• University of Southampton Featured Masters Courses
  • University of Edinburgh Featured Masters Courses
  • Anglia Ruskin University Featured Masters Courses
  • Goldsmiths, University of London Featured Masters Courses
  • Jacobs University Bremen gGmbH Featured Masters Courses
  • University of Edinburgh Featured Masters Courses
  • Ross University School of Veterinary Medicine Featured Masters Courses
  • Swansea University Featured Masters Courses
Middlesex University Featured Masters Courses
Leeds Beckett University Featured Masters Courses
FindA University Ltd Featured Masters Courses
Nottingham Trent University Featured Masters Courses
Bath Spa University Featured Masters Courses
"magnetic" AND "resonance…×
0 miles

Masters Degrees (Magnetic Resonance)

We have 70 Masters Degrees (Magnetic Resonance)

  • "magnetic" AND "resonance" ×
  • clear all
Showing 1 to 15 of 70
Order by 
Take your clinical skills in Magnetic Resonance Imaging forward in a range of settings of increasing complexity. Read more
Take your clinical skills in Magnetic Resonance Imaging forward in a range of settings of increasing complexity.

Who is it for?

The MSc Medical Magnetic Resonance has been designed for Qualified Radiographers working in or rotating through Magnetic Resonance Imaging who wish to advance their clinical practice and understanding of this modality.

Objectives

This course has been designed to:
-Enhance the professional practice and personal development of practitioners.
-Provide opportunities for discussion and shared experience between practitioners.
-Enhance critical, analytical, professional, research and communication skills and promote the ability to relate these skills to individual clinical practice.
-Further develop the skills necessary for life-long independent learning.
-Prepare you to take on the professional roles of advanced practitioners.
-Encourage autonomous planning and implementation of tasks at a professional level.
-Encourage the development of originality in the application of knowledge to clinical practice.
-Enhance your understanding of how established techniques of research and enquiry are used to interpret knowledge in your field.

Placements

Students should be working as a radiographer in a Magnetic Resonance Imaging department at least thre days per week (or equivalent). City is unable to provide a clinical placement.

Teaching and learning

You will learn through a mix of lectures, class discussions, seminars, presentations, case study analyses, interactive computer-based exercises, a virtual learning environment, guided independent learning and individual supervision.

You will be taught by City Academics who specialise in Computed Tomography, Radiologists, Industry Professionals and Radiographers.

Assessment
You are assessed on a range of areas including your project dissertation, exams, written assignments, oral presentations and posters.

Modules

Core and elective module diet will vary depending on which certificate is undertaken.

Core modules
Year One (PGCert):
-RCM124 Physics and Instrumentation of Medical Magnetic Resonance (30 credits) - year one, term one
-RDM017 Clinical Applications of Medical Magnetic Resonance (30 credits) - year one, term two.

Year Two (PGDip):
-RCM124 Physics and Instrumentation of Medical Magnetic Resonance (30 credits) - year one, term one
-RDM017 Clinical Applications of Medical Magnetic Resonance (30 credits) - year one, term two
-HRM011 Introduction to Research Methods and Applied Data Analysis (15 credits)- year two, term one.

The remainder of the course will be selected from elective modules.

Year Three (MSc):
-RCM124 Physics and Instrumentation of Medical Magnetic Resonance (30 credits) - year one, term one
-RDM017 Clinical Applications of Medical Magnetic Resonance (30 credits) - year one, term two
-HRM011 Introduction to Research Methods and Applied Data Analysis (15 credits)- year two, term one
-APM002 Dissertation (60 credits)- year two, terms one and two.

The remainder of the course will be selected from elective modules.

Elective modules
-RCM005 Evidence Based Practice (15 credits – distance learning)
-RCM010 Student Negotiated Module 1 (15 credits – distance learning)
-CHM003 Comparative Imaging (30 credits – distance learning)
-CHM002 Education in the Workplace (15 credits – distance learning)
-RCM124 Physics and Instrumentation of Medical Magnetic Resonance (30 credits – 36 hours classroom based) only suitable for students with some CT rotation
-RDM017 Clinical Applications of Medical Magnetic Resonance (30 credits – 36 hours, classroom based). Only suitable for students with some CT rotation.

Career prospects

The postgraduate programme in Medical Magnetic Resonance will enable you to work towards advancing your practice and support a rationale for more senior roles in the profession including specialist clinical practice, management and research.

The programme is accredited by the College and Society of Radiographers.

Previous students have gone on to take positions overseas, in research, management and advance clinical practice. Some of our students have taken their skills and continued to study to PhD level.

Read less
This part-time programme is designed to be studied over an eleven month period, commencing in early September and being completed in July of the following year. Read more
This part-time programme is designed to be studied over an eleven month period, commencing in early September and being completed in July of the following year. The programme consists of two 30 credit core modules.

The MRI theory module, delivered in the first semester, is designed to give students an understanding of the scientific principles behind magnetic resonance imaging and the knowledge to explore the relationship between technical parameters and anatomical and pathological appearances. This theoretical module may also be accessed by students who are not registered for the full MRI certificate course as an option within the MSc in Medical Imaging programme.

The second module, clinical MRI, is delivered in semester two and is designed to provide the student with a structured and monitored experiential learning opportunity in their workplace. It is designed to enable students to critically evaluate MRI protocols used in clinical practice with respect to the evidence base in order to inform service delivery and practice.

The programme sits within the MSc in Medical Imaging programme and the Faculty of Health Studies SSPRD framework, and upon successful completion of this MRI course students can continue their studies by registering for additional modules from the Medical Imaging or School module portfolio, to obtain a postgraduate Diploma or Master's Degree.

Why Bradford?

The Magnetic Resonance Imaging (MRI) programme was first validated in 1996 and since then it has proved to be a popular choice of study demonstrating its continued clinical relevance. The programme is delivered in partnership with clinical and scientific experts working within MRI to ensure it remains clinically relevant and of value to radiographers in developing the knowledge, understanding and skills, in MRI, that are required of a professional who aspires to work at an advanced level.

Modules

-Magnetic Resonance Imaging
-Clinical Magnetic Resonance Imaging

Learning activities and assessment

A 'block' attendance format is utilised in the delivery of the academic learning and this mode of delivery has proved to be popular with students who benefit academically from the concentrated period of time that can be devoted to their studies and learning with their peers. There are 5 blocks of academic learning and these are delivered in the first 6 months of the course.

Career support and prospects

The University is committed to helping students develop and enhance employability and this is an integral part of many programmes. Specialist support is available throughout the course from Career and Employability Services including help to find part-time work while studying, placements, vacation work and graduate vacancies. Students are encouraged to access this support at an early stage and to use the extensive resources on the Careers website.

Discussing options with specialist advisers helps to clarify plans through exploring options and refining skills of job-hunting. In most of our programmes there is direct input by Career Development Advisers into the curriculum or through specially arranged workshops.

Read less
This module aims to enable you to. -Critically evaluate the Magnetic Resonance (MR) protocols used in clinical practice with respect to the evidence base in order to inform service delivery and practice policy. Read more
This module aims to enable you to:
-Critically evaluate the Magnetic Resonance (MR) protocols used in clinical practice with respect to the evidence base in order to inform service delivery and practice policy
-Develop your ability to evaluate MR images within a structured and monitored experiential learning environment

The learning in the module will utilise the knowledge and understanding gained in the Magnetic Resonance Imaging module, which is a pre-requisite and apply it to your own clinical practice. Evidence-based content will be delivered by Faculty experts with support from the technical and clinical fields.

You will be encouraged to identify the evidence base and critique clinical practice and protocols. In the clinical workplace you will undertake clinical MRI examinations of a wide range of anatomical regions/systems for a variety of clinical indications, gaining experience of advanced practice where applicable.

Tutorials will be used to facilitate peer learning and sharing of information by students. Case scenarios will facilitate group discussion and enhance your confidence in debating and justifying imaging techniques.

Why Bradford?

Postgraduate provision in Medical Imaging at the University of Bradford has long been established and is known for its quality and success in supporting development of healthcare professionals in their diverse roles, with students coming from around the UK, and full time international students choosing to study here. The modules are delivered by an experienced radiography team, clinical specialists and medical physicists, and a research informed curriculum ensures it is relevant to current and innovative practice.

Modules

This module is provided as part of this interdisciplinary Framework within the Faculty of Health Studies. The Framework enables students to create an individualised programme of study that will meet either their needs and/or the employers’ needs for a changing diverse workforce within a modern organisation.

The modules and academic awards are presented in areas representing employment practice or work based or clinical disciplines.

Whilst some students can build their own academic awards by choosing their own menu of module options, other students will opt for a named academic award. The Framework also provides the option for students to move from their chosen named award to another award if their job or personal circumstances change and they need to alter the focus of their studies. The majority of named awards also offer students, the option of choosing at least one module, sometimes more, from across the Faculty module catalogue enabling them to shape their award more specifically to their needs.

Learning activities and assessment

Achievement of the learning outcomes will be demonstrated through the completion of a portfolio, to include reflective journal entries, work-based case studies, a presentation and a log of clinical experience as part of the learning process. All assessments within a module must achieve 40% to pass.

Career support and prospects

The module is designed to support healthcare practitioners develop the knowledge, understanding and skills in medical imaging that are required of a professional who aspires to work at an advanced level of practice.

Read less
This module aims to enable you to. -Gain a comprehensive understanding of the physical principles and technology underpinning the acquisition, production and presentation of magnetic resonance (MRI) images. Read more
This module aims to enable you to:
-Gain a comprehensive understanding of the physical principles and technology underpinning the acquisition, production and presentation of magnetic resonance (MRI) images
-Develop your ability to critically analyse and evaluate a broad range of magnetic resonance (MRI) imaging applications and protocols
-Develop your ability to comment on normal and variant anatomy seen in common MRI examinations

Lectures will introduce the students to the physical principles of MRI technology and the clinical applications of MRI, delivered by Faculty experts with support from the technical and clinical fields.

Students will be exposed to current MRI technology and its applications in clinical practice, encouraging reflection on existing practice.

Tutorials will be used to facilitate peer learning and sharing of information and directed study based on critiquing up to date literature and practice will be used to further stimulate the student's learning.

Why Bradford?

Postgraduate provision in Medical Imaging at the University of Bradford has long been established and is known for its quality and success in supporting development of healthcare professionals in their diverse roles, with students coming from around the UK, and full time international students choosing to study here.

The modules are delivered by an experienced radiography team, clinical specialists and medical physicists, and a research informed curriculum ensures it is relevant to current and innovative practice.

Modules

This module is provided as part of this interdisciplinary Framework within the Faculty of Health Studies. The Framework enables students to create an individualised programme of study that will meet either their needs and/or the employers’ needs for a changing diverse workforce within a modern organisation.

The modules and academic awards are presented in areas representing employment practice or work based or clinical disciplines.

Whilst some students can build their own academic awards by choosing their own menu of module options, other students will opt for a named academic award. The Framework also provides the option for students to move from their chosen named award to another award if their job or personal circumstances change and they need to alter the focus of their studies. The majority of named awards also offer students, the option of choosing at least one module, sometimes more, from across the Faculty module catalogue enabling them to shape their award more specifically to their needs.

Learning activities and assessment

Achievement of the learning outcomes will be demonstrated through the completion of a written examination based on the physical principles, and a second examination which involves responding to questions based on case studies with accompanying medical images.

All assessments within a module must achieve 40% to pass.

Career support and prospects

The module is designed to support healthcare practitioners develop the knowledge, understanding and skills in medical imaging that are required of a professional who aspires to work at an advanced level of practice.

Read less
The School of Clinical Medicine offers a programme in Medical Imaging with an option in Nuclear Medicine, Radiation Safety or Magnetic Resonance Imaging and Computed Tomography. Read more
The School of Clinical Medicine offers a programme in Medical Imaging with an option in Nuclear Medicine, Radiation Safety or Magnetic Resonance Imaging and Computed Tomography.

The Nuclear Medicine and Radiation Safety strands are offered in parallel on a bi-annual basis, the Magnetic Resonance Imaging and CT strand are offered on alternate years. In September 2013, the MRI and CT strands will commence.

The main aim of the programme is to train and qualify Radiographers in the practice of Nuclear Medicine, Radiation Safety, Magnetic Resonance Imaging or Computed Tomography.

The course is intended for qualified Radiographers with a clinical placement in a Nuclear Medicine Department, a Radiology Department, a Magnetic Resonance Imaging Department or a Computed Tomography Department. It is a course requirement that the student must spend a minimum of 15 hours per week on clinical placement in a Nuclear Medicine Department, a Radiology Department, a Magnetic Resonance Imaging Department or a Computed Tomography Department as appropriate to fulfill the requirements of the course.

The M.Sc. in Medical Imaging will be run over 12 months on a part-time basis.

In the M.Sc. in Medical Imaging, there are 4 separate strands: Nuclear Medicine, Radiation Safety, Magnetic Resonance Imaging and Computed Tomography. Students will choose one of the 4 options.

The taught component of the course is covered in the first 8 months. The student may opt to exit the programme upon completion of the taught component with a Postgraduate Diploma in Medical Imaging.

From May to September, students undertake an independent research project. Successful completion of the research component of the programme leads to the award of M.Sc. in Medical Imaging.

The list of common core modules currently available to students of the Nuclear Medicine, Radiation Safety, Magnetic Resonance Imaging and CT strands are:

Medico-Legal Aspects, Ethics and Health Services Management (5 ECTS)
Clinical Practice (10 ECTS)

The additional modules in the Nuclear Medicine strand are:

Physics and Instrumentation, and Computer Technology Radiation Protection and Quality Control in Nuclear Medicine (15 ECTS)
Clinical Applications of Nuclear Medicine and Hybrid Imaging (15 ECTS)
Anatomy, Physiology and Pathology applied to Nuclear Medicine (5 ECTS)
Radiopharmacy (5 ECTS)

The additional modules in the Radiation Safety strand are:

Radiation Protection Legislation (10 ECTS)
Practical Aspects of Radiation Protection (5 ECTS)
Physics and Instrumentation and Computer Technology (10 ECTS)
Quality Management and Quality Control (15 ECTS)

The additional modules in the Magnetic Resonance Imaging strand are:

Physics and Instrumentation of MR and computer technology (15 ECTS)
Anatomy, Physiology and Pathology applied to MR (10 ECTS)
Safety in MR and Quality Control (5 ECTS)
MR Imaging Techniques and Protocols (15 ECTS)

The additional modules in the Computed Tomography strand are:

Physics and Instrumentation of CT and computer technology (10 ECTS)
Anatomy, Physiology and Pathology applied to CT (10 ECTS)
CT Imaging Techniques and Protocols (15 ECTS)
Radiation protection and quality assurance in CT (5 ECTS)

All common modules and strand-specific modules must be undertaken. The taught component thus consists of 60 ECTS.
Dissertation (30 ECTS)

Read less
Distance learning only. This is the longest-running distance-learning course of its type in the world, and one of very few dedicated solely to MRI. Read more

Campus

Distance learning only

Overview

This is the longest-running distance-learning course of its type in the world, and one of very few dedicated solely to MRI. It is led by a world-renowned MRI educator Catherine Westbrook and supported by a team of MRI experts.
Study MRI to master’s level and open up exciting opportunities in clinical, research, management and academic careers. Develop as an independent and critical thinker, continually linking what you learn to your practice in this fast-changing field. Deepen your knowledge of scientific principles, learn to critically evaluate MRI images, and
understand their emotional impact on your patient. Engage in researching and advancing the world of MRI imaging. Undertake research that leads to publication offering the chance to contribute to wider MRI practice. When you graduate, you will have the advanced experience to seek more senior roles in the imaging profession. Many of our former students have had their research and theses published widely.

Core Modules

Applied Scientific Principles of MRI (30 credits)
Essentials of MRI Clinical Practice (30 credits)
Advanced MRI Practice (30 credits)
Research Studies (30 Credits)
Major Project (60 credits)
Please note that you will need to complete all of the above core modules. This course does not have any optional modules. Modules are subject to change and availability.

Start dates

September 2017

Read less
Gain both theoretical and applied knowledge of clinical cognitive neuroscience. Read more

Gain both theoretical and applied knowledge of clinical cognitive neuroscience. Cognitive neuroscience combines techniques and skills including psychometric testing, electroencephalography (EEG), eye tracking and imaging techniques – for application to neuropathological and healthy groups in clinical, academic or biomedical settings. Various neurobiological mechanisms of cognitive and perceptual functions with demonstration of practical recordings, as well as psychology experimental software are taught on the course.

This course is ideal if you

  • are a graduate with an applied or pure science degree including psychology, biosciences and nursing, and want to pursue a research, clinical or biomedical career in neuroscience
  • work in a related area and wish to formalise and develop your skills, knowledge and expertise as part of continuing professional development
  • want to open alternative career pathways
  • are an EU or international student with the appropriate background and qualifications.

The course gives you the knowledge and skills to evaluate cognitive and brain function and dysfunction in healthy and neuropathological groups. You learn to understand the important ethical issues involved in neuroscientific research targeted at various age groups and people with range of cognitive abilities, as well as developmental disorders.

You have an opportunity to learn psychophysiological recording techniques, including electrocardiogram (ECG), Skin Conductance (SC), performance speed and accuracy, as well as perceptual mechanisms using Eprime, Martlab and other specialist software.

We also build your research skills enabling you to work as an independent researcher in this area. You have the opportunity to attend workshops run by experts from relevant professions and fields of work. Examples include private clinical consultants, NHS neuropsychologist, teaching staff from the Doctorate in Clinical Psychology course at the University of Sheffield and alumni from our course working in academia and the private sector.

Our specialist learning resources include psychometric measures for assessing cognitive function and 3D model brains for understanding neuroanatomy. You learn to use specialist equipment including • EEG • transcranial magnetic stimulation • analysis of Biopack • structural magnetic resonance imaging (MRI) and functional magnetic resonance imaging (fMRI) data • visuo-psychophysics equipment.

Some lectures are taught by guest tutors including clinical psychologists and neuroimaging experts.

You are automatically affiliated with our Brain, Behaviour and Cognition Research Group, which

  • delivers targeted neuroscience workshops
  • organises subject specific presentations
  • has regular research meetings
  • has strong collaborative links with other institutions.

International students are most welcome on this course. At Sheffield Hallam University we provide international students with a wealth of support, from pre-arrival right up to, and including, study support while you are studying here. Please see the International Experience Team webpage for more information.

Course structure

Full-time – one year

Part-time – typically one day per week for two years

Core modules

  • Neursopsychopharmacology
  • Neuron to neuropathology
  • Cognitive neuroscience methods
  • Electrophysiology
  • Perception and cognition across the lifespan
  • Research dissertation

Assessment

  • coursework
  • seminar activities
  • examinations
  • dissertation

Employability

This course gives you the skills to work in both academic and clinical settings with healthy population and diverse neuropathological groups.

Graduates have the skills and knowledge to work in roles involved in assessing and evaluating cognitive function and dysfunction in healthy ageing across the lifespan and patient groups including people with Parkinson’s disease, head injury, dementia, and other neuropathological conditions.

During the course you benefit from employability sessions, where our alumni currently working in academia or industry, clinical psychologists and professionals from private research companies discuss possible career choices.

You may find roles in academic and clinical contexts using methods of neuroscience such as • functional magnetic resonance imaging (fMRI) • structural magnetic resonance imaging (MRI) • electroencephalogram (EEG) • transcranial magnetic stimulation • eye tracking techniques • visual psychophysics.

You can also complete further cognitive neuroscience postgraduate academic work.



Read less
Diagnostic radiography and medical imaging are core components of modern healthcare and rely on rapidly changing diagnostic modalities. Read more

Diagnostic radiography and medical imaging are core components of modern healthcare and rely on rapidly changing diagnostic modalities. It is widely accepted that medical imaging will remain an essential component of diagnostic services for many years to come and that the demand for imaging services will continue to rise.

Recent modernisation within the NHS has raised the profile and extended the scope of practice for allied health professionals (AHPs). Diagnostic radiographers, as one of the sixteen registered AHP groups, are now required to build and extend their scope of professional expertise within a multi-professional setting. Continuing professional development (CPD) is a requirement for all AHPs in the UK in order to secure re-registration with the Health and Care Professions Council (HCPC) and to retain the right to practise within the UK. Radiographers are therefore required to evidence their learning and to demonstrate how this learning has informed practice.

Diagnostic radiography is a profession which is both intellectually and scientifically demanding. Professional responsibility includes a need to be able to formulate imaging standards and strategies as well as assume a greater degree of autonomy within different imaging modalities. To practise effectively the radiographer needs to be able to analyse and evaluate the requirements of healthcare delivery and to be aware of the roles and skills of other healthcare professionals. To optimise patient care the diagnostic radiographer must adopt a critical approach to decision-making in the context of current practice.

This MSc provides CPD opportunities for diagnostic radiographers and other healthcare professionals, but does not lead to UK registration with the HCPC or the right to practice within the UK. Therefore, this course aims to foster an intellectual approach to personal and professional development, encouraging diagnostic radiographers to challenge and progress radiography practice in response to evolutionary change. The course aims to provide flexibility in learning with the opportunity for learners to select modules in order to support individual practice development.

Teaching, learning and assessment

This course uses a wide range of learning and teaching methods, based on a problem based learning approach with students working independently and collaboratively.  The teaching and learning strategies are designed to enable independent progress within a supportive framework.

Teaching hours and attendance

The course is modular and offers a variety of attendance pathways for study: work-based learning; online and block attendance. A range of modules related to the development and progression of the Radiography profession can be used to form the course content.

Modules

To obtain a PgCert in any route, you will study 60 credits from the profession specific modules outlined below. To obtain a PgDip, you will study a further 60 credits taken from either profession specific modules or elective modules from the QMU Postgraduate Module Catalogue.

Ultrasound

15 credits: Physics and Instrumentation of Ultrasound+/ Professional Issues Relating to Medical Imaging+

30 credits: General Medical Ultrasound in Clinical Practice*/ Obstetric Ultrasound in Clinical Practice*/ Breast Ultrasound in Clinical Practice*/ Musculoskeletal Ultrasound in Clinical Practice*/ Musculoskeletal Ultrasound in Clinical Practice for AHPs*

MRI

15 credits: Principles of Magnetic Resonance Imaging+/ Principles of Image Evaluation+

30 credits: Magnetic Resonance Imaging in Practice*/ Advanced Practice in Magnetic Resonance Imaging (negotiated study)

CT

15 credits: Principles of Computed Tomography+ / Principles of Image Evaluation+ 30 credits: Advanced Practice in Computed Tomography of the Head*/ Computed Tomography in Practice (Head, Chest, Abdomen and Pelvis)*/ Advanced Practice in Computed Tomography  Colonography*

Clinical Reporting

15 credits: Pathophysiology for Musculoskeletal Image Evaluation+/ Principles of Image Evaluation+

30 credits: Clinical Reporting of the Axial and Appendicular Musculoskeletal System* A sample of relevant elective modules are:

15 credits: Epidemiology (distance)/  Developing Professional Practice*/ Leading Professional Practice+/ Practice Development for Person-centred Cultures+

30 credits: Current Developments (distance)/ Developing Professional Practice*

45 credits: Developing Professional Practice*

To obtain an MSc, you require:

30 credits: Research Methods (distance/ contact)

60 credits: Research Project (in an area relevant to medical imaging) (distance) Key: * attendance and work-based + Block/ day release

Careers

This qualification may enhance your career prospects within the allied health professions.

Quick Facts

  • A flexible approach to learning is taken.  
  • This course is accredited by the Society and College of Radiographers. 
  • The ultrasound route is accredited by the Consortium of Sonographic Education (CASE).


Read less
Your programme of study. If you want to study Medical Physics with applications in nuclear medicine, radiotherapy, electronics and MRI University of Aberdeen has an world renowned historic reputation within major global innovation in this health area. Read more

Your programme of study

If you want to study Medical Physics with applications in nuclear medicine, radiotherapy, electronics and MRI University of Aberdeen has an world renowned historic reputation within major global innovation in this health area. Did you know the first MRI (Magnetic Resonance Imaging) scanner was invented at Aberdeen over 30 years ago? Major innovations to this technology are still being researched at Aberdeen today. You learn everything you need to know as an advanced grounding in medical physics such as understanding anatomy and how cells are altered by disease. You look at the engineering behind MRI and other visual scanning techniques to understand how applications are made in areas such as nuclear, Positron, Tomography, Radio diagnosis (X-ray), MRI and Ultrasound. You understand radiation and you apply electronics and computing to medical physics. The degree ensures plenty of practical understanding and application and you learn MRI within the department that built it.

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. You can also work as a researcher, risk manager, radiation physics specialist and within the medical device industry in product development and innovation.

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 start

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



Read less
Your programme of study. If you are interested in medical imaging and highly sophisticated ways of assisting in diagnostics visually the medical imaging programme comes from a long heritage of major world innovation which was led by research at Aberdeen. Read more

Your programme of study

If you are interested in medical imaging and highly sophisticated ways of assisting in diagnostics visually the medical imaging programme comes from a long heritage of major world innovation which was led by research at Aberdeen. Did you know researchers at Aberdeen invented the first MRI scanner (Magnetic Resonance Imaging) for instance? Since this time much has been done to further work on the MRI scanner and deliver some of the most advanced forms of body visualisation tools available to the health area. If you have ever wondered how X rays work or you are interested in the latest radiotherapy techniques to provide therapeutic tools from radiographic equipment and advances this programme not only gives you the theory and practice in applying imaging in a health setting, it also gives you opportunities to think about the technologies involved and the applications. There is a lot of Physics and Maths required behind the different technologies involved in medical imaging so if you have these subjects and a life science background plus engineering or similar science disciplines this will make the programme more accessible.

By the end of the MSc programme you 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. There are wide ranging career possibilities after graduation. You may wish to go straight into clinic settings to apply your skills within diagnostics or you may wish to study further for a PhD towards teaching or researching. There have also been spin out companies as a result of understanding and applying imaging technologies towards innovative applications. This subject also aligns with some major innovations in Photonics and other areas of medical science which you may like to explore further if you are interested in invention and innovation at the Scottish Innovation Centres: http://www.innovationcentres.scot/

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 - a major innovation which has been global in impact

Where you study

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

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



Read less
Over the last decades, improvements in technology have led to a rapid increase in the use of neuroimaging to study human brain function non-invasively in health and disease. Read more
Over the last decades, improvements in technology have led to a rapid increase in the use of neuroimaging to study human brain function non-invasively in health and disease. In particular, functional magnetic resonance imaging (fMRI), electro-encephalography (EEG), magneto-encephalography (MEG) and transcranial magnetic stimulation (TMS) are now routinely used by neuroscientists to study brain-behaviour relationships. Our MSc in Brain Imaging showcases Nottingham’s multi-disciplinary environment and offers a comprehensive programme that will provide you with the theoretical knowledge and practical skills required to conduct high-quality neuroimaging work and neuroscience research. Translational in vivo neuroscience approaches in animal models will also be considered, and interested students will have the opportunity to receive research training in this area.

The MSc in Brain Imaging has a flexible course structure and offers four pathways with core modules alongside a choice of optional modules that permits tailor-made study. The options are:

MSc Brain Imaging (Cognitive Neuroscience)
MSc Brain Imaging (Neuropsychology)
MSc Brain Imaging (Integrative Neuroscience)
MSc Brain Imaging (Developmental Science)

Graduating from the University of Nottingham opens up a wide range of career options. Many of our students use this programme as a preparation for PhD study or other advanced degree positions. Others opt for science-related jobs. Our graduates are highly regarded by employers in private and public sector organisations because of the solid academic foundation and transferable skills they gain during their degree course such as analytical evaluation, data management, statistical analysis as well as presentation and writing skills. In the past, graduates of this programme have taken-up career opportunities in university, hospital and industry settings.

Please email for more information or visit the PG prospectus. Given the breadth of training available, the MSc is recommended to students with a background in psychology, neuroscience or a bioscience discipline as well as those with training in physics, engineering, mathematics, or computer sciences.

Upcoming Open Days: Wednesday 29 June and Wednesday 6 July (1.30-3 pm). Please contact us if you have specific questions about the programme. Phone: +44 (0)115 951 5361 or email:

Key facts

• Programme delivered through lectures, practicals and research project resulting in a dissertation
• Core and optional modules according to specific pathways
• Four pathways with applications in Cognitive Neuroscience, Developmental Science, Neuropsychology, and Integrative Neuroscience
• Taught by active and internationally renowned research scientists
• Interdisciplinary approach with specialist lectures and/or project supervision by scientists from: the School of Psychology; Sir Peter Mansfield Magnetic Resonance Centre; Department of Academic Radiology

Read less
Medical Imaging is an essential component of modern medicine, playing a key role in the diagnosis, treatment and monitoring of disease. Read more

Medical Imaging is an essential component of modern medicine, playing a key role in the diagnosis, treatment and monitoring of disease. The Medical Imaging MSc covers:

  • the basic physics involved in the different imaging techniques
  • image formation, pattern recognition and applications in the field of radiology
  • current issues in a modern UK NHS radiology department.

Whilst not a clinical skills course, the teaching of the technical aspects of imaging techniques is firmly grounded and in their clinical usage. Many of our lecturers are at the forefront of research in their field and bring insights from emerging imaging techniques.

This programme is designed for recent graduates preparing for a career in medical imaging, professionals already working in the field, and medical students wishing to intercalate.

More Information

You can study this subject at a MSc, Postgraduate Diploma or Postgraduate Certificate level.

You may transfer from your original programme to another one, provided that you do this before you have completed the programme and before an award has been made. Part-time study is also an option. 

You’ll become familiar with the range of clinical imaging techniques.

By the end of the programme you should be able to:

  • Demonstrate knowledge and understanding of the physical and mathematical aspects of image formation of several techniques;
  • Identify the anatomical and physiological properties of tissue associated with image formation and contrast for several techniques;
  • Analyse and compare the technical performance of various modalities;
  • Demonstrate an understanding of the clinical applications of each technique, the variables involved and how they can be compared;
  • Apply IT in literature searching, analysis and display of data, and report writing to enhance life-long learning in medical imaging;
  • Demonstrate enhancement of their professional skills in communication, problem-solving, learning effectively and quickly, and effective self-management;
  • Critically evaluate relevant published work, demonstrating an understanding of the underpinning principles of statistics, project design and data analysis.

Course structure

PGCert

Compulsory modules:

  • Medical Imaging Core Skills 15 credits

For more information on typical modules, read Medical Imaging PGCert in the course catalogue

PGDip

Compulsory modules :

  • Principles for Medical Imaging Interpretation 15 credits
  • Medical Imaging Core Skills 15 credits
  • Digital Radiography and X-ray Computed Tomography 15 credits
  • Magnetic Resonance Imaging 15 credits
  • Ultrasound Imaging 15 credits
  • Radionuclide Imaging 15 credits
  • Medical Image Analysis 15 credits
  • Research Methods 15 credits

For more information on typical modules, read Medical Imaging PGDip in the course catalogue

MSc

You’ll study modules worth 180 credits. If you study this programme part time you will study fewer modules in each year.

Compulsory modules:

  • Principles for Medical Imaging Interpretation 15 credits
  • Medical Imaging Core Skills 15 credits
  • Digital Radiography and X-ray Computed Tomography 15 credits
  • Magnetic Resonance Imaging 15 credits
  • Ultrasound Imaging 15 credits
  • Radionuclide Imaging 15 credits
  • Medical Image Analysis 15 credits
  • Research Methods 15 credits
  • Research Project 60 credits 

As an MSc student, you undertake a research project in the field of Medical Imaging. New research topics are available each year and include projects in MRI, Ultrasound, X-ray and their clinical application. You'll be asked to state your preferred research project. Before projects are allocated, you are encouraged to meet potential supervisors and discuss the research work.

Learning and teaching

All modules (except for your research project) are taught through traditional lectures, tutorials, practicals and computer based sessions. We also employ blended learning, combining online learning with other teaching methods.

You’ll be taught about the underpinning science of the various imaging modalities, and we cover a range of clinical applications demonstrating the use of medical imaging in modern medicine. Many of the lecturers are at the forefront of research in their particular field and will bring insights from current clinical imaging practice and developments of new and emerging imaging techniques.

Assessment

The taught modules are assessed by coursework and unseen written examinations. Exams are held during the University exam periods in January and May.

The research project is assessed in separate stages, where you submit a 1,000-word essay (20%), a 5,000-word journal-style research article (70%) and make an oral presentation (10%).

Career opportunities

Past graduates have gone on to enter careers in medical imaging or related disciplines, such as radiology and radiography. Often students are already working in the area, and use the skills and knowledge gained in the programme to enhance their careers. Students have gone on to take lecturer or research positions, and have also chosen to take post graduate research degrees (such as a PhD). As a intercalated degree for medical students the programme is useful for students considering radiology or many other medical specialties.

Careers support

We encourage you to prepare for your career from day one. That’s one of the reasons Leeds graduates are so sought after by employers.

The Careers Centre and staff in your faculty provide a range of help and advice to help you plan your career and make well-informed decisions along the way, even after you graduate. Find out more at the Careers website.



Read less
Pharmacy at Sunderland is ranked sixth in the country, according to The Guardian University Guide 2013. Read more
Pharmacy at Sunderland is ranked sixth in the country, according to The Guardian University Guide 2013.

Course overview

Do you want to contribute to the discovery and development of drugs that could potentially improve the health and well-being of millions of people? The UK has long been a leader in this complex technical area, in which each new drug requires around $1 billion of development work.

Our research-led teaching and state-of-the-art facilities make the University of Sunderland one of the UK's top locations for pharmaceutical science. Our strong links with the pharmaceutical industry ensure a flow of guest speakers and good contacts for your chosen Masters project/dissertation. Previous projects have involved collaborations with companies such as AstraZeneca, Pfizer and Helena Biosciences.

The course covers advanced pharmaceutics, pharmaceutical analysis, drug design, pharmacology, proteomics and pharmacogenomics. You will also cover regulatory processes for medicines, in line with ICH guidelines. The course is a direct response to employers’ search for postgraduates who have a mix of theoretical and practical skills and who will push boundaries in drug development.

With a Masters course, it’s important to consider the relevance of the research interests of tutors who will supervise your dissertation. At Sunderland, our interests include pharmaceutical analysis, process chemistry, various drug discovery programmes, and drug delivery systems, including those for large biological pharmaceuticals. Our academic team have produced some ‘world-leading’ research, according to the latest Research Excellence Framework (2014).

Course content

The course mixes taught elements with self-directed research. The topic of the project / dissertation is negotiated to fit both your personal interests and the expertise of Sunderland's supportive tutors. Modules on this course include:
Core modules
-Essential Research and Study Skills (20 Credits)
-Fundamentals for Pharmaceutical Science (20 Credits)
-The Pharmaceutical R&D Cycle and its Regulation (20 Credits)

Choose four out of the five following modules
-Advanced Pharmacology (15 Credits)
-Pharmacogenomics and Proteomics (15 Credits)
-Advanced Pharmaceutical Analysis (15 Credits)
-Advanced Drug Design (15 Credits)
-Advanced Pharmaceutics (15 Credits)

Choose one Masters option
-Double Project (60 Credits)
Or
-Double Dissertation (60 Credits)
Or
-Single Project (30 Credits) and Single Dissertation (30 Credits)

Teaching and assessment

We use a wide variety of teaching and learning methods which include lectures, seminars, open learning, laboratory work and group work.

The Masters project may involve collaboration with a pharmaceutical company. Previous projects have involved collaborations with companies such as AstraZeneca, Pfizer and Helena Biosciences.

Compared to an undergraduate course, you will find that this Masters requires a higher level of independent working and problem solving. Assessment methods include laboratory reports, oral presentations, case studies, critical reviews, examinations and the Masters project.

Facilities & location

This course is based in the Sciences Complex at our City Campus, which boasts multi-disciplinary laboratories and cutting-edge equipment thanks to multi-million pound investments.

Facilities for Pharmaceutics
We have pharmaceutical-related equipment for wet granulation, spray drying, capsule filling, tablet making, mixing inhalation, film coating and freeze drying. As well as standard pharmacopoeial test methods, such as dissolution testing, friability and disintegration, we also offer highly sophisticated test methods. These include rheometry, thermal analysis (differential scanning calorimetry and hot stage microscopy), tests for powder flow, laser diffraction, photon correlation spectroscopy, image analysis and laser confocal microscopy.

Facilities for Medicinal Chemistry
Our state-of-the-art spectroscopic facility allows us to confirm the structures of new molecules that could be potential pharmaceutical products and to investigate the structures of potential medicinal substances that have been isolated from plants. We are equipped with Liquid Chromatography-Nuclear Magnetic Resonance and Mass Spectroscopy (LC-NMR/MS) platforms; this is an exceptional facility for a university. We also have low and high resolution mass spectrometry, nuclear magnetic resonance and elemental analysis equipment. Our facilities allow you to gain hands-on experience of a wide range of analytical techniques such as atomic absorption spectroscopy and infra-red spectroscopy, which are of great importance in determining both ionic/metal content of pharmaceuticals and simple chemical structures respectively. You will also gain experience of revolutionary protein and DNA separation techniques, as well as Ultra High Performance Liquid Chromatography (x8) and Gas Chromatography for separating all kinds of samples of pharmaceutical or biomedical interest.

Facilities for Pharmacology
Our highly technical apparatus will give you first-hand experience of the principles of drug action and the effects of drugs on pharmacological and cellular models. As a result, you gain a better understanding of the effects of drugs on specific receptors located throughout the human body and related physiological effects.

University Library Services
We’ve got thousands of books and e-books on pharmaceutical and biomedical science, with many more titles available through the inter-library loan service. We also subscribe to a comprehensive range of print and electronic journals so you can access the most reliable and up-to-date academic and industry articles. Some of the most important sources for your studies include:
-Embase, which is a complex database covering drug research, pharmacology, pharmaceutics, toxicology, clinical and experimental human medicine, health policy and management, public health, occupational health, environmental health, drug dependence and abuse, psychiatry, forensic medicine and biomedical engineering/instrumentation
-PsycINF, which includes information about the psychological aspects of medicine, psychiatry, nursing, sociology, pharmacology and physiology
-PubMed, which contains life science journals, online books and abstracts that cover fields such as medicine, nursing, dentistry, veterinary medicine and health care
-Science Direct, which offers more than 18,000 full-text journals published by Elsevier
-Web of Science, which covers a broad range of science areas

Learning Environment
Sunderland Pharmacy School has a rich heritage in scientific studies and our degree courses are extremely well respected in the industry. We are fully plugged into relevant medical and pharmaceutical industry bodies, with strong links and an exchange of ideas and people. Your Masters project may involve collaboration with a pharmaceutical company, including working at their sites.

Employment & careers

Graduates from this course can pursue a variety of careers in the following areas; Drug Design, Pharmaceutical Analysis and Research, Pre-clinical Research in Experimental and Biological Studies, Formulation and Product Development, Pharmacogenomics and Proteomics, Clinical Research, Product Registration, Licensing and Regulatory Affairs.

Previous Sunderland graduates have been employed in companies such as GSK, Eisai, Reckitt Benckiser, Merck, Sharp & Dohme and Norbrook Laboratories.

Some students may apply for a PhD programme or those who already hold a Pharmacy degree can pursue MSc/PG Pharmaceutical Sciences for the Overseas Pharmacist Assessment Programme (OSPAP) and go through one-year pre-registration training.

Read less
Sunderland is the only university in the north of England to offer an Overseas Pharmacist Assessment Programme (OSPAP) that is accredited by the General Pharmaceutical Council. Read more
Sunderland is the only university in the north of England to offer an Overseas Pharmacist Assessment Programme (OSPAP) that is accredited by the General Pharmaceutical Council.

Course overview

Pharmaceutical Sciences for the Overseas Pharmacist Assessment Programme (OSPAP) is designed for those who are qualified pharmacists outside the European Economic Area and who are now looking to become registered pharmacists in the UK.

Our course is one of a small number of courses that are accredited by the General Pharmaceutical Council. Their accreditation is based on quality reviews that ensure Sunderland is meeting the required standards.

Completing the OSPAP postgraduate diploma allows for entry to the next stages of registering as a pharmacist in the UK: firstly, 52 weeks of supervised training in employment; secondly, a registration assessment.

Once all these stages are successfully completed, and assuming you have the necessary visa and work permit, you would be in a position to apply for roles as a practising pharmacist in the UK. There is virtually no unemployment of registered pharmacists in the UK.

You can also apply to undertake a Masters research project in addition to your postgraduate diploma. Pharmacy is a particular area of strength at the University of Sunderland and our Department has been teaching the subject since 1921.

Course content

The content of this course reflects the accreditation requirements of the General Pharmaceutical Council.

Modules on the course include:
-Pharmacy, Law, Ethics and Practice (60 Credits)
-Clinical Therapeutics (60 Credits)
-Research Methods for Pharmaceutical Practice and Masters Research Project (60 Credits)

Teaching and assessment

We use a wide variety of teaching and learning methods which include lectures, debate sessions, online learning packages, tutorials and seminars.

Compared to an undergraduate course, you will find that this Masters requires a higher level of independent working. Assessment methods include end-of-year examinations, practical assessments as well as assignments throughout the year.

Facilities & location

This course is based in the Sciences Complex at our City Campus, which boasts multi-disciplinary laboratories and cutting-edge equipment thanks to multi-million pound investments.

Facilities for Pharmaceutics
We have pharmaceutical-related equipment for wet granulation, spray drying, capsule filling, tablet making, mixing inhalation, film coating and freeze drying.

As well as standard pharmacopoeial test methods, such as dissolution testing, friability and disintegration, we also offer highly sophisticated test methods. These include rheometry, thermal analysis (differential scanning calorimetry and hot stage microscopy), tests for powder flow, laser diffraction, photon correlation spectroscopy, image analysis and laser confocal microscopy.

Facilities for Medicinal Chemistry
Our state-of-the-art spectroscopic facility allows us to confirm the structures of new molecules that could be potential pharmaceutical products and to investigate the structures of potential medicinal substances that have been isolated from plants.

We are equipped with Liquid Chromatography-Nuclear Magnetic Resonance and Mass Spectroscopy (LCNMR/MS) platforms; this is an exceptional facility for a university. We also have low and high resolution mass spectrometry, nuclear magnetic resonance and elemental analysis equipment.

Our facilities allow you to gain hands-on experience of a wide range of analytical techniques such as atomic absorption spectroscopy and infra-red spectroscopy, which are of great importance in determining both ionic/metal content of pharmaceuticals and simple chemical structures.

You will also gain experience of revolutionary protein and DNA separation techniques, as well as Ultra High Performance Liquid Chromatography and Gas Chromatography for separating unknown chemical mixtures.

Facilities for Pharmacology
Our highly technical apparatus will give you first-hand experience of the principles of drug action and the effects of drugs on pharmacological and cellular models. As a result, you gain a better understanding of the effects of drugs on specific receptors located throughout the human body and related physiological effects.

Simulation technology
You’ll have the opportunity to apply your training in a realistic setting with our two advanced simulation technology ‘SimMan’ models.
Each of our £57,000 SimMan mannequins has blood pressure, a pulse and other realistic physiological behaviour. The models can be pre-programmed with various medical scenarios, so you can demonstrate your pharmacological expertise in a realistic yet safe setting. Our academic team is also actively working with the SimMan manufacturers to develop new pharmacy simulations.

Pharmacy Practice
One of the most important skills of pharmacists is to communicate their expertise in a manner that the public can understand and accept.

The University has invested in a purpose-built model pharmacy complete with consultation suite. This allows you to develop skills in helping patients take the correct medicine in the right way, with optional video recording of your interaction with patients for the purposes of analysis and improvement.

In addition, we can accurately simulate hospital-based scenarios in a fully equipped ward environment where medical, nursing and pharmacy students can share learning.

University Library Services
We’ve got thousands of books and e-books on pharmaceutical and biomedical science, with many more titles available through the inter-library loan service. We also subscribe to a comprehensive range of print and electronic journals so you can access the most reliable and up-to-date academic and industry articles.

Some of the most important sources for your studies include:
-Embase, which is a complex database covering drug research, pharmacology, pharmaceutics, toxicology, clinical and experimental human medicine, health policy and management, public health, occupational health, environmental health, drug dependence and abuse, psychiatry, forensic medicine and biomedical engineering/instrumentation
-PubMed, which contains life science journals, online books and abstracts that cover fields such as medicine, nursing, dentistry, veterinary medicine and health care
-Science Direct, which offers more than 18,000 full-text journals published by Elsevier
-Web of Science, which covers a broad range of science areas

Learning Environment
Sunderland Pharmacy School has a rich heritage in scientific studies and our degree courses are extremely well respected in the industry. We are fully plugged into relevant medical and pharmaceutical industry bodies, with strong links and an exchange of ideas and people. Our vibrant learning environment helps ensure a steady stream of well-trained pharmacists whose most important concern is patient-centred pharmaceutical care.

Employment & careers

On completing this course you can register and practise in the UK as a qualified pharmacist. An entry-level pharmacist usually starts within Band 5 of the NHS pay rates (up to around £28,000). Advanced pharmacists, consultants, team managers and managers of pharmaceutical services are rated as Bands 8-9 and can earn up to £99,000. Currently there is virtually no unemployment of qualified pharmacists. Typical starting salaries for community pharmacists range from £21,000 to £35,000 depending on location, conditions of employment and experience.

Most pharmacists work in the following areas:
Community pharmacy: this involves working in pharmacies on high streets or in large stores. You will dispense prescriptions, deal with minor ailments, advise on the use of medicines and liaise with other health professionals.

Hospital pharmacy: this involves the purchasing, dispensing, quality testing and supply of medicines used in hospitals.

Primary care: this involves working in General Practice surgeries, either as an employee of the Practice or the Primary Care Trust. Roles include Medicines Management Pharmacists, who are responsible for prescribing budgets and the development of prescribing directives.

Secondary care: this involves working in hospitals to supply medicines, manage clinics, provide drug information and prescribe medicines.

Industrial pharmacists are involved in areas such as Research & Development, Quality Assurance and product registration.
Research degrees can be undertaken in many aspects of pharmacy. Sunderland Pharmacy School offers excellent facilities and a wide range of research expertise.

You can also work in areas of the pharmaceutical industry, medical writing and in education. By completing a Masters project in addition to your OSPAP postgraduate diploma it will enhance opportunities in academic roles or further study towards a PhD.

Read less
This programme pathway is designed for students with an interest in the engineering aspects of technology that are applied in modern medicine. Read more
This programme pathway is designed for students with an interest in the engineering aspects of technology that are applied in modern medicine. Students gain an understanding of bioengineering principles and practices that are used in hospitals, industries and research laboratories through lectures, problem-solving sessions, a research project and collaborative work.

Degree information

Students study in detail the engineering and physics principles that underpin modern medicine, and learn to apply their knowledge to established and emerging technologies in medical imaging and patient monitoring. The programme covers the engineering applications across the diagnosis and measurement of the human body and its physiology, as well as the electronic and computational skills needed to apply this theory in practice.

Students undertake modules to the value of 180 credits.

The programme consists of six core modules (90 credits), two optional modules (30 credits), and a research project (60 credits). A Postgraduate Diploma (120 credits) is offered.

Core modules
-Imaging with Ionising Radiation
-Clinical Practice
-Magnetic Resonance Imaging and Optics
-Medical Electronics and Control
-Professional Skills module

Optional modules
-Aspects of Biomedical Engineering
-Biomedical Engineering
-Computing in Medicine

Dissertation/report
All MSc students undertake an independent research project within the broad area of physics and engineering in medicine which culminates in a written report of 10,000 words, a poster and an oral examination.

Teaching and learning
The programme is delivered through a combination of lectures, demonstrations, practicals, assignments and a research project. Lecturers are drawn from UCL and from London teaching hospitals including UCLH, St. Bartholomew's, and the Royal Free Hospital. Assessment is through supervised examination, coursework, the dissertation and an oral examination.

Careers

Graduates from the Biomedical Engineering and Medical Imaging stream of the MSc programme have obtained employment with a wide range of employers in healthcare, industry and academia sectors.

Employability
Postgraduate study within the department offers the chance to develop important skills and acquire new knowledge through involvement with a team of scientists or engineers working in a world-leading research group. Graduates complete their study having gained new scientific or engineering skills applied to solving problems at the forefront of human endeavour. Skills associated with project management, effective communication and teamwork are also refined in this high-quality working environment.

Why study this degree at UCL?

The spectrum of medical physics activities undertaken in UCL Medical Physics & Biomedical Engineering is probably the broadest of any in the United Kingdom. The department is widely acknowledged as an internationally leading centre of excellence and students receive comprehensive training in the latest methodologies and technologies from leaders in the field.

The department operates alongside the NHS department which provides the medical physics and clinical engineering services for the UCL Hospitals Trust, as well as undertaking industrial contract research and technology transfer.

Students have access to a wide range of workshop, laboratory, teaching and clinical facilities in the department and associated hospitals. A large range of scientific equipment is available for research involving nuclear magnetic resonance, optics, acoustics, X-rays, radiation dosimetry, and implant development, as well as new biomedical engineering facilities at the Royal Free Hospital and Royal National Orthopaedic Hospital in Stanmore.

Read less

Show 10 15 30 per page



Cookie Policy    X