you to apply key theories and concepts critically, and to develop the skills required to engage in debates about the impact of cancer on the individual, the family and society.

A wide range of additional modules offers the opportunity to examine aspects of cancer in greater detail from different perspectives, ranging from professional practice to historical perspectives, from epidemiological and medical research to biotechnology.

See the website http://www.brookes.ac.uk/courses/postgraduate/cancer-studies/

Why choose this course?

- Our lecturers maintain excellent practice links in their specialist areas locally, regionally and nationally.

- You will have access to state-of-the-art clinical skills simulation suites and resources.

- The department hosts the prestigious HRH Prince Sultan Chair in Cancer Care and the Cancer Care research group.

- In the Research Excellence Framework (REF) 2014, 98% of our research in Allied Health Professions, Dentistry, Nursing and Pharmacy was rated as internationally recognised, with 82% being world leading or internationally excellent.

- You will be undertaking advanced study in Oxford, which has a new Cancer Centre and a range of expert practitioners working in the cancer field.

- "Students on this course will gain important insights into the nature of cancer research and its broader implications." Sir Paul Nurse

Teaching and learning

You will be given opportunities to be involved in all aspects of your programme - its management and delivery.

Different students will bring varied experiences and cultures and will be encouraged to share these with each other. You will be expected to take responsibility for your own learning and also to contribute to the learning of your fellow students.

The programme includes a taught element, informed by relevant national and international research and evidence-based literature, designed to be a starting point for critical reading and reflection. Mutual support between students enhances the learning experience and will be strongly encouraged.

In order to make the most of the range of experience, skills and knowledge within the group, a variety of teaching and learning strategies will be employed.
- Lectures introduce you to new areas of study and provide the context for further independent reading and practical work.

- Group activities (eg seminars, workshops, presentations) are used as a means of sharing knowledge and experience, developing critical skills, and emphasising the inter-disciplinary nature of the course.

- Presentation skills are developed through student-led seminars, presentations to your fellow students for some of the assessments.

Studying on this course will give you in-depth knowledge of cancer from the molecular level to the personal, social, societal and international levels. In doing so, you will draw on knowledge from life sciences, psychology, sociology, history, and the health care professions. This means that the course requires a flexible mind and a willingness to see familiar subjects in challenging new ways.
This course does not provide a specialised clinical training in medicine or any other health profession, but it does provide professionals with an opportunity to develop a deeper understanding of the nature of cancer.

Approach to assessment

Assessment is designed to ensure that you develop and demonstrate the required knowledge and skills to successfully complete your programme. Types of assessments within your programme are varied and appropriate for individual module and programme learning outcomes and content, the academic standard expected and different learning styles.

Assessment is mainly by essay writing, helping you to develop high levels of critical analysis, original thinking and clarity of expression.

Assessments are used to give you an opportunity to demonstrate your knowledge as well as the critical and reflective analysis required for professional practice. You will be given the opportunity to submit draft work for feedback and formative assessment.

Endorsements

Sir Paul Nurse (Nobel Laureate and former chief executive of Cancer Research UK)

"Students on this course will gain important insights into the nature of cancer research and its broader implications. As the influence of science on society continues to grow, such insights are as important to scientists as they are to the wider public."

Jon Snow (Journalist, broadcaster and former Chancellor of Oxford Brookes University)

"Cancer and how it is dealt with needs to be seen in its wider social and political context. Oxford Brookes University provides a great environment in which students can engage with these issues."

Attendance pattern

Most modules on the programme involve attendance in the classroom once a week over a 12-week semester period.

How this course helps you develop

You will be given opportunities to develop your academic abilities at master's level, including critical reading and writing skills, digital literacy, communication and teamwork skills. Your contact with other students from different disciplines will provide you with networks that may be of value to you in the development of your future career.

Careers

You will be provided with additional knowledge and expertise to enable you to pursue your chosen career, whether this is in the biological, social sciences or humanities.

Free language courses for students - the Open Module

Free language courses are available to full-time undergraduate and postgraduate students on many of our courses, and can be taken as a credit on some courses.

Please note that the free language courses are not available if you are:
- studying at a Brookes partner college
- studying on any of our teacher education courses or postgraduate education courses.

Research highlights

Cancer research is a key focus and the department hosts the prestigious HRH Prince Sultan Chair in Cancer Care. This is a very exciting addition to our portfolio, as it enables us to play a leading role in research development and education to improve the experience of patients undergoing cancer treatment and palliative care.

In the Research Excellence Framework (REF) 2014, 98% of our research in Allied Health Professions, Dentistry, Nursing and Pharmacy was rated as internationally recognised, with 82% being world leading or internationally excellent. The university has been careful to nurture emerging research strengths, and the international standing achieved by subjects allied to health demonstrates significant progress since 2008.

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The area of cancer immunotherapy considers how to use conventional therapies including surgery, radiation and chemotherapy. Read more
The area of cancer immunotherapy considers how to use conventional therapies including surgery, radiation and chemotherapy. Whilst these treatment have served well and new drugs will continue to be designed, clinical trials over the last five years have shown that boosting the body’s immune system, whose main task is to deal with invading pathogens, can help our immune system to destroy tumour cells. Many of the new immunotherapies may be tested in combination with more conventional treatments or tested alone, but investigators and oncologists now believe immunotherapy, initially combined with pharmacological treatments, will soon provide curative therapies and certainly give many patients a new lease of life.

More about this course

Worldwide the incidence of cancer is increasing, and is expected to reach 22 million new cases per year by 2030. In addition to treatments such as radiotherapy and surgery, chemotherapy has a vital role to play in prolonging the lives of patients.

The aims of the Cancer Immunotherapy MSc are to:
-Provide an in-depth understanding of the molecular targets at which the different classes of anticancer drugs are aimed, and of how drug therapies are evolving
-Review the biology of cancer with respect to genetics, pathological considerations, and the molecular changes within cells which are associated with the progression of the disease
-Enhance intellectual and practical skills necessary for the collection, analysis, interpretation and understanding of scientific data
-Deliver a programme of advanced study to equip students for a future career in anti-cancer drug and immunotherapy development
-Cover new areas in immunotherapy (some of which may enhance existing pharmacological therapies including: History of immunotherapy and review of immune system; Monoclonal antibodies in cancer therapy and prevention; DNA vaccines against cancer; Adoptive T cell therapy; Dendritic cell vaccines; Antibodies that stimulate immunity; Adjuvant development for vaccines; Epigenetics and cancer: improving immunotherapy; Immuno-chemotherapy: integration of therapies; Exosomes and Microvesicles (EMVs) in cancer therapy and diagnosis; Dendritic cell vaccine development and Pox virus cancer vaccine vectors; Microbial causes of cancer and vaccination

Students will have access to highly qualified researchers and teachers in pharmacology and immunology, including those at the Cellular and Molecular Immunology Research Centre. Skills gained from research projects are therefore likely to be highly marketable in industry, academia and in the NHS. Students will be encouraged to join the British Society of Immunology and the International Society of Extracellular Vesicles.

Assessment is a combination of coursework, which includes tests and essays, the research project and its oral defence and examination.

Modular structure

The modules listed below are for the academic year 2016/17 and represent the course modules at this time. Modules and module details (including, but not limited to, location and time) are subject to change over time.

Year 1 modules include:
-Advanced Immunology (core, 20 credits)
-Cancer Immunotherapy (core, 20 credits)
-Cancer Pharmacology (core, 20 credits)
-Cancer: Diagnosis and Therapy (core, 20 credits)
-Molecular Oncology (core, 20 credits)
-Research Project (core, 60 credits)
-Scientific Frameworks for Research (core, 20 credits)

After the course

Students will have many opportunities to work in industry. There are established industries working hard to develop cancer immunotherapies including Bristol-Myers Squibbs, MERCK, AstraZeneca and Roche. There are also an innumerate number of start-up companies appearing including Omnis Pharma, UNUM Therapeutics and Alpine Immune Sciences.

Students will also have ample opportunity for future postgraduate study either within the School of Human Sciences and the Cellular and Molecular Immunology Centre at the MPhil/PhD level or beyond, even with some of our research partners within the UK, Europe and beyond.

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The MSc in Cancer Biology is for students who wish to gain an advanced education and training in the biological sciences, within the context of a disease that affects a large proportion of the global population. Read more
The MSc in Cancer Biology is for students who wish to gain an advanced education and training in the biological sciences, within the context of a disease that affects a large proportion of the global population.

The programme provides training in the modern practical, academic and research skills that are used in academia and industry. Through a combination of lectures, small-group seminars and practical classes, students will apply this training towards the development of new therapies.

The programme culminates with a research project that investigates the molecular and cellular basis of cancer biology or the development of new therapies under the supervision of active cancer research scientists.

Visit the website: https://www.kent.ac.uk/courses/postgraduate/226/cancer-biology

About the School of Biosciences

The School of Biosciences is among the best-funded schools of its kind in the UK, with current support from the BBSRC, NERC, MRC, Wellcome Trust, EU, and industry. It has 38 academic staff, 56 research staff (facility managers, research fellows, postdoctoral researchers and technicians), approximately 100 postgraduate students and 20 key support staff. The school's vibrant atmosphere has expanded to become a flourishing environment to study for postgraduate degrees in a notably friendly and supportive teaching and research environment.

Research in the School of Biosciences revolves around understanding systems and processes in the living cell. It has a strong molecular focus with leading-edge activities that are synergistic with one another and complementary to the teaching provision. Our expertise in disciplines such as biochemistry, microbiology and biomedical science allows us to exploit technology and develop groundbreaking ideas in the fields of genetics, molecular biology, protein science and biophysics. Fields of enquiry encompass a range of molecular processes from cell division, transcription and translation through to molecular motors, molecular diagnostics and the production of biotherapeutics and bioenergy.

In addition to research degrees, our key research strengths underpin a range of unique and career-focused taught Master’s programmes that address key issues and challenges within the biosciences and pharmaceutical industries and prepare graduates for future employment.

Course structure

Each one-hour lecture is supplemented by two hours of small-group seminars and workshops in which individual themes are explored in-depth. There are practical classes and mini-projects in which you design, produce and characterise a therapeutic protein with applications in therapy.

In additional to traditional scientific laboratory reports, experience will be gained in a range of scientific writing styles relevant to future employment, such as literature reviews, patent applications, regulatory documents, and patient information suitable for a non-scientific readership.

Modules

The following modules are indicative of those offered on this programme. This list is based on the current curriculum and may change year to year in response to new curriculum developments and innovation. Most programmes will require you to study a combination of compulsory and optional modules. You may also have the option to take modules from other programmes so that you may customise your programme and explore other subject areas that interest you.

BI830 - Science at Work (30 credits)
BI836 - Practical and Applied Research Skills for Advanced Biologists (30 credits)
BI837 - The Molecular and Cellular Basis of Cancer (15 credits)
BI838 - Genomic Stability and Cancer (15 credits)
BI840 - Cancer Therapeutics: From the Laboratory to the Clinic (15 credits)
BI857 - Cancer Research in Focus (15 credits)
BI845 - MSc Project (60 credits)

Assessment

The programme features a combination of examinations and practically focused continuous assessment, which gives you experience within a range of professional activities, eg, report writing, patent applications and public health information. The assessments have been designed to promote employability in a range of professional settings.

Programme aims

This programme aims to:

- provide an excellent quality of postgraduate-level education in the field of cancer, its biology and its treatment

- provide a research-led, inspiring learning environment

- provide a regional postgraduate progression route for the advanced study of a disease that affects a high proportion of the population

- promote engagement with biological research into cancer and inspire you to pursue a scientific career inside or outside of the laboratory

- develop subject specific and transferable skills to maximise employment prospects

- promote an understanding of the impact of scientific research on society and the role for scientists in a range of professions.

Research areas

Research in the School of Biosciences is focused primarily on essential biological processes at the molecular and cellular level, encompassing the disciplines of biochemistry, genetics, biotechnology and biomedical research.

The School’s research has three main themes:

- Protein Science – encompasses researchers involved in industrial biotechnology and synthetic biology, and protein form and function

- Molecular Microbiology – encompasses researchers interested in yeast molecular biology (incorporating the Kent Fungal Group) and microbial pathogenesis

- Biomolecular Medicine – encompasses researchers involved in cell biology, cancer targets and therapies and cytogenomics and bioinformatics.

Each area is led by a senior professor and underpinned by excellent research facilities. The School-led development of the Industrial Biotechnology Centre (IBC), with staff from the other four other schools in the Faculty of Sciences, facilitates and encourages interdisciplinary projects. The School has a strong commitment to translational research, impact and industrial application with a substantial portfolio of enterprise activity and expertise.

Careers

A postgraduate degree in the School of Biosciences is designed to equip our graduates with transferable skills that are highly valued in the workplace. Our research-led ethos ensures that students explore the frontiers of scientific knowledge, and the intensive practical components provide rigorous training in cutting edge technical skills that are used in the modern biosciences while working in areas of world-leading expertise within the School.

Destinations for our graduates include the leading pharmaceutical and biotechnological companies within the UK and leading research institutes both at home and abroad.

Find out how to apply here - https://www.kent.ac.uk/courses/postgraduate/apply-online/226

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Take advantage of one of our 100 Master’s Scholarships to study Clinical Science (Medical Physics) at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study Clinical Science (Medical Physics) at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

Medical physicists fill a special niche in the health industry. The role includes opportunities for laboratory work, basic and applied research, management and teaching, which offers a uniquely diverse career path. In addition there is satisfaction in contributing directly to patient treatment and care.

This three-year programme in Clinical Science (Medical Physics), hosted by the College of Medicine, builds on an existing collaboration with the NHS in providing the primary route for attaining the professional title of Clinical Scientist in the field of Medical Physics.

Key Features of MSc in Clinical Science (Medical Physics)

The Clinical Science (Medical Physics) programme is accredited by the NHS and provides the academic component of the Scientist Training Programme for medical physics trainees, within the Modernising Scientific Careers framework defined by the UK Department of Health, and offers students the chance to specialise in either radiotherapy physics or radiation safety. This Master’s degree in Clinical Science (Medical Physics) is only suitable for trainees sponsored by an NHS or an equivalent health care provider.

The MSc in Clinical Science (Medical Physics) is modular in structure, supporting integration of the trainee within the workplace. Students must obtain a total of 180 credits to qualify for the degree. This is made up of 120 credits of taught-course elements and a project that is worth 60 credits and culminates in a written dissertation.

The Clinical Science (Medical Physics) MSc is accredited by the Department of Health.

Modules

Modules on the Clinical Science (Medical Physics) MSc typically include:

• Introduction to Clinical Science
• Medical Imaging
• Nuclear Medicine and Diagnostic Imaging
• Radiation Protection
• Radiotherapy Physics
• Research Methods
• Advanced Radiotherapy
• Specialist Radiotherapy
• Advanced Radiation Safety
• Specialist Radiation Safety

Careers

The MSc in Clinical Science (Medical Physics) provides the main route for the professional qualification of Clinical Scientist in Medical Physics.

Additionally, the need for specific expertise in the use of medical radiation is enshrined in law. The Ionising Radiation (Medical Exposure) Regulations (IRMER) 2000 defines the role of Medical Physics Expert, required within any clinical context where radiation is being administered, either a diagnostic or therapeutic.

Links with industry

The close working relationship between Swansea University and the NHS in Wales, through the All-Wales Training Consortium for Medical Physics and Clinical Engineering, provides the ideal circumstances for collaborative teaching and research. The Consortium is recognised by the Welsh Government. A significant proportion of the teaching is delivered by NHS Clinical Scientists and other medical staff.

Facilities

The close proximity of Swansea University to Singleton Hospital, belonging to one of the largest health providers in Wales, Abertawe Bro Morgannwg University (ABMU) health board, as well as the Velindre NHS Trust, a strongly academic cancer treatment centre, provide access to modern equipment, and the highest quality teaching and research.

The Institute of Life Science (ILS) Clinical Imaging Suite has recently been completed and overlaps the University and Singleton Hospital campuses. It features adjoined 3T MRI and high-resolution CT imaging. ILS has clinical research of social importance as a focus, through links with NHS and industrial partners.

Research

Swansea University offers a vibrant environment in medically-oriented research. The Colleges of Medicine has strong research links with the NHS, spearheaded by several recent multimillion pound developments, including the Institute of Life Science (ILS) and the Centre for NanoHealth (CNH).

The University provides high-quality support for MSc student research projects. Students in turn make valuable progress in their project area, which has led to publications in the international literature or has instigated further research, including the continuation of research at the doctoral level.
The College of Medicine provides an important focus in clinical research and we have the experience of interacting with medical academics and industry in placing students in a wide variety of research projects.

Medical academics have instigated projects examining and developing bioeffect planning tools for intensity modulated radiotherapy and proton therapy and devices for improving safety in radiotherapy. Industry partners have utilised students in the evaluation of the safety of ventricular-assist devices, intense-pulsed-light epilators and in the development of novel MRI spectroscopic methods. The student join teams that are solving research problems at the cutting-edge of medical science.

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Haematologists specialise in disorders of the blood and blood-forming tissues, and their contribution to patient care is fundamental and wide-ranging. Read more
Haematologists specialise in disorders of the blood and blood-forming tissues, and their contribution to patient care is fundamental and wide-ranging. Whether you’re analysing data from patients' samples, matching donated blood with someone who needs a transfusion or researching cures for blood cancers, your work will improve and save countless lives.


Why study MSc Biomedical Science -Haematology and Transfusion Science at Middlesex?

Our Biomedical Science courses have a burgeoning international reputation, due to our world-class research in areas including biomarkers, public health and bio modelling. Our Centre for Investigative and Diagnostic Oncology has pioneered techniques for cancer diagnosis and treatment, and the Haematology department is very active in research into blood cancers, HIV and AIDS.

Our course has a strong practical element, with an emphasis on developing laboratory skills and gaining hands-on experience of diagnostic techniques. Our teaching and research facilities surpass those at some UK medical schools, with £3 million specialist labs equipped with the most up-to-date technology- the perfect place to work on your own research project. You’ll learn to use cutting-edge equipment, including MALDI-TOF mass spectrometers and flow cyto meters; we have a molecular biology laboratory for techniques such as DNA sequencing, real-time PCR, electrophoresis and HPLC, fully-equipped proteomics facilities, a microbiology lab and an incredibly modern cell culture facility.

Course highlights

- Course leader Dr Colin Casimir is famed for his research into the biology of haemopoietic stem cells and gene therapy for haematologic conditions. He is the holder of a number of international patents, and his research has been published in top international journals, including the British Journal of Haematology.
- Other teaching staff include Dr Stephen Butler, a world expert on cancer biomarkers and reproductive biochemistry; Dr Ajit Shah, a former principal scientist at GlaxoSmithKline; and Dr Lucy Ghali, an expert in immunohistochemistry. Guest lecturers include Peter Gregory, haematology services manager at Barnet and Chase Farm Hospitals Trust.
- Our staff are supportive and hands-on – ever-ready with advice on your studies, they’re also known for their strong pastoral care and for going the extra mile for their students. All our teaching staff are involved in research.
- The course is accredited by the Institute of Biomedical Science, so on graduation you’ll have fulfilled the academic requirement for Licentiate membership of the institute; you can apply for student membership while you study.
- We work with London hospitals and NHS laboratories to ensure you’re fully versed in both the latest practice and the latest research. - You’ll visit diagnostic laboratories and of course, our location gives you easy access to the British Library, the Science Museum, the Royal Institution and more.

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The Pre-Masters in Biomedical Science (Graduate Diploma in Biomedical Science) provides a discipline-specific pathway (a pre-masters year) into the taught Biomedical Blood Science masters level programme. Read more

Overview

The Pre-Masters in Biomedical Science (Graduate Diploma in Biomedical Science) provides a discipline-specific pathway (a pre-masters year) into the taught Biomedical Blood Science masters level programme. It is a one-year full-time programme designed for both home and international students, with a background in life sciences, who wish to study at postgraduate level for the MSc in Biomedical Blood Science. The programme is open to science graduates who do not meet the academic criteria for a direct entry into the MSc. The MSc in Biomedical Blood Science is accredited by the Institute of Biomedical Science (IBMS). The IBMS is the professional body of Biomedical Scientists within the United Kingdom. The IBMS aims to promote and develop the role of Biomedical Science within healthcare to deliver the best possible service for patient care and safety.

See the website https://www.keele.ac.uk/pgtcourses/biomedicalsciencegraduatediploma/

Course Aims

The overall aim is to provide the students with the academic background necessary for the masters programme and to enable them to develop and practise the subject specific academic skills required for the intensive pace of study at masters level. The course also aims to allow international students to benefit from English language support that will help them to develop their academic English language skills.

Intended learning outcomes of the programme reflect what successful students should know, understand or to be able to do by the end of the programme. Programme specific learning outcomes are provided in the Programme Specification available by request; but, to summarise, the overarching course aims are as follows:

- To provide students with core knowledge, understanding and skills relevant to Biomedical Science

- To produce skilled and motivated graduates who are suitably prepared for the MSc in Biomedical Science and for further study.

- To cultivate interest in the biosciences, particularly at the cellular and molecular level, within a caring and intellectually stimulating environment.

- To get an accurate insight into the role of Biomedical Scientists in the diagnosis, treatment and monitoring of disease.

- To develop an understanding of the analytical, clinical and diagnostic aspects of Cellular Pathology, Clinical Biochemistry, Medical Microbiology, Blood Transfusion, Clinical Immunology and Haematology pathology laboratories.

- To promote the development of a range of key skills, for use in all areas where numeracy and an objective, scientific approach to problem-solving are valued.

- To provide students with a wide range of learning activities and a diverse assessment strategy in order to fully develop their employability and academic skills, ensuring both professional and academic attainment.

- To promote the development of critical thinking, autonomous learning, independent research and communication skills to help prepare the students for the MSc in Biomedical Blood Science and for a lifetime of continued professional development.

Course Content

All the modules in this one year programme are compulsory. The programme consists of a total of 90 credits made up of one 30 credit module and four 15 credit modules. An additional English module (English for Academic Purposes) will be offered for non-native English speakers if required. This module will not form part of the overall award, but successful completion is required for progression to the Masters programme.

Modules:
- Biomedical Science and Pathology (30 credits):
The module provides the student with the knowledge and understanding of the pathobiology of human disease associated with Cellular Pathology, Clinical Immunology, Haematology, Clinical Biochemistry, Medical Microbiology and Clinical Virology. It also examines the analytical and clinical functions of three more of the major departments of a modern hospital pathology laboratory, including Haematology, Clinical Pathology, Clinical Immunology, Blood Transfusion, Clinical Biochemistry and Medical Microbiology. In addition, the module will give an accurate insight into the role of Biomedical Scientists and how they assist clinicians in the diagnosis, treatment and monitoring of disease.

- Biochemistry Research Project (non-experimental) (15 credits):
This module aims to introduce students to some of the key non-experimental research skills that are routinely used by biochemists and biomedical scientists, such as in depth literature searching, analysis of experimental data and the use of a computer as tool for both research (bioinformatics) and dissemination of information (web page construction). The student will research the literature on a specific topic, using library and web based resources and will produce a written review. In addition, the student will either process and interpret some raw experimental data provided to them.

- Advances in Medicine (15 credits):
This module will describe and promote the understanding of advances in medicine that have impacted on diagnosis, treatment, prevention of a range of diseases. It will highlight fast emerging areas of research which are striving to improve diagnosis including nanotechnology and new biochemical tests in the fields of heart disease, cancer and fertility investigations which will potentially improve patient care.

- Clinical Pathology (15 credits):
The majority of staff that contribute to the module are employees of the University Hospital of North Staffordshire (UHNS). Students will benefit from lectures and expertise in Clinical Diagnostic Pathology, Pharmacology, Biochemistry, Genetics and Inflammatory Diseases. Students will gain an insight into how patients are managed, from their very first presentation at the UHNS, from the perspective of diagnosis and treatment. The course will cover both standardised testing options and the development of new diagnostic procedures with a particular emphasis on genetic and epigenetic aspects of disease. Students will also gain an appreciation of the cost benefit of particular routes for diagnosis and treatment and the importance of identifying false positive and false negative results. Finally, the students will have the opportunity to perform their own extensive literature review of a disease-related topic that is not covered by the lectures on the course.

- Case Studies in Biomedical Science (15 credits):
This module aims to give you an understanding of the UK health trends and the factors that affect these trends. Through clinical case studies and small group tutorials, you will explore why the UK has some of the highest incidences of certain diseases and conditions in Europe and consider what factors contribute to making them some of the most common and/or rising health problems faced by this country. This will include understanding the relevant socioeconomic factors as well as understanding the bioscience of the disease process and its diagnosis and management. You will also focus on what is being done by Government and the NHS to tackle these major health problems.

- English for Academic Purposes (EAP ):
For non-native English speakers if required

Teaching & Assessment

In addition to the lecture courses and tutorials, problem based learning (PBL) using clinical scenarios is used for at least one module. Students will also be given the opportunity to undertake an independent non-experimental research project, supervised and supported by a member of staff. Web-based learning using the University’s virtual learning environment (KLE) is also used to give students easy access to a wide range of resources and research tools, and as a platform for online discussions and quizzes. Students will be given many opportunities to become familiar with word processing, spreadsheets and graphics software as well as computer-based routes to access scientific literature.

All modules are assessed within the semester in which they are taught. Most contain elements of both ‘in-course’ assessment (in the form of laboratory reports, essays, posters) and formal examination, although some are examined by ‘in-course’ assessment alone.

Additional Costs

Apart from additional costs for text books, inter-library loans and potential overdue library fines we do not anticipate any additional costs for this post graduate programme.

Find information on Scholarships here - http://www.keele.ac.uk/studentfunding/bursariesscholarships/

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This unique practical and applied course will develop specialised knowledge of clinical exercise science using an evidence-based approach to enhance your career prospects. Read more
This unique practical and applied course will develop specialised knowledge of clinical exercise science using an evidence-based approach to enhance your career prospects.

This novel programme is designed for those wishing to gain and develop expert knowledge in the science of exercise assessment and prescription and learn applied techniques which will enable you to develop a career in clinical exercise science, academic research, teaching and other science based professions. The evidence demonstrating that physical activity reduces the risk of developing chronic conditions such as cardiovascular disease, cancer, obesity and type 2 diabetes highlights the need for clinical exercise practitioners with high level knowledge of physical activity and health who can work within community and healthcare settings.

This programme offers a well-balanced blend between practice and theory. The course is multi-disciplinary in nature covering aspects of exercise physiology, exercise and health psychology as well as clinical skills.

What you'll learn

During your studies you will develop an advanced understanding of the research evidence in the context of clinical exercise science. You will learn to apply theoretical concepts and professional skills in practical situations likely to be encountered by a clinical exercise scientist. You will employ advanced investigative, analytical and practical techniques to advance knowledge in clinical exercise science. You will present evidence based clinical exercise prescription appropriate for a range of pathologies and in seemingly healthy populations and be able to effectively communicate (evidence and treatment goals) with a variety of populations.

You will gain enhanced knowledge and learn skills in clinical exercise science to increase employability in an academic or applied setting.

There are opportunities to complete a PgDip (120 credits) or a PgCert (60 credits). Alternatively you may wish to complete specific module/modules as part of your own continuous professional development.

Modules

Trimester 1:
• Exercise, wellbeing and psychological health (20 credits)
• Exercise Physiology & Health (20 credits)
• Research Methods in Sport and Exercise Science (20 credits)

Trimester 2 (option of 3 out of 4):
• Physical Activity and Cardio-metabolic Conditions (20 credits)
• Physical Activity and Cancer Survivorship (20 credits)
• Physical Activity for Neurological Conditions (20 credits)
• Independent Study (20 credits)

Trimester 3:
• Research Project (60 credits)

Study modules mentioned above are indicative only. Some changes may occur between now and the time that you study.

Careers

Within the taught option modules, you may have the option of gaining accredited Level 4 occupational qualifications. For example you may choose to sit the Skills Active Validated Level 4 Cancer and Exercise examinations following on from successful completion of the Physical Activity and Cancer Survivorship module in trimester 2 (please note there will be an additional cost to sit the examinations).

On successful completion of this programme you will have the knowledge, understanding and skills to gain postgraduate-level employment within the NHS, private healthcare sector, third sector, local government and leisure services. You will be equipped to deliver high level exercise testing, assessment and prescription for health impaired individuals and groups both individually as an autonomous practitioner; or within multi-disciplinary teams in clinical or community settings. This programme will prepare you for occupations such as a:
• GP exercise referral coordinator
• trainee clinical scientist
• health advisor
• exercise science research technician
• health and wellbeing physiologist
• physical activities adviser
• private exercise physiologist

You may also to progress to a research degree up to PhD level. Alternatively you may wish to complete specific module/modules as part of your continuous professional development.

How to apply

http://www.napier.ac.uk/study-with-us/postgraduate/how-to-apply

SAAS Funding

Nothing should get in the way of furthering your education. Student Awards Agency Scotland (SAAS) awards funding for postgraduate courses, and could provide the help you need to continue your studies. Find out more: http://www.napier.ac.uk/study-with-us/postgraduate/fees-and-funding/saas-funded-courses

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Clinicians, scientists and students engaged in cancer research at Newcastle share a common purpose. to improve treatment outcomes for patients with cancer. Read more
Clinicians, scientists and students engaged in cancer research at Newcastle share a common purpose: to improve treatment outcomes for patients with cancer. Work covers a broad spectrum - understanding the biological and molecular differences between normal and malignant cells and using this knowledge to develop new anti-cancer drugs.

Our staff and postgraduate students are based in the Northern Institute for Cancer Research (NICR) or the School of Chemistry. The NICR incorporates the Newcastle Cancer Centre, a unique collaboration between Cancer Research UK and the North of England Children's Cancer Research Fund.

We are a major training base for the next generation of cancer researchers. Our Institute covers many areas of cancer research, including:
-Solid tumours and leukaemias
-Childhood and adult cancers
-Drug discovery and early phase clinical trials

We offer approximately 15 MD, PhD and integrated MRes/PhD studentships each year, including the Newcastle Cancer Centre training programme. Projects in all research areas are available to fully-funded international students.

Members of our postgraduate community come from a variety of subject backgrounds including biological and biomedical sciences, chemistry, genetics, pharmacy, medicine, dentistry and veterinary medicine.

We hold regular postgraduate seminars which you will be required to attend and where you will deliver presentations. You will also attend and present your data annually at national cancer research meetings and at least one international meeting.

Placements

Our Institute has close working relationships with companies in the pharmaceutical and biotechnology sectors.

A number of our studentships are direct collaborations with industrial partners, with opportunities to spend placements with these partners.

Facilities

Our staff and postgraduate students are based in the Northern Institute for Cancer Research (NICR) or the School of Chemistry (medicinal chemistry students).

Our laboratories contain a full range of contemporary genomic, bioinformatic, proteomic, synthetic chemistry and pharmacology equipment, and clinical research facilities.

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