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Masters Degrees (Cell And Gene Therapy)

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This Master's degree in Cell and Gene Therapy provides an in-depth education in this cutting-edge and rapidly developing field. Read more
This Master's degree in Cell and Gene Therapy provides an in-depth education in this cutting-edge and rapidly developing field. It is delivered by scientists and clinicians researching, developing and testing new treatments for genetically inherited and acquired diseases using gene delivery technology, stem cell manipulation and DNA repair techniques.

Degree information

The degree covers all aspects of the subject, including basic biomedical science, molecular basis of disease, current and developing technologies and clinical applications. Students also receive vocational training in research methodology and statistics, how to perform a research project and complete a practical laboratory-based project.

Students undertake modules to the value of 180 credits.

The programme consists of four core modules (60 credits), four optional modules (60 credits) and a research dissertation (60 credits). A Postgraduate Diploma (120 credits, full-time nine months or flexible up to five years) is offered. A Postgraduate Certificate (60 credits, full-time 12 weeks, part-time nine months, or up to two years flexible) is offered.

Core modules
-Molecular Aspects of Cell and Gene Therapy
-Clinical Applications of Cell and Gene Therapy
-Research Methodology and Statistics
-Stem Cell and Tissue Repair

Research Methodology and Statistics is not a core module for the PG Certificate. Students of the PG Certificate can choose an optional module.

Optional modules
-Foundations of Biomedical Sciences
-Applied Genomics
-HIV Frontiers from Research to Clinics
-Molecular and Genetic Basis of Paediatric Disease
-Understanding Research and Critical Appraisal: Biomedicine
-Laboratory Methods in Biomedical Science
-Research Methodology and Statistics

Dissertation/report
All MSc students undertake an independent research project which culminates in a dissertation.

Teaching and learning
Teaching includes lectures, seminars, problem classes and tutorials. Assessment varies depending on the module, but includes written coursework, multiple-choice questions, written examinations, a practical analysis examination and the dissertation.

Careers

The majority of our graduates have gone on to secure PhD places. Please see our programme website to read testimonials from past students which include their destinations following graduation.

Employability
This novel programme aims to equip students for careers in research, education, medicine and business in academic, clinical and industrial settings. Examples of potential careers could include academic research and/or lecturing in a university or other higher education setting, conducting clinical trials as part of a team of clinicians, scientists and allied health professionals, monitoring and analysing the results of clinical trials as part of a clinical trials unit, developing new therapies or intellectual property in the pharmaceutical industry or other business ventures.

Why study this degree at UCL?

The Institute of Child Health (ICH), and its clinical partner Great Ormond Street Hospital (GOSH), is the largest centre in Europe devoted to clinical, basic research and post-graduate education in children's health, including haematopoietic stem cell transplantation (HSCT) and gene therapy.

The UCL School of Life & Medical Sciences (SLMS) has the largest concentration of clinicians and researchers active in cell and gene therapy research in Europe. This is reflected by the many groups conducting high-quality research and clinical trials in the field including researchers at the Institute of Child Health, the Division of Infection and Immunity, the Institute of Ophthalmology, the Institute for Women's Health, the Institute of Genetics and the Cancer Institute.

Keywords: Stem Cells, Therapy, Genomics, Regenerative Medicine, Gene Editing

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This comprehensive programme is intended for professionals specialising in paediatrics and child health and is based at the Institute of Child Health, which sits in a unique position in UK paediatrics because of its strong links to Great Ormond Street Hospital for Children and UCL. Read more
This comprehensive programme is intended for professionals specialising in paediatrics and child health and is based at the Institute of Child Health, which sits in a unique position in UK paediatrics because of its strong links to Great Ormond Street Hospital for Children and UCL.

Degree information

Students on this pathway gain an understanding of the principles of evidence-based paediatrics, and of the impact of molecular genetics on diagnosis and management of the child and family. They will build an awareness of current and future developments in paediatric medicine and child health and gain the skills necessary to critically appraise practice and policy, and undertake independent research if the full MSc is taken.

Students undertake modules to the value of 180 credits. The programme consists of four core modules (60 credits), four optional modules (60 credits) and a dissertation/report (60 credits). A Postgraduate Diploma (120 credits, full-time 9 months, flexible 2-5 years) is offered. The programme consists of four core modules (60 credits) and four optional modules (60 credits). A Postgraduate Certificate (60 credits, part-time 1 year, flexible 1-2) is offered. The programme consists of four core modules (60 credits).

Core modules
-Evidence-based Child Health
-Research Methodology and Statistics

Students must also choose at least two further core modules from the following:
-Molecular Biology of Normal Development and Birth Defects
-Molecular and Clinical Aspects of Childhood Cancers
-Clinical Genomics, Genetics and Rare Diseases

Please note: those modules not taken as core will still be available as options

Optional modules - students must take at least two modules from those available across the other pathways of the Paediatrics and Child Health MSc, with the following modules particularly recommended for students in this area:
-Stem Cells and Tissue Repair
-Molecular Aspects of Cell and Gene Therapy
-Clinical Applications of Cell and Gene Therapy
-Applied Genomics

Dissertation/report
All students undertake an independent research project which culminates in a dissertation of 10,000 words.

Teaching and learning
The programme is delivered through a combination of lectures, seminars, tutorials and research project supervision. Assessment is through a combination of multiple choice questions and short answer questions, essays, posters, presentations, reflective portfolios, critical appraisal of the literature and, for the full MSc, a dissertation and oral presentation.

Careers

The programme provides an ideal foundation for further doctoral research in this field and/or a career in research and evidence-based practice in paediatrics.

Employability
The first cohort of students on the Paediatrics and Child Health: Molecular and Genomic Paediatrics MSc will graduate in 2016, therefore no information on graduate destinations is currently available.

Why study this degree at UCL?

The Institute of Child Health pursues an integrated, multidisciplinary approach to enhance understanding, diagnosis, therapy and prevention of childhood diseases. Our research and our educational portfolio covers a broad range of paediatric issues, from molecular genetics to population health sciences, and our structure facilitates interdisciplinary work and follows flexibility for the development of new areas of investigation.

Our close relationship with the Great Ormond Street Hospital for Children means that much of our research and teaching is combined.

Students benefit from excellent facilities in both laboratory and non-laboratory subjects.

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

Degree information

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

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

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

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

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

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

Careers

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

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

Why study this degree at UCL?

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

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

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

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

About the course

Lead academic: Dr Martin Nicklin

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

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

Our study environment

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

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

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

How we teach

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

Our resources

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

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

Hepatitis B policy

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

Core modules

From Genome to Gene Function; Human Gene Bioinformatics; Research Literature Review; Human Disease Genetics; Modulating Immunity; Laboratory Practice and Statistics.

You choose: six optional pathways

1. Genetic Mechanisms pathway:


Modelling Protein Interactions; Gene Networks: Models and Functions.

2. Microbes and Infection pathway:


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

3. Experimental Medicine pathway:


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

4. Cancer pathway:

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

5. Cardiovascular pathway:

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

6. Clinical Applications pathway:

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

Teaching and assessment

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

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

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There is a separate entry on admission to the P.Grad.Dip. in Molecular Medicine. Read more
There is a separate entry on admission to the P.Grad.Dip. in Molecular Medicine.

This course aims to give participants an indepth understanding of the emerging field of molecular medicine which draws together developments in molecular and cellular biology to describe disease processes at a functional level - that of molecular interactions.

The course aims to provide students with an understanding of the molecular basis of human disease and its implications for the practice of clinical medicine and research in the life sciences. The course will ensure that students from all disciplines have the skills necessary to conduct research and critically evaluate the scientific and medical literature.

The course includes lectures on cellular biology and molecular genetics as they apply generally to normal cell and tissue function and to disease processes. Modules on molecular signalling and therapeutics, bioinformatics and ethical-legal aspects of the discipline are included, as well as literature reviews, laboratory practicals and a laboratory project.

The course is available in a one-year, full-time and a two-year, part-time format. It consists of lectures on cellular biology and molecular genetics as they apply generally to normal cell and tissue function and more specifically to disease processes such as cancer, immune dysfunction, and diseases with an inherited component. The course content includes molecular signalling and therapeutics, molecular and population genetics, nanoscience, and high content cell analysis. There is a core, 'Research Skills' module which encompasses bioinformatics and ethical-legal aspects of the emerging discipline, literature reviews, and laboratory practicals in basic molecular and cellular techniques. Candidates will complete a laboratory project of three months (full-time) or six months (part-time) duration. Candidates must also complete the taught module, Molecular Mechanisms of Human Disease I. This course provides the applicant with state-of-the-art information and critical analysis of: The human genome at a molecular level, the integration of molecular and cellular biology in relation to human diseases; the molecular basis of human genetic disease; the molecular interactions between microbiological pathogens and the human host; the technology currently employed in researching molecular medicine; the molecular basis of common human inflammatory diseases and malignancies; the utilisation of knowledge on the molecular basis of human disease in planning and design of novel therapies, using pharmacological agents or gene therapy; the ethical and legal aspects of molecular medicine as it impinges on clinical practice. You will also gain a working appreciation of molecular and cellular biology at the practical level and development of the ability to perform independent research with the ability to apply bioinformatic and computational techniques in medical and biological research, and information retrieval. The student is examined on the basis of a submitted critical literature review essay, a written examination, assessment of laboratory practicals and the writing of a dissertation based on a research project. Candidates from health science (medical, dental, veterinary), biological science and other science disciplines (e.g. chemical or pharmacy), are invited to apply.

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

Degree information

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

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

Core modules
-Basic Biology and Cancer Genetics
-Cancer Therapeutics

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

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

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

Careers

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

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

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

Why study this degree at UCL?

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

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

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This Masters in Translational Medicine is the first year of a British Heart Foundation 4-Year PhD studentship. it is not offered as an individual programme of study. Read more
This Masters in Translational Medicine is the first year of a British Heart Foundation 4-Year PhD studentship: it is not offered as an individual programme of study.

Why this programme

◾The programme will provide you with the skills needed to assess critically recent advances in biology relevant to human disease.
◾It covers the areas of cardiovascular medicine, inflammation and immunology, neuroscience, mathematics, bioinformatics and cell biology, and advances in fundamental biomedical science relevant to integrative mammalian biology.
◾You will be taught the administrative procedures and ethical and project planning requirements for applying for statutory licenses (personal and project) for animal work as well as ethical aspects of gene and cell therapy.
◾The University is one of the few centres in the UK offering BHF 4-Year PhD studentships. Successful applicants accepted into the programme will be fully funded. For more information, see: BHF 4 year PhD programme.

Programme structure

The programme is part of a 4-year PhD with the first year being an MRes. The MRes is made up of three individual 12-week research placements after an intense two-week induction. Each project will be based on different themes with three different supervisors. Years 2-4 make up the PhD portion of the programme.

Induction

You will be required to attend an in-depth introductory programme, which will provide training in research ethics, statistics, project design, literature review and laboratory safety techniques.

Placements

The induction is followed by three individual research placements. These are at the core of this programme, providing three separate projects to allow you to define your areas of interest for your PhD studies. Each placement is a 12-week project and this will be with three different principal supervisors. You will be encouraged to choose placements beyond your undergraduate subject experience to maximise your exposure to new techniques and science. Supervisors are drawn from a wide range of academic disciplines, such as medicine, biomedical and life sciences, mathematics, electronics and electrical engineering, and veterinary medicine.

Career prospects

You will be taught the practical laboratory skills needed to pursue a career in basic translational medicine and applied science through research projects. After successfully completing year 1, you will be awarded an MRes, and progress to a PhD. The programme produces fully trained scientists ready for progression to academic or industrial careers.

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This masters course will bring you up to speed with the post genomic era. We are now in a scientific age that has followed the game changing breakthrough that was the sequencing of the human genome. Read more
This masters course will bring you up to speed with the post genomic era. We are now in a scientific age that has followed the game changing breakthrough that was the sequencing of the human genome. But that was not the end, just the beginning. The “big” data being generated is coming out at an amazing rate. Personalised medicine is around the corner. We need skilled and talented biologists who are capable of analysing, processing and innovating. Gene therapy is hitting the headlines. Stem cell therapy may treat the previously untreatable. You can be part of this new golden age with a masters in medical genomics.

More about this course

We will be enhancing knowledge of genomic science from a health perspective. With our superb laboratory facilities we’re able to offer unique research project opportunities together with outstanding quality of teaching from research active staff.

We have access to guest lecturers at the highest levels of their profession who are collaborating with our staff (Barts, Imperial, Kings, UCL, St Georges, Brunel). In addition, we have a strong collaboration with the prestigious ACFIES in Columbia, which offers exciting international work exchange opportunities.
Students will be eligible to join the Royal Society of Biology with whom we are registering to be accredited.

We can offer unrivalled student learning support and our location means that the job market is on our doorstep. Connections with other prestigious universities mean that students will have the opportunity to meet and discuss their career options and secure work placements or apply for studentships.

You’ll be tested using a wide variety of assessment tools. We will ask students to write laboratory reports, give presentations, sit written exams, take part in debates, answer quizzes and experience virtual labs via asynchronous e-learning, make posters and defend their work aurally.

Modular structure

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

Year 1 modules includes:
-Biomedical Informatics (core, 20 credits)
-Fundamentals of Medical Genetics and Genomics (core, 20 credits)
-Medical Genetics (core, 20 credits)
-Research Project for Medical Genomics (core, 60 credits)
-Scientific Frameworks for Research (core, 20 credits)
-Advanced Immunology (option, 20 credits)
-Bioinformatics and Molecular Modelling (option, 20 credits)
-Biomedical Diagnostics (option, 20 credits)
-Epidemiology of Emerging Infectious Disease (option, 20 credits)
-Ethical Issues in Biomedical Science (option, 20 credits)
-Molecular Oncology (option, 20 credits)

After the course

Genomics is important in both public and private domains. It is key for the NHS and via governmental initiatives (the 100,000 genome project). Thus there is a commensurate burgeoning of new genome centres in the UK and abroad: ie the Cambridge Genome centre. There are opportunities for people with degrees and training in human genetics. As genetic testing becomes part of many routine medical evaluations, more geneticists are needed to perform the tests. As genetics is recognised to be a basic part of all biological sciences, more teachers with expertise in genetics will also be needed. In India, genomics is growing through companies like Medgenome. It is indubitable that this is a currently growing area of the job market.

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The Department of Medical Biophysics, an interdisciplinary department with three fields—Cellular and Molecular Biology, Medical Physics, and Molecular and Structural Biology—is located primarily at the Princess Margaret Cancer Centre, the Toronto Medical Discovery Tower, and the Sunnybrook Research Institute. Read more
The Department of Medical Biophysics, an interdisciplinary department with three fields—Cellular and Molecular Biology, Medical Physics, and Molecular and Structural Biology—is located primarily at the Princess Margaret Cancer Centre, the Toronto Medical Discovery Tower, and the Sunnybrook Research Institute.

The department offers opportunities for research—leading to the Master of Science and Doctor of Philosophy degrees—in a variety of problems in medical science; projects which cut across the conventional boundaries of biology, physics, engineering, chemistry, and medicine are encouraged. The department emphasizes basic and applied research related to cancer. Projects include the following areas: tumour biology, radiobiology, membrane function, molecular interactions, gene expression, cell differentiation and growth control, viral and chemical carcinogenesis, cellular and molecular immunology, hemopoiesis, macromolecular structure via x-ray crystallography, NMR spectroscopy and electron microscopy, the physics and engineering of diagnostic imaging and radiation therapy, development of imaging and therapy systems using x-rays, ultrasound, nuclear magnetic resonance, light and electron optics.

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This is a multidisciplinary degree that brings together aspects of chemistry, biology and cell biology. The modules are carefully tailored to cover the knowledge in key fields such as. Read more

This is a multidisciplinary degree that brings together aspects of chemistry, biology and cell biology. The modules are carefully tailored to cover the knowledge in key fields such as:

  • Gene therapy
  • Drug design
  • Genomics
  • Proteomics
  • Genetic engineering for plants
  • Animals and micro-organisms
  • Bioinformatics.

This degree produces graduates with a critical, analytical and flexible approach to problem solving, enhancing laboratory and professional competence and enabling students to work independently and use their initiative in solving the diverse problems they encounter.

The programme helps you to obtain a creative attitude to the development and manufacture of biotechnology products. The intention is that skills and knowledge can be more readily transferred to professional activities.

The aims of the programme are:

  • To provide students with subject-specific knowledge, as well as a critical, analytical and flexible approach to problem solving in the field of biotechnology
  • To provide students with enhanced practical and professional skills and thus prepare them effectively for professional employment or doctoral studies in the field of biotechnology
  • To enable students to work independently and use initiative to solve the diverse problems they may encounter
  • To instil a critical awareness of advances at the forefront of biotechnology.

Science - General

We offer a range of sciences programmes from biotechnology to formulation science. Whatever you choose to study you will be taught by experienced staff in state-of-the-art laboratories and gain the skills you need to succeed in your chosen field. Employability is central to all our programmes and you will benefit from our strong links with employers, industry work placements and professional accreditations.

What you'll study

Full time

- Year 1

Students are required to study the following compulsory courses.

Biotechnology Research Projects (60 credits)

Bioinformatics (30 credits)

Research Methods and Data management (30 credits)

English Language Support (for Postgraduate students in the Faculty of Engineering and Science)

Applied Molecular Biology (30 credits)

Students are required to choose 1 course from this list of options.

Biotechnology and Transgenic Crops (30 credits)

Pharmaceutical Biotechnology (30 credits)

Fees and finance

Your time at university should be enjoyable and rewarding, and it is important that it is not spoilt by unnecessary financial worries. We recommend that you spend time planning your finances, both before coming to university and while you are here. We can offer advice on living costs and budgeting, as well as on awards, allowances and loans.

Find out more about our fees and the support available to you at our:

- Postgraduate finance pages (https://www.gre.ac.uk/study/finance/postgraduate)

- International students' finance pages (http://www2.gre.ac.uk/students/international/international-students/finance)

Assessment

Students are assessed through:

  • Coursework
  • Examinations
  • Presentations
  • Thesis
  • Online assessment.

Teaching and learning

This programme involves a series of lectures, seminars and workshops. Case studies will provide you with exposure to up-to-date problems and enhance your problem solving and team-work in a way that simulates an industrial setting. A research project in a well equipped department led by staff with a diversity of research experience will give you the opportunity to carry out novel research and enhance your practical skills, analytical thinking and independence.

Career options

Biotechnology and pharmaceutical industries, intellectual property industry (IP), academics, bio-informatics/IT, health services, research and higher degrees (PhD).

Find out how to apply here - https://www2.gre.ac.uk/study/apply



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What is the Master of Biomedical Sciences all about?. Biomedical sciences underwent a spectacular evolution during the past decades. Read more

What is the Master of Biomedical Sciences all about?

Biomedical sciences underwent a spectacular evolution during the past decades. New diseases such as bird flu arose, whereas others such as AIDS and diabetes have expanded. At the same time, researchers are discovering new ways to fight these diseases. The human genome has been decoded, gene technology is steadily growing, immunotherapy has been introduced for the treatment of several cancers and the first steps in the direction of stem cell therapy have been made. The laboratories at KU Leuven and University Hospital Gasthuisberg deliver cutting edge work in the field of disease and development of new therapies, stretching from bench to bedside. The Master of Biomedical Sciences at KU Leuven allows students to live this journey themselves, hands on.

Do you dream of working on the frontline of the ongoing battle for a better understanding of human health and diseases? Are dedicated to applying this knowledge to better prevention and treatment options? Then this programme is for you. During the two master's years you will be truly immersed in scientific biomedical research. By doing scientific research in a domestic or foreign laboratory, you will gain thorough know-how, strengthen your scientific skills and learn the newest scientific methods. All of these skills and accumulated knowledge will be applied in the most important part of the master's programme: your master's thesis.

Objectives

The main goal of the curriculum is to train researchers in biomedical sciences by providing a rigorous scientific training based on the acquisition of knowledge, the collection and interpretation of information and the use of modern research techniques. This is expected to stimulate the critical thinking and independence required to address a specific research question related to (dys)function of the human body and its interaction with the environment. Furthermore, the curriculum provides broad, intellectually rigorous training allowing for a wide array of job opportunities in industry, research centres and society.

The aims of the curriculum follow the educational principles of KU Leuven, important among which is the independence of the student. For the acquisition of knowledge, the university uses its own high-quality interdisciplinary scientific research. KU Leuven aims to be a centre of critical thinking where, in addition to factual knowledge, people are stimulated to identify, define and solve problems.

The quality of the curriculum is guaranteed due to the strong interconnection between education and research in the Biomedical Sciences in the broadest sense. The faculty commits itself to a future-oriented educational project in an academic setting that is at once intellectually stimulating, socially supportive and student friendly.

Career perspectives

Internationalisation has become an integral part of the profile of researchers in biomedical sciences. International exchange is the key to opening mindsets to global solutions in health and disease. Graduates can expect to embark on international-level careers in very diverse areas touching on human health.

First and foremost, biomedical scientists are prepared for a personal career full of exciting scientific research in academic or pharmaceutical laboratories dedicated to improving knowledge in human health and finding prevention strategies and cures for diseases. Beyond this, there are many different directions open to you.

Many graduates go on to careers in consultancy, policy, sales and marketing, communication and management in areas related to human health, such as the pharmaceutical industry, scientific writing agencies, regulatory agencies and government administration. Graduates find rewarding work in a wide variety of sectors: the pharmaceutical industry, the academic or educational world, healthcare, the environmental sector and food inspection, among others.

Programme graduates are in high demand in the pharmaceutical and medical industry. As a biomedical scientist, for example, you provide thoroughly prepared research, which is a crucial phase in the development of new drugs and other medical products. It is also possible to cooperate with the set-up and follow-up of preclinical trials in the pharmaceutical industry. The programme gives you the perfect profile for clinical trial design, as well as the monitoring and conducting of these trials, on both the business and clinical sides of the process.

You can also work for service companies that deliver or develop products or equipment to the medical sector. Positions in government are also open to you, especially in the area of public health. Some biomedical scientists choose to specialise in the legislation around patents and the protection of biomedical discoveries, and others begin careers as biology, chemistry or biotechnology teachers. Additionally, there is a current need for experts who can clearly communicate scientific information and research results to non-specialists and the general public.



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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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This. MRes Cancer Biology. course will give you advanced knowledge of cellular systems. You will learn about the pathogenesis of cancer, cardiovascular disease, diabetes and kidney fibrosis, along with an exploration of current approaches to cancer gene therapy and immunotherapy. Read more

This MRes Cancer Biology course will give you advanced knowledge of cellular systems. You will learn about the pathogenesis of cancer, cardiovascular disease, diabetes and kidney fibrosis, along with an exploration of current approaches to cancer gene therapy and immunotherapy.

Modules

  • Research Methods and Bioethics
  • Research Project
  • Cell Culture and Antibody Technology
  • Biology of Disease

COME VISIT US ON OUR NEXT OPEN DAY!

Visit us on campus throughout the year, find and register for our next open event on http://www.ntu.ac.uk/pgevents.



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Medway School of Pharmacy is a joint venture between the Universities of Greenwich and Kent. Since 2004, the Department has invested heavily in facilities and equipment. Read more
Medway School of Pharmacy is a joint venture between the Universities of Greenwich and Kent. Since 2004, the Department has invested heavily in facilities and equipment: it houses strong and vibrant research groups that span a range of pharmacy-related areas. Staff have a wealth of research experience and UK and international links with both industry and academic institutions. Our excellent relationship with both Greenwich and Kent gives the Department access to world-class research facilities. PhD studentships are awarded on a competitive basis and in a broad range of research areas, including chemistry and drug delivery, biological sciences and pharmacy practice.

The programme aims to give postgraduate students the integrated, broad-based research training needed to exploit the advances in pharmaceutical and biological sciences and pharmacy practice for conducting contemporary research. We also offer part-time MPhil/PhD programmes.

Visit the website http://www2.gre.ac.uk/study/courses/pg/res/pharm

What you'll study

Research areas and recent research topics include:

Chemistry and drug delivery
Synthesis and biological evaluation of potential anti-cancer agents
Structure-based drug design
Quantitive structure-activity relationship (QSAR) predication of ADMET properties
Controlled release
Particle engineering
Powder technology
Pharmaceutical technology
Novel drug delivery systems with a focus on respiratory drug delivery
Pharmacology, cell and molecular biology
Cancer gene therapy
Immunology of allergic response
Neuropharmacology
Neurobiology (circadian rhythms)
Control of microbial infection
Ion channels and their role in disease states
Pharmacy practice
Rational cost-effective use of drugs
Pharmaceutical care - with an emphasis on new models of care for specific patient groups
Medicines management
Pharmaceutical services, ethics and pharmacy practice

Fees and finance

Your time at university should be enjoyable and rewarding, and it is important that it is not spoilt by unnecessary financial worries. We recommend that you spend time planning your finances, both before coming to university and while you are here. We can offer advice on living costs and budgeting, as well as on awards, allowances and loans.Find out more about our fees and the support available to you at our:

- Postgraduate finance pages (http://www.gre.ac.uk/finance/pg)
- International students' finance pages (http://www.gre.ac.uk/finance/international)

Assessment

Students are assessed through their thesis and an oral examination.

Career options

Graduates from this programme can pursue positions in the pharmaceutical industry, consultancy, the NHS and other parts of the public sector, and academia.

Find out how to apply here - http://www2.gre.ac.uk/study/apply

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The Faculty of Engineering and Science offers advanced research training opportunities across a broad range of subject areas, including chemical, pharmaceutical, biomedical, environmental and sports sciences. Read more
The Faculty of Engineering and Science offers advanced research training opportunities across a broad range of subject areas, including chemical, pharmaceutical, biomedical, environmental and sports sciences. The research activities within the Department are supported by state of the art analytical and computer facilities.

Upon acceptance to a programme, students normally register initially for an MPhil, and at the end of the first year, the student is examined by viva voce for consideration for transfer to PhD. Upon completion of the Doctoral training, students are ideally equipped to work in an academic or industrial research environment.

Recent research project topics include:

- Solar energy conversion

- Synthesis of biologically active molecules

- Fragment-based drug discovery

- In situ monitoring of chemical reactions

- Treatment of contaminated soils by accelerated carbonation

- Production of novel silicate-based sorbents

- Integrated production of biodiesel from oilseed rape

- Pathogenesis of autoimmune diseases

- Bioremediation and composting technologies

- Expert Cognition and Training

The aims of the programme are:

- To develop, create and interpret new knowledge, through original research or other advanced scholarship, of a quality to satisfy peer review, extend the forefront of the discipline, and merit publication

- To systematically acquire an understanding of a substantial body of knowledge which is at the forefront of an academic discipline or area of professional practice

- To demonstrate the ability to conceptualise, design and implement a project for the generation of new knowledge, applications or understanding at the forefront of the discipline, and to adjust the project design in the light of unforeseen problems

- To show a detailed understanding of applicable techniques for research and advanced academic enquiry.

Visit the website http://www2.gre.ac.uk/study/courses/pg/res/scires

What you'll study

Research areas may include:

- Materials analysis
- Molecular spectroscopy, Advanced spectral analysis
- Biomaterials
- Formulation chemistry, Biophysical chemistry
- Pharmaceutical science
- Gene therapy
- Biochemistry, Cell biology
- Forensic science
- Environmental geochemistry
- Sports science and human performance
- Applied cognitive science

Fees and finance

Your time at university should be enjoyable and rewarding, and it is important that it is not spoilt by unnecessary financial worries. We recommend that you spend time planning your finances, both before coming to university and while you are here. We can offer advice on living costs and budgeting, as well as on awards, allowances and loans.

Find out more about our fees and the support available to you at our:

- Postgraduate finance pages (http://www.gre.ac.uk/finance/pg)
- International students' finance pages (http://www.gre.ac.uk/finance/international)

Assessment

Students are assessed through their thesis and an oral examination.

Career options

Graduates from this programme can pursue careers in industry, government and academia.

Find out how to apply here - http://www2.gre.ac.uk/study/apply

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