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Take advantage of one of our 100 Master’s Scholarships to study Medicine and Life Sciences 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 Medicine and Life Sciences 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.

The MRes in Medicine and Life Sciences provides an ideal opportunity and environment in which to gain practical training in Research Methods and to join a thriving research team within Swansea University Medical School. The Medicine and Life Sciences course has been developed with an emphasis on providing students with a research-oriented approach to their learning.

Students are able to tailor their studies towards a career in one of the School's internationally recognised research themes:

– Biomarkers and Genes,
– Devices,
– Microbes and Immunity,
– Patient & Population Health and Informatics.

Key Features

The Medicine and Life Sciences programme is committed to supporting the development of evidence within the areas of Health, Medicine and Life Science through the training of researchers whose findings will directly inform their own understanding and that of others. The ethos of this programme in Medicine and Life Sciences is to produce graduates with the research skills and knowledge to become effective researchers, who will contribute to the body of knowledge within their chosen area of interest that will have an impact upon the health and well-being of all.

The advantage of an MRes over other formats is that it provides a structured yet in-depth approach, taking the taught component of FHEQ Level 7 teaching as a framework for conducting research on the candidate's own practice.
Innovative and integrated curriculum that reflects the various aspects of the research process.
Multidisciplinary teaching team with vast experience and expertise in conducting high quality research.
Research informed teaching.
Teaching is supported by online learning and support.
Flexibility for you to gain specialist knowledge.
A one year full-time taught masters programme designed to develop the essential skills and knowledge required for a successful research career.
This Medicine and Life Sciences course is also available for two years part-time study.
The opportunity to conduct an individual research project with an interdisciplinary team within a supportive environment.
Students will be assigned a research-active supervisory team

The aim of the MRes Medicine and Life Sciences is to provide students with broad research training to prepare them for a research career in Medical and Life Science research with emphasis on: Biomarkers & Genes, Devices, Microbes & Immunity, Patient & Population Health and Informatics. The course has been developed to enable graduates to pursue a variety of research careers in Medical and Life Sciences. The Medicine and Life Sciences programme comprises both taught and research elements.

By the end of the programme students will have:

Developed necessary skills to critically interpret and evaluate research evidence; Gained experience in analysis and interpretation of research data; Advanced knowledge at the forefront of Medical and Life Science research, with the ability to integrate the theoretical and practical elements of research training; Developed the ability to conceptualise, design and implement a research project for the generation of new evidence that informs Health, Medicine and Life Science; Developed practical research skills by working with an interdisciplinary research team; The ability to confidently communicate research ideas and conclusions clearly and effectively to specialist and non-specialist audiences; Acquired transferable skills which enhance your employability and future research career.

Course Structure

Students must complete 3 modules of 20 credits each and produce a 120 credits thesis on a research project aligned to one of the School’s research themes. Each taught module of the programme requires a short period of attendance that is augmented by preparatory and reflective material supplied via the course website before and after attendance.

The Medicine and Life Sciences programme is designed in two phases:

Phase 1 – Training and Application (October – January; 60 credits)

Taught modules in Research Methods and their application to Medicine and Life Science. Personalised education and training relevant to student’s research interests. Identification of research questions and how they might be addressed. Focus on students' existing knowledge and research skills.

Phase 2 – Research Project (February – September; 120 credits)

The project is selected by the student in combination with an academic supervisory team. Focussed on one of the School’s four main research themes: Biomarkers and Genes, Devices, Microbes and Immunity, and Patient & Population Health and Informatics. At the end of Part 2 students submit a 40,000 word thesis worth 120 credits leading to the award of Master of Research in Medicine and Life Science.

Modules on the MRes Medicine and Life Sciences typically include:

Critical Appraisal and Evaluation
Data Analysis for Health and Medical Sciences
Research Leadership and Project Management OR any topic specific FHEQ Level 7 module from the Medical School's portfolio

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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

Programme Overview

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.

Research Supervision

Exploratory biology, target and biomarker discovery
Molecular genetic and mechanistic studies are used to identify critical molecular changes in cancer and their relevance to disease development and progression, and to validate these as biomarkers and targets for therapeutic intervention. A wide range of contemporary genomic, bioinformatic, molecular biology, biochemical and cell biology techniques are used.

Studies focus on haematological malignancies (leukaemia and lymphoma), paediatric solid tumours (neuroblastoma and medulloblastoma), and adult solid tumours (eg breast, ovarian, prostate, bladder and liver cancers).

Drug development
The exploitation of novel targets is achieved by the use of rational drug design, notably the use of structure-based design, in conjunction with medium-throughput screening. Target molecule synthesis and multiple parallel synthesis approaches are used for lead optimisation, and candidate drugs are evaluated in cell-free and whole cell target-based assays.

Biomarker development
We exploit critical molecular defects as biomarkers to enhance disease detection and diagnosis, prediction of disease course, sensitivity to specific drugs and therapeutic monitoring. We play leading roles in molecular diagnostics, biomarker assessment and therapeutic monitoring for national and international clinical trials.

Clinical trials
Clinical trials (Phase I/II/III) are undertaken in both adults and children. Trials have a strong hypothesis-testing translational research component and are performed under the auspices of national or international research networks (eg CR–UK, CCLG, EORTC), as well as directly in collaboration with the pharmaceutical industry.

Training and Skills

As a research student you will receive a tailored package of academic and support elements to ensure you maximise your research and future career. The academic information is in the programme profile and you will be supported by our Faculty of Medical Sciences Graduate School.

For further information see http://www.ncl.ac.uk/postgraduate/courses/degrees/cancer-mphil-phd-md/#training&skills

How to apply

For course application information see http://www.ncl.ac.uk/postgraduate/courses/degrees/cancer-mphil-phd-md/#howtoapply

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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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Cellular pathology is the study of structural and functional changes in cells, tissues and organs that underlie disease. It is a dynamic, fast-evolving specialism which saves many lives by providing rational clinical care and therapy in the fight against many serious diseases, particularly cancer. Read more
Cellular pathology is the study of structural and functional changes in cells, tissues and organs that underlie disease. It is a dynamic, fast-evolving specialism which saves many lives by providing rational clinical care and therapy in the fight against many serious diseases, particularly cancer.


Why study MSc Cellular Pathology at Middlesex?

Our Biomedical Science courses have a burgeoning international reputation, due to our world-class research in areas including biomarkers, public health and biomodelling. Our Centre for Investigative and Diagnostic Oncology has pioneered techniques for cancer diagnosis and treatment, including our breakthrough in the development of a vaccine for bladder cancer.

Our course has a strong practical element, with an emphasis on developing the skills needed in a laboratory and gaining hands-on experience of diagnostic techniques, and our teaching and research facilities surpass those at some UK medical schools. Our £3 million specialist labs are equipped with the most up-to-date technology; here you'll learn to use cutting-edge techniques and equipment for cellular and molecular analysis, such as MALDI-TOF mass spectrometers, flow cytometers, DNA sequencing, real-time PCR, electrophoresis and high-performance liquid chromatography, histology and confocal microscopy. We also have fully-equipped proteomics facilities, a histopathology lab and an incredibly modern cell culture facility.

Course highlights

- All our teaching staff are involved in research and many are pioneers in their own field. Course leader Professor Lucy Ghali is an expert in immunohistochemistry; other teaching staff include Dr Frank Hills, a former clinical scientist at St Bartholomew's Hospital; Dr Ajit Shah, a former principal scientist at GlaxoSmithKline; Sandra Appiah, a former research scientist at Leatherhead Food Research; and Professor Stephen Dilworth, Professor Lucy Ghali and Dr Song Wen are world experts on cancer and Biomarkers.
- 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.
- 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.
- Our flexible timetable means you'll only spend two days a week at university if you're studying full-time, or one if you're part-time.

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Bioimaging sciences have played a vital role in improving human life. Read more
Bioimaging sciences have played a vital role in improving human life. A wide range of imaging techniques such as magnetic resonance imaging (MRI), positron emission tomography (PET), ultrasound and optical imaging are now important tools for the early detection of disease, understanding basic molecular aspects of living organisms and the evaluation of medical treatment.

This one-year MRes course covers the fundamentals of modern imaging methodologies, including their techniques and application within medicine and the pharmaceutical industry, along with the chemistry behind imaging agents and biomarkers.

Imperial's research strength in imaging sciences is recognised both nationally and internationally, as exemplified by the creation of Imperial's Imaging Sciences Centre (ISC).

The course will progress interdisciplinary development in imaging sciences and create a multidisciplinary team involving chemists, immunologists, radiologists, image scientists, physicists, biomedical scientists and computer scientists.

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Analytical bioscience - the investigation of biomolecules as exploitable biomarkers - is a growing field, driven by improving analytical methods with increasing sensitivity. Read more
Analytical bioscience - the investigation of biomolecules as exploitable biomarkers - is a growing field, driven by improving analytical methods with increasing sensitivity. Following completion of the Human Genome Project, the pharmaceutical industry is preparing for a revolution in cancer and inherited disorder therapies.

This course is training a new generation of bioscientists to meet challenges at the interface between biology and chemistry, and to apply pharmaceutical and analytical knowledge directly to improve quality of life.

Please note: this course was previously called Analytical Bioscience and Drug Design.

Key benefits:

• Train for a career in the newly emerging industries of the post-genomic era
• Work at the interface between biology and chemistry – a truly multidisciplinary Masters degree
• Excellent career prospects in pharmaceuticals and biotechnology

Visit the website: http://www.salford.ac.uk/pgt-courses/drug-design-and-discovery

Suitable for:

This course is aimed at students who wish to acquire the specialised skills needed to design drugs for the 21st century.

Course content

This course is designed to enable you to gain a systematic knowledge, critical awareness of current problems and new insights regarding the analysis of biomolecules. There is particular reference to drug design and discovery, along with a comprehensive and critical understanding of applied techniques and their current application in research in the field of biomolecule analysis and drug design.

Format

Teaching is by lectures to provide thorough grounding in the techniques of biomolecule characterisation and drug design.

Practical sessions and workshops demonstrate techniques and methods used in biomolecule characterisation and drug design, and provide a structured opportunity for you to practise techniques and methods in analytical biosciences and drug design.

Guided reading will recommend texts, key articles and other materials in advance of, or following, lecture classes.

The research project will enable you to practice the application of appropriate, and selected, bioscientific techniques in an academic or industrial context, and demonstrate research methodologies and skills appropriate to and valuable with biomolecule characterisation and drug design.

You will be supervised by expert staff who are actively engaged in international research programmes.

Module Titles

• Research Methods 1
• Drug Pharmacology
• Drug Design
• Novel Theraputics
• Analytical Methods
• Natural Products
• Identification of Drugs
• Bioscience Enterprise
• Research Project

Assessment

• Literature Review and Presentation
• Portfolio
• Examination
• Oral Presentation
• Dissertation

Career progression

Although particularly relevant if you are looking for a career in the pharmaceutical and biotechnology industries, this course will also equip you for a career in research, teaching and many other professions including cosmetic science, animal health, food science, medical laboratory research, patent law, scientific journalism and health and safety.

Research projects may be carried out at Salford or other institutions (e.g. universities in Germany, France and the Paterson Institute, UK). We also invite visiting lecturers to share their expertise on the subject areas.

How to apply: http://www.salford.ac.uk/study/postgraduate/applying

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The MRes in Biomedical Research offers advanced research training in a broad range of laboratory based medical science. The emphasis of the course is how to do successful research and the research area is decided by the student. Read more
The MRes in Biomedical Research offers advanced research training in a broad range of laboratory based medical science. The emphasis of the course is how to do successful research and the research area is decided by the student. Participating departments include Biomolecular Medicine, Molecular Medicine, Cancer Medicine, Reproductive and Developmental Biology, Anaesthetics, Pain Medicine and Intensive Care, Biosurgery and Surgical Technology, Leukocyte Biology and Cardiovascular Sciences.

The research interests of the participating departments cover many aspects of molecular, cellular and physiological science including Bacterial virulence, Biomarkers of disease, Bioinformatics, Carcinogenesis, Cancer Biology, Cell Biology, Cell Signalling, Chemokines and their receptors, DNA damage and Repair, Electrophysiology, Immunosuppression, Leukocyte biology, Live cell imaging, Metabolomics/Metabonomics, Microbial Pathogenesis, Molecular Genetics, Molecular Motors, Molecular Pharmacology, Molecular Toxicology, Muscle Physiology, and Vascular Development, Neurological receptors, Nuclear receptors, Sepsis, Single molecule microscopy, Stem Cell Biology.

Students complete two research projects of their own choosing and through a core programme learn how to collect, analyse and interpret scientific research findings. They learn how to prepare data for publication, how to present and defend research data at scientific meetings and how to put together a grant application. The core programme also introduces students to advanced research techniques through a series of workshops and offers students a wide range of transferable skills courses. In addition to the core programme, the course comprises of other streams that offer further opportunities in specific areas. The course is an excellent grounding for students wishing to pursue a career in research and about 90% of past graduates have progressed to the PhD degree.

Please visit the course website for more information about how to apply, and for more information about the streams of specialism which run within the course.

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This programme focuses on interdisciplinary research in the field of innovation and usage of drugs, for example vaccines, gene therapeutics, medical nutrition and antibodies. Read more

DRUG INNOVATION: A UNIQUE PROGRAMME

This programme focuses on interdisciplinary research in the field of innovation and usage of drugs, for example vaccines, gene therapeutics, medical nutrition and antibodies.

Typical research questions addressed in the field of Drug Innovation include:
* How do we make new drugs against resistant microorganisms?
* Which proteins can we target for personalized cancer medicine?
* Can we differentiate stem cells by means of proteomics?
* How can we imprint the immune system to become tolerant?
* What is the connection between gut microbes and brains disease?
* Can we deliver proteins and gens to diseased cells, by learning from viruses and bacteria?
* How can we innovate and speed up the regulatory process of weighing benefit and risk?
* Which biomarkers predict for quality adjusted life years?

As a graduate you will be eligible for many PhD programmes and be able to contribute to drug innovation within research institutes, pharmaceutical and biotechnology companies or health care organisations.

Our programme offers a diverse suite of elective courses. This means you can concentrate on the topics of most interest to you.

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The Department of Oncology and the Department for Continuing Education’s CPD Centre offer a part-time MSc in Experimental Therapeutics that brings together some of Oxford's leading clinicians and scientists to deliver an advanced modular programme designed for those in full-time employment, both in the UK and overseas. Read more
The Department of Oncology and the Department for Continuing Education’s CPD Centre offer a part-time MSc in Experimental Therapeutics that brings together some of Oxford's leading clinicians and scientists to deliver an advanced modular programme designed for those in full-time employment, both in the UK and overseas.

The Programme draws on the world-class research and teaching in experimental therapeutics at Oxford University and offers a unique opportunity to gain an understanding of the principles that underpin clinical research and to translate this into good clinical and research practice.

Visit the website https://www.conted.ox.ac.uk/about/msc-in-experimental-therapeutics

The first deadline for applications is Friday 20 January 2017

If your application is completed by this January deadline and you fulfil the eligibility criteria, you will be automatically considered for a graduate scholarship. For details see: http://www.ox.ac.uk/admissions/graduate/fees-and-funding/graduate-scholarships.

Programme details

The MSc in Experimental Therapeutics is a part-time course consisting of six modules and a research project and dissertation. The programme is normally completed in two to three years. Students are full members of the University of Oxford and are matriculated as members of an Oxford college.

The modules in this programme can also be taken as individual short courses. It is possible to transfer credit from up to three previously completed modules into the MSc programme, if the time elapsed between commencement of the accredited module(s) and registration for the MSc is not more than two years.

Programme modules:

- The Structure of Clinical Trials and Experimental Therapeutics
- Drug Development, Pharmacokinetics and Imaging
- Pharmacodynamics, Biomarkers and Personalised Therapy
- Adverse Drug Reactions, Drug Interactions, and Pharmacovigilance
- How to do Research on Therapeutic Interventions: Protocol Preparation
- Biological Therapeutics

Course aims

The aim of the MSc programme is to provide students with the necessary training and practical experience to enable them to understand the principles that underpin clinical research, and to enable them to translate that understanding into good clinical and research practice.

By the end of the MSc programme, students should understand the following core principles:

- Development, marketing and regulations of drugs
- Pharmaceutical factors that affect drug therapy
- Pharmacokinetics, pharmacogenetics and pharmacodynamics
- Adverse drug reactions, drug interactions, and pharmacovigilance
- Designing phase I, II and III clinical trials for a range of novel therapeutic interventions (and imaging agents).
- Application of statistics to medicine
- Laboratory assays used to support trial end-points
- Use of non-invasive imaging in drug development
- Application of analytical techniques

By the end of the programme, students should be equipped to:

- demonstrate a knowledge of the principles, methods and techniques for solving clinical research problems and translate this into good clinical and research practice
- apply skills gained in techniques and practical experience from across the medical and biological sciences
- develop skills in managing research-based work in experimental therapeutics
- carry out an extended research project involving a literature review, problem specification and analysis in experimental therapeutics and write a short dissertation

Guidance from the UK Royal College of Physician's Faculty of Pharmaceutical Medicine

The Faculty have confirmed that if enrolled for Pharmaceutical Medicine Specialty Training (PMST), trainees may be able to use knowledge provided by Experimental Therapeutics modules to cover aspects of a module of the PMST curriculum. Trainees are advised to discuss this with their Educational Supervisor.

Experimental Therapeutics modules may also be used to provide those pursuing the Faculty's Diploma in Pharmaceutical Medicine (DPM) with the necessary knowledge required to cover the Diploma syllabus. Applicants for the DPM exam are advised to read the DPM syllabus and rules and regulations.

Members of the Faculty of Pharmaceutical Medicine who are registered in the Faculty's CPD scheme can count participation in Experimental Therapeutics modules towards their CPD record. Non-members may wish to obtain further advice about CPD credit from their Royal College or Faculty.

Assessment methods

To complete the MSc, students need to:

Attend the six modules and complete an assessed written assignment for each module.
Complete a dissertation on a topic chosen in consultation with a supervisor and the Course Director.

Dissertation:
The dissertation is founded on a research project that builds on material studied in the taught modules. The dissertation should normally not exceed 15,000 words.

The project will normally be supervised by an academic supervisor from the University of Oxford, and an employer-based mentor.

The following are topics of dissertations completed by previous students on the course:

- The outcomes of non-surgical management of tubal pregnancy; a 6 month study of the South East London population

- Analysis of the predictive and prognostic factors of outcome in a cohort of patients prospectively treated with perioperative chemotherapy for adenocarcinoma of the stomach or of the gastroesophageal junction

- Evolution of mineral and bone disorder in early Chronic Kidney Disease (CKD): the role of FGF23 and vitamin D

- Survey of patients' knowledge and perception of the adverse drug reporting scheme (yellow cards) in primary care

- The predictive role of ERCC1 status in oxaliplatin based Neoadjuvant for metastatic colorectal cancer (CRC) to the liver

- Endothelial Pathophysiology in Dengue - Dextran studies during acute infection

- Literature review of the use of thalidomide in cancer

- An investigation into the phenotypical and functional characteristics of mesenchymal stem cells for clinical application

- Identification of genetic variants that cause capecitabine and bevacizumab toxicity

- Bridging the evidence gap in geriatric medicines via modelling and simulations

Teaching methods

The class-based modules will include a period of preparatory study, a week of intensive face-to-face lectures and tutorials, followed by a period for assignment work. Attendance at modules will be a requirement for study. Some non-classroom activities will be provided at laboratory facilities elsewhere in the University. The course will include taught material on research skills. A virtual learning environment (VLE) will provide between-module support.

The taught modules will include group work, discussions, guest lectures, and interaction and feedback with tutors and lecturers. Practical work aims to develop the students' knowledge and understanding of the subject.

Find out how to apply here - http://www.ox.ac.uk/admissions/graduate/applying-to-oxford

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The range of research topics for our Ageing MPhil, PhD and MD programmes is diverse. They include. biology of ageing; age-related diseases; ageing health and society; technology; nutrition and oral health; and ethics. Read more

Course overview

The range of research topics for our Ageing MPhil, PhD and MD programmes is diverse. They include: biology of ageing; age-related diseases; ageing health and society; technology; nutrition and oral health; and ethics.

Increased life expectancy is one of the most notable human achievements of the last century. We are living longer, and our quality of life depends on healthy ageing. Older people are at increased risk of disease and disability. This can seriously affect their quality of life and impact on their families. This is why Newcastle's research and treatment of our ageing population is important for us all.

MPhil, PhD and MD supervision is normally available in the following areas: Biological mechanisms of ageing (Intrinsic cellular and molecular mechanisms and biomarkers of the ageing process); Clinical studies of age-related diseases (Experimental medicine and translation of basic science for patient benefits); Ageing health and society (The social dimensions of population ageing, and health care policy and provision); Technology for an ageing population (Research and development of innovative assistive technologies to support independence and quality of life); Nutrition and oral health (The role of nutritional factors in healthy ageing and the impacts of oral health); Ethics, philosophy and engagement (Ethics and principles underlying attempts to improve the quality of later life. This includes working with older people and their representative organisations).

Training and Skills

As a research student you will receive a tailored package of academic and support elements to ensure you maximise your research and future career. The academic information is in the programme profile and you will be supported by our Faculty of Medical Sciences Graduate School.

For further information see http://www.ncl.ac.uk/postgraduate/courses/degrees/ageing-mphil-phd-md/#training&skills

How to apply

For course application information see http://www.ncl.ac.uk/postgraduate/courses/degrees/ageing-mphil-phd-md/#howtoapply

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One of the most rapidly developing areas of toxicology is the use of molecular, cell biology and omics to identify adverse outcome pathways (AOPs) and to develop a mechanistic understanding of chemical toxicity at the cellular and molecular level. Read more
One of the most rapidly developing areas of toxicology is the use of molecular, cell biology and omics to identify adverse outcome pathways (AOPs) and to develop a mechanistic understanding of chemical toxicity at the cellular and molecular level. This is not only of fundamental interest (i.e., understanding the mechanism of action) but it also relates to an increased need for a mechanistic component in chemical risk assessment and development of high throughput screens for chemical toxicity.

The MRes in Molecular Mechanistic Toxicology is a one-year full-time programme that provides students with a research-orientated training in a lively, highly interactive teaching and research environment.

Programme content

The programme is coordinated by the School of Biosciences, which is recognised internationally as a major centre for both teaching and research in Toxicology. Molecular Toxicology is a major component of the School of Biosciences research activities along with interactions with other departments including Chemistry and the Medical School.

Specific areas of active research include:

- Mechanisms of cell toxicity
- Development of novel DNA binding chemicals
- Cellular proliferation and differentiation
- Environmental genomics and metabolomics
- Molecular biomarkers of genotoxicity, oxidative stress and cellular responses
- Role of environmental and genetic factors in disease
- Learning and teaching

Two five-week taught modules are held in Semester 1 in conjunction with the taught MSc in Toxicology programme. Training in generic and laboratory research skills is also an important element of the programme. The programme also includes a six-month research project, which provides students with an opportunity for further advanced research training and hands-on experience of molecular and cellular biology techniques embedded in a research laboratory. Research projects can take place either in academic or industrial institutions.

About the School of Biosciences

As one of the top biosciences departments in the UK, our research covers the entire spectrum of cutting-edge biosciences. We are home to the Institute of Microbiology and Infection and part of the University’s Systems Science for Health initiative.
Our research focuses on a number of important themes that run through modern biological and biochemical research: Biosystems and Environmental Change; Microbiology and Infection; Molecules, Cells, Signalling and Health; and Plant Science.
Our postgraduate students join a diverse international community of staff and students. For students on research degrees, the annual Biosciences Graduate Research Symposium, organised by PhD students, is an example of an event where the whole School comes together to talk about science.
We have extensive high-technology facilities in areas such as functional genomics, proteomics and metabolomics, including a world-class Advanced Mass Spectrometry Facility. Our cutting-edge facilities extend to protein structure determination and analysis, confocal microscopy, drug discovery, horticulture, structural biology and optical imaging. The £8 million Phenome Centre Birmingham is a large metabolic phenotyping facility led by internationally recognised metabolomics and clinical experts at the University of Birmingham, in collaboration with Birmingham Health Partners.

Funding and Scholarships

There are many ways to finance your postgraduate study at the University of Birmingham. To see what funding and scholarships are available, please visit: http://www.birmingham.ac.uk/pgfunding

Open Days

Explore postgraduate study at Birmingham at our on-campus open days.
Register to attend at: http://www.birmingham.ac.uk/pgopendays

Virtual Open Days

If you can’t make it to one of our on-campus open days, our virtual open days run regularly throughout the year. For more information, please visit: http://www.pg.bham.ac.uk

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The course combines an introduction to the theory behind and technologies currently used in drug discovery, pharmacokinetics, role of biomarkers and surrogate endpoints, preclinical safety assessment, first-time-in-human studies, clinical investigation paradigms, research governance and medical statistics. Read more
The course combines an introduction to the theory behind and technologies currently used in drug discovery, pharmacokinetics, role of biomarkers and surrogate endpoints, preclinical safety assessment, first-time-in-human studies, clinical investigation paradigms, research governance and medical statistics.

Suitable for all medical disciplines, but of particular interest to Cardiovascular/Respiratory, Neuroscience, Oncology, and Metabolic medicine, the programme is highly suitable for graduates in medicine who wish to pursue a career as clinical academics and for medical professionals in industry.

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Overview. Advances in molecular biology have enabled major developments in biotechnology which in turn has lead to huge advances in medicine, molecular biology and industry. Read more
Overview
Advances in molecular biology have enabled major developments in biotechnology which in turn has lead to huge advances in medicine, molecular biology and industry. Students choosing this MSc degree will enjoy a comprehensive course that covers the key aspects of practical and theoretical medically-related molecular biology, developing advanced skills in this area.

Description
The course is composed of a modular 120-credit taught component and a 60-credit research project and dissertation. The taught component covers a broad range of medical molecular topics and techniques and includes thorough laboratory training. The course is run in conjuncture with our School of Medicine to ensure that students gain a broad view of modern molecular biology and laboratory techniques.

Overseas Students
A two-year course aimed at students from non-European Union countries who come to the UK requiring pre-MSc level training in English language and basic pre-MSc molecular biology. The first year of this course will bring students up to a level where they will be capable of studying for a full MSc degree and it will develop English language skills to the minimum level required for MSc level learning. Year one will be run in conjunction with ELCOS (English Language Courses for Overseas Students). Students can obtain the minimal English certification for MSc entry.

Module list (1st year of English-life sciences modules)
The English language content and life sciences teaching are integrated to enable students to undertake MSc level life-sciences modules through the medium of English

Life-sciences for none native English speakers - 50 credits
Academic Writing & Grammar
Speaking & Listening
Ad.Vocabulary Use & Reading
Near Native English 1
Near Native English 2

Modules list: (for first year of 1 year course and 2nd year of 2 year course)

Semester 1
Molecular and Medical Techniques
Techniques of molecular biology and biotechnology
Medical microbes viruses and parasites
Development, cancer and the human body
Genomes and Genetics
IT skills for medical and molecular research

Semester2
Project preparation course
Medical Biotechnology
Cellular causes of disease
Biomarkers in autoimmunity

Summer term
Research Project (Experimental research into a medical/molecular or genetics research topic)

Aims and Objectives
* Provide an excellent grounding in laboratory techniques and a critical approach to research planning and implementation.
* Develop understanding of molecular biology and the molecular basis of disease.
* Develop transferable skills, including their ability to work as a member of a team, and communicate in scientific writing and speech.
* Provide the opportunity for students to gain and enhance skills required by research organisations and biotechnology companies.
*Provide the ability to attain a level required to carry out research for a higher degree (PhD) in medical molecular and related areas.

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Translational Cancer Medicine enables you to gain detailed knowledge and understanding of research methods applied to rational drug design, clinical study design, molecular and cell biology, tumour immunology, genetics and cancer imaging. Read more
Translational Cancer Medicine enables you to gain detailed knowledge and understanding of research methods applied to rational drug design, clinical study design, molecular and cell biology, tumour immunology, genetics and cancer imaging. Practical experience gained through two six-month laboratory rotations.

Key benefits

- The range of topics including advanced imaging methods is unique for this translational cancer programme

- The sponsoring laboratories and departments all have international standing and have agreed to closely supervise the trainees

- Recently released data from the Higher Education Funding Council for England (Hefce) shows that King’s College London is equal top in England (with Queen Mary, University of London) for its PhD completion rates. This programme will potentially select candidates for the PhD programme within the Division of Cancer Studies

Visit the website: http://www.kcl.ac.uk/study/postgraduate/taught-courses/translational-cancer-medicine-mres.aspx

Course detail

- Description -

Overview of subjects covered:

• Biomarkers, biostatistics and modelling
• Breast cancer
• Cancer bioinformatics
• Cancer imaging (optical)
• Cancer imaging (PET)
• Clinical trials and translational research
• Gene discovery through to therapeutic applications
• Haemato-oncology and associated genetics/genomics
• Immunology of cancers
• Molecular pathology
• Signal transduction in cancers

- Course purpose -

The programme will provide students with a detailed knowledge and understanding of research methods applied to rational drug design, clinical study design, molecular and cell biology, tumour immunology, genetics and cancer imaging, all of which are relevant to Translational Cancer Research. In addition, practical experience will be gained through two laboratory rotations of six months duration.

- Course format and assessment -

Work with 2 supervisors and their teams, 6 months in each lab

Assignments:

• 30 credit taught module:

2-3 weekly lectures during first 3 months

Throughout the year, students also attend literature reviews and journal clubs that their labs/departments organise and any other internal or external seminars deemed relevant to their projects/assignments.

The assessment for this module is an essay on the fundamentals and the overall concept of Translational Cancer Medicine

• 75 credit laboratory based research project 1:

Assessed by a written dissertation, a seminar presentation and an oral examination

• 75 credit laboratory based research project 2:

Assessed by a draft of a paper of the standard and format required by a scientific journal.

Career prospects

Future PhD studies. Clinical and non-clinical academic careers in cancer medicine.

How to apply: http://www.kcl.ac.uk/study/postgraduate/apply/taught-courses.aspx

About Postgraduate Study at King’s College London:

To study for a postgraduate degree at King’s College London is to study at the city’s most central university and at one of the top 20 universities worldwide (2015/16 QS World Rankings). Graduates will benefit from close connections with the UK’s professional, political, legal, commercial, scientific and cultural life, while the excellent reputation of our MA and MRes programmes ensures our postgraduate alumni are highly sought after by some of the world’s most prestigious employers. We provide graduates with skills that are highly valued in business, government, academia and the professions.

Scholarships & Funding:

All current PGT offer-holders and new PGT applicants are welcome to apply for the scholarships. For more information and to learn how to apply visit: http://www.kcl.ac.uk/study/pg/funding/sources

Free language tuition with the Modern Language Centre:

If you are studying for any postgraduate taught degree at King’s you can take a module from a choice of over 25 languages without any additional cost. Visit: http://www.kcl.ac.uk/mlc

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This modular part-time programme is particularly suitable for academically gifted medical and dental trainees with the potential to be the independent researchers of the future. Read more
This modular part-time programme is particularly suitable for academically gifted medical and dental trainees with the potential to be the independent researchers of the future.

Applications for admisson in October 2016 are now open, the deadline to receive applications by is Friday 29 July 2016 (12 noon UK time).

Description

This progamme is designed to be taken by Academic Clinical Fellows alongside work commitments, the Health Research programme exists to enable students to:

- develop skills of research, design and data analysis in both qualitative and quantitative research

- critically evaluate health research

- identify, critically appraise and incorporate the results of medical and social science research into the day-to-day decision-making of clinical, scientific and administrative practice

- apply the principles of evidence-based practice in health care settings

- plan how to implement the findings of research to improve health care

- use theories and principles underpinning clinical research to inform their own research practice.

The programme is delivered through the Department for Continuing Education, with the expertise in curriculum design and teaching drawn from the Nuffield Department of Primary Care Health Sciences, the Centre for Evidence-Based Medicine, and the Oxford University Clinical Academic Graduate School.

Visit the website https://www.conted.ox.ac.uk/about/postgraduate-certificate-in-health-research

Programme details

The Postgraduate Certificate is normally completed between 1-2 years. It consists of three assessed taught modules and includes thorough introductions to the principles of evidence-based practice in health, and to study design and research methods.

Compulsory Modules

• The Practice of Evidence-Based Health Care
• Introduction to Study Design and Research Methods

The third module may be chosen from the following list:

- Clinical Trial Management
- Ethics for Biosciences
- Mixed Methods in Health Research
- Knowledge into Action
- Evidence-based Diagnosis and Screening
- Introduction to Statistics for Health Care Research
- Systematic Reviews
- Randomized Controlled Trials
- Qualitative Research Methods
- The Structure of Clinical Trials and Experimental Therapeutics
- How to do Research on Therapeutic Interventions: Protocol preparation
- Biological Therapeutics
- Pharmacodynamics, Biomarkers and Personalised Therapy
- Adverse drug reactions, drug interactions and Pharmacovigilance
- Drug development, Pharmacokinetics and Imaging

Course aims

At the end of the course students will be able to:

- demonstrate a knowledge of the principles, methods and techniques appropriate for solving evidence-based health care/health-research problems and be able to translate (through a critical comprehension of the relative advantages and disadvantages) that understanding into good clinical practice

- demonstrate a range of research skills enabling them to complete research successfully, either as part of a research team or as an individual

- acquire, interpret and analyse biological information with a critical understanding of the appropriate contexts for their use through the study of the existing primary literature in the field

- apply skills and expertise gained across the medical and biological sciences expected of professional researchers

Students will know and understand:

- health-care organizations, their management and the changing context in which they operate

- the ethical issues in health research and research governance

- methods to integrate and synthesise different sorts of information, from diverse sources, when making both individual patient and health-policy decisions in a wide range of situations

- the key issues for evidence-based practice in their own professional area or specialty

- how to work comfortably in situations of uncertainty and make sound judgements in the absence of definitive evidence

- research methods and concepts in the field of health and health care

All graduates of the Postgraduate Certificate in Health Research will be able to:

- understand the role of most commonly used methods appropriate for specifying problems through a critical comprehension of the relative advantages and disadvantages of these methods

- understand and express the main principles of some commonly applied techniques and methods

- explain the rationale for the selection of tools used in the analysis of phenomena.

Assessment methods

To complete the Postgraduate Certificate students must:

- Attend and complete the 2 compulsory modules and 1 option module.

Students will also be expected to complete three written assignments, usually of no more than 4000 words, one on each of the chosen modules above.

With the exception of the online modules, the EBHC modules are based on an eight week study cycle. Week One is a preparatory week where you may be required to undertake some pre-reading and to familiarise yourself with the Virtual Learning Environment. During Week Two you are required to attend the face to face teaching week in Oxford. This is followed by an additional six weeks where you are expected to participate in online activities and submit your assignment

Level and demands

Candidates will, in all but exceptional circumstances be admitted to the Postgraduate Certificate with optional progression on successful completion to the Diploma, provided that a candidate:

- has successfully completed the final year of the Bachelor of Medicine and Bachelor of Surgery or Bachelor of Dental Surgery or equivalent; or

- has an appropriate degree or equivalent professional qualification in a profession allied to medicine with post-qualification experience

Applicants will be expected to demonstrate an approach to their study which includes demonstrable skills of critical analysis, wide contextual knowledge and the ability to manage their own time.

Additionally candidates should:

- have a good working knowledge of email, internet, word processing and Windows applications (for communications with course members, course team and administration)

- show evidence of the ability to commit time to study and an employer's commitment to make time available to study, complete course work and attend course and University events and modules

Successful candidates will normally provide evidence of all of the following:

- A professional interest in Health Research, evidenced by prior experience, qualification and work

- Motivation and ability to complete the course

- A clear and well argued understanding of the benefits of the course to the candidate's current employment and future prospects

Find out how to apply here - http://www.ox.ac.uk/admissions/graduate/applying-to-oxford

Visit the Postgraduate Certificate in Health Research page on the University of Oxford website for more details!

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