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Masters Degrees (Experimental Medicine)

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The Department of Medicine is within the Faculty of Medicine at the University of British Columbia. The Department of Medicine has an active research program with investigators conducting research in all experimental aspects of medicine. Read more

Background of the Experimental Medicine Program

The Department of Medicine is within the Faculty of Medicine at the University of British Columbia. The Department of Medicine has an active research program with investigators conducting research in all experimental aspects of medicine. The Department and Faculty originated and developed this program for graduate studies in Experimental Medicine, and the first students were accepted into the program at the University of British Columbia in September 1987.

Experimental Medicine is the study of the pathogenesis and treatment of disease. Modern experimental medicine represents a rapidly growing body of knowledge involving the determination of diseases processes and the development of appropriate therapies.

The Experimental Medicine Program is intended for individuals seeking a career in research. The Department of Medicine offers opportunities and facilities for advanced studies in Experimental medicine, leading toward the M.Sc. and Ph.D. degrees. Members of the Department direct research programs in a wide range of basic and clinically relevant areas. There are a variety of special interest areas of national and international stature.

Specialties within the Experimental Medicine Program include: Cardiology, Endocrinology, Gastroenterology, Hematology, Infectious Diseases, Medical Immunology, Medical Oncology, Molecular Biology, Nephrology, Neurology and Respiratory Medicine.

Students may work with investigators located on the main campus of the University of B.C., or they may work in laboratories located off campus (Vancouver General Hospital, Jack Bell Research Centre, Terry Fox Laboratory, St. Paul’s Hospital, Biomedical Research Centre, BC Children’s Hospital).

Objectives of the Experimental Medicine Program

The objectives of the program are:
1. To teach the student the application of modern techniques in research.
2. To develop within the student the ability to read and criticize scientific literature, and to know the current state of knowledge in their particular field.
3. To teach the student to accurately define a problem and to design experiments which solve problems according to scientific standards.
4. To teach the student to conduct research on an independent basis.
5. To develop in all students the ability to communicate results of their research to the scientific community.

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The objective of the course is to equip students with a strong foundation in the fundamental techniques of clinical and translational research in experimental medicine, applying contemporary research tools to clinically relevant areas of investigation. Read more
The objective of the course is to equip students with a strong foundation in the fundamental techniques of clinical and translational research in experimental medicine, applying contemporary research tools to clinically relevant areas of investigation. The bespoke experimental medicine research training will be taught by Cambridge academics and industry, and will incorporate a research project focused experimental medicine. Each student is allocated an individual supervisor, who will provide support throughout the course and help build a customised training programme.

The MPhil includes formal modular teaching in core experimental modules (Statistics, Epidemiology, and Practical Aspects of Clinical Research) as well as specialist modules in Clinical Pharmacology and Clinical Drug Development. In addition, all students will have the opportunity to undertake a relevant 12 week research projects with one of our outstanding supervisors, including clinicians across a range of specialties, bio-medical scientists and bio-medical industry partners.

The course aims to provide students with broad research study and communications skills.

See the website http://www.graduate.study.cam.ac.uk/courses/directory/cvmdmptmt

Course detail

Upon successful completion of the MPhil graduates will have developed a strong foundation in the fundamental knowledge and techniques required to enable them to undertake clinical and translational research in experimental medicine. They will be able to apply contemporary research tools to clinically relevant areas of investigation.

The MPhil programme will produce clinical researchers who are competitive in seeking research support and
who are knowledgeable about the complex issues associated with conducting sound clinical research and
trials.

Format

The course consists of core modules in Practical Aspects of Clinical Research, Statistics, Epidemiology, as well as bespoke modules in Clinical Pharmacology and Clinical Drug Development timetabled over two terms. Students from both themes (Experimental Medicine and Rare Diseases) will have the opportunity to attend the modules of the other theme.

Students will be allocated mentor groups to work on a group research project; and all students will conduct their own individual supervised 12 week research project for which they will submit a thesis. The course is examined by two sat exams and thesis assessment.

Assessment

Students are expected to submit a thesis with a maximum word count of 15000 words.

Students will sit two exams of 2 hours each. The exams will be multiple choice questions and structured answer questions.

Students are required to present their work to their supervisors lab and a supervisor report is submitted to the programme directors - this is not assessed, but gives an indication of the progress of the student.

The course components are completed by the end of July. However, to complete the course, students will be required to attend a viva in person on a date (to be announced) in late August or early September.

Continuing

Students who are progressing well, have the support of a Principal supervisor, and have the necessary funding, may apply during the year to continue to do a PhD on successful completion of their MPhil. Such students will need to gain a pass mark of 70% or more in the MPhil examination.

Find out how to apply here http://www.graduate.study.cam.ac.uk/applying

Funding Opportunities

There are no specific funding opportunities advertised for this course. For information on more general funding opportunities, please follow the link below.

General Funding Opportunities: http://www.graduate.study.cam.ac.uk/finance/funding

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The University of Edinburgh Centre for Genomics and Experimental Medicine (CGEM) is part of the MRC / University of Edinburgh Institute of Genetics and Molecular Medicine (IGMM). Read more

Research profile

The University of Edinburgh Centre for Genomics and Experimental Medicine (CGEM) is part of the MRC / University of Edinburgh Institute of Genetics and Molecular Medicine (IGMM). CGEM’s mission is to use genetics and genomics to understand the mechanisms of disease and design novel intervention strategies. Our research has consistently obtained the highest possible ranking in national assessments of research excellence.

We undertake detailed studies of populations, families and individuals to study a wide range of health related conditions. We use state-of-the-art genetic, epigenetic, genomic, statistical, bioinformatic, biological and molecular approaches in model systems and clinical studies for systematic investigation of disease aetiology. With this knowledge, we aim to improve disease prediction, prevention and prognosis. Our translational agenda encompasses the development of new medicines and genetically-informed use of existing medicines in clinical trials.

Training and support

CGEM offers an exceptional, well-managed and well-equipped laboratory environment for cutting edge research and research training. Within CGEM there are ~25, and within the IGMM over a hundred, PhD students, overseen by a well-established Graduate School structure.

Training sessions for PhD students are available in a wide variety of topics. These include: good research practice; experimental design; data analysis and statistics; student-supervisor working relationships; research ethics and assessment mechanisms, as well as lectures/workshops on specific wet and dry laboratory techniques.

There is a Postgraduate Studies Committee (PGSC) which is responsible for student training and assessment. Its role is to develop and implement guidelines for optimal student training, and to ensure best practice in monitoring and assessment. Assessments are carried out by carefully selected thesis committees, who remain with the student throughout their PhD. The committees consist of the Supervisors, an External Member (with expertise relevant to the student’s project) and an experienced Chair. The students also have a thriving postgrad society which runs career talks, social events and an annual scientific retreat.

Facilities

A principal aim of both CGEM and the IGMM is develop fully integrated, multi-disciplinary research programmes across the whole spectrum of basic, clinical and translational research. We have state of the art imaging, DNA sequencing and drug discovery units, a bioinformatics service and excellent lab facilities.

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This course provides you with the opportunity to work within a world class Phase 1 cancer clinical trials unit and, through a mix of taught and experiential learning, to master the discipline of experimental cancer medicine. Read more
This course provides you with the opportunity to work within a world class Phase 1 cancer clinical trials unit and, through a mix of taught and experiential learning, to master the discipline of experimental cancer medicine.

You will spend a year as a member of the Experimental Cancer Medicine Team at The Christie. During this year, you will participate in four structured taught modules.

Alongside the taught elements, you will be allocated to one or more clinical trials that are being conducted by The Christie experimental cancer medicine team. You will have a named trainer and be exposed to tasks required in the setup, delivery, interpretation and audit of a clinical study.

As a nursing and physician student enrolled on this course, you will be expected to participate in patient care, with physicians and nursing staff participating in new and follow-on patient clinics, treatment and care giving episodes with patients.

For clinical trials coordinators, no direct patient contact is envisaged and duties will involve clinical trial setup, protocol amendments, database setup, data entry, costing and billing for clinical research.

Aims

The primary purpose of the MRes in Experimental Cancer Medicine is to provide you with the opportunity to work within a premier UK Phase 1 cancer clinical trials unit and, through a mix of taught and experiential learning, master the discipline of Experimental Cancer Medicine.

Teaching and learning

Our course is structured around a 2:1 split between clinical-based research projects and taught elements respectively.

Taught course units will predominantly use lectures and workshops, with e-learning limited to parts of course unit 1.

For the research projects, teaching and learning will take place through one-to-one mentoring from a member of the Experimental Cancer Medicine team.

The clinical and academic experience of contributors to this course will provide you with an exceptional teaching and learning experience.

Coursework and assessment

You will be are assessed through oral presentations, single best answer exams, written reports and dissertation.

Career opportunities

The MRes in Experimental Cancer Medicine is relevant to physician, nursing and clinical research students who are considering a career in Phase 1 clinical studies.

The course provides a theoretical and experiential learning experience and offers a foundation for roles within other experimental cancer medicine centres within the UK and EU, as well as careers in academia, the pharmaceutical industry, clinical trials management and medicine.

The MRes is ideal for high calibre graduates and professionals wishing to undertake directly channelled research training in the clinical and medical oncology field.

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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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Take advantage of one of our 100 Master’s Scholarships to study Tissue Engineering and Regenerative Medicine 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 Tissue Engineering and Regenerative Medicine 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.

Every day we are hearing of ground breaking advances in the field of tissue engineering which offer tremendous potential for the future of regenerative medicine and health care. Staff at Swansea University are active in many aspects of tissue engineering.

Key Features of Tissue Engineering and Regenerative Medicine

We are actively researching many aspects of tissue engineering including the following areas:

- Characterisation and control of the stem cell niche
- Mechanical characterisation of stem cells and tissues
- Production of novel scaffolds for tissue engineering
- Electrospinning of scaffold materials
- Cartilage repair and replacement
- Bone repair and replacement
- The application of nanotechnology to regenerative medicine
- Wound healing engineering
- Reproductive Immunobiology
- Bioreactor design

As an MSc By Research Tissue Engineering and Regenerative Medicine student, you will join one of the teams at Swansea University working in tissue engineering and use state of the art research equipment within the Centre for NanoHealth, a collaborative initiative between the College of Engineering and Swansea University Medical School.

The MSc by Research in Tissue Engineering and Regenerative Medicine typically lasts one year full-time, two to three years part-time. This is an individual research project written up in a thesis of 30,000 words.

Aim of Tissue Engineering and Regenerative Medicine programme

The aim of this MSc by Research in Tissue Engineering and Regenerative Medicine is to provide you with a solid grounding within the field of tissue engineering and its application within regenerative medicine.

This will be achieved through a year of research in a relevant area of tissue engineering identified after discussion with Swansea academic staff. Working with two academic supervisors you will undertake a comprehensive literature survey which will enable the formulation of an experimental research programme.

As a student on the MSc by Research Tissue Engineering and Regenerative Medicine course, you will be given the relevant laboratory training to undertake the research program. The research will be written up as a thesis that is examined. You will also be encouraged to present your work in the form of scientific communications such as journals and conference poster presentation.

The MSc by Research in Tissue Engineering and Regenerative Medicine will equip you with a wealth of research experience and knowledge that will benefit your future career in academia or the health care industries.

Recent MSc by Research theses supervised in the area of Tissue Engineering at Swansea University include:

- Quality assurance of human stem cell/primary cell bank
- The development of electrospinning techniques for the production of novel tissue engineering scaffolds.
- The incorporation of pulsed electromagnetic fields into wound dressings.
- The application of pulsed electromagnetic fields for improved wound healing.
- The use of nanoparticles in the control of bacterial biofilms in chronic wounds.
- The control of bacterial adhesion at surfaces relevant to regenerative medicine.
- The production of micro-porous particles for bone repair

Facilities

The £22 million Centre for Nanohealth is a unique facility linking engineering and medicine, and will house a unique micro-nanofabrication clean room embedded within a biological research laboratory and with immediate access to clinical research facilities run by local NHS clinicians.

Links with industry

The academic staff of the Medical Engineering discipline have always had a good relationship with industrial organisations. The industrial input ranges from site visits to seminars delivered by clinical contacts.

The close proximity of Swansea University to two of the largest NHS Trusts in the UK outside of London also offers the opportunity for collaborative research.

Research

The Research Excellence Framework (REF) 2014 ranks Engineering at Swansea as 10th in the UK for the combined score in research quality across the Engineering disciplines.

World-leading research

The REF shows that 94% of research produced by our academic staff is of World-Leading (4*) or Internationally Excellent (3*) quality. This has increased from 73% in the 2008 RAE.

Research pioneered at the College of Engineering harnesses the expertise of academic staff within the department. This ground-breaking multidisciplinary research informs our world-class teaching with several of our staff leaders in their fields.

Highlights of the Engineering results according to the General Engineering Unit of Assessment:

Research Environment at Swansea ranked 2nd in the UK
Research Impact ranked 10th in the UK
Research Power (3*/4* Equivalent staff) ranked 10th in the UK

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This online taught MSc in Sports Science is designed to provide you with an advanced, research-led programme of study in sport and exercise science and medicine. Read more
This online taught MSc in Sports Science is designed to provide you with an advanced, research-led programme of study in sport and exercise science and medicine. A key strength of this programme is its flexibility, which enables you to specialise in physical activity and health, sports performance, or sports medicine.

Why this programme

-This is the only MSc in Sports Science in Scotland that merges Sport and Exercise Medicine and Sport and Exercise Science within a single degree programme providing a broad range of options across these disciplines.
-You will benefit from access to the expertise of the staff at the National Stadium Sports, Health and Injury Clinic at Hampden Park – a custom-built, state-of-the-art sports medicine facility.
-We have exciting scholarship opportunities, find out more
-You will develop and enhance your skills in literature searching and critically evaluating relevant scientific evidence; application of knowledge to novel concepts and situations; experimental design; research methods and ethics; data handling and statistics; interpretation and evaluation of experimental data; scientific writing; and oral presentations.
-The University has state-of-the-art facilities to study performance and health aspects of sport and exercise science, from the whole body to the molecular level. These include advanced exercise laboratories, metabolic investigation suites and a molecular biochemistry lab. We are the best equipped exercise science group for laboratory facilities in Scotland, making the University of Glasgow the perfect place to study an MSc in Sports Science.
-The University has close links with a number of regional/national sporting bodies and a number of professional sporting clubs. There may be opportunities for internships (in place of a research project) for some students.
-You will have access to a number of guest lecture staff providing interactive sessions in their specialist fields.

[[Programme structure
The course will involve online lectures, seminars and tutorials and during a residential week at the end of year 1 you will take part in lab classes. You will also take part in journal clubs, presentations and self-directed learning. The programme is made up of 60 compulsary credits and 3 x 20 credit options (X,Y and Z) plus a research project (60 credits).

Core Courses
-Evidence Based Medicine (20 credits)
-Medical Statistics (10 credits)
-Physiological Exercise Testing 1 - Aerobics Fitness and Physical Activity (10 credits)
-Physiological Exercise Testing 2 - Strength, power and intensity domains (10 credits)
-Human physiological & metabolic assessment (10 credits)

Optional Courses - Choose one X option, one Y option and one Z option:

Option courses - X
-Physical activity and health: public health, policy & behaviour changes
-Sports injuries: scientific basis of preventation and rehabilitation
-Clinical Sports Injuries (also involves a short residential period at the end of year 2)

Option courses - Y
-Physical activity and health: biological mechanisms
-Ergogenic Aids for Exercise Performance
-Sport and Exercise Medicine in Practice

Option courses - Z
-Cellular and molecular exercise physiology
-The world class athlete: nature, nurture and maximising performance
-Exercise in clinical populations

Career prospects

The flexibility of this programme will provide you with many career opportunities. These include working in clinical exercise, health-promotion or in sports science support. A number of our graduates are employed in senior sports science positions with national sporting bodies and professional sports clubs. This programme also allows doctors and physiotherapists to aid their knowledge; for science graduates, there are opportunities in rehabilitation and higher education. It also provides an excellent basis if you wish to pursue PhD level research.

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This taught MSc in Sports Science is designed to provide you with an advanced, research-led programme of study in sport and exercise science and medicine. Read more
This taught MSc in Sports Science is designed to provide you with an advanced, research-led programme of study in sport and exercise science and medicine. A key strength of this programme is its flexibility, which enables you to specialise in physical activity and health, sports performance, or sports medicine.

Why this programme

-This is the only Msc in Sports Science in Scotland that merges Sport and Exercise Medicine and Sport and Exercise Science within a single degree programme providing a broad range of options across these disciplines.
-You will benefit from access to the facilities and resources of the National Stadium Sports, Health and Injury Clinic at Hampden Park – a custom-built, state-of-the-art sports medicine facility.
-We have exciting scholarship opportunities, find out more
-You will develop and enhance your skills in literature searching and critically evaluating relevant scientific evidence; application of knowledge to novel concepts and situations; experimental design; research methods and ethics; data handling and statistics; interpretation and evaluation of experimental data; scientific writing; and oral presentations.
-The University has state-of-the-art facilities to study performance and health aspects of sport and exercise science, from the whole body to the molecular level. These include advanced exercise laboratories, metabolic investigation suites and a molecular biochemistry lab. We are the best equipped exercise science group for laboratory facilities in Scotland, making the University of Glasgow the perfect place to study an MSc in Sports Science.
-The University has close links with a number of regional/national sporting bodies and a number of professional sporting clubs. There may be opportunities for internships (in place of a research project) for some students.
-You will have access to a number of guest lecture staff providing interactive sessions in their specialist fields.

Programme structure

You will attend lectures, seminars and tutorials and take part in lab classes, journal clubs, presentations and self-directed learning. The programme is made up of 60 compulsory credits and 3 x 20 credit options (X,Y and Z) plus a research project (60 credits)

Core Courses
-Evidence Based Medicine (20 credits)
-Medical Statistics (10 credits)
-Physiological Exercise Testing 1 - Aerobics Fitness and Physical Activity (10 credits)
-Physiological Exercise Testing 2 - Strength, power and intensity domains (10 credits)
-Human physiological & metabolic assessment (10 credits)

Optional Courses - Choose one X option, one Y option and one Z option.
Option courses X
-Physical activity and health: public health, policy & behaviour changes
-Sports injuries: scientific basis of prevention and rehabilitation.
-Clinical Sports Injuries

Option courses Y
-Physical activity and health: biological mechanisms
-Ergogenic Aids for Exercise Performance
-Sport and Exercise Medicine in Practice

Option courses Z
-Cellular and molecular exercise physiology
-The world class athlete: nature, nurture and maximising performance.
-Exercise in clinical populations

Career prospects

The flexibility of this programme will provide you with many career opportunities. These include working in clinical exercise, health-promotion or in sports science support. A number of our graduates are employed in senior sports science positions with national sporting bodies and professional sports clubs. This programme also allows doctors and physiotherapists to aid their knowledge; for science graduates, there are opportunities in rehabilitation and higher education. It also provides an excellent basis if you wish to pursue PhD level research.

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

About the course

Lead academics 2016: Dr Janine Kirby and Professor Winston Hide

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

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

Our study environment

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

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

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

How we teach

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

Our resources

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

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

Hepatitis B policy

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

Core modules

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

Examples of optional modules

Option one: Research Project.

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

Teaching and assessment

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

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

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The Experimental and Medical Biosciences master’s programme prepares students for a scientific career within the broad field of Life Sciences, with particular emphasis on understanding cellular and molecular mechanisms related to health and diseases. Read more
The Experimental and Medical Biosciences master’s programme prepares students for a scientific career within the broad field of Life Sciences, with particular emphasis on understanding cellular and molecular mechanisms related to health and diseases.

The Experimental and Medical Biosciences master's programme is designed to provide students with frontline knowledge in biomedicine and related subjects. The aim of the programme is to mix theoretical knowledge with practical skills and is most pronounced in the individual experimental projects done during the first and second year of studies.

The programme is newly designed but has evolved from two previous master’s programmes at Linköping University: Medical Biosciences, and Molecular Genetics and Physiology. Previously existing courses have been further developed and new ones have been created to meet the rapid development within the area. This means that the experiences from previous programmes and the novelty of a newly improved and updated programme are united.

Courses are taught using a multitude of formats, including regular lectures, tutorial groups with Problem-Based Learning methodology, laboratory work and seminar discussions. The laboratory classes use powerful model systems to illustrate modern concepts of medical biology and Problem-Based Learning promotes lifelong learning. After two initial, mandatory courses, the choice of elective courses offers individual study plans and flexibility in creating a profile that increases employability for all students within the area of Life Sciences. Different areas, such as: Cardiovascular biology, Stem cells and Applied Regenerative Medicine, Medical Genetics, and Neurobiology are covered (for a summary of all courses, please see the curriculum), but there is also a special emphasis on scientific reasoning, ethical attitudes, and multidisciplinary collaboration in order to prepare students for an independent and professional future in the field of biomedicine.

Individual projects in which students apply their theoretical and methodological knowledge in practice are key parts of the programme. During the first year, the Project in Experimental and Medical Biosciences will allow students to work with a specific assignment for ten or twenty weeks. During the second year, a one semester Degree Project (Master Thesis) is done. For both projects, chosen in collaboration with the project supervisor, the aim is to define a research goal, carry out the experimental project and produce a written synthesis of the data generated in relation to the current knowledge within the field. The degree project is conducted in a research laboratory, either at Linköping University, or at other Swedish or international universities, in the industry or in the public administration sector.

Double degree programme: An extra feature of the programme is the possibility for a limited number of students to study the second year in Vienna, Austria. Apart from the experience, an additional degree, is earned - Master of Science in Engineering. In contrast to the research oriented environment in Linköping, the studies at the University of Applied Science Technikum Wien within the Tissue Engineering and Regenerative Medicine programme, have a strong link to the industry.

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The MRes offers exciting opportunities to develop advanced scientific, research and transferable skills required to become an independent researcher. Read more

Course Description

The MRes offers exciting opportunities to develop advanced scientific, research and transferable skills required to become an independent researcher.

The MRes is organised by the Centre for Human Development, Stem Cells & Regeneration (CHDSCR) which undertakes fundamental research into early development and stem cells, together with applied translational research targeting the NHS and patient benefit.

Through research projects totalling 32 weeks, you will develop a broad range of laboratory skills and work in different research environments. You will be supervised by internationally recognised academic researchers. In addition to providing broader training in scientific research, the course will develop your transferable skills including time and project management, public speaking, critical appraisal and scientific writing, thus aiding employability for a variety of careers.

Key Information

The intake for this MRes is 15-20 students.

What does this MRes provide?

During the one year, full time programme that commences in September/October, MRes students undertake taught modules in Research Skills in Biomedical Sciences, Stem Cells, Development & Regenerative Medicine, and Advanced Scientific Skills. Students also undertake two research projects totalling 32 weeks, to develop a broad range of laboratory skills and gain experience of working in different research environments. Students are supervised by internationally recognised Academic researchers in the CHDSCR.

Why study this MRes at the University of Southampton?

The University of Southampton is consistently ranked in the top 10 national and the top 100 international Universities. We are a world leading research intensive university, with a strong emphasis on education and are renowned for our innovation and enterprise. The CHDSCR is a Centre for excellence and strategic importance. Students work within vibrant and thriving interdisciplinary research programmes that harness the translational strength of the University, together with an outstanding clinical infrastructure and enterprise to translate pioneering developmental and stem cell science for patient benefit.

Who should apply?

High-achieving Biological/Biomedical Science graduates interested in developing further laboratory based research skills and subject specific knowledge before committing to a PhD programme, or a career in academia, industry, government policy or science journalism.

How will this MRes enhance your career prospects?

In addition to providing broader training in the intellectual basis of scientific research in Stem Cells, Development and Regenerative Medicine, the course will develop your transferable skills including time and project management, public speaking, critical appraisal and scientific writing, thus aiding employability for a variety of careers.

What will you learn in the modules?

i) Stem Cells, Development & Regenerative Medicine module
Students are introduced to core concepts through a series of facilitator-led workshops focussing on key research publications. Students critically appraise primary research papers and develop the skills required to understand, critique and interpret research findings. Integral to these workshops is the requirement for students to present their thoughts and participate in group discussions with both their peers and academic facilitators.

ii) Research Skills in Biomedical Sciences (RSBS) module
A combination of taught and practical sessions are used to introduce students to the core concepts underlying statistical analysis and study design that support students in handling their own data and critically appraising data published by others.

iii) Advanced Scientific Skills module
A series of taught and practical sessions introduce students to additional core concepts used in Biomedical Sciences such as the analysis and critical appraisal of large data sets. In addition, key principles required to relay research to both a scientific and lay audience are introduced. Students write both a scientific and lay abstract for a published primary paper and give a research presentation suitable for a lay audience. Thus, students develop the skills required to communicate their research to both scientists and non-specialists.

iv) Research Project modules
In the two research projects, students are introduced to a range of laboratory skills gaining valuable practical experience of research methodology, experimental design, data interpretation, viva voce, scientific writing, oral and poster presentations.

What teaching and learning methods will be used?

A variety of methods are used including lectures, research seminars, small group discussions, journal club presentations, analysis of large data sets and in depth research projects which incorporate the evaluation and presentation of research findings within the field of stem cell biology. A range of summative and formative assessment methods are used to assess student performance. These include oral presentation, poster presentation, written assignments/critical review, viva voce, laboratory proficiency, analysis of large datasets, lay/scientific abstracts and preparation of a research proposal.

What are the entry requirements for this MRes?

The minimum classification normally expected for a degree entrant is at least a second class upper division (1st or 2:1) in Biological/Biomedical Sciences or a closely related subject from any approved University.

Qualifications from non-UK institutions must be of an equivalent standard to those of UK Universities. Before commencing the course, non-UK applicants should obtain an overall IELTS score of 7.0, with a minimum of 6.0 in each component.

What are the fees for this MRes?

Home/EU: £5,900 tuition fee + £5,100 bench fee

Overseas: £18,800 tuition fee + £5,100 bench fee

Scholarships

The University of Southampton offers a number of Scholarships. Please refer to: http://www.southampton.ac.uk/uni-life/fees-funding/international-fees-funding/funding-by-country.page

To Apply

Please click on the “Apply Now” button on our website
Please state Faculty of Medicine in the drop down menu as this Programme is delivered by the Faculty of Medicine. Or click on the link below

https://studentrecords.soton.ac.uk/BNNRPROD/bzsksrch.P_Login?pos=7009&majr=7009&term=201617#_ga=1.107238786.1658067525.1460548452

To register interest, or for further Programme information please contact:

Programme Leader: Dr Franchesca Houghton
Deputy Programme Leader: Dr Rahul Tare

Email:

For general enquiries please contact:

Email:

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This programme aims to provide you with a firm foundation in biomedical research methodology, focused on translational cardiovascular medicine, by enhancing your knowledge, understanding, critical awareness and practical research experience in this area. Read more

Programme overview

This programme aims to provide you with a firm foundation in biomedical research methodology, focused on translational cardiovascular medicine, by enhancing your knowledge, understanding, critical awareness and practical research experience in this area. The programme provides a firm theoretical grounding in the scientific principles and clinical applications of translational cardiovascular medicine, as well as intensive training in research methodology, experimental design, statistical analyses, data interpretation and science communication.

The core of the programme is a six-month research project, conducted within one of the University of Bristol's internationally recognised translational cardiovascular medicine research groups. Opportunities will be available in laboratory or clinical-based investigations.

The programme is suitable for clinical and bioscience graduates who wish to develop their research skills within this exciting field. It is also suitable for clinical students interested in pursuing a research-intensive intercalation option after three years of study.

Programme structure

This programme is delivered by research scientists and clinicians through lectures, tutorials, seminars, research clubs and practical classes. In addition to four mandatory units relating to research methodology, students choose two units on aspects of cardiovascular science.

Mandatory units

- Introduction to Research Methods in Health Sciences (10 credits)
This unit introduces a variety of research methods used in basic and applied clinical research including: finding and reading relevant research information; presenting research results; basic statistical analysis; data interpretation; ethics.
- Further Research Methods in Health Sciences (20 credits)
This unit aims to develop further knowledge and practical experience in statistical analyses, experimental design and laboratory methods and includes training in the use of a statistical software package and practical experience in several laboratory techniques.
- Research Club in Health Sciences (10 credits)
This unit aims to develop your ability to present, critically evaluate and discuss scientific findings by contributing to journal clubs, attending and summarising research seminars and presenting your own research.
- Research Project in Translational Cardiovascular Medicine (100 credits)
During this unit you will gain extensive experience in scientific/clinical research by conducting an independent project. You will write up your research in the form of a thesis, present and discuss your work in a viva and research symposium.

Plus a choice of two of the following units:

- Coronary Artery Disease I (20 credits)
- Coronary Artery Disease II (20 credits)
- Heart and Valve Disease (20 credits)
- Paediatric Heart Disease (20 credits)
- Aneurysm, Peripheral Vascular Disease and Stroke (20 credits)

Careers

This programme is suitable for those with a bioscience or clinical background who wish to develop their research skills before embarking on a research/clinical career in academia or the pharmaceutical industry. It provides the ideal foundation for further studies leading to a PhD.

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The UBC Department of Pathology and Laboratory Medicine offers a remarkable opportunity to study with numerous world renowned faculty and research programs. Read more

General Information

The UBC Department of Pathology and Laboratory Medicine offers a remarkable opportunity to study with numerous world renowned faculty and research programs. We are recognized as national and international leaders in both basic and clinical research. Experimental Pathology refers to research in any area of biomedical investigation that is relevant to human disease. Since it is necessary to understand the normal working of the system to fully define the changes associated with disease, the areas represented at UBC cover a wide range of fields and approaches. Work at all levels of biological organization is involved, from protein to lipoprotein biochemistry and molecular biology through cell and tumour biology, animal models for studies on pulmonary and cardiovascular pathophysiology and viral and bacterial infection processes, to clinical studies on human population and the AIDS epidemic.

We train students with varied backgrounds in science and medicine including: biochemistry, physiology, cell biology and microbiology/immunology.

We are committed to effective, cutting-edge, ethical research. The results of which will reach beyond the academic realm to effect positive change in the lives of our families, communities and, ultimately, our world.

Quick Facts

- Degree: Master of Science
- Specialization: Pathology and Laboratory Medicine
- Subject: Life Sciences
- Mode of delivery: On campus
- Program components: Coursework + Thesis required
- Registration options: Full-time
- Faculty: Faculty of Medicine

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

About the course

Lead academic 2016: Dr Mark Fenwick

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

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

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

Our study environment

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

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

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

How we teach

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

Our resources

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

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

Hepatitis B policy

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

Core modules

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

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Molecular Medicine is a broad discipline that relates to the study of the molecular mechanisms of disease and their application in developing therapies for the clinic. Read more
Molecular Medicine is a broad discipline that relates to the study of the molecular mechanisms of disease and their application in developing therapies for the clinic. It is an exciting time to be a biomedical scientist, with the forefront of healthcare research currently focused on personalised medicine, stem cells and the prospect of gene editing. This taught Masters aims to provide students with an in-depth grounding in contemporary molecular medicine. The Department of Biology has considerable research expertise spanning several areas relevant to molecular medicine, including cancer, immunology, microbiology, neuroscience and parasitology.

Key features

-Learn how basic biomedical research is conducted and translated by scientists in one of the UK’s top-ranked biological sciences departments
-Develop the skills to pursue a PhD in biomedical research or other specialist career path within the healthcare/pharmaceutical sector.

Taught modules

-Molecular Basis of Disease
-Data Analysis and Programming in the Biosciences
-Research, Professional and Team Skills
-Optional modules in topics including cancer, neuroscience, cell and tissue engineering, and microbiology.

Research projects

After receiving training in core laboratory techniques and experimental design, students will undertake an Independent Study Module under the supervision of a biomedical researcher in the Department of Biology or as an external placement. Recent external placement destinations include MicroLab Devices, Leeds; Cancer Research UK, London; Computomics GmbH & Co, Tübingen; Forsite Diagnostics Ltd, York; MRC Harwell, Oxford; Smith & Nephew, York; GSK, London; Francis Crick Institute, London; and AstraZeneca, Cambridge.

Research and transferable skills

We will equip students with the key skills of the modern researcher, including critical thinking, data interpretation, statistics, programming, and the written, oral and graphical presentation of scientific data and ideas.

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