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Take advantage of one of our 100 Master’s Scholarships to study 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 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.

Swansea University is the only UK university to offer a British Blood Transfusion Society approved degree in Advanced Specialist Blood Transfusion.

This is a part-time course that will be delivered via the Work-based Learning (WBL) route with students employed in a variety of heath care settings.

The Master's level course for the Specialist Blood Transfusion has been developed in collaboration with the British Blood Transfusion Society. Members of the British Blood Transfusion Society (BBTS) will work in partnership with colleagues from the College of Human and Health Sciences in providing appropriate support for these students.

The Advanced Specialist Blood Transfusion programme team will provide academic support and facilitation of the WBL and the identified work-based mentor will provide guidance clinically.

Students can therefore be working in a setting distinct from the College and able to work at their own pace and react to learning opportunities in a real life setting.

The BBTS is a professional membership body which is committed to supporting transfusion professionals through the provision of career development and learning opportunities, thus assuring ongoing advancement of blood transfusion and its practitioners. It currently has in excess of 1600 members, representing transfusion professionals at all levels and locations.

Course Description

Whilst formal training and education has been available for doctors, clinical scientists and biomedical scientists specialising in transfusion medicine for some years, nurses and transfusion practitioners have had limited access to formal programmes of education in blood transfusion. The educational preparation of nurses and transfusion practitioners is critical to promoting safe and effective transfusion practice. The purpose of this degree in Advanced Specialist Blood Transfusion Practice is to prepare the practitioner to achieve the level of expertise that the BBTS has detailed in its curriculum framework for nurses and transfusion practitioners working in UK Blood Services and the wider NHS.

The programme reflects, in part, the content of the original framework for the BBTS Specialist Certificate in Blood Transfusion Science Practice (2008). The framework for the BBTS Specialist Certificate in Transfusion Science Practice for nurses and practitioners working in blood transfusion and associated specialties was compiled by representatives from the BBTS Professional Affairs and Education nursing sub-committee, the UK Blood Services and NHS hospital transfusion team representatives.

The format of work-based learning is well established within the College and concurs with modern learning philosophies, enabling students to learn in their working environment whilst being mentored by experts in their field of practice. This learning enables the employer to support students within their workplace. The student professionally develops whilst continuing to work in their workplace environment.

The CHHS will deliver the Advanced Specialist Blood Transfusion Practice programme in partnership with the BBTS, who will provide subject expertise and curriculum guidance.

This programme is offered on a part-time basis, and will normally take three years to complete.

The MSc programme in Advanced Specialist Blood Transfusion comprises 6 modules (120 credits) and a dissertation (60 credits). The first year will comprise of three 20-credit core modules and the second year will comprise of two 30-credit composite modules. In the final year, students complete the dissertation module (60 credits).

PGDip students undertake the same first and second year modules, but do not undertake the dissertation.

PGCert students undertake the first year modules only.

Modules

Modules on the Advanced Specialist Blood Transfusion programme typically include:

The Work Place Learning Journey
The History, Science and Practice of Blood Transfusion
Clinical Governance and its Impact on Managing Adverse Events in Blood Transfusion
Advanced Specialist Practice in Blood Transfusion
Advanced Clinical Governance and Contemporary Issues
Professional Practice in Advanced Specialist Blood Transfusion

Who should take this programme?

Nurses and other allied health care professionals (e.g. ODPs) may be interested in studying for a Master's or postgraduate qualification in Advanced Specialist Blood Transfusion Practice.

Staff Expertise

The core team for the College of Human and Health Sciences have professional backgrounds in either haematology and/or work-based learning. The programme manager, Mrs Heulwen Morgan-Samuel, has extensive clinical experience in general medical nursing, and has developed expertise in the care of cancer patients, including palliative care, and teaches on many palliative care and oncology modules. She is also the designated lead for haematology nursing in the College. She has published a number of research studies in peer reviewed journals specifically on infection control for the immune-compromised patient and the role of the nurse lecturer in supporting students. Heulwen Morgan- Samuel’s research interests include factors that enhance learning within the clinical environment, student support, principles of care and education for oncology nurses. She has co-edited a revised edition of the Fundamentals of Nursing book which is aimed at the pre registration nursing curriculum designated.

Teaching and learning is based on the best research evidence available, and the programme manager will work in close collaboration with members of the British Blood Transfusion Society (BBTS). Their membership includes professionals from all levels across the transfusion community, maintaining clinical and academic currency, to support and enhance practice in this field. The aim of BBTS is to “play a leading role in safe and effective transfusion practice by delivering high quality education and training, setting standards and promoting research and development and innovation” (BBTS, 2015).

Employability

Healthcare professionals employed in the field of blood transfusion that require advanced level education in the speciality would benefit from this degree in Advanced Specialist Blood Transfusion.

It is relevant to those wishing to build on their knowledge of blood transfusions within their existing career, but would also be beneficial to those currently working in an environment that manages blood transfusion who wish to focus and develop their career within this field of practice, as well as being a stepping stone for research study. The knowledge, understanding and skills developed would enhance students' expertise and would build on current practice within their own workplaces.

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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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This programme aims to respond to a national and international need for clinicians, scientists and allied health professions who can apply a molecular approach to the investigation, diagnosis and management of clinical disease. Read more
This programme aims to respond to a national and international need for clinicians, scientists and allied health professions who can apply a molecular approach to the investigation, diagnosis and management of clinical disease.

We will provide you with theoretical and practical knowledge of modern molecular technologies as applied to human disease, with an emphasis on cancer, and train you in the application and interpretation of advanced molecular technologies.

Compulsory Modules

• Basic Pathology
• Cancer Biology
• Cancer Prevention & Screening
• Genomic Approaches to Human Diseases
• Molecular Diagnostic & Therapeutics
• Molecular Pathology of Solid Tumours
• Research Lab Skills
• Research Methods

Elective Modules

• Introduction to Bioinformatics
• Biological Therapies
• Molecular Targeted Therapies and Immunotherapy for Blood Cancers

Core Modules for MSc

• Lab project



Barts Cancer Institute is a Cancer Research UK Centre of Excellence and one of the leading cancer institutes in the country.
Based in the heart of London, our programmes are all taught by experts in the field.

Find out more about the BCI at http://www.bci.qmul.ac.uk/study-with-us

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Improved global life expectancy has resulted in a cancer epidemic. It is well recognised that accurate early diagnosis is an essential aspect of the administration of increasingly expensive and tailored cancer treatment care plans. Read more
Improved global life expectancy has resulted in a cancer epidemic. It is well recognised that accurate early diagnosis is an essential aspect of the administration of increasingly expensive and tailored cancer treatment care plans.

The Biomedical Sciences (Cancer Biology) MSc programme has been devised to provide knowledge of key aspects of this increasingly important disease area.

You will become familiar with the genetic and cellular changes occurring in both solid and blood-borne cancers, the current and emerging technological approaches for diagnosis of the disease and the effect on pertinent cellular changes on patient prognosis. Studies on populations and the influence of genotypic variation will ensure that you are qualified to make sense of cancer statistics.

You are able to tailor your programme by selecting from a menu of option modules and pursuing a research project in an area ranging from molecular through to cellular or tissue-based aspects of cancer.

During the course you will join our thriving research environment and will have access to excellent laboratory facilities within the Faculty. On successful completion of the course you will be equipped to take forward your career with an in-depth knowledge of this increasingly common disease area.

Modules

The following modules are indicative of what you will study on this course.

Core modules
-ADVANCED CANCER BIOLOGY
-CELL SIGNALLING AND GENETICS
-MOLECULAR SCIENCE AND DIAGNOSTICS
-POSTGRADUATE PROJECT
-POSTGRADUATE RESEARCH METHODS

Option modules
-COMMUNICATING SCIENCE
-EXTENDED POSTGRADUATE PROJECT
-IMMUNOPATHOLOGY
-IMMUNOTHERAPY
-MOLECULAR AND CELLULAR THERAPEUTICS
-SYSTEMS BIOLOGY

Associated careers

After graduation, you will be equipped with the skills and knowledge to pursue a range of cancer-focused careers including appointments in diagnostic laboratories, academic, biotechnological and pharmaceutical research.

As a graduate of this course, you will be ideally placed to play an essential role in both diagnosis and improved care of cancer patients. Opportunities are also available to pursue a career in clinical trials and in areas such as data analysis and public health.

Professional recognition

The course is accredited by the Institute of Biomedical Science (IBMS).

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This programme aims to provide you with a clear understanding of the scientific basis underlying the principles and practice of treating cancer. Read more
This programme aims to provide you with a clear understanding of the scientific basis underlying the principles and practice of treating cancer.

This will be underpinned by a thorough knowledge of cancer biology and pathology and research methodologies.

This knowledge will provide an excellent grounding in the development, use and evaluation of cancer therapies, which will enhance career prospects in many areas of early phase clinical trials and clinical drug development in the cancer setting.

Compulsory Modules

• Ablative Therapies
• Cancer Biology
• Cancer Pharmacology
• Cancer Prevention & Screening
• Drug Development
• Molecular Diagnostic & Therapeutics
• Molecular Targeted Therapies and Immunotherapy for Blood Cancer
• Research Methods
• Site Specific Tumour Treatment

Elective Modules

• Genomic Approaches to Human Diseases
• Paediatric & Adolescent Oncology
• Pathology of Cancer

Core Module for MSc

• Dissertation.

Barts Cancer Institute is a Cancer Research UK Centre of Excellence and one of the leading cancer institutes in the country.
Based in the heart of London, our programmes are all taught by experts in the field.

Find out more about the BCI at http://www.bci.qmul.ac.uk/study-with-us

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This programme aims to provide you with a clear understanding of the scientific basis underlying the principles and practice of clinical oncology and the development, evaluation and implementation of new treatments. Read more
This programme aims to provide you with a clear understanding of the scientific basis underlying the principles and practice of clinical oncology and the development, evaluation and implementation of new treatments.

This will be underpinned by a thorough knowledge of cancer biology and pathology, drug development and research methodologies.

This knowledge will provide you with a good grounding in oncology within a clinical setting which will enhance prospects for those wanting to pursue a clinical academic career.

Compulsory Modules

• Ablative Therapies
• Cancer Biology
• Cancer Pharmacology
• Cancer Prevention & Screening
• Drug Development
• Genomic Approaches to Human Diseases
• Imaging
• Paediatric & Adolescent Oncology
• Pathology of Cancer
• Research Methods
• Site Specific Tumour Treatment

Elective Modules

• Biological Therapies
• Molecular Targeted Therapies and Immunotherapy for Blood Cancer

Core Module for MSc

• Dissertation

Barts Cancer Institute is a Cancer Research UK Centre of Excellence and one of the leading cancer institutes in the country.
Based in the heart of London, all our programmes are taught by experts in the field.

To find out more about BCI visit http://www.bci.qmul.ac.uk/study-with-us

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Lead academic 2016. Dr Carolyn Staton. Translational oncology is the process by which laboratory research informs the development of new treatments for cancer. Read more

About the course

Lead academic 2016: Dr Carolyn Staton

Translational oncology is the process by which laboratory research informs the development of new treatments for cancer. It’s a rapidly advancing field with massive therapeutic and commercial potential.

Our MSc(Res) is taught by leading research scientists and clinicians. The course offers training in the theory and practice of translational oncology and provides you with transferable skills for your future career. It includes a six-month research project for which you’ll work as part of a team within the oncology research community at Sheffield.

Our study environment

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

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

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

How we teach

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

Our resources

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

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

Hepatitis B policy

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

Core modules

Cellular and Molecular Basis of Cancer; Cancer Epidemiology; Cancer Diagnosis and Treatment; Tumour Microenvironment; Cancer Technologies and Clinical Research; Literature Review; Research Project.

Teaching and assessment

Teaching is by lectures, seminars, class discussions/workshops, interactive tutorials, practical demonstrations, student-led group work and patient encounters.

Alongside the taught modules students attend the Sheffield Cancer Research seminars which include question and answer sessions with the experts, and a series of professional skills development tutorials.

Assessment is by a combination of written seen exams, oral and poster presentations, case studies and written assignments. The research project is assessed by an oral presentation and a written dissertation.

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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 programme offers a fascinating range of subjects, including molecular biology, genetics, biochemistry, microbiology, immunology, tissue engineering, clinical medicine, laboratory management and statistics. Read more
This programme offers a fascinating range of subjects, including molecular biology, genetics, biochemistry, microbiology, immunology, tissue engineering, clinical medicine, laboratory management and statistics.

It is accredited by the Institute of Biomedical Science and is based at one of the largest transfusion centres in the world, enabling visits to manufacturing, testing and tissue typing sections. You will learn from specialist lecturers based at the University, NHS Blood and Transplant (NHSBT), and NHS hospitals, and have an opportunity to become fully embedded in an NHS environment while you develop your knowledge.

The programme will give you extensive practical experience of transfusion and transplantation, allowing you to gain skills that directly relate to your future career. As well as being academically interesting, this continually developing area of healthcare science has a major impact on patients' quality of life.

The programme:
-Is one of just two specialist full-time courses in transfusion and transplantation, and is a recommended course at level seven in the Career Framework for Health.
-Gives you the opportunity to carry out your MSc project with NHSBT research staff within the transfusion centre.
-Has high contact hours, with teaching each day and practical classes.
-Includes a large skills component (eg writing in different formats, conference and publication skills, assignments with specific study aims).
-Includes laboratory management, a key skill required at level seven.
-Attracts a diverse range of students (about 50 per cent overseas students), including new graduates, those working in blood centres or blood transfusion/haematology in hospitals, or training to lecture in transfusion.

Programme structure

The programme comprises eight taught units that run from September to March and a research project that begins in May and runs until August. Example project topics have included:
-A study on red cell antibody formation in trauma patients
-Optimisation of platelet antigen detection using recombinant proteins
-Expression of red cell membrane proteins during large-scale red cell culture
-A comparison of stem cell mobilisation drugs for stem cell transplantation

Taught units
-Transfusion and Transplantation Science:
-Pathology of Transfusion and Transplantation Science
-Provision of Blood, Cells, Tissues and Organs
-Clinical Transfusion and Transplantation
-Transfusion and Transplantation in Practice (two units)
-Biostatistics
-Research and Laboratory Management

Assessments are designed to teach skills such as comprehension, scientific writing in different formats and conference skills, and to further knowledge in subject areas not covered in the lectures. Students must pass the taught component to be able to progress to the project.

Part-time students complete the Postgraduate Certificate components in their first year and the Postgraduate Diploma in the second. The project is usually taken during year three to complete the MSc.

Careers

Some of the career paths that graduates have followed include: blood transfusion and fetal medicine research, working for a bone marrow donor laboratory or bone marrow registry, biostatistics, graduate entry to medical school, NHS Clinical Scientist Training programme, and progression to PhD study in several areas including cancer biology and stem cell regeneration.

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Despite the fact that we have improved methods of detection and have developed many novel therapies, cancer is still a major killer worldwide. Read more
Despite the fact that we have improved methods of detection and have developed many novel therapies, cancer is still a major killer worldwide. This course aims to inform and equip the practitioner with the necessary skills to function in a modern biomedical/clinical environment specialising in caring for the cancer patient, and will be relevant to researchers, day-to-day NHS hospital practice and general practice.

Why Study Oncology with us?

You will receive training in the skills required in the reading and interpretation of the literature and translating that into evidence-based practice. The course culminates in the Research Dissertation, which will be assessed through your production of two publishable scientific articles.

The content of the course is mapped to The Joint Royal Colleges of Physicians Training Board Speciality Training Curriculum for Medical Oncology.

If biomedical or clinical research is your interest, successful completion of the MSc will allow you to directly register onto PhD study and join our team of researchers at the Institute of Medicine.

What will I learn?

We will discuss mechanistic models of tumour formation and how knowledge of the cell biology can inform the treatment of a cancer. Blood-borne hormones and cytokines can be used as biomarkers of cancer and we will examine the problems associated with some of these measurements. You will evaluate new developments in research into oncology, and carry out a research project.

Seminars and tutorials will be held with various healthcare professionals and clinical researchers. You will also attend cancer clinics in one of our partner hospital trusts.

How will I be taught?

Our course consists of taught modules and a Research Dissertation.

We deliver taught modules as three-day intensive courses to facilitate attendance from students in employment. Weekly support sessions and journal club supplement learning – all held in our modern facilities in Bache Hall.
The total number of contact hours for the whole course are 360 hours, out of a total study time of 1,800 hours.

How will I be assessed?

You will be assessed via clinical reviews, laboratory reports, posters, oral presentations, or data manipulation exercises.

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The only Master’s specialisation in the Netherlands covering the function of our epigenome, a key factor in regulating gene expression and in a wide range of diseases. Read more

Master's specialisation in Medical Epigenomics

The only Master’s specialisation in the Netherlands covering the function of our epigenome, a key factor in regulating gene expression and in a wide range of diseases.
Our skin cells, liver cells and blood cells all contain the same genetic information. Yet these are different types of cells, each performing their own specific tasks. How is this possible? The explanation lies in the epigenome: a heritable, cell-type specific set of chromosomal modifications, which regulates gene expression. Radboud University is specialised in studying the epigenome and is the only university in the Netherlands to offer a Master’s programme in this field of research.

Health and disease

The epigenome consists of small and reversible chemical modifications of the DNA or histone proteins, such as methylation, acetylation and phosphorylation. It changes the spatial structure of DNA, resulting in gene activation or repression. These processes are crucial for our health and also play a role in many diseases, like autoimmune diseases, cancer and neurological disorders. As opposed to modifications of the genome sequence itself, epigenetic modifications are reversible. You can therefore imagine the great potential of drugs that target epigenetic enzymes, so-called epi-drugs.

Big data

In this specialisation, you’ll look at a cell as one big and complex system. You’ll study epigenetic mechanisms during development and disease from different angles. This includes studying DNA and RNA by next-generation sequencing (epigenomics) and analysing proteins by mass spectrometry (proteomics). In addition, you‘ll be trained to design computational strategies that allow the integration of these multifaceted, high-throughput data sets into one system.

Why study Medical Epigenomics at Radboud University?

- Radboud University combines various state-of-the-art technologies – such as quantitative mass spectrometry and next-generation DNA sequencing – with downstream bioinformatics analyses in one department. This is unique in Europe.
- This programme allows you to work with researchers from the Radboud Institute for Molecular Life sciences (RIMLS), one of the leading multidisciplinary research institutes within this field of study worldwide.
- We have close contacts with high-profile medically oriented groups on the Radboud campus and with international institutes (EMBL, Max-Planck, Marie Curie, Cambridge, US-based labs, etc). As a Master’s student, you can choose to perform an internship in one of these related departments.
- Radboud University coordinates BLUEPRINT, a 30 million Euro European project focusing on the epigenomics of leukaemia. Master’s students have the opportunity to participate in this project.

Career prospects

As a Master’s student of Medical Epigenomics you’re trained in using state-of-the art technology in combination with biological software tools to study complete networks in cells in an unbiased manner. For example, you’ll know how to study the effects of drugs in the human body.
When you enter the job market, you’ll have:
- A thorough background of epigenetic mechanisms in health and disease, which is highly relevant in strongly rising field of epi-drug development
- Extensive and partly hands-on experience in state-of-the-art ‘omics’ technologies: next-generation sequencing, quantitative mass spectrometry and single cell technologies;
- Extensive expertise in designing, executing and interpreting scientific experiments in data-driven research;
- The computational skills needed to analyse large ‘omics’ datasets.

With this background, you can become a researcher at a:
- University or research institute;
- Pharmaceutical company, such as Synthon or Johnson & Johnson;
- Food company, like Danone or Unilever;
- Start-up company making use of -omics technology.

Apart from research into genomics and epigenomics, you could also work on topics such as miniaturising workflows, improving experimental devices, the interface between biology and informatics, medicine from a systems approach.

Or you can become a:
- Biological or medical consultant;
- Biology teacher;
- Policy coordinator, regarding genetic or medical issues;
- Patent attorney;
- Clinical research associate;

PhD positions at Radboud University

Each year, the Molecular Biology department (Prof. Henk Stunnenberg, Prof. Michiel Vermeulen) and the Molecular Developmental Biology department (Prof. Gert-Jan Veenstra) at the RIMLS offer between five and ten PhD positions. Of course, many graduates also apply for a PhD position at related departments in the Netherlands, or abroad.

Our approach to this field

- Systems biology
In the Medical Epigenomics specialisation you won’t zoom in on only one particular gene, protein or signalling pathway. Instead, you’ll regard the cell as one complete system. This comprehensive view allows you to, for example, model the impact of one particular epigenetic mutation on various parts and functions of the cell, or study the effects of a drug in an unbiased manner. One of the challenges of this systems biology approach is the processing and integration of large amounts of data. That’s why you’ll also be trained in computational biology. Once graduated, this will be a great advantage: you’ll be able to bridge the gap between biology, technology and informatics , and thus have a profile that is desperately needed in modern, data-driven biology.

- Multiple OMICS approaches
Studying cells in a systems biology approach means connecting processes at the level of the genome (genomics), epigenome (epigenomics), transcriptome (transcriptomics), proteome (proteomics), etc. In the Medical Epigenomics specialisation, you’ll get acquainted with all these different fields of study.

- Patient and animal samples
Numerous genetic diseases are not caused by genetic mutations, but by epigenetic mutations that influence the structure and function of chromatin. Think of:
- Autoimmune diseases, like rheumatoid arthritis and lupus
- Cancer, in the forms of leukaemia, colon cancer, prostate cancer and cervical cancer
- Neurological disorders, like Rett Syndrome, Alzheimer, Parkinson, Multiple Sclerosis, schizophrenia and autism

We investigate these diseases on a cellular level, focusing on the epigenetic mutations and the impact on various pathways in the cell. You’ll get the chance to participate in that research, and work with embryonic stem cell, patient, Xenopus or zebra fish samples.

See the website http://www.ru.nl/masters/medicalbiology/epigenomics

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Lead academic 2016. Dr Martin Nicklin. This flexible course focuses on the molecular and genetic factors of human diseases. Understanding those factors is crucial to the development of therapies. Read more

About the course

Lead academic 2016: Dr Martin Nicklin

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

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

Our study environment

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

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

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

How we teach

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

Our resources

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

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

Hepatitis B policy

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

Core modules

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

1. Genetic Mechanisms pathway:


Modelling Protein Interactions; Gene Networks: Models and Functions.

2. Microbes and Infection pathway:


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

3. Experimental Medicine pathway:


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

4. Cancer pathway:

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

5. Cardiovascular pathway:

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

6. Clinical Applications pathway:

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

Teaching and assessment

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

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

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The Institute of Genetic Medicine brings together a strong team with an interest in clinical and developmental genetics. Our research focuses on the causes of genetic disease at the molecular and cellular level and its treatment. Read more
The Institute of Genetic Medicine brings together a strong team with an interest in clinical and developmental genetics. Our research focuses on the causes of genetic disease at the molecular and cellular level and its treatment. Research areas include: genetic medicine, developmental genetics, neuromuscular and neurological genetics, mitochondrial genetics and cardiovascular genetics.

As a research postgraduate in the Institute of Genetic Medicine you will be a member of our thriving research community. The Institute is located in Newcastle’s Life Science Centre. You will work alongside a number of research, clinical and educational organisations, including the Northern Genetics Service.

We offer supervision for MPhil in the following research areas:

Cancer genetics and genome instability

Our research includes:
-A major clinical trial for chemoprevention of colon cancer
-Genetic analyses of neuroblastoma susceptibility
-Research into Wilms Tumour (a childhood kidney cancer)
-Studies on cell cycle regulation and genome instability

Cardiovascular genetics and development

We use techniques of high-throughput genetic analyses to identify mechanisms where genetic variability between individuals contributes to the risk of developing cardiovascular disease. We also use mouse, zebrafish and stem cell models to understand the ways in which particular gene families' genetic and environmental factors are involved in the normal and abnormal development of the heart and blood vessels.

Complex disease and quantitative genetics

We work on large-scale studies into the genetic basis of common diseases with complex genetic causes, for example autoimmune disease, complex cardiovascular traits and renal disorders. We are also developing novel statistical methods and tools for analysing this genetic data.

Developmental genetics

We study genes known (or suspected to be) involved in malformations found in newborn babies. These include genes involved in normal and abnormal development of the face, brain, heart, muscle and kidney system. Our research includes the use of knockout mice and zebrafish as laboratory models.

Gene expression and regulation in normal development and disease

We research how gene expression is controlled during development and misregulated in diseases, including the roles of transcription factors, RNA binding proteins and the signalling pathways that control these. We conduct studies of early human brain development, including gene expression analysis, primary cell culture models, and 3D visualisation and modelling.

Genetics of neurological disorders

Our research includes:
-The identification of genes that in isolation can cause neurological disorders
-Molecular mechanisms and treatment of neurometabolic disease
-Complex genetics of common neurological disorders including Parkinson's disease and Alzheimer's disease
-The genetics of epilepsy

Kidney genetics and development

Kidney research focuses on:
-Atypical haemolytic uraemic syndrome (aHUS)
-Vesicoureteric reflux (VUR)
-Cystic renal disease
-Nephrolithiasis to study renal genetics

The discovery that aHUS is a disease of complement dysregulation has led to a specific interest in complement genetics.

Mitochondrial disease

Our research includes:
-Investigation of the role of mitochondria in human disease
-Nuclear-mitochondrial interactions in disease
-The inheritance of mitochondrial DNA heteroplasmy
-Mitochondrial function in stem cells

Neuromuscular genetics

The Neuromuscular Research Group has a series of basic research programmes looking at the function of novel muscle proteins and their roles in pathogenesis. Recently developed translational research programmes are seeking therapeutic targets for various muscle diseases.

Stem cell biology

We research human embryonic stem (ES) cells, germline stem cells and somatic stem cells. ES cell research is aimed at understanding stem cell pluripotency, self-renewal, survival and epigenetic control of differentiation and development. This includes the functional analysis of genes involved in germline stem cell proliferation and differentiation. Somatic stem cell projects include programmes on umbilical cord blood stem cells, haematopoietic progenitors, and limbal stem cells.

Pharmacy

Our new School of Pharmacy has scientists and clinicians working together on all aspects of pharmaceutical sciences and clinical pharmacy.

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This Biomedical Sciences degree offers research training for students in order to gain all the required Biomedical Sience entry requirements to proceed to a PhD. Read more
This Biomedical Sciences degree offers research training for students in order to gain all the required Biomedical Sience entry requirements to proceed to a PhD. It is largely based on individual research projects rather than coursework, and allows you to specialise in a particular area of study.

Why this programme

◾Ranked world top 100 for Biological Sciences
◾The Masters in Biomedical Science provides training in a wide range of modern molecular biology techniques required to pursue a research career.
◾You will gain valuable practical research experience by using the skills and techniques acquired during the programme to complete two extensive research projects.
◾The Biomedical Science programme is distinctive in that students complete two different extensive research projects of their choice, allowing them to acquire a wide range of knowledge and skills directly relevant to the study of human disease.
◾If you are aiming to study for a higherBiomedical Science degree , this programme is designed for you.
◾If you want to enter the pharmaceutical and biotechnology industries, this programme provides excellent training; and is an ideal introduction for overseas students who may wish to proceed to PhD biomedical science studies in the UK.
◾You can choose to specialise within a particular discipline or area, which can be important for career development, see programme structure below for more information.

Programme structure

The overall aims of the programme are:
◾to provide students with the knowledge, skills and confidence needed to pursue a career in laboratory research.
◾to provide students with a theoretical and practical understanding of advanced techniques used in modern biomedical sciences research.
◾to provide students with the opportunity to practice research skills in the laboratory by completing two extensive research projects.

MRes students have the opportunity to specialise in a particular discipline or area, which can be important for their career development. The specialisations are:
◾Biotechnology
◾Cancer Studies
◾Cardiovascular Studies
◾Cell Engineering
◾Integrative Mammalian Biology SFC funded places available

◾Medical Biochemistry and Molecular Biology
◾Molecular Genetics
◾Neuroscience
◾Proteomics

To qualify for a specialisation, students must select two research projects in a cognate research area.

Research projects

The central and most important part of the MRes is the two research projects that students undertake. Students choose both projects themselves in the subject areas that interest them and that will allow them to follow the career path they wish to follow. The MRes programme has a huge number of projects which students can choose from, across a wide spectrum of biomedical science.

The following are examples of the types of projects offered, to illustrate the range of subject areas.

• Making blood from human embryonic stem cells

• A gene-microarray based approach to the detection of recombinant human erythropoietin doping in endurance athletes

• Neuropathology of trypanosomiasis

• Development of a new technique for stem cell transfection

• Cloning and analysis of an inflammatory factor in cancer and autoimmune disease

• Analysis of viral induced cancer

Each year students have about 100 different projects to choose from and all students find research topics that interest them.

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