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Masters Degrees in Biomedical Imaging, United Kingdom

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Imaging has contributed to some of the most significant advances in biomedicine and healthcare and this trend is accelerating. Read more
Imaging has contributed to some of the most significant advances in biomedicine and healthcare and this trend is accelerating. This MSc, taught by leading scientists and clinicians, will equip imaging students from all science backgrounds with detailed knowledge of the advanced imaging techniques which provide new insights into cellular, molecular and functional processes, preparing them for a PhD or a career in industry.

Degree information

Imaging is essential for diagnosis of disease and development of novel treatments. This programme focuses on translational medical imaging, and the development and use of preclinical imaging technologies to detect, monitor and prevent illnesses such as cancer, heart diseases and neurodegeneration. Students will undertake an independent research-based project in UCL’s world-class laboratories and develop their communication skills in biomedical science.

Students undertake modules to the value of 180 credits.

The programme consists of six core modules (120 credits), and a research dissertation (60 credits). A Postgraduate Diploma (120 credits, full-time) is offered. A Postgraduate Certificate (60 credits, full-time) is offered. There are no optional modules for this programme.

Core modules
-Advanced Biomedical Imaging Techniques I & II
-Practical Preclinical Research (including Home Office Personal Licence)
-Translational Biomedical Imaging of Disease and Therapy I & II
-Science Communication for Biomedicine
-Statistical Methods in Research
-Ethics and Regulation of Research

Dissertation/report
All MSc students undertake an independent research project which culminates in a dissertation of 7,000 words or a manuscript suitable for submission to a peer-reviewed journal.

Teaching and learning
The programme is delivered through a combination of seminars, lectures, laboratory work, site visits and practicals. Assessment is through examination, presentations, essays, practical reports and the dissertation.

Careers

UCL is involved in the dynamic and successful London-based entrepreneurial activity in biomedical imaging. It has a strong track record in placing postgraduates in key positions within industry (e.g. Siemens, Philips, GE Healthcare, GSK, SMEs and start-ups) and at other leading academic institutions with preclinical imaging facilities, including the Universities of Oxford and Cambridge in the UK, and MIT and NIH in the US. This MSc will provide ideal training for students who wish to apply to UCL’s EPSRC Centre for Doctoral Training in Medical Imaging.

Employability
This programme belongs to the School of Life and Medical Sciences; one of the largest and most prestigious aggregations of academics in its field, with a global reputation for teaching informed by cutting-edge research. Our close links with major hospitals and industry allow students to perform significant research projects.

Students will foster an awareness of the commercial opportunities and diverse funding mechanisms for the development of new ideas, technologies and applications using imaging. Our learning methods will prepare students for careers in academic or industrial science, as well as providing transferable skills in presentation, writing, organisation and team work.

The first cohort of students on the Advanced Biomedical Imaging MSc are due to graduate in 2016, therefore no information on graduate destinations is currently available.

Why study this degree at UCL?

UCL offers a world-class environment in medical imaging and hosts several medical and biomedical imaging centres of excellence.

The UCL Centre for Advanced Biomedical Imaging is one of the world’s most advanced imaging centres, with 11 state-of-the-art imaging technologies, and is dedicated to developing imaging techniques of the future. Biomedical imaging is an interdisciplinary field drawing together biology, medicine, physics, engineering, and art.

The MSc is linked to University College London Hospitals (UCLH), including Great Ormond Street Hospital, the UCH Macmillan Cancer Centre and National Hospital for Neurology and Neurosurgery. This will provide an ideal training for further research and applications for a PhD at UCL Centre for Doctoral Training in Medical Imaging.

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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 MSc Medical Imaging programme is intended to provide a Masters-level postgraduate education in the knowledge, skills and understanding of engineering design of advanced medical and biotechnology products and systems. Read more
The MSc Medical Imaging programme is intended to provide a Masters-level postgraduate education in the knowledge, skills and understanding of engineering design of advanced medical and biotechnology products and systems. Students will also acquire a working knowledge of the clinical environment to influences their design philosophy.

Why study Medical Imaging at Dundee?

With biotechnology replacing many of the traditional engineering disciplines within the UK, this programme will allow you to develop the skills to apply your engineering or scientific knowledge to technologies that further the developments in this field. As a result, employment opportunities will be excellent for graduates, both in research and in industry.

We have an active research group, and you will be taught by leading researchers in the field.

What's so good about Medical Imaging at Dundee?

The MSc in Medical Imaging at the University of Dundee will:

Provide knowledge, skills and understanding of medical imaging technologies, particularly in modern biomedical, radiological and surgical imaging instrumentation, biomaterials, biomechanics and tissue engineering

Enhance your analytical and critical abilities, competence in multi-disciplinary research & development

Provide broad practical training in biology and biomolecular sciences sufficient for you to understand the biomedical nomenclature and to have an appreciation of the relevance and potential clinical impact of the research projects on offer

Allow you to experience the unique environment of clinical and surgical aspects in medical imaging in order to provide an understanding of the engineering challenges for advanced practice

Provide core training in electrical, microwave, magnetic, acoustic and optical techniques relevant to the life sciences interface and

Provide broad experience of analytical and imaging techniques relevant for biology, biomolecular and clinical sciences
provide core training in acoustic ultrasound technologies.

Who should study this course?

This course is suitable for students who are recent graduates of mechanical engineering courses or other related programmes.

This course has two start dates - January & September, and lasts for 12 months.

How you will be taught

The programme will involve a variety of teaching formats including lectures, tutorials, seminars, hands-on imaging classes, laboratory exercises, case studies, coursework, and an individual research project.

The teaching programme will include visits to and seminars at IMSaT and clinical departments at Ninewells Hospital and Medical School and Tayside University Hospitals Trust, including the Clinical Research Centre, the Departments of Medicine, Surgery, Dentistry and ENT, the Vascular Laboratory and Medical Physics.

A high degree of active student participation will be encouraged throughout. Taught sessions will be supported by individual reading and study. You will be guided to prepare your research project plan and to develop skills and competence in research including project management, critical thinking and problem-solving, project report and presentation.

What you will study

The course is divided into two parts:

Part I has 60 credits:

Biomechanics (20 Credits)
Biomaterials (20 Credits)
Bioinstrumentation (10 Credits)
Introduction to Medical Sciences (10 Credits)

Part II has one taught module and a research project module. It starts at the beginning of the University of Dundee's Semester 2, which is in mid-January:

Taught module: Advanced Biomedical Imaging Technologies (30 Credits).
Research project (30 Credits for diploma or 90 Credits for MSc)

How you will be assessed

The taught modules will be assessed by a combination of written examinations and coursework. The research project will be assessed by a written thesis and oral presentation.

Careers

This Master's programme provides you with the skills to continue into research in areas such as biomedical and biomaterials engineering as well as progression into relevant jobs within the Mechanical Engineering and Mechatronics industries.

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By the end of the MSc programme students will have received a thorough academic grounding in Medical Imaging, been exposed to the practice of Medical Imaging in a hospital Department, and carried out a short research project. Read more

Your programme of study

By the end of the MSc programme students will have received a thorough academic grounding in Medical Imaging, been exposed to the practice of Medical Imaging in a hospital Department, and carried out a short research project. The MSc programme is accredited by the Institute of Physics & Engineering in Medicine as fulfilling part of the training requirements for those wishing to work in the NHS.

Courses listed for the programme

Semester 1
Radiation in Imaging
Introduction to Computing and Image Processing

Biomedical and Professional Topics in Healthcare Science
Imaging in Medicine
Generic Skills

Semester 2
Nuclear Medicine and Positron Emission Tomography
Magnetic Resonance Imaging
Medical Image Processing and Analysis
Diagnostic and Radiation Protection

Semester 3
MSc Project for Programme in Medical Physics and Medical Imaging

Find out more detail by visiting the programme web page
https://www.abdn.ac.uk/study/postgraduate-taught/degree-programmes/178/medical-imaging/

Why study at Aberdeen?

• You have the opportunity to contribute research within the department, expanding the knowledge of medical imaging technology
within the largest teaching hospital and Medical School in Europe
• You have access to a PET-CT scanner, new radiotherapy centre and linac treatment machines.
• The university won the Queens Anniversary Prize in recognition of achievements in new medical imaging techniques
• The MRI scanner was invented at the University over 30 years ago

Where you study

• University of Aberdeen
• 12 or 24 months
• September

International Student Fees 2017/2018

Find out about fees:
https://www.abdn.ac.uk/study/international/tuition-fees-and-living-costs-287.php

*Please be advised that some programmes have different tuition fees from those listed above and that some programmes also have additional costs.

Scholarships

View all funding options on our funding database via the programme page
https://www.abdn.ac.uk/study/postgraduate-taught/finance-funding-1599.php
https://www.abdn.ac.uk/funding/

Living in Aberdeen

Find out more about:
• Your Accommodation
• Campus Facilities
• Aberdeen City
• Student Support
• Clubs and Societies

Find out more about living in Aberdeen:
https://abdn.ac.uk/study/student-life

Living costs
https://www.abdn.ac.uk/study/international/finance.php

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This Masters in Sensor and Imaging Systems (SIS) focuses on the technologies and techniques that underpin a vast range of societal, research and industrial needs. Read more
This Masters in Sensor and Imaging Systems (SIS) focuses on the technologies and techniques that underpin a vast range of societal, research and industrial needs. It is delivered and awarded jointly by the Universities of Glasgow and Edinburgh. Sensing and sensor systems are essential for advances in research across all fields of physics, engineering and chemistry and are enhanced when multiple sensing functions are combined into arrays to enable imaging. Industrial applications of sensor systems are ubiquitous: from mass-produced sensors found in modern smart phones and every modern car to the state-of-the-art, specialist high-value sensors routinely used in oil and gas recovery, scientific equipment, machine tools, medical equipment and environmental monitoring. This is an industry-focused programme, designed for people looking to develop skills that will open up opportunities in a host of end applications.

Why this programme

◾This is a jointly taught and awarded degree from the University of Glasgow and the University of Edinburgh, developed in with conjunction with CENSIS.
◾CENSIS is a centre of excellence for Sensor and Imaging Systems (SIS) technologies, CENSIS enables industry innovators and university researchers to collaborate at the forefront of market-focused SIS innovation, developing products and services for global markets.
◾CENSIS, the Innovation Centre for Sensor and Imaging Systems, is one of eight Innovation Centres that are transforming the way universities and business work together to enhance innovation and entrepreneurship across Scotland’s key economic sectors, create jobs and grow the economy. CENSIS is funded by the Scottish Funding Council (£10m) and supported by Scottish Enterprise, Highlands and Islands Enterprise and the Scottish Government.
◾CENSIS has now launched its collaborative MSc in Sensor and Imaging Systems, designed to train the next generation of sensor system experts.
◾This programme will allow you to benefit from the commercial focus of CENSIS along with the combined resources and complementary expertise of staff from two top ranking Russell Group universities, working together to offer you a curriculum relevant to the needs of industry.
◾The Colleges of Science and Engineering at the University of Glasgow and the University of Edinburgh delivered power and impact in the 2014 Research Excellent Framework. Overall, 94% of Edinburgh’s and 90% of Glasgow’s research activity is world leading or internationally excellent, rising in Glasgow’s case to 95% for its impact.
◾Fully-funded places and bursaries are available to Scottish/EU candidates. Further information on funded places.

Programme structure

The programme comprises a mix of core and optional courses. The curriculum you undertake is flexible and tailored to your prior experience and expertise, your particular research interests, and the specific nature of the extended research project topic provisionally identified at the beginning of the MSc programme.

Graduates receive a joint degree from the universities of Edinburgh and Glasgow.

Programme timetable
◾Semester 1: University of Glasgow
◾Semester 2: University of Edinburgh
◾Semester 3: MSc project, including the possibility of an industry placement

Core courses
◾Circuits and systems
◾Fundamentals of sensing and imaging
◾Imaging and detectors
◾Technology and innovation management
◾Research project preparation.

Optional courses
◾Biomedical imaging techniques
◾Biophysical chemistry
◾Biosensors and instrumentation
◾Chemical biology
◾Digital signal processing
◾Electronic product design and manufacture
◾Electronic system design
◾Entrepreneurship
◾Lab-on-chip technologies
◾Lasers and electro-optic systems
◾Microelectronics in consumer products
◾Microfabrication techniques
◾Nanofabrication
◾Physical techniques in action
◾Waves and diffraction.

Career prospects

You will gain an understanding of sensor-based systems applicable to a whole host of markets supported by CENSIS.

Career opportunities are extensive. Sensor systems are spearheading the next wave of connectivity and intelligence for internet connected devices, underpinning all of the new ‘smart markets’, e.g., grid, cities, transport and mobility, digital healthcare and big data.

You will graduate with domain-appropriate skills suitable for a range of careers in areas including renewable energy, subsea and marine technologies, defence, automotive engineering, intelligent transport, healthcare, aerospace, manufacturing and process control, consumer electronics, and environmental monitoring.

Globally, the market for sensor systems is valued at £500Bn with an annual growth rate of 10%. The Scottish sensor systems market is worth £2.6Bn pa. There are over 170 sensor systems companies based in Scotland (SMEs and large companies), employing 16,000 people in high-value jobs including product R&D, design, engineering, manufacturing and field services.

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This industry-focused programme - run jointly by the universities of Edinburgh and Glasgow - focuses on the principles, methods, techniques and technologies that underpin a vast range of needs in applications spanning from research to industry to medicine. Read more

This industry-focused programme - run jointly by the universities of Edinburgh and Glasgow - focuses on the principles, methods, techniques and technologies that underpin a vast range of needs in applications spanning from research to industry to medicine.

The programme is designed for students looking to develop the skills and knowledge that will open up opportunities in the many companies developing sensor and image based solutions.

Sensing and sensor systems are essential for advances in research across all fields of physics, engineering and chemistry and can be enhanced when multiple sensing functions are combined into arrays to enable imaging.

Industrial applications of sensor systems are ubiquitous: from mass-produced sensors found in modern smartphones and cars to the state-of-the-art, specialist high-value sensors routinely used in oil and gas recovery, scientific equipment, machine tools, medical equipment and environmental monitoring.

Programme structure

This programme is run over 12 months. The first semester of taught courses is run at the University of Glasgow and the second at the University of Edinburgh. The taught courses are followed by a research project, carried out at either university, leading to the production of your masters thesis.

Semester 1

Semester 1 is delivered at the University of Glasgow.

  • Sensing and Imaging
  • Imaging and Detectors
  • Detection and Analysis of Ionising Radiation
  • Circuits and Systems
  • Optional course in physics or engineering

Semester 2

Semester 2 is delivered at the University of Edinburgh.

Two compulsory courses:

  • Applications of Sensor and Imaging Systems
  • Research Project Preparation

Two optional courses in engineering and/or chemistry:

  • Biophysical Chemistry
  • Biosensors and Instrumentation
  • Lab-on-Chip Technologies
  • Biomedical Imaging Techniques
  • Microfabrication Techniques

Career opportunities

Sensor and imaging systems (SIS) underpin a vast range of societal, research and industrial needs. Sensing is essential for advances in capability across all fields of physics, engineering and chemistry and is enhanced when individual sensing units are configured in arrays to enable imaging and when multiple sensing functions are integrated into a single smart system.



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If you want to work within imaging and medical physics to pursue a medical career in hospitals, industry and healthcare and diagnose disease by different methods of imaging the degree in Medical Physics will help you towards this goal. Read more

Your programme of study

If you want to work within imaging and medical physics to pursue a medical career in hospitals, industry and healthcare and diagnose disease by different methods of imaging the degree in Medical Physics will help you towards this goal. You can also develop your own research portfolio and PhD from this MSc and work within academia to pursue innovation in the discipline.

You receive a thorough academic grounding in Medical Physics, are exposed to its practice in a hospital environment, and complete a short research project. Many graduates take up careers in health service medical physics, either in the UK or their home country. The MSc programme is accredited by the Institute of Physics & Engineering in Medicine as fulfilling part of the training requirements for those wishing to work in the NHS.

Courses listed for the programme

Semester 1
Biomedical and Professional Topics in Healthcare Science
Imaging in Medicine
Radiation in Medicine
Computing and Electronics in Medicine
Generic Skills

Semester 2
Radiation and Radiation Physics
Nuclear Medicine and Post Emission Tomography
Magnetic Resonance Imaging
Medical Electronics and Instrumentation
Medical Image Processing and Analysis
Diagnostic Radiology and Radiation Protection

Semester 3
Project Programmes in Medical Physics and Medical Imaging

Find out more detail by visiting the programme web page
https://www.abdn.ac.uk/study/postgraduate-taught/degree-programmes/180/medical-physics/

Why study at Aberdeen?

• You are taught by renowned researchers with opportunity to contribute to the expanding research portfolio
• You learn in a cutting edge medical facility adjacent to the teaching hospital including a PET-CT scanner, radiotherapy centre and
linac treatment machines, plus MRI scanners
• The MRI scanner was invented and developed at University of Aberdeen

Where you study

• University of Aberdeen
• 12 months or 24 months
• Full time or Part Time
• September

International Student Fees 2017/2018

Find out about fees:
https://www.abdn.ac.uk/study/international/tuition-fees-and-living-costs-287.php

*Please be advised that some programmes have different tuition fees from those listed above and that some programmes also have additional costs.

Scholarships

View all funding options on our funding database via the programme page
https://www.abdn.ac.uk/study/postgraduate-taught/finance-funding-1599.php
https://www.abdn.ac.uk/funding/

Living in Aberdeen

Find out more about:
• Your Accommodation
• Campus Facilities
• Aberdeen City
• Student Support
• Clubs and Societies

Find out more about living in Aberdeen:
https://abdn.ac.uk/study/student-life

Living costs
https://www.abdn.ac.uk/study/international/finance.php

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This internationally recognised course will prepare you for a fulfilling career as a biomedical scientist in the rapidly developing bioscience and healthcare sectors. Read more
This internationally recognised course will prepare you for a fulfilling career as a biomedical scientist in the rapidly developing bioscience and healthcare sectors.

This course is designed to enable you pursue a career as a professional biomedical scientist in a variety of research, development and leadership roles.

You'll be supported by an internationally recognised and highly active biomedicine science group with varied research interests and links with healthcare industries, research institutes and the NHS.

See the website http://www.napier.ac.uk/en/Courses/MSc-Biomedical-Science-Postgraduate-FullTime

What you'll learn

This course provides detailed knowledge of key concepts in immunology, toxicology, pharmacology and disease biology and how these disciplines are applied in biomedical science.

You’ll gain critical understanding of specialist research areas and unique insights into the challenges currently facing biomedical science. You’ll also acquire an in-depth appreciation of research and development practices in the healthcare industries through guest lectures and site visits to specialised laboratories. These experiences will allow you to explore and critique issues of relevance to professional working practice, enhancing your skills in evidence based decision making.

There is an emphasis on developing your practical laboratory skills with various opportunities for hands-on experience in a range of current techniques and practices. In your final trimester you’ll undertake an independent project within a vibrant biomedical research team, allowing you to apply and further develop your technical, research and professional skills. There may be the opportunity to conduct your research project externally in a relevant organisation or industry.

You’ll also develop key skills including communication, problem solving, team work, project management, and leadership. You’ll learn through interactive lectures, workshops, tutorials and laboratory sessions, and by engaging with guided independent study. A variety of assessment tools are used to enhance and evaluate your learning.

This is a full-time course over one year and is split up into three trimesters. You can choose to start in either January or September There may also be some opportunities to study abroad.

This programme is also available as a Masters by Research: http://www.napier.ac.uk/research-and-innovation/research-degrees/courses

Modules

• Advanced immunology
• Biology of disease and therapeutics
• Molecular pharmacology and toxicology
• Research skills
• Molecular pathogenesis of microbial Infection
• Drug design and chemotherapy
• Research project

Study modules mentioned above are indicative only. Some changes may occur between now and the time that you study.

Careers

You’ll be prepared for employment in the rapidly developing bioscience and healthcare sectors. This may be in hospitals, NHS, local government or health and safety divisions in various roles including research, R&D support management and consultancy.

Opportunities also exist for qualified biomedical scientists in a range of industrial settings from smaller medical biotechnology enterprises to global pharmaceutical companies.

If you currently work in the biomedical sector, this programme will enhance your prospects for career progression. Graduates will also be qualified to continue their studies at PhD level and follow an academic career.

How to apply

http://www.napier.ac.uk/study-with-us/postgraduate/how-to-apply

SAAS Funding

Nothing should get in the way of furthering your education. Student Awards Agency Scotland (SAAS) awards funding for postgraduate courses, and could provide the help you need to continue your studies. Find out more: http://www.napier.ac.uk/study-with-us/postgraduate/fees-and-funding/saas-funded-courses

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This course has been specifically designed as, a 'top-up' qualification for individuals who wish to become Health and Care Professions Council (HCPC)-registered biomedical scientists but who do not hold an Institute of Biomedical Science (IBMS)-accredited BSc Honours degree. Read more
This course has been specifically designed as, a 'top-up' qualification for individuals who wish to become Health and Care Professions Council (HCPC)-registered biomedical scientists but who do not hold an Institute of Biomedical Science (IBMS)-accredited BSc Honours degree. This programme is accredited by the IBMS and, in combination with a suitable first degree, the Applied Biomedical Science MSc will ensure that you possess the required academic knowledge for HCPC registration.

When you have completed both this course and the IBMS registration training portfolio (and been awarded your Certificate of Competence from the IBMS) you will then meet the HCPC standards of competency and can apply to become registered as a Biomedical Scientist.

The combination of modules that you study will be based in part upon your requirements for supplementary education as identified by the IBMS but, depending on the number of compulsory modules required, there is still some scope to tailor the course to match your own interests. The course also includes the opportunity to study Masters-level research projects in an area of your interest.

Modules

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

Core modules
-POSTGRADUATE RESEARCH METHODS
-POSTGRADUATE PROJECT

Option modules
-CELLULAR PATHOLOGY
-CLINICAL CHEMISTRY
-CLINICAL IMMUNOLOGY
-HAEMATOLOGY AND TRANSFUSION SCIENCE
-MEDICAL MICROBIOLOGY
-MOLECULAR AND CELLULAR THERAPEUTICS
-MOLECULAR SCIENCE AND DIAGNOSTICS
-PRINCIPLES OF MOLECULAR MEDICINE

Associated careers

If you do not already have an IBMS accredited BSc Honours degree in Biomedical Science then this MSc programme is the next step on your path to becoming an HCPC registered Biomedical Scientist. Biomedical Scientists have the knowledge and skills to provide the crucial laboratory diagnostic service central to modern medicine and will be involved in over 70 per cent of all disease diagnoses from ante-natal care to emergency medicine.

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Please note. this programme is only available to home/EU students. Breast cancer care, diagnosis and treatment exist in a changing professional environment that requires practitioners to continually update and review clinical practice. Read more
Please note: this programme is only available to home/EU students.

Choose Kingston's Breast Evaluation PgCert/PgDip/MSc

Breast cancer care, diagnosis and treatment exist in a changing professional environment that requires practitioners to continually update and review clinical practice. If you are a registered healthcare practitioner working in the field of breast evaluation, this course is relevant to you.

This interprofessional programme enables participants to gain competence in the multi-skilled practice of breast evaluation. Shared learning for different healthcare disciplines is facilitated through a range of modules provided by collaborative partners at the Jarvis National Breast Screening Training Centre, Guildford, and at the South West London National Breast Screening Training Centre at St George's. By developing your multidisciplinary approach to the diagnosis, care and management of breast disease, this programme enables the enhancement of service provision to the client requesting or requiring breast evaluation.

You may be granted credits for your previous academic and professional qualification through Accreditation of Prior Experiential Learning (APEL) scheme. An independent work-based learning module enables you to study around your individual CPD and workplace needs.

What will you study?

You will study modules relating to breast cancer diagnosis, treatment and care, research methods and ethics as well as independent work-based learning topics to meet your personal and clinical needs.

Some of the modules are developed in partnership with the Jarvis and St George's Breast Screening Centres.

Assessment

Case studies, research protocols, dissertation, essays, portfolios, practical assessment, OSCE, reflective log book.

Course structure

The postgraduate admissions administrator will help you choose the most suitable combination of modules depending on your needs. Some of the modules are developed in partnership with a range of healthcare providers.

Please note that this is an indicative list of modules and is not intended as a definitive list.

Available modules
-Advanced Principles and Practice of Breast Interventional Techniques
-Clinical Breast Examination and Client Communication
-Contemporary Practice In Breast Cancer Genetics and Diagnosis
-Interpretation and Reporting in Mammography
-Professional Practice in Mammography 1 ^
-Professional Practice in Mammography 2 ^
-Ultrasound of the Breast
-Advanced Practice - Negotiated Independent Work Based Learning
-Management of Resources and Quality within Healthcare
-Practice Education and Mentorship+
-Research and Evidence Based Practice in Healthcare (for PgDip)
-Dissertation (for MSc)

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We understand that you may not have the time to do a full-time degree, so our CPD pathways allow you to study flexibly, in the way that best suits you. Read more
We understand that you may not have the time to do a full-time degree, so our CPD pathways allow you to study flexibly, in the way that best suits you. The structure, mode of delivery and level of support allow you to progress towards a qualification at postgraduate certificate, postgraduate diploma or Masters level.

We offer two musculoskeletal pathways which enable you, as a clinician, to assess and manage patients with a range of musculoskeletal conditions beyond your normal scope of practice. Optional modules allow you to expand your musculoskeletal practice with a focus on imaging, including ultrasonography, or a focus on patient management including injection therapy.

We:
-Provide you with a critical understanding of the key concepts underlying advanced musculoskeletal clinical skills beyond your normal professional scope of practice
-Provide you with the opportunity to acquire advanced musculoskeletal clinical skills beyond your normal professional scope of practice
-Provide you with skills to access and critically appraise research findings to develop your own evidence-based practice
-Enhance your understanding of the essential principles of research design and to conduct an extensive piece of independent research including: planning, formulating, designing, choosing research methods, collecting data, analysing, interpreting and writing-up
-Ensure you acquire a range of transferable employment-related skills

We are committed to embedding the NHS Constitution Values (which are strongly reflected in our University values) into everything we do. They define the behaviours and expectations of all our staff and students underpinning the work we do in the university, clinical arena and other workplaces.

We understand that not all of our students and staff are employed within the NHS but these values uphold the underlying principles of excellent care as a standard, and as such we expect that anyone who cares for others will aspire to uphold these values.

For us, involving not only our students, but service users, experts by experience, carers and NHS/non NHS professionals in the creation and delivery of all programmes is vital.

Our expert staff

We have a range of guest specialists who work with us, including Billy Fashanu, consultant physiotherapist and various other tutors such as consultant rheumatologists, radiologists, consultant neurophysiologists and other injecting practitioners.

Specialist facilities

The School of Health and Human Sciences is located at two sites; in the Kimmy Eldridge building on the Colchester campus and in the Gateway Building on the Southend campus.

As one of our CPD students, you may be taking modules at either campus or online to suit your needs, which means that you can access facilities across both campuses as required.

Example structure

Postgraduate study is the chance to take your education to the next level. The combination of compulsory and optional modules means our courses help you develop extensive knowledge in your chosen discipline, whilst providing plenty of freedom to pursue your own interests. Our research-led teaching is continually evolving to address the latest challenges and breakthroughs in the field, therefore to ensure your course is as relevant and up-to-date as possible your core module structure may be subject to change.

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Medical imaging is a rapidly-growing discipline within the healthcare sector, involving clinicians, physicists, computer scientists and those in IT industries. Read more

Medical imaging is a rapidly-growing discipline within the healthcare sector, involving clinicians, physicists, computer scientists and those in IT industries.

This programme delivers the expertise you'll need to forge a career in medical imaging, including radiation physics, image processing, biology, computer vision, pattern recognition, artificial intelligence and machine learning.

Programme structure

This programme is studied full-time over 12 months and part-time over 48 months. It consists of eight taught modules and an extended project.

Example module listing

The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.

Facilities, equipment and support

To support your learning, we hold regular MSc group meetings where any aspect of the programme, technical or non-technical, can be discussed in an informal atmosphere. This allows you to raise any problems that you would like to have addressed and encourages peer-based learning and general group discussion.

We provide computing support with any specialised software required during the programme, for example, Matlab.

The Department’s student common room is also covered by the university’s open-access wireless network, which makes it a very popular location for individual and group work using laptops and mobile devices. There is also a Faculty quiet room for individual study.

We pride ourselves on the many opportunities that we provide to visit collaborating hospitals. These enable you to see first-hand demonstrations of medical imaging facilities and to benefit from lectures by professional practitioners.

To support material presented during the programme, you will also undertake a selection of ultrasound and radiation detection experiments, hosted by our sister MSc programme in Medical Physics.

Educational aims of the programme

The taught postgraduate Degree Programmes of the Department are intended both to assist with professional career development within the relevant industry and, for a small number of students, to serve as a precursor to academic research.

Our philosophy is to integrate the acquisition of core engineering and scientific knowledge with the development of key practical skills (where relevant).

To fulfil these objectives, the programme aims to:

  • Attract well-qualified entrants, with a background in Electronic Engineering, Physical Sciences, Mathematics, Computing & Communications, from the UK, Europe and overseas
  • Provide participants with advanced knowledge, practical skills and understanding applicable to the MSc degree
  • Develop participants' understanding of the underlying science, engineering, and technology, and enhance their ability to relate this to industrial practice
  • Develop participants' critical and analytical powers so that they can effectively plan and execute individual research/design/development projects
  • Provide a high level of flexibility in programme pattern and exit point
  • Provide students with an extensive choice of taught modules, in subjects for which the Department has an international and UK research reputation

Technical characteristics of the pathway

Medical Imaging is a rapidly growing discipline within the healthcare sector, incorporating engineers, physicists, computer scientists and clinicians. It is driven by the recent rapid development of 3-D Medical Imaging Systems, fuelled by an exponential rise in computing power.

New methods have been developed for the acquisition, reconstruction, processing and display of digital medical-image data with unprecedented speed, resolution and contrast.

This programme in Medical Imaging is aimed at training graduates for careers in this exciting multi-disciplinary area, and our graduates can expect to find employment in the medical imaging industry or the public health care sector.

It represents a blend of fundamental medical physics topics concerned with image acquisition and reconstruction coupled with imaging science and image engineering topics such that graduates understand how images are formed and how advanced machine-based methods can be bought to bare to provide new diagnostic information.

Global opportunities

We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.



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This programme is the first taught Masters programme in medical visualisation in the UK. Offered jointly by the University of Glasgow and the Glasgow School of Art, it combines actual cadaveric dissection with 3D digital reconstruction, interaction and visualisation. Read more
This programme is the first taught Masters programme in medical visualisation in the UK. Offered jointly by the University of Glasgow and the Glasgow School of Art, it combines actual cadaveric dissection with 3D digital reconstruction, interaction and visualisation.

Why this programme

◾You will examine human anatomy and reconstruct it in a real-time 3D environment for use in education, simulation, and training.
◾You will have access to the largest stereo 3D lab in Europe, and its state-of-the-art facilities such as laser scanner (for 3D data acquisition), stereo 3D projection, full body motion capture system, haptic devices and ambisonic sound.
◾You will also have access to the Laboratory of Human Anatomy at the University of Glasgow, one of the largest in Europe.
◾The programme has excellent industry connections through research and commercial projects and there are possible internship opportunities. You will benefit from guest lectures by practitioners, researchers and experts from industry.
◾This programme is accredited by the Institute of Medical Illustrators.

Programme structure

You will split your time between the Glasgow School of Art (Digital Design Studio) and the University of Glasgow (Laboratory of Human Anatomy). The programme is structured into three stages.

Stage one: digital technologies applied to medical visualisation (delivered by the Digital Design Studio at the Glasgow School of Art)

Core courses
◾3D modelling and animation
◾Applications in medical visualisation
◾Volumetric and 3D surface visualisation
◾Core research skills for postgraduates.

Stage two: human anatomy (delivered by the Laboratory of Human Anatomy at the University of Glasgow).

Core courses
◾Introduction to anatomy
◾Structure and function of the human body
◾Cadaveric dissection techniques.

In stage three you will complete a self-directed final project, supported throughout with individual supervision.

Career prospects

Career opportunities exist within the commercial healthcare device manufacturer, the public and private healthcare sectors, as well as in academic medical visualisation research. Students with medical, biomedical, anatomy, or health professional backgrounds will be able to gain 3D visualisation skills that will enhance their portfolio of abilities; students with computer science or 3D graphics background will be involved in the design and development of healthcare related products through digital technology, eg diagnostic and clinical applications, creating content involving medical visualisation, simulation, cardiac pacemakers, and biomechanically related products for implantation, such as knee, hip and shoulder joint replacements.

Here are some examples of roles and companies for our graduates:
◾Interns, Clinical Assistants and Clinical Researchers at Toshiba Medical Visualisation Systems
◾Research Prosector (GU)
◾3D printing industry
◾Demonstrators in Anatomy
◾PhD studies - medical history, medical visualisation
◾Medical School
◾Dental School
◾Digital Designer at Costello Medical
◾Lead Designer at Open Bionics
◾Founder of Axial Medical Printing Ltd
◾Digital Technician at University of Leeds
◾Digital Project Intern at RCPSG
◾Researcher and Factual Specialist at BBC
◾Graduate Teaching Assistants
◾Freelance Medical Illustration
◾Numerous successful placements on PhD programmes (medical visualisation, anatomy, anatomy education, medical humanities)
◾MBChB, BDS courses

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Radiography exists in a changing professional environment and requires practitioners to continually update and review clinical practice. Read more
Radiography exists in a changing professional environment and requires practitioners to continually update and review clinical practice. This course provides a flexible framework to prepare you for advanced practice by studying topics relevant to your needs and those of your clinical departments.

You may be granted credits for your previous academic and professional qualification through Accreditation of Prior Experiential Learning (APEL) scheme. An independent work-based learning module enables you to study around your individual CPD and workplace needs.

What will you study?

You will study modules relating to clinical roles, management, supervisory and assessment roles, quality issues, research methods and ethics, as well as taking a module of independent study to meet a particular professional need or interest.

Assessment

Case studies; research protocols; dissertation; essays; portfolios; practical assessment; OSCE; reflective log book.

Course structure

The postgraduate admissions administrator will help you to choose the most suitable combination of modules depending on your needs.

Please note that this is an indicative list of modules and is not intended as a definitive list.

Available modules
-Research and Evidence Based Practice in Healthcare (for PgDip)
-Dissertation (for MSc)
-Advanced Principles and Practice of Breast Interventional Techniques
-Advanced Practice - Negotiated Independent Work Based Learning
-Clinical Breast Examination and Client Communication
-Contemporary Practice In Breast Cancer Genetics and Diagnosis
-Cross-sectional Imaging - Diagnostic
-Interpretation and Reporting in Mammography
-Professional Practice in Mammography 1 ^
-Professional Practice in Mammography 2 ^
-Ultrasound of the Breast
-Management of Resources and Quality within Healthcare
-Practice Education and Mentorship+
-PACS (Picture Archiving and Communication System) Administration

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Our EngD projects are defined by our long standing industrial sponsors and address operational requirements identified by these companies. Read more
Our EngD projects are defined by our long standing industrial sponsors and address operational requirements identified by these companies. Projects are focused on our established areas of engineering expertise.

We are a leader in developing new manufacturing processes and products, such as functional coated steel. Our research in this area is led by the SPECIFIC project, in collaboration with Tata Steel.

Research into advanced, structural materials is undertaken in conjunction with the Rolls-Royce University Technology Centre (UTC) in Materials based at Swansea. These projects are funded by the EPSRC Strategic Partnership in Structural Metals for Gas Turbines.

We also offer EngD programmes in the research areas of functional coatings and advanced manufacturing. Please visit our website for more information.

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