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Masters Degrees (Tissue Engineering For Regenerative Medicine)

We have 34 Masters Degrees (Tissue Engineering For Regenerative Medicine)

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Our MRes Tissue Engineering for Regenerative Medicine course gives students from biological, engineering and/or medical-related backgrounds the specialist knowledge and research skills to pursue a career in this field. Read more

Our MRes Tissue Engineering for Regenerative Medicine course gives students from biological, engineering and/or medical-related backgrounds the specialist knowledge and research skills to pursue a career in this field.

You will focus on strategies to repair, replace and regenerate various tissues and organs to solve major clinical problems, gaining insights into topical issues including stem cells, polymer technology, biomaterial fabrication/characterisation and gene delivery. You will learn how to identify major clinical needs and formulate novel therapeutic solutions.

This course has both taught and research components and is suitable for those with little or no previous research experience. You will learn practical skills through two research placements.

Tissue engineering and regenerative medicine as a discipline shows enormous potential for future health and, economically, there is a national demand for specific interdisciplinary training in this area.

We have a vast research network in this field comprising international experts from multiple disciplines and, as such, this course is a collaborative degree from the Faculty of Biology, Medicine and Health and the Faculty of Science and Engineering.

Teaching and learning

This course is structured around taught elements and laboratory-based research projects, with an emphasis on the research-based element.

You will gain hands-on laboratory experience through both the practical skills unit and research placements in tissue engineering/regenerative medicine-focused laboratories at the University lasting 25 weeks.

The course comprises five compulsory components:

  • research methods course unit - 15 credits;
  • tutorial course unit - 15 credits;
  • masterclass course unit - 15 credits;
  • practical skills course unit - 15 credits;
  • research placements:
  • part 1 - literature review and project proposal - 30 credits;
  • part 2 - a 25-week project including practical work, oral presentation and final dissertation, and an assessment of research performance - 90 credits.

You will experience the interdisciplinary nature of the field during the course and gradually increase the depth and complexity of your research through the masterclass unit.

Each project is written up and assessed separately when submitted during the year.

You will be allocated a personal tutor and a personal logbook is introduced at the start of the programme to monitor progress through the course and assess learning and career objectives.

Research placements

The research placements are the largest component of the course and aim to give you the specialist knowledge and practical skills to pursue a research career in tissue engineering and regenerative medicine, as well as develop your practical research expertise in a chosen area and enhance your ability to analyse and interpret data and summarise your findings in the form of written reports and an oral presentation.

The first placement runs alongside the taught units in Semester 1 and involves writing a comprehensive literature review and formulating a research project proposal.

The second placement (25 weeks) runs concurrently with the tutorial course unit for the first part, but is full-time thereafter. It involves hands-on practical experience in a laboratory and integration within a research team. The project is assessed by oral presentation at an end of year symposium, research performance and by submission of a dissertation.

You will choose from a list of research projects (see sample research projects ) and supervisors. Close interaction with the project supervisor at the start of the project and regular monitoring allows you to take responsibility for your own research development. The development of an interactive supervisory/student arrangement is often a useful grounding for future PhD collaboration.

Coursework and assessment

You will be assessed continually during the year through:

  • oral presentations;
  • group participation;
  • multiple choice questionnaires;
  • written reports;
  • a final dissertation.

Facilities

You will have access to a range of facilities throughout the University.

Disability support

Practical support and advice for current students and applicants is available from the Disability Support Office .

Career opportunities

After the course, many students continue their studies and register for a PhD.

However, the course is also of value to students wishing to progress in the pharmaceutical or biotechnology industry, or go into specialist clinical training.

It is also ideal for MBChB intercalating students who wish to undertake directly channelled research training in the tissue engineering/regenerative medicine field.

Associated organisations

You will benefit from close interaction with members of the following groups.



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Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Tissue Engineering and Regenerative Medicine at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017). Read more

Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Tissue Engineering and Regenerative Medicine at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).

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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Overview. Located within a European Centre of Excellence for Tissue engineering, and based on Keele’s University’s local hospital campus at the Guy Hilton Research Centre, the MSc in Cell and Tissue Engineering provides support and development to enhance your career within this rapidly expanding field. Read more

Overview

Located within a European Centre of Excellence for Tissue engineering, and based on Keele’s University’s local hospital campus at the Guy Hilton Research Centre, the MSc in Cell and Tissue Engineering provides support and development to enhance your career within this rapidly expanding field. The research centre is also an EPSRC Doctoral Training Centre for Regenerative Medicine, an Arthritis UK Centre and a UK Regenerative Medicine Platform Research Hub. This multidisciplinary environment enables close interaction with leading academics and clinicians involved in cutting-edge, and clinically transformative research.

Course Director: Dr Adam Sharples ()

Studying Cell and Tissue Engineering at Keele

Our MSc Cell and Tissue Engineering programme has tracked alongside the strongly emergent global Regenerative Medicine industry and will prepare you for an exciting future within a range of medical engineering areas, be that in academic or industrial research, medical materials, devices, or therapeutics sectors, or in the clinical arena. The modular structure to the course enables flexibility and personalisation to suit your career aspirations, build upon strengths and interests and develop new understanding in key topics.

Graduate destinations for our students could include: undertaking further postgraduate study and research (PhD); pursuing a university-based, academic research career; providing technical consultancy for marketing and sales departments within industry; working within biomedical, biomaterials, therapeutic, life science and regenerative medicine industries or working for a governmental regulatory agency for healthcare services and products.

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

‌‌The course provides support from the basics of human anatomy and physiology, through to development of novel nanotechnologies for healthcare. Due to the teaching and research involvement of clinical and academic staff within the department, there are exciting opportunities to be exposed to current clinical challenges and state-of-the-art developments. Clinical visits and specialist seminars are offered and students will be able to select dissertation projects that span fundamental research to clinical translation of technologies – a truly ‘bench to bedside’ approach.

Learning and teaching methods include lectures and demonstrations from medical and engineering specialists, practical classes using state-of-the-art facilities and seminars with leading national and international researchers. Full-time study will see the course completed in 12 months; part-time study will allow you to complete it over two years.

About the department

Delivered through the Keele School of Medicine and the Research Institute for Science and Technology in Medicine (ISTM), the course dates as far back as 1999, when it was established in partnership with Biomedical Engineering and Medical Physics at the University Hospital. Most teaching now takes place in the Guy Hilton Research Centre, a dedicated research facility located on the hospital campus. The medical school is one of the top-ranked in the UK, and the research institute has an international reputation for world-leading research.

The centre was opened in 2006 and offers state-of-the-art equipment for translational research including newly-developed diagnostic instruments, advanced imaging modalities and additive manufacturing facilities. Its location adjacent to the university hospital ensures that students experience real-world patient care and the role that technology plays in that. Students also have access to advanced equipment for physiological measurement, motion analysis and functional assessment in other hospital and campus-based laboratories. The School embraces specialists working in UHNM and RJAH Orthopaedic Hospital Oswestry, covering key medical and surgical subspecialties.

The course runs alongside its sister course, the MSc in Biomedical Engineering, and an EPSRC-MRC funded Centre for Doctoral Training, ensuring a stimulating academic environment for students and many opportunities for engaging with further study and research.

Course Aims

The aim of the course is to provide multidisciplinary Masters level postgraduate training in Cell and Tissue Engineering to prepare students for future employment in healthcare, industrial and academic environments. This involves building on existing undergraduate knowledge in basic science or engineering and applying it to core principles and current issues in medicine and healthcare.

Specifically, the objectives of the course are to:

- provide postgraduate-level education leading to professional careers in Cell and Tissue Engineering in industry, academia and a wide range of healthcare establishments such as medical organisations, medical research institutions and hospitals;

- provide an opportunity for in-depth research into specialist and novel areas of Biomaterials, and Cell and Tissue Engineering;

- expose students to the clinically translational environment within an active medical research environment with hands-on practical ability and supporting knowledge of up-to-date technological developments at the forefront of the field;

- introduce students to exciting new fields such as regenerative medicine, nanotechnology and novel devices for physiological monitoring and diagnostics.

Teaching and Learning Methods

The course is taught through subject-centred lectures and seminars, supported by tutorials and practical exercises. Collaborative learning and student-centred learning are also adopted giving widespread opportunity for group work and individual assignments. Students are required to conduct extensive independent study, and this is supported by full access to two libraries, online journal access and a suite of dedicated computers for exclusive use by MSc students on the course. In addition, students are supported by the guidance of a personal tutor within the department, as well as having access to university-wide support services. This includes English language support where appropriate.

Assessment

Modules will be assessed by a mixture of assessment methods, including lab reports, essays, and presentations, and final examination. This ensures the development of a range of transferrable employability skills such as time management and planning, written and verbal communication and numeracy as well as technical and subject-specific knowledge. The project dissertation forms a major component of the student’s assessed work.

Additional Costs

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

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



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Overview. The MSc in Biomedical Engineering at Keele is a multidisciplinary course that will prepare you for an exciting career across a wide range of areas of engineering in medicine, be that in academic or industrial research, the medical devices sector or in the clinical arena. Read more

Overview

The MSc in Biomedical Engineering at Keele is a multidisciplinary course that will prepare you for an exciting career across a wide range of areas of engineering in medicine, be that in academic or industrial research, the medical devices sector or in the clinical arena. The course is professionally accredited and suitable for people with both engineering and life science backgrounds, including medicine and subjects allied to medicine.

Course Director: Dr Ed Chadwick ()

Studying Biomedical Engineering at Keele

The course will cover the fundamentals of engineering in medicine, introduce you to the latest developments in medical technology, and expose you to the challenges of working with patients through clinical visits. Learning and teaching methods include lectures and demonstrations from medical and engineering specialists, practical classes using state-of-the-art facilities and seminars with leading national and international researchers.

Graduate destinations for our students could include: delivering non-clinical services and technology management in a hospital; designing, developing and manufacturing medical devices in the private sector; working for a governmental regulatory agency for healthcare services and products; undertaking further postgraduate study and research (PhD); pursuing a university-based, academic research career; or providing technical consultancy for marketing departments.

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

Course Accreditation by Professional Body

The course is accredited by the Institute for Physics and Engineering in Medicine, whose aims are to ensure that graduates of accredited programmes are equipped with the knowledge and skills for the biomedical engineering workplace, be that in industry, healthcare or academic environments. Accreditation gives you confidence that the course meets strict suitability and quality criteria for providing Masters-level education in this field.‌‌‌

About the department

Delivered through the Keele School of Medicine and the Research Institute for Science and Technology in Medicine (ISTM), the course dates as far back as 1999, when it was established in partnership with Biomedical Engineering and Medical Physics at the University Hospital. Most teaching now takes place in the Guy Hilton Research Centre, a dedicated research facility located on the hospital campus. The medical school is one of the top-ranked in the UK, and the research institute has an international reputation for world-leading research.

The centre was opened in 2006 and offers state-of-the-art equipment for translational research including newly-developed diagnostic instruments, advanced imaging modalities and additive manufacturing facilities. Its location adjacent to the university hospital ensures that students experience real-world patient care and the role that technology plays in that. Students also have access to advanced equipment for physiological measurement, motion analysis and functional assessment in other hospital and campus-based laboratories. The School embraces specialists working in UHNM and RJAH Orthopaedic Hospital Oswestry, covering key medical and surgical subspecialties.

The course runs alongside its sister course, the MSc in Cell and Tissue Engineering, and an EPSRC and MRC-funded Centre for Doctoral Training, ensuring a stimulating academic environment for students and many opportunities for engaging with further study and research.

Course Aims

The aim of the course is to provide multidisciplinary Masters level postgraduate training in Biomedical Engineering to prepare students for future employment in healthcare, industrial and academic environments. This involves building on existing undergraduate knowledge in basic science or engineering and applying it to core principles and current issues in medicine and healthcare.

Specifically, the objectives of the course are to:

- provide postgraduate-level education leading to professional careers in biomedical engineering in industry, academia and a wide range of healthcare establishments such as medical organisations, medical research institutions and hospitals;

- provide an opportunity for in-depth research into specialist and novel areas of biomedical and clinical engineering;

- expose students to practical work in a hospital environment with hands-on knowledge of patient care involving technological developments at the forefront of the field;

- introduce students to exciting new fields such as regenerative medicine and novel technologies for physiological monitoring and diagnostics.

Teaching and Learning Methods

The course is taught through subject-centred lectures and seminars, supported by tutorials and practical exercises. Collaborative learning and student-centred learning are also adopted giving widespread opportunity for group work and individual assignments. Students are required to conduct extensive independent study, and this is supported by full access to two libraries, online journal access and a suite of dedicated computers for exclusive use by MSc students on the course. In addition, students are supported by the guidance of a personal tutor within the department, as well as having access to university-wide support services. This includes English language support where appropriate.

Assessment

Modules will be assessed by a mixture of assessment methods, including lab reports, essays, and presentations, and final examination. This ensures the development of a range of transferrable employability skills such as time management and planning, written and verbal communication and numeracy as well as technical and subject-specific knowledge. The project dissertation forms a major component of the student’s assessed work.

Additional Costs

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

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



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Regenerative Medicine. MSc ( 1 year Full-time ). Overview. Regenerative medicine is an interdisciplinary field, which aims to repair diseased or damaged tissues using biological or cell-based technologies. Read more
Regenerative Medicine
MSc ( 1 year Full-time )

Overview

Regenerative medicine is an interdisciplinary field, which aims to repair diseased or damaged tissues using biological or cell-based technologies. It is a rapidly growing area of biomedical research that encompasses stem cell biology, tissue engineering, drug delivery, and nanotechnology. This MSc course provides advanced, multi-disciplinary training in the scientific principles and clinical applications of regenerative medicine, and is delivered jointly by Barts and The London School of Medicine and Dentistry and the School of Engineering and Materials Science.

Taught modules will develop a strong scientific foundation in the biology of stem cells and regeneration and the fundamental principles of biomaterials, tissue engineering and cellular reprogramming. Through an intensive 12-week research project, students will then gain hands on experience applying these concepts to problems in human health and the development of novel regenerative technologies.

Upon completion of the MSc in Regenerative Medicine, students will be well placed for further training at the PhD level or professional careers in the biotechnology and pharmaceutical industries.

Structure
The MSc in Regenerative Medicine is a one year, full-time programme. Students are required to complete 180 credits comprising taught and research modules.


Taught Modules (15 credits each)

o Cellular and Molecular Basis of Regeneration
o Stem Cell and Developmental Biology
o Advanced Tissue Engineering and Regenerative Medicine
o Research Skills and Methodology
o Biomaterials in Regenerative Medicine
o Tissue-specific Stem Cells
o Induced Pluripotent Stem Cells and Genome Engineering
o Ethics and Regulatory Affairs

Research Project in Regenerative Medicine (60 credits)
During the final 12 weeks of the course, students will work full time on their laboratory-based research projects. Students will select research projects from a wide range of topics in regenerative medicine. Examples include research on the cellular and molecular aspects of tissue regeneration, disease pathogenesis, development of stem cell therapies, design of novel nano-biotechnologies, or engineering biomaterials and tissue scaffolds.


Entry requirements
As a multi-disciplinary course, the MSc is appropriate for a wide range of students. Graduates with degrees in biological sciences or medicine will gain an in-depth understanding of the cellular and molecular aspects of regenerative medicine as well as an introduction to the interdisciplinary fields of biomaterials and tissue engineering. Similarly, students with a physical sciences background will have the opportunity to broaden their experiences and acquire new skills in the biological sciences.
Admission to the course is selective, and based upon academic credentials, research experience, and motivation. At a minimum, students must have an undergraduate degree equivalent to UK second-class honours from a recognised academic institution. Applicants are required to submit a statement of purpose and letter of recommendation with their application.
Applications are accepted all year round, but there are limited places to ensure high-quality training, so please apply early to avoid disappointment.

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This MSc will equip you with state-of-the-art knowledge of biomaterials, bioengineering, tissue engineering, medical engineering and related management topics. Read more

This MSc will equip you with state-of-the-art knowledge of biomaterials, bioengineering, tissue engineering, medical engineering and related management topics. Delivered by experts from across UCL and eminent visiting lecturers from industry and medical charities, this interdisciplinary programme attracts physical sciences, engineering and life sciences graduates, including those with qualifications in medicine.

About this degree

You will develop an advanced knowledge of topics in biomaterials and tissue engineering alongside an awareness of the context in which healthcare engineering operates, in terms of safety, environmental, social and economic aspects. You will also gain a wide range of intellectual, practical and transferable skills necessary for a career in this field.

Students undertake modules to the value of 180 credits.

The programme consists of eight core modules (120 credits) and a research dissertation (60 credits).

Core modules

  • Biomaterials
  • Tissue Engineering
  • Biofluids and Medical Devices
  • Biomechanics and Biostructures
  • Applications of Biomedical Engineering
  • Bioengineering
  • Medical Imaging (ionising and non-ionising)
  • Evaluation and Planning of Business Opportunities

Optional modules

There are no optional modules for this programme.

Dissertation/report

Culminating in a substantial dissertation and oral presentation, the research project focuses your research interests and develops high-level presentation, critical thinking and problem-solving skills. The project can be based in any relevant UCL department.

Teaching and learning

This dynamic programme is delivered through lectures, tutorials, individual and group projects, and practical laboratory work. Assessment is through written, oral and viva voce examinations, the dissertation and coursework (including the evaluation of laboratory reports, technical and project reports, problem-solving exercises, assessment of computational and modelling skills, and oral presentations).

Further information on modules and degree structure is available on the department website: Biomaterials and Tissue Engineering MSc

Careers

There are many career opportunities and the programme is suitable for students wishing to become academics, researchers or professionals and for those pursuing senior management careers, in manufacturing or healthcare engineering

Recent career destinations for this degree

  • Dentist, Dental Life
  • Good Manufacturing Process Scientist, RMS (Regenerative Medical System)
  • Postgraduate Research Assistant, University of Cambridge
  • PhD in Biomaterials and Tissue Engineering, UCL
  • PhD in Surgery, UCL

Employability

Delivered by leading researchers from across UCL, as well as industrial experts, you will have plenty of opportunities to network and keep abreast of emerging ideas in biomaterials and tissue engineering. Collaborating with companies and bodies such as the NHS, JRI Orthopaedics and Orthopaedics Research (UK) is key to our success and you will be encouraged to develop networks through the programme itself and through the department’s careers programme which includes employer-led events and individual coaching. We equip our graduates with the skills and confidence needed to play a creative and leading role in the professional and research community.

Careers data is taken from the ‘Destinations of Leavers from Higher Education’ survey undertaken by HESA looking at the destinations of UK and EU students in the 2013–2015 graduating cohorts six months after graduation.

Why study this degree at UCL?

There are internationally renowned research groups in biomaterials and bioengineering in UCL Engineering and you will have access to a state-of-the-art research portfolio.

In recent years, UCL Mechanical Engineering has seen unprecedented activity in refurbishing and re-equipping our laboratories. For example, six new biomaterials and bioengineering laboratories have been set up with funding from the Royal Society and Wolfson Foundation. A new biomaterials processing and forming laboratory is also available in the Materials Hub in the Engineering Building.

The programme is also delivered by leading researchers across UCL's Division of Medicine, Eastman Dental Institute, the Institute of Biomedical Engineering and visiting experts from other UK organisations.

Research Excellence Framework (REF)

The Research Excellence Framework, or REF, is the system for assessing the quality of research in UK higher education institutions. The 2014 REF was carried out by the UK's higher education funding bodies, and the results used to allocate research funding from 2015/16.

The following REF score was awarded to the department: Mechanical Engineering

90%: Aeronautical, Mechanical, Chemical and Manufacturing Engineering subjects; 95%: General Engineering subjects rated 4* (‘world-leading’) or 3* (‘internationally excellent’)

Learn more about the scope of UCL's research, and browse case studies, on our Research Impact website.



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You will develop advanced knowledge in all aspects of precision medicine including genomics, bioinformatics, structural biology, genetics and epigenetics of disease and their precision diagnosis and treatment, biomedical imaging techniques, nanomedicines; generation and analysis of big data. Read more

You will develop advanced knowledge in all aspects of precision medicine including genomics, bioinformatics, structural biology, genetics and epigenetics of disease and their precision diagnosis and treatment, biomedical imaging techniques, nanomedicines; generation and analysis of big data. You will gain awareness of the context in which precision medicine is being applied in healthcare, research and industry. You will also develop a range of intellectual, practical and transferable skills essential for a career in this field.

Students undertake modules to the value of 180 credits.

A Postgraduate Diploma (120 credits) is also offered.

A Postgraduate Certificate (60 credits) is also offered.

Core modules

The programme consists of four core modules (60 credits), four optional modules (60 credits) and a research project (60 credits).

  • Bioinformatics and Structural Biology
  • The Genetics and Epigenetics of disease
  • Advanced Biomedical Imaging Techniques I
  • Precision Diagnosis for Precision Medicine

Optional modules

Select four optional modules.

  • Multiomics and Ethics
  • Translational Biomedical Imaging of Disease & Therapy I
  • Mathematics, Computers and Medicine
  • Nanomedicines
  • Generation and Analysis of Big Data

Dissertation/report

All MSc students undertake an independent research project which can take the form of a wet lab/computer modelling based project or a literature project.

Teaching and learning

The programme is delivered through a combination of lectures, tutorials, self study, practical sessions and discussion groups. The research project forms one third of the programme. Each of the taught modules is assessed by unseen written examination (50%) and coursework (50%). The research project is assessed by the dissertation and viva.

Further information on modules and degree structure is available on the department website: Precision Medicine MSc

Funding

For a comprehensive list of the funding opportunities available at UCL, including funding relevant to your nationality, please visit the Scholarships and Funding website.

Careers

The MSc will provide an excellent background for those looking to establish a career in biotech, pharma, national research laboratories and NHS agencies. The knowledge and transferable skills delivered will also be useful for those who intend to pursue academic research or medical studies.

Why study this degree at UCL?

UCL, in partnership with UCL Hospitals, is an internationally renowned and productive centre with established strengths in translating pioneering scientific research into tangible treatments. The results of REF2014 show that UCL enjoys the greatest amount of “world leading” (4*) research in Medicine and Biological sciences. This was a tremendous achievement for the Division of Medicine, which led the return in Clinical Medicine for UCL. In Clinical Medicine, UCL was ranked first in the UK (according to Research Fortnight's Power Rankings), a testament to our research strength in the Division of Medicine.

The UCL Division of Medicine has significiant expertise in the field of precision medicine. The division has pioneered multidisciplinary research and successfully translated innovative research into useful clinical benefit. Students on the MSc will have the opportunity to interact and conduct research with leading groups in the field.

The UCL Division of Medicine research expertise includes: inflammation, internal medicine, metabolism, nephrology, respiratory, liver and digestive health, medicinal chemistry, computational drug design, neuronal development and signalling, cell cycle control, intensive care medicine, regenerative medicine, tissue engineering, nanomedicine, stem cells, mitochondrial biology and cancer.

Department: Division of Medicine

Student / staff numbers › 411 staff including 84 postdocs › 133 taught students › 193 research students 

Staff/student numbers information correct as of 1 August 2017.

Research Excellence Framework (REF)

The Research Excellence Framework, or REF, is the system for assessing the quality of research in UK higher education institutions. The 2014 REF was carried out by the UK's higher education funding bodies, and the results used to allocate research funding from 2015/16.

Learn more about the scope of UCL's research, and browse case studies, on our Research Impact website.

Application and next steps

Applications

Students are advised to apply as early as possible due to competition for places. Those applying for scholarship funding (particularly overseas applicants) should take note of application deadlines.

Application fee: There is an application processing fee for this programme of £75 for online applications and £100 for paper applications. More details about the application fee can be found at http://www.ucl.ac.uk/prospective-students/graduate/taught/application.

Who can apply?

This MSc is primarily suitable for life science or medical science graduates. Students with an interest in precision medicine who have a background in biological sciences, chemical sciences, physics, mathematics or pharmacy may also be eligible to apply.

What are we looking for?

When we assess your application we would like to learn:

  • why you want to study Precision Medicine at graduate level
  • why you want to study Precision Medicine at UCL
  • what particularly attracts you to the chosen programme
  • how your academic and professional background meets the demands of this programme
  • where you would like to go professionally with your degree

Together with essential academic requirements, the personal statement is your opportunity to illustrate whether your reasons for applying to this programme match what the programme will deliver.

Application deadlines

All applicants

27 July 2018

For more information see our Applications 

Apply Now: http://www.ucl.ac.uk/prospective-students/graduate/apply



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Tissue engineering is an ever-emerging interdisciplinary field of biomedical research, which combines life, engineering and materials sciences, to progress the maintenance, repair and replacement of diseased and damaged tissues. Read more
Tissue engineering is an ever-emerging interdisciplinary field of biomedical research, which combines life, engineering and materials sciences, to progress the maintenance, repair and replacement of diseased and damaged tissues. The Cardiff Institute of Tissue Engineering & Repair (CITER) MSc in Tissue Engineering aims to provide graduates from life sciences and clinical backgrounds with an advanced knowledge, understanding and skills in the science and practice of tissue engineering; from theoretical science, through to research translation and clinical application. The Programme provides in-depth training in this branch of biomedical science, including stem cell biology, biomaterials and tissue/organ engineering. The MSc offers a balanced combination of theory and practice; and can serve either as preparation for a PhD or as a self-contained advanced qualification in its own right. The MSc in Tissue Engineering is both lecture- and laboratory-based, and includes a number of opportunities to visit relevant clinical settings and local industrial partners. Graduates from this Programme will have a broad spectrum of knowledge and a variety of skills, making them highly attractive both to potential employers and research establishments.

Distinctive features of this course include:

• The first course of its kind in the UK, created in response to demand in the field of tissue engineering for interdisciplinary teaching.

• Excellent clinical, academic and research facilities.

• High probability of further research study and careers in tissue engineering and repair, relevant to the CITER MSc remit.

• Opportunity to study at Cardiff University, one of the UK’s major teaching and research universities.

• Opportunity to join a vibrant postgraduate community.

Structure

The CITER MSc Programme commences in September each year with Stage 1, a 6-month, taught component.

Stage 1 is taught almost entirely at a small group teaching level, supported by laboratory sessions, interactive workshops and tutorials, in addition to visits to relevant hospital clinics and local companies involved in producing tissue engineering and repair therapies. Modules are assessed by various written assignments, presentations and formal examinations.

On completing Stage 1, students undertake a 5-month, laboratory-based research project within the CITER network, between April-September (Stage 2). Projects are chosen by students from topics supplied by academic supervisors within CITER. Previous student projects have been in research areas such as embryonic or mesenchymal stem cell biology; cartilage, bone, skin or oral tissue repair; fibrosis; and biomaterials and drug delivery. Stage 2 culminates in the submission of an MSc Dissertation, based on MSc Project findings.

Core modules:

Cellular & Molecular Biology
Tissue Engineering From Concept To Clinical Practice
Research Methods
Stem Cells and Regenerative Medicine
Dissertation

Teaching

Teaching is delivered via lectures, laboratory sessions, interactive workshops and tutorials, in addition to visits to relevant hospital clinics, such as orthopaedics, nephrology and dermatology, and local companies involved in producing tissue engineering and repair therapies.

This Programme is based within the School of Dentistry and taught by academic staff from across Cardiff University and by external speakers.

All taught modules within the Programme are compulsory and students are expected to attend all lectures, laboratory sessions and other timetabled sessions. Students will receive supervision to help them complete the dissertation, but are also expected to engage in considerable independent study. Dissertation topics are normally chosen by the students from a list of options proposed by CITER academic staff in areas relevant to the MSc in Tissue Engineering.

Assessment

The 4 taught Modules within the Programme are assessed through in-course assessments, including:

Extended essays.
Oral presentations.
Poster presentations.
Statistical assignments.
Critical appraisals.
Dissertation (no more than 20,000 words).

Career prospects

After successfully completing this MSc, you should have a broad spectrum of knowledge and a variety of skills, making you highly attractive both to potential employers and research establishments.

Since its introduction in 2006, 95% of our MSc graduates have progressed onto career paths highly relevant to the CITER MSc remit. These include PhDs within CITER and at other UK, EU and USA Universities, Graduate-Entry Medicine, Specialist Registrar Training, Teaching, and positions in Industry and Clinical Laboratory settings.

Placements

You will have the opportunity to attend clinical attachments, in areas such as orthopaedics, nephrology and dermatology. Furthermore, you will also have the opportunity to visit local companies involved in producing tissue engineering and repair therapies for clinical use. These include Cell Therapy Ltd., Reneuron plc, Biomonde Ltd., and MBI Wales Ltd.

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Tissue engineering is an ever-emerging interdisciplinary field of biomedical research, which combines life, engineering and materials sciences, to progress the maintenance, repair and replacement of diseased and damaged tissues. Read more
Tissue engineering is an ever-emerging interdisciplinary field of biomedical research, which combines life, engineering and materials sciences, to progress the maintenance, repair and replacement of diseased and damaged tissues. The Cardiff Institute of Tissue Engineering & Repair (CITER) MSc in Tissue Engineering aims to provide graduates from life sciences and clinical backgrounds with an advanced knowledge, understanding and skills in the science and practice of tissue engineering; from theoretical science, through to research translation and clinical application. The Programme provides in-depth training in this branch of biomedical science, including stem cell biology, biomaterials and tissue/organ engineering. The MSc offers a balanced combination of theory and practice; and can serve either as preparation for a PhD or as a self-contained advanced qualification in its own right. The MSc in Tissue Engineering is both lecture- and laboratory-based, and includes a number of opportunities to visit relevant clinical settings and local industrial partners. Graduates from this Programme will have a broad spectrum of knowledge and a variety of skills, making them highly attractive both to potential employers and research establishments.

Distinctive features of this course include:

• The first course of its kind in the UK, created in response to demand in the field of tissue engineering for interdisciplinary teaching.

• Excellent clinical, academic and research facilities.

• High probability of further research study and careers in tissue engineering and repair, relevant to the CITER MSc remit.

• Opportunity to study at Cardiff University, one of the UK’s major teaching and research universities.

• Opportunity to join a vibrant postgraduate community.

Course structure

The CITER MSc Programme commences in September each year with Stage 1, a 6-month, taught component.

Stage 1 is taught almost entirely at a small group teaching level, supported by laboratory sessions, interactive workshops and tutorials, in addition to visits to relevant hospital clinics and local companies involved in producing tissue engineering and repair therapies. Modules are assessed by various written assignments, presentations and formal examinations.

On completing Stage 1, students undertake a 5-month, laboratory-based research project within the CITER network, between April-September (Stage 2). Projects are chosen by students from topics supplied by academic supervisors within CITER. Previous student projects have been in research areas such as embryonic or mesenchymal stem cell biology; cartilage, bone, skin or oral tissue repair; fibrosis; and biomaterials and drug delivery. Stage 2 culminates in the submission of an MSc Dissertation, based on MSc Project findings.

Core modules:

Cellular & Molecular Biology
Tissue Engineering From Concept To Clinical Practice
Research Methods
Stem Cells and Regenerative Medicine
Dissertation

Teaching

Teaching is delivered via lectures, laboratory sessions, interactive workshops and tutorials, in addition to visits to relevant hospital clinics, such as orthopaedics, nephrology and dermatology, and local companies involved in producing tissue engineering and repair therapies.

This Programme is based within the School of Dentistry and taught by academic staff from across Cardiff University and by external speakers.

All taught modules within the Programme are compulsory and students are expected to attend all lectures, laboratory sessions and other timetabled sessions. Students will receive supervision to help them complete the dissertation, but are also expected to engage in considerable independent study. Dissertation topics are normally chosen by the students from a list of options proposed by CITER academic staff in areas relevant to the MSc in Tissue Engineering.

Support

All Modules within the Programme make extensive use of Cardiff University’s Virtual Learning Environment (VLE) Blackboard, on which students will find course materials and links to related materials. Students will be supervised when undertaking their dissertation. Supervision will include scheduled regular meetings to discuss progress, provide advice and guidance; and provide written feedback on draft dissertation contents.

Feedback:

Students will receive written feedback on all assessments, in addition to oral feedback on assessed oral/poster presentations.

Assessment

The 4 taught Modules within the Programme are assessed through in-course assessments, including:

Extended essays.
Oral presentations.
Poster presentations.
Statistical assignments.
Critical appraisals.
Dissertation (no more than 20,000 words).

Career prospects

After successfully completing this MSc, you should have a broad spectrum of knowledge and a variety of skills, making you highly attractive both to potential employers and research establishments.

Since its introduction in 2006, 95% of our MSc graduates have progressed onto career paths highly relevant to the CITER MSc remit. These include PhDs within CITER and at other UK, EU and USA Universities, Graduate-Entry Medicine, Specialist Registrar Training, Teaching, and positions in Industry and Clinical Laboratory settings.

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Nanotechnology and Regenerative Medicine are rapidly expanding fields with the potential to revolutionise modern medicine. This cross-disciplinary programme provides students with a robust scientific understanding in these fields, combined with a "hands-on" practical and translational focus. Read more

Nanotechnology and Regenerative Medicine are rapidly expanding fields with the potential to revolutionise modern medicine. This cross-disciplinary programme provides students with a robust scientific understanding in these fields, combined with a "hands-on" practical and translational focus.

About this degree

This programme will equip students with a critical understanding of:

  • how nanotechnology can be harnessed for the improved detection and treatment of disease
  • the use of stem cells in medicine
  • tissue engineering strategies for tissue regeneration
  • improving biomaterials for directing cell behaviour
  • the regulatory, ethical and commercial hurdles for the translation of these emerging technologies.

Students undertake modules to the value of 180 credits.

The programme consists of five core modules (75 credits), one optional module (15 credits) and a research project (90 credits).

A PG Certificate (60 credits) is offered in Flexible/Modular study mode only, over a maximum two years. The programme consists of two core modules (30 credits) and two optional modules (30 credits).

Core modules

  • Nanotechnology in Medicine *
  • Applied Tissue Engineering *
  • Biomaterials
  • Research Methodologies
  • Practical Bio-Nanotechnology and Regenerative Medicine

*PG Cert - compulsory modules

Optional modules

Choose one of the following options; attendance at the other module is possible but will not be assessed.

  • Stem Cells in Medicine and their Applications in Surgery
  • Translation of Nanotechnology and Regenerative Medicine

Dissertation/report

All students undertake an extensive laboratory-based (90 credits) research project which culminates in a dissertation of c.15,000 words and an individual viva voce.

Teaching and learning

The programme is delivered through a combination of lectures, tutorials, workshops, group discussions, practical sessions, and demonstrations. Assessment is through presentations, problem-solving workshops, written practical reports, coursework, unseen written examinations and the dissertation.

Further information on modules and degree structure is available on the department website: Nanotechnology and Regenerative Medicine MSc

Funding

For a comprehensive list of the funding opportunities available at UCL, including funding relevant to your nationality, please visit the Scholarships and Funding website.

Careers

Student career options and progression during and following the completion of the degree are considered to be of the utmost importance. Personal tutors will offer individual advice and seminars are arranged on a variety of career competencies including CV writing, writing research proposals and positive personal presentation.

Networking with world-leading scientists, new biotechnology CEO's and clinicians is encouraged and enabled throughout the programme. Research output in terms of publishing papers and presenting at conferences is also promoted. 

Recent career destinations include:

  • Studying PhDs or Medicine at UCL, Imperial College London and Universities of Oxford and Cambridge
  • Clinical PhD training programmes
  • NHS hospitals in the UK
  • EU and overseas hospitals and research facilities

Recent career destinations for this degree

  • Data Integrity Analyst, IMS Health
  • Medical Device Analyst, GlobalData
  • Tissue Processing Specialist Consultant, UCL
  • PhD in Applied Engineering, Universidad de Navarra (University of Navarra)
  • PhD in Bioengineering, Imperial College London

Employability

Graduates of the programme gain the transferable laboratory, critical and soft skills, such as science communication, necessary to pursue a scientific or clinical research career in the fields of nanomedicine and regenerative medicine.

Careers data is taken from the ‘Destinations of Leavers from Higher Education’ survey undertaken by HESA looking at the destinations of UK and EU students in the 2013–2015 graduating cohorts six months after graduation.

Why study this degree at UCL?

Based within the world-leading medical research environment of the UCL Division of Surgery & Interventional Science this MSc retains a clinical focus and addresses real medicine needs. Students learn about the route of translation from research ideas into actual products which can benefit patients.

An in-depth laboratory-based research project is an integral component of the programme; expert support allows students to investigate cutting-edge projects and thereby open up opportunities for further research and publications.

Students are embedded within the vibrant research community of the Faculty of Medical Sciences which provides students - through research seminars, symposia and eminent guest lecturers - outstanding networking opportunities within the research, clinical and translational science communities.



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The Masters in Biomedical Engineering is an interdisciplinary programme that will equip you for employment within the biomedical engineering sector. Read more

The Masters in Biomedical Engineering is an interdisciplinary programme that will equip you for employment within the biomedical engineering sector. This programme addresses all the key aspects of biomedical engineering.

Why this programme

  • The University of Glasgow’s School of Engineering has been delivering engineering education and research for more than 150 years and is the oldest School of Engineering in the UK.
  • Biomedical Engineering is the newest division of the School, bringing together our long standing expertise. Research covers four themes, Biomaterials and Tissue Engineering, Bionanotechnology, Rehabilitation Engineering, Biosensors and Diagnostics.
  • The course is based on in-depth modules and individual projects, which are designed to give graduates an opportunity to specialise in specific areas of Biomedical Engineering or to cover a more general Biomedical Engineering syllabus.
  • This taught MSc/PG Dip offers a wide exposure to the philosophy and practice of Biomedical Engineering whilst simultaneously enabling the students to deepen their knowledge of specific areas of biomedical engineering disciplines, which have been chosen on the basis of the research strengths of the Discipline. The choice includes Biomaterials and Biomechanics including their application in Tissue Engineering and Regenerative Medicine, Rehabilitation Engineering includes applied within Glasgow hospital and bioelectronics and diagnostic systems, designed to be applied from advanced hospitals to out-in-the-field situations.
  • The compulsory part provides the basic underlying knowledge need throughout biomedical engineering these core courses are taken in both semesters to allow a wide range of optional subjects to be available.
  • You will broaden and/or deepen your knowledge of biomedical engineering disciplines.

Programme structure

Modes of delivery of the MSc in Biomedical Engineering include lectures, seminars and tutorials and allow students the opportunity to take part in lab, team work and study trips in the UK. You will undertake an MSc project working on a specific research area with one of the academics.

Core courses

  • Applications of biomedical engineering
  • Biological fluid mechanics
  • Cellular biophysics
  • Energy in biological systems
  • Medical imaging
  • Statistics for biomedical engineering
  • MSc project.

Optional courses

  • Advanced imaging and therapy
  • Applied engineering mechanics
  • Bioinformatics and systems biology
  • Biomechanics
  • Biosensors and diagnostics
  • Microscopy and optics
  • Nanofabrication
  • Rehabilitation engineering
  • Scaffolds and tissues
  • Signal processing of bio-signatures
  • Tissue and cell engineering.

Career prospects

Career opportunities include positions in rehabilitation engineering, biomaterials for reconstructive surgery, biosensors, device and implant design and development, and biosignal processing.



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The Masters in Biomedical Engineering is an interdisciplinary programme that will equip you for employment within the biomedical engineering sector. Read more

The Masters in Biomedical Engineering is an interdisciplinary programme that will equip you for employment within the biomedical engineering sector. This programme addresses all the key aspects of biomedical engineering.

Why This Programme

  • The University of Glasgow’s School of Engineering has been delivering engineering education and research for more than 150 years and is the oldest School of Engineering in the UK.
  • Biomedical Engineering is the newest division of the School, bringing together our long standing expertise. Research covers four themes, Biomaterials and Tissue Engineering, Bionanotechnology, Rehabilitation Engineering, Biosensors and Diagnostics.
  • The course is based on in-depth modules and individual projects, which are designed to give graduates an opportunity to specialise in specific areas of Biomedical Engineering or to cover a more general Biomedical Engineering syllabus.
  • This taught MSc/PG Dip offers a wide exposure to the philosophy and practice of Biomedical Engineering whilst simultaneously enabling the students to deepen their knowledge of specific areas of biomedical engineering disciplines, which have been chosen on the basis of the research strengths of the Discipline. The choice includes Biomaterials and Biomechanics including their application in Tissue Engineering and Regenerative Medicine, Rehabilitation Engineering includes applied within Glasgow hospital and bioelectronics and diagnostic systems, designed to be applied from advanced hospitals to out-in-the-field situations.
  • The compulsory part provides the basic underlying knowledge need throughout biomedical engineering these core courses are taken in both semesters to allow a wide range of optional subjects to be available.
  • You will broaden and/or deepen your knowledge of biomedical engineering disciplines.

Programme structure

Modes of delivery of the MSc in Biomedical Engineering include lectures, seminars and tutorials and allow students the opportunity to take part in lab, team work and study trips in the UK. You will undertake an MSc project working on a specific research area with one of the academics.

Core courses

  • Applications of biomedical engineering
  • Biological fluid mechanics
  • Cellular biophysics
  • Energy in biological systems
  • Medical imaging
  • Statistics for biomedical engineering
  • MSc project.

Optional courses

  • Advanced imaging and therapy
  • Applied engineering mechanics
  • Bioinformatics and systems biology
  • Biomechanics
  • Biosensors and diagnostics
  • Microscopy and optics
  • Nanofabrication
  • Rehabilitation engineering
  • Scaffolds and tissues
  • Signal processing of bio-signatures
  • Tissue and cell engineering.

Career prospects

Career opportunities include positions in rehabilitation engineering, biomaterials for reconstructive surgery, biosensors, device and implant design and development, and biosignal processing.



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Biomedical engineering is a fast evolving interdisciplinary field, which has been at the forefront of many medical advances in recent years. Read more

Biomedical engineering is a fast evolving interdisciplinary field, which has been at the forefront of many medical advances in recent years. As such, it is a research-led discipline, which sits at the cutting edge of advances in medicine, engineering and applied biological sciences.

This MSc programme is designed to provide an advanced biomedical engineering education and to develop specialist understanding; the programme contains a large project component which allows you to develop advanced knowledge and research skills in a specialist area.

The programme also aims to develop a multidisciplinary understanding of the subject, which can be applied in a variety of clinical, biomedical and industrial settings. All subjects are taught by biomedical/medical engineers and clinical scientists. This allows you to gain the related skills and experience in healthcare science and technology, engineering principles and manufacturing, and management of various industry standard medical devices.

Cutting-edge research feeds directly into teaching and various student projects, ensuring your studies are innovative, current and focused with direct relation to related industries. All academic staff are research active and very enthusiastic, leading to research led/taught core modules with an excellent pass rate.

What you will study

Modules

Core

Option

  • Regenerative Medicine
  • Genomic Coding
  • Clinical Biomechanics
  • Clinical Diagnostics
  • Polymer and Materials Engineering
  • Risk Assessment & Management
  • Engineering Computational Methods
  • Biomaterials with Implant Design & Technology

Learning and assessment

  • Formal and informal lectures
  • Tutorials
  • Laboratory practicals
  • Workshop skills
  • Seminars
  • Group and individually assessed projects

Facilities

Tissue characterisation laboratory, incorporating three state-of-the-art atomic force microscopes (AFM), which enables the nano- and microstructure of various tissues and other biomaterials to be characterised in great detail. This facility enables the mechanical, physical and biological performance characteristics of tissue/biomaterials to be better understood.

Modern cell/tissue engineering laboratory for in-vitro culturing of various cells/tissues such as skin, bone, cartilage, muscle, etc, and wound repair.

State-of-the-art human movement laboratory, which enables the movement and gait of patients to be analysed in great detail. In particular, the laboratory incorporates a new VICON motion capture facility.

Prosthetic/orthotic joint laboratory containing several state-of-the-art test machines, including a friction hip/knee simulator, for evaluating the performance of artificial hip and knee joints.

Human physiology laboratory for evaluating human physiological performance including EMG, ECG, Blood Pressure, Urine, skin analysis and Spirometry (lung function) tests, etc.

World-class bioaerosol test facility for performing microbiological experiments. This facility comprises a class two negatively pressurised chamber, into which microorganisms can be safely nebulised, thus enabling infection control interventions to be evaluated.

Electrostatics laboratory for evaluating the impact of electrical charge on biological and medical systems.

Medical Electronics Laboratory equipped for the design and manufacturing of Medical diagnostic devices such as Electrocardiography (ECG), Pacemaker, Oximeter and Heart Rate Monitoring, etc.

Other Engineering Laboratories for related subjects such as materials testing and characterisation. Labs and Workshops shared with Mechanical Engineering undergraduate and postgraduate students.

Career prospects

Biomedical Engineering is a growing, increasingly important field, with many significant diagnostic and therapeutic advances pioneered by biomedical engineers. It is highly interdisciplinary in nature and requires engineers who are flexible, able to acquire new skills, and who have a broad knowledge base. In particular, given the research-lead nature of the discipline, there is demand for engineers who can work effectively in a research-lead environment and who can push forward technological boundaries.

Consequently, there is need for people with advanced knowledge and skills, who have a good appreciation of developments in the clinical and biological fields. The MSc in Advanced Biomedical Engineering programme is designed to give you this. 

There is a shortage of professionally qualified engineers in both routine clinical and medical research activities in hospitals, industrial research centres and companies that design, maintain, repair and manufacture electronic medical devices and equipment for public and private health services

We aim to produce postgraduates who aspire to challenging careers in industry, the National Health Service (NHS), commerce and the public sector or to developing their own enterprises. You should therefore be able to move directly into responsible roles in employment with a minimum of additional training. This aim is achieved by:

  • Providing a supportive, structured environment in which students are encouraged to develop independent learning and research skills
  • Developing subject knowledge and understanding, developing discipline skills and developing personal transferable skills, to enable graduates to pursue programmes of advanced study, or to move directly into responsible employment

Various local and national companies including NHS trusts are invited for graduate careers/schemes and for providing placement year specific to biomedical/medical engineering students.

Study support

You will be allocated a personal tutor who is someone with whom you will be able to talk about any academic or personal concerns. There are time-tabled personal tutorial hours per week throughout the academic year, including feedback sessions for all assignments and group/individual projects.

Programme leaders are available for any related matters and advice is given regularly towards curriculum and progression.

University central services are rich with support teams to assist students with every aspect of their journey through our degree programmes. From our Career and Employability Service, through our strong Students' Union, to our professional and efficient Student Finance team, there are always friendly faces ready to support you and provide you with the answers that you need.

Research

At Bradford, you’ll be taught only by lecturers who are involved in cutting edge research and you'll work in their research laboratories, using top-class facilities.



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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.

About this degree

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 Science

Immunotherapy specialisation

  • Inflammation and Disease
  • Stem Cell Therapy
  • Ethics, Translations & Commercialisation
  • Tissue Engineering and Regenerative Medicine
  • Transplantation Science

Transplantation Science specialisation

  • Applied Biomaterials
  • Ethics, Translation & Commercialisation
  • Immunological Basis of Disease
  • Stem Cell Therapy
  • Tissue Engineering and Regenerative Medicine
  • Inflammation and Disease

Dissertation/report

Students undertake a research project culminating in a dissertation of 5,000 words in the style of a manuscript for scientific publication.

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.

Further information on modules and degree structure is available on the department website: Human Tissue Repair MSc

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.

Research Excellence Framework (REF)

The Research Excellence Framework, or REF, is the system for assessing the quality of research in UK higher education institutions. The 2014 REF was carried out by the UK's higher education funding bodies, and the results used to allocate research funding from 2015/16.

The following REF score was awarded to the department: Division of Medicine

80% rated 4* (‘world-leading’) or 3* (‘internationally excellent’)

Learn more about the scope of UCL's research, and browse case studies, on our Research Impact website.



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Biomedical Engineering is a field of engineering that relies on highly inter- and multi-disciplinary approaches to research and development, in order to address biological and medical problems. Read more
Biomedical Engineering is a field of engineering that relies on highly inter- and multi-disciplinary approaches to research and development, in order to address biological and medical problems. Specialists in this area are trained to face scientific and technological challenges that significantly differ from those related to more traditional branches of engineering. Nevertheless, at the same time Biomedical Engineering makes use of more traditional engineering methodologies and techniques, which are adapted and further developed to meet specifications of biomedical applications.

This MSc programme covers the following topics:

• Fundamentals of human physiology;
• Ethics and regulatory affairs in the biomedical field;
• Advanced aspects of tissue engineering, regenerative medicine and biomaterials;
• Advanced techniques to synthesize and/or characterise materials for biomedical engineering;
• Mechanics of tissues, cells and sub-cellular components;
• Biocompatibility of implantable materials and devices;
• Materials and techniques for nanotechnology and nanomedicine.

Applications are welcome from students with a background in physical sciences (Chemistry, Physics, Mathematics and Materials Science) or Engineering.The programme has strong roots within the well-recognised expertise of the academics that deliver the lectures, who have international standing in cutting-edge research on Biomaterials and Tissue Engineering.

This fact ensures that the programme is delivered with the highest standards in the field. The students also benefit from access to state-of-the-art facilities and instrumentation in the areas of Biomaterials and Tissue Engineering, while undertaking research projects in brand-new large laboratories that are the result of a recent multi-million investment from the College.

The programme is designed with a careful balance of diversified learning components, such that, on completion of their studies, the postgraduates acquire extensive knowledge and skills that make them able to undertake careers in a wide range of professional ambits within the biomedical field, including health care services, industry and scientific research

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