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The Medical Physics and Bioengineering MRes provides structured training in this diverse and multi-disciplinary field and students may subsequently progress to an MPhil/PhD as part of a Doctoral Training Programme. Read more
The Medical Physics and Bioengineering MRes provides structured training in this diverse and multi-disciplinary field and students may subsequently progress to an MPhil/PhD as part of a Doctoral Training Programme.

See the website http://www.ucl.ac.uk/prospective-students/graduate/taught/degrees/medical-physics-bioengineering-mres

Key Information

- Application dates
All applicants:
Open: 5 October 2015
Close: 29 July 2016

English Language Requirements

If your education has not been conducted in the English language, you will be expected to demonstrate evidence of an adequate level of English proficiency.
The English language level for this programme is: Standard
Further information can be found on http://www.ucl.ac.uk/prospective-students/graduate/life/international/english-requirements .

International students

Country-specific information, including details of when UCL representatives are visiting your part of the world, can be obtained from http://www.ucl.ac.uk/prospective-students/international .

Degree Information

The programme covers all forms of ionising and non-ionising radiation commonly used in medicine and applies it to the areas of imaging and treatment. The programme involves Master's level modules chosen from a wide range offered by the department and a research project. Good performance in the MRes will lead to entry into the 2nd year of the Doctoral Training Programme where the research project is continued.

Students undertake modules to the value of 180 credits.

The programme consists of four optional modules and a research project.

- Core Modules
There are no core modules for this programme.

- Options
Students choose four optional modules from the following:
Ionising Radiation Physics: Interactions and Dosimetry
Medical Imaging
Clinical Practice
Treatment with Ionising Radiation
Medical Electronics and Control
Bioengineering
Optics in Medicine
Computing in Medicine
Medical Devices and Applications
Foundations and Anatomy and Scientific Computing
Image Processing
Computational Modelling in Biomedical Imaging
Programming Foundations for Medical Image Analysis
Information Processing in Medical Imaging
Image-Directed Analysis and Therapy

- Dissertation/report
All students undertake a research project.

Further information on modules and degree structure available on the department web site Medical Physics and Bioengineering MRes http://www.ucl.ac.uk/medphys/prospective-students/phd/dtp

Funding

Scholarships relevant to this department are displayed (where available) below. For a comprehensive list of the funding opportunities available at UCL, including funding relevant to your nationality, please visit the Scholarships and Funding website http://www.ucl.ac.uk/prospective-students/scholarships .

Careers

Our graduates typically find work in academia, the NHS, and in industry

Why study this degree at UCL?

The department is one of the largest medical physics and bioengineering departments in Europe, with links to a large number of active teaching hospitals. We have arguably the widest range of research of any similar department, and work closely with other world-leading institutions.

Students on the programme will form part of an interactive network of researchers across many disciplines and will benefit from the strengths of UCL in the healthcare field.

Student / staff ratios › 144 staff including 110 postdocs › 107 taught students › 135 research students

Application and next steps

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

- Who can apply?
The programme is suitable either for students wishing to study for a stand-alone MRes in Medical Physics & Bioengineering or for students planning progression to a Doctoral Training Programme.

What are we looking for?
When we assess your application we would like to learn:
- why you want to study Medical Physics and Bioengineering at graduate level
- why you want to study Medical Physics and Bioengineering at UCL
- what particularly attracts you to this programme
- how your personal, academic and professional background meets the demands of a challenging programme
- where you would like to go professionally with your degree

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

For more information see the Applications page http://www.ucl.ac.uk/prospective-students/graduate/apply .

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The course aims to provide science or engineering graduates from a diversity of backgrounds with a solid grounding in modern bioengineering technologies, together with options to develop an emphasis in biomechanics and biomaterials, bioimaging and biosensing and digital modelling of various human systems which will prepare students for a career in an industrial, clinical or research environment. Read more
The course aims to provide science or engineering graduates from a diversity of backgrounds with a solid grounding in modern bioengineering technologies, together with options to develop an emphasis in biomechanics and biomaterials, bioimaging and biosensing and digital modelling of various human systems which will prepare students for a career in an industrial, clinical or research environment.

This course is one of a suite of four closely related bioengineering masters courses that comprise of a common core with the ability to focus on specific aspects of bioengineering.
The course has a broader scope than the three related courses, allowing students to select modules related to biomaterials, biomechanics, imaging and sensing and digital modelling.

This course may be appropriate for students who have yet to decide which area of bioengineering they wish to focus on. The principles of the course are highly relevant to the established medical device sector, the biotechnology and the emerging regenerative medicine industry.

This multidisciplinary masters covers practical and theoretical aspects of bioengineering, including:
-cell-biomaterial surface interactions
-materials characterisation
-functionalisation of surface
-biomechanics and mathematical modelling

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This course aims to provide science or engineering graduates from a diversity of backgrounds with a solid grounding in modern bioengineering technologies, together with a strong emphasis in biomechanics and biomaterials. Read more
This course aims to provide science or engineering graduates from a diversity of backgrounds with a solid grounding in modern bioengineering technologies, together with a strong emphasis in biomechanics and biomaterials. This course will prepare students for a career in an industrial, clinical or research environment, independent learning, and postgraduate research or careers in industry or hospitals.

This course is one of a suite of four closely related bioengineering masters courses that comprise of a common core with the ability to focus on specific aspects of bioengineering.

The course covers material optimisation and engineering of biomedical devices while addressing biological considerations to optimise device performance. Such an approach has a wide application range, incorporating transitory invasive devices to permanent implants for repair, replacement and regenerative treatments. The principles of the course are highly relevant to both the established medical device sector and the emerging regenerative
medicine industry.

This multidisciplinary MSc covers practical and theoretical aspect of bioengineering, including:
-cell-biomaterial surface interactions
-materials characterisation
-functionalisation of surface
-biomechanics and mathematical modelling

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This exciting interdisciplinary MSc programme focuses on providing advanced academic training in the cellular and molecular processes that relate to the production of biomedicines for use in healthcare. Read more
This exciting interdisciplinary MSc programme focuses on providing advanced academic training in the cellular and molecular processes that relate to the production of biomedicines for use in healthcare.

This is coupled with rigorous practical training in the design, production and characterisation of biomolecules using state-of-theart biotechnological and bioengineering analytical and molecular technologies.

You acquire practical, academic and applied skills in data analysis, systems and modelling approaches, and bioinformatics, together with transferable skills in scientific writing, presentation and public affairs. On successful completion of the programme, you will be able to integrate these skills to develop novel solutions to modern biotechnological issues from both academic and industrial perspectives.

Visit the website: https://www.kent.ac.uk/courses/postgraduate/213/biotechnology-and-bioengineering

About the School of Biosciences

The School of Biosciences is among the best-funded schools of its kind in the UK, with current support from the BBSRC, NERC, MRC, Wellcome Trust, EU, and industry. It has 38 academic staff, 56 research staff (facility managers, research fellows, postdoctoral researchers and technicians), approximately 100 postgraduate students and 20 key support staff. The school's vibrant atmosphere has expanded to become a flourishing environment to study for postgraduate degrees in a notably friendly and supportive teaching and research environment.

Research in the School of Biosciences revolves around understanding systems and processes in the living cell. It has a strong molecular focus with leading-edge activities that are synergistic with one another and complementary to the teaching provision. Our expertise in disciplines such as biochemistry, microbiology and biomedical science allows us to exploit technology and develop groundbreaking ideas in the fields of genetics, molecular biology, protein science and biophysics. Fields of enquiry encompass a range of molecular processes from cell division, transcription and translation through to molecular motors, molecular diagnostics and the production of biotherapeutics and bioenergy.

In addition to research degrees, our key research strengths underpin a range of unique and career-focused taught Master’s programmes that address key issues and challenges within the biosciences and pharmaceutical industries and prepare graduates for future employment.

Course structure

The MSc in Biotechnology and Bioengineering involves studying for 120 credits of taught modules, as indicated below. The taught component takes place during the autumn and spring terms, while a 60-credit research project take place over the summer months.

The programme is taught by staff from the Industrial Biotechnology Centre, an interdisciplinary research centre whose aim is to solve complex biological problems using an integrated approach to biotechnology and bioengineering. It is administered by the School of Biosciences who also contribute to the programme.

Modules

The following modules are indicative of those offered on this programme. This list is based on the current curriculum and may change year to year in response to new curriculum developments and innovation. Most programmes will require you to study a combination of compulsory and optional modules. You may also have the option to take modules from other programmes so that you may customise your programme and explore other subject areas that interest you.

BI830 - Science at Work (30 credits)
BI836 - Practical and Applied Research Skills for Advanced Biologists (30 credits)
BI852 - Advanced Analytical and Emerging Technologies for Biotechnology and Bio (30 credits)
BI857 - Cancer Research in Focus (15 credits)
CB612 - New Enterprise Startup (15 credits)
CB613 - Enterprise (15 credits)
BI840 - Cancer Therapeutics: From the Laboratory to the Clinic (15 credits)
BI845 - Research project (60 credits)

Assessment

Assessment is by coursework and the research project.

Programme aims

You will gain the following transferable skills:

- the ability to plan and manage workloads

- self-discipline and initiative

- the development of reflective learning practices to make constructive use of your own assessment of performance and use that of colleagues, staff and others to enhance performance and progress

- communication: the ability to organise information clearly, create and respond to textual and visual sources (eg images, graphs, tables), present information orally, adapt your style for different audiences.

- enhanced understanding of group work dynamics and how to work as part of a group or independently.

Research areas

Research in the School of Biosciences is focused primarily on essential biological processes at the molecular and cellular level, encompassing the disciplines of biochemistry, genetics, biotechnology and biomedical research.

The School’s research has three main themes:

- Protein Science – encompasses researchers involved in industrial biotechnology and synthetic biology, and protein form and function

- Molecular Microbiology – encompasses researchers interested in yeast molecular biology (incorporating the Kent Fungal Group) and microbial pathogenesis

- Biomolecular Medicine – encompasses researchers involved in cell biology, cancer targets and therapies and cytogenomics and bioinformatics.

Each area is led by a senior professor and underpinned by excellent research facilities. The School-led development of the Industrial Biotechnology Centre (IBC), with staff from the other four other schools in the Faculty of Sciences, facilitates and encourages interdisciplinary projects. The School has a strong commitment to translational research, impact and industrial application with a substantial portfolio of enterprise activity and expertise.

Careers

A postgraduate degree in the School of Biosciences is designed to equip our graduates with transferable skills that are highly valued in the workplace. Our research-led ethos ensures that students explore the frontiers of scientific knowledge, and the intensive practical components provide rigorous training in cutting edge technical skills that are used in the modern biosciences while working in areas of world-leading expertise within the School.

Destinations for our graduates include the leading pharmaceutical and biotechnological companies within the UK and leading research institutes both at home and abroad.

Find out how to apply here - https://www.kent.ac.uk/courses/postgraduate/apply-online/213

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The Department offers a one-year full-time MRes in Bioengineering, which has been developed to prepare students for a research career in bioengineering. Read more
The Department offers a one-year full-time MRes in Bioengineering, which has been developed to prepare students for a research career in bioengineering.

The course involves lectures and practical work in the first term, followed by a full-time work on a research project. A variety of seminars and workshops are provided to deepen and broaden students’ research skill base.

The course will prepare you to analyse and solve problems in bioengineering using an integrated, multidisciplinary approach.

You can also take this course as the first year of a four-year PhD programme.

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Core modules. Compulsory modules on research methodology and research practice. Innovation, Management and Research Methods (15 credits). Read more
Core modules

Compulsory modules on research methodology and research practice
Innovation, Management and Research Methods (15 credits)
Bioengineering Research Method (15 credits)
Biomedical Engineering Principles (15 credits)
Biomedical Statistics (15 credits)
Dissertation (90 credits)

Optional modules

The two optional modules for each of the four offered streams are designed to suit students of different backgrounds. The optional modules are all designed to enhance the students’ knowledge or fill the student knowledge gaps on specific disciplines of bioengineering so that students are enabled to perform high quality research.

Stream A
Biomedical Imaging and Image Processing (15 credits)
Control Theory for Bioengineering (15 credits)

Stream B
Biofluid Mechanics (15 credits)
Advanced Biofluid Mechanical Research (15 credits)

Stream C
Biomechanics and Biomaterials (15 credits)
Tissue Engineering and Regenerative Medicine (15 credits)

Stream D
Advanced Separation Science and Industrial Case Studies (15 credits)
Process Instrumentation and Practice (15 credits)

The dissertation module starts early in the first year and last through the entire year. Students may not decide the specific dissertation title at the beginning of the year, but the desired research area (stream). The students can decide on the specific dissertation title at mid-term when they have gained further knowledge about the stream subject area. However, the intensive research activities only start from the second term once the exam period for the first term modules has finished.

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Explore how engineering principles can be applied to biological challenges, work with the latest nanoscale applications, and learn about the innovations that are driving the world of nanotechnology. Read more
Explore how engineering principles can be applied to biological challenges, work with the latest nanoscale applications, and learn about the innovations that are driving the world of nanotechnology.

KEY LEARNING OUTCOMES

Through the master's degree in the field of bioengineering and nanotechnology you:
-Gain an understanding of emerging biomedical technologies, including microfluidics for cellular analysis, tissue regeneration, and the use of nanomaterial for drug delivery.
-Build experience in experimental or case study design, scientific data analysis, writing and communication, ethical practices, and effective collaboration.
-Develop knowledge in life science theory as it relates to biotechnology.

PROGRAM OVERVIEW

The degree includes nine courses—at least four taken on campus—and a thesis.
-Get started. You begin by completing three admission courses from the program curriculum. This is your opportunity to demonstrate your commitment and ability to perform well as a Harvard student.
-Apply to the program. While you are completing your third admission course, you may submit your application. We have application periods in the fall, spring, and summer.
-Continue your studies, online and on campus. As you progress through the program, you may choose from courses offered on campus or online, in the fall, spring, or summer. You are required to take at least four courses on campus as part of your degree.
-Complete your thesis. Working with a thesis director, you conduct in-depth research on a topic relevant to your work experience or academic interests, producing publishable quality results. You’ll emerge with a solid understanding of how scientific research is executed and communicated.
-Graduate with your Harvard degree. You participate in the annual Harvard Commencement, receiving your Harvard University degree: Master of Liberal Arts (ALM) in extension studies, field: Bioengineering and Nanotechnology.

COST

Affordability is core to our mission. Our 2016–17 graduate tuition is $2,550 per course; the total tuition cost of earning the graduate degree is approximately $25,500.

FINANCIAL SERVICES

The Student Financial Services staff can assist you in identifying funds that will help you meet the costs of your education. You can find more information here: http://www.extension.harvard.edu/tuition-enrollment/financial-aid

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The Institute for Bioengineering (IBioE) connects Engineering, Physical Sciences, Biology and Medicine, for innovative diagnostic and therapeutic biomedical devices and technologies. Read more

Research profile

The Institute for Bioengineering (IBioE) connects Engineering, Physical Sciences, Biology and Medicine, for innovative diagnostic and therapeutic biomedical devices and technologies.

Research themes include:

Synthetic Biology - to design and construct (e.g. to ‘engineer’) biological devices and systems, often at cellular level. Applications range from therapeutic to environmental.

Tissue Engineering - the production of 3D or 2D scaffolds or guidance cues for biological cells. Applications are largely therapeutic and also include new forms of lab-on-chip technology.

Biomedical Modelling and Measurement - understanding biological materials through modelling and measurement for applications in, for example, prosthetics, prediction of failure in blood vessels and the behaviour of bone with ageing. We also study the behaviour of biological materials experimentally and in most cases, non-invasively (e.g. via Raman and CARS spectroscopy).

Biomedical Devices and Sensors - working with colleagues in chemistry, we develop sensors on silicon for simple biological parameters (e.g. oxygen concentration) along with sensors of specific biomarkers of disease and therapy.

Training and support

The development of transferable skills is a vital part of postgraduate training and a vibrant, interdisciplinary training programme is offered to all research students by the University’s Institute for Academic Development (IAD). The programme concentrates on the professional development of postgraduates, providing courses directly linked to postgraduate study.

Courses run by the IAD are free and have been designed to be as flexible as possible so that you can tailor the content and timing to your own requirements.

Our researchers are strongly encouraged to present their research at conferences and in journal during the course of their PhD.

Every year, the Graduate School organises a Postgraduate Research Conference to showcase the research carried out by students across the Research Institutes

Our researchers are also encouraged and supported to attend transferable skills courses provided by organisations such as the Engineering and Physical Sciences Research Council (EPSRC).

Research opportunities

We offer a comprehensive range of exciting research opportunities through a choice of postgraduate research degrees: MSc by Research, MPhil and PhD.

Masters by Research

An MSc by Research is based on a research project tailored to a candidate’s interests. It lasts one year full time or two years part time. The project can be a shorter alternative to an MPhil or PhD, or a precursor to either – including the option of an MSc project expanding into MPhil or doctorate work as it evolves. It can also be a mechanism for industry to collaborate with the School.

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This course provides science or engineering graduates from a diversity of backgrounds with the technical knowledge and skills necessary to develop a career in this rapidly expanding area. Read more
This course provides science or engineering graduates from a diversity of backgrounds with the technical knowledge and skills necessary to develop a career in this rapidly expanding area. The principles of the course are highly relevant to the established medical device sector, the biotechnology industry and the emerging regenerative medicine industry. The course builds on our internationally leading research in biomedical optical imaging and teaching is undertaken by experts in imaging and sensing.

Students will:

-learn about cutting edge imaging and sensing techniques being applied in clinical care, the pharmaceutical and biotechnology sectors
-understand basic structure and function of both cells and humans
-learn how the function of single cells can be probed using electronic and optical methods
-understand how light interacts with tissue and can be used to monitor blood flow and oxygen content
-build an optical device to monitor heart rate
-undertake an individual summer research project.

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This exciting, two year MSc programme is concerned with a wide range of biomedical imaging and sensing science and technology. Biomedical Imaging and Sensing is, in a broad sense, a set of competencies from engineering and sciences to support future quantitative biology and personalised medicine. Read more
This exciting, two year MSc programme is concerned with a wide range of biomedical imaging and sensing science and technology. Biomedical Imaging and Sensing is, in a broad sense, a set of competencies from engineering and sciences to support future quantitative biology and personalised medicine.

It will provide you with theoretical and practical knowledge to develop methods and systems for disease understanding, diagnosis, prognosis and therapeutics where imaging and sensing play a key role.

Core modules

Interdisciplinary Seminars in Biomedical Imaging and Sensing
Mathematics of Imaging Sciences
Scientific Software Development for Biomedical Imaging

Departmental optional modules

Advanced Signal Processing
Computer Vision, Biomedical Signals and Systems
Physiological Signals and Sensing; Physics of Light Microscopy of Cells and Tissues
Physics of Medical Imaging with Ionising Radiation
Physical Principles of Imaging: Radiation-Matter Interaction
Medical Image Computing
Biomaging with Light and Sound
Microscopy Image Analysis
Magnetic Resonance Imaging and Spectroscopy

Interdisciplinary optional modules

The programme allows you to explore some elective modules from interdisciplinary domains that relate to anatomy, physiology, cell biology, physics of the senses, and vision and neurosciences, among others.

Teaching and assessment

Research-led teaching from our department, and various interdisciplinary modules from other departments from the Faculty of Engineering and the Faculty of Medicine, Health and Dentistry.

Individual support for your research project and dissertation.

Assessment is by examination, a project, and coursework in the first year with future examinations and dissertation in your second year.

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The Musculoskeletal Science MSc covers a broad spectrum of musculoskeletal topics, including basic science and clinical aspects. Read more
The Musculoskeletal Science MSc covers a broad spectrum of musculoskeletal topics, including basic science and clinical aspects. It aims to give students, in a multidisciplinary setting, a holistic view of musculoskeletal science, orthopaedic bioengineering and medicine, and provides an in-depth knowledge of specific areas appropriate to each student's individual interests.

Degree information

Students on this MSc programme acquire essential scientific knowledge, improve their basic research skills, and are equipped with the ability to solve the musculoskeletal problems emphasised within the NHS framework. The programme emphasises the four major areas as identified by the Bone and Joint Decade - arthritis, osteoporosis, trauma and spinal disorders, and transferable skills and research methodology in orthopaedic bioengineering.

Students undertake modules to the value of 180 credits. The programme consists of eight taught modules (120 credits), and a research project (60 credits).

Students will be awarded an MSc on successful completion of all taught modules and research project; a Postgraduate Diploma on successful completion of eight taught modules (all core modules plus any four from options); and a Postgraduate Certificate on successful completion of four taught modules.

A Postgraduate Diploma (120 credits, full-time nine months and flexible study up to five years) is offered. A Postgraduate Certificate (60 credits, full-time three months and flexible study up to two years) is offered.

Core modules
-Clinical Aspects of Musculoskeletal Medicine and Surgery, Part I
-Musculoskeletal Tissue Biology - Form and Function
-Musculoskeletal Biomechanics and Biomaterials, Part I
-Research Methodology and Generic Skills

Optional modules - up to 60 credits of optional modules (4 modules) drawn from the following:
-Clinical Aspects of Musculoskeletal Medicine and Surgery, Part II
-Musculoskeletal Tissue Biology - Disease and Dysfunction
-Musculoskeletal Biomechanics and Biomaterials, Part II
-Research Governance
-Clinical Experience in Musculoskeletal Surgery
-Surgical Skills in Orthopaedic Surgery

Dissertation/report
All MSc students undertake an independent research project that will contribute to cutting-edge scientific, clinical and industrial research, and culminates in a dissertation and oral examination.

Teaching and learning
The programme is delivered through a combination of taught lectures, seminars, tutorials, group project work and workshops. Assessment is through online MCQs, coursework, and the dissertation and viva voce. Candidates are examined in the year in which they complete the programme.

Careers

This programme offers students from a wide variety of disciplines the opportunity to gain a higher degree in an exciting and rapidly developing field, and equips them to make a strong contribution to the development of musculoskeletal services. The students can develop their careers in healthcare sector, medical device industry and bio-industry, regenerative medicine, regulatory bodies, as well as academic community.

Top career destinations for this degree:
-Orthopaedic Surgeon, St Thomas' Hospital (NHS)
-MBBS (Bachelor of Medicine, Bachelor of Surgery), King's College London
-Medical Research on Replacement Joints, Cardiff University (Prifysgol Caerdydd)
-Occupational Therapy Assistant, Watford General Hospital (NHS)
-Orthopaedic Surgeon, Assaswa International Hospital

Why study this degree at UCL?

The Division of Surgery & Interventional Science is part of one of the most prestigious medical schools in Europe, with a team of nearly 400 people, from surgeons, biologists, bioengineers and material scientists and oncologists, to clinical trials specialists and researchers. Our aim is to understand the causes of human musculoskeletal disease and develop innovative therapies and technology to improve the quality of life.

Students on this MSc will gain an unparalleled grounding in musculoskeletal science and orthopaedic bioengineering, including a holistic view of clinical care as well as orthopaedic sciences and bioengineering. The programme is run at the internationally renowned Royal Orthopaedic Hospital in Stanmore.

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The Musculoskeletal Science MSc covers a broad spectrum of musculoskeletal topics, including basic science and clinical aspects. Read more
The Musculoskeletal Science MSc covers a broad spectrum of musculoskeletal topics, including basic science and clinical aspects. It aims to give students, in a multidisciplinary setting, a holistic view of musculoskeletal science, orthopaedic bioengineering and medicine, and provides an in-depth knowledge of specific areas appropriate to each student's individual interests.

Degree information

Students on this MSc programme acquire essential scientific knowledge, improve their basic research skills, and are equipped with the ability to solve the musculoskeletal problems emphasised within the NHS framework. The programme emphasises the four major areas as identified by the Bone and Joint Decade - arthritis, osteoporosis, trauma and spinal disorders, and transferable skills and research methodology in orthopaedic bioengineering.

Students undertake modules to the value of 180 credits. The programme consists of four core modules (60 credits), four optional modules (60 credits) and a research project (60 credits). A Postgraduate Diploma (120 credits, full-time nine months and flexible study up to five years) is offered. A Postgraduate Certificate (60 credits, full-time three months and flexible study up to two years) is offered.

Core modules
-Clinical aspects of Musculoskeletal Medicine and Surgery, Part I
-Musculoskeletal Tissue Biology - Form and Function
-Musculoskeletal Biomechanics and Biomaterials, Part I
-Research Methodology and Generic Skills

Optional modules - up to 60 credits of optional modules (4 modules) drawn from the following:
-Clinical aspects of Musculoskeletal Medicine and Surgery, Part II
-Musculoskeletal Biology, Part II
-Musculoskeletal Biomechanics and Biomaterials, Part II
-Musculoskeletal Epidemiology and Research Methodology, Part II
-Clinical Experience in Musculoskeletal Surgery

Dissertation/report
All MSc students undertake an independent research project, which can be carried out at their own institution or hospital, and culminates in a dissertation and oral examination.

Teaching and learning
The programme is delivered through a combination of web-based taught lectures, seminars, tutorials, online research forum, group project work and workshops. Assessment is through unseen written examination, coursework, and the dissertation and viva voce. Candidates are examined in the year in which they complete the programme.

Careers

This programme offers students from a wide variety of disciplines the opportunity to gain a higher degree in an exciting and rapidly developing field, and equips them to make a strong contribution to the development of musculoskeletal services. The students can develop their careers in healthcare sector, medical device industry and bio-industry, regenerative medicine, regulatory bodies, as well as academic community.

Top career destinations for this degree:
-Trauma and Orthopaedics, NHS Bradford Teaching Hospitals NHS Foundation Trust and studying Engineering, The Open University.

Why study this degree at UCL?

The UCL Division of Surgery & Interventional Science is part of one of the most prestigious medical schools in Europe, with a team of nearly 400 people, from surgeons, biologists, bioengineers and material scientists and oncologists to clinical trials specialists and researchers. Our aim is to understand the causes of human musculoskeletal disease and develop innovative therapies and technology to improve the quality of life of the people around us.

Students on this MSc will gain an unparalleled grounding in musculoskeletal science and orthopaedic bioengineering including a holistic view of clinical care as well as orthopaedic sciences and bioengineering. The programme is run at the internationally renowned Royal Orthopaedic Hospital in Stanmore.

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

Degree information

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

Students undertake modules to the value of 180 credits. The programme consists of eight core modules (120 credits) and a research dissertation (60 credits). There are no optional modules for this programme.

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

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

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

Careers

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

Top career destinations for this degree:
-Clinical Fellow Plastic Surgeon, Royal London Hospital, Barts Health NHS Trust
-MRes in Synthetic Biology, UCL
-PhD in Biomaterials and Tissue Engineering, UCL
-Transcranial Ultrasonic Stimulation, UCL
-Chief Research and Technology Officer, eSpin NanoTech

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

Why study this degree at UCL?

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

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

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

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The Medical Physics and Bioengineering MRes provides structured training in this diverse and multidisciplinary field and students may subsequently progress to an MPhil/PhD as part of a Doctoral Training Programme. Read more
The Medical Physics and Bioengineering MRes provides structured training in this diverse and multidisciplinary field and students may subsequently progress to an MPhil/PhD as part of a Doctoral Training Programme.

Degree information

The programme covers all forms of ionising and non-ionising radiation commonly used in medicine and applies it to the areas of imaging and treatment. The programme involves Master's level modules chosen from a wide range offered by the department and a research project. Good performance in the MRes will lead to entry into the 2nd year of the Doctoral Training Programme where the research project is continued.

Students undertake modules to the value of 180 credits. The programme consists of four optional modules and a research project. There are no core modules for this programme.

Optional modules - students choose four optional modules from the following:
-Ionising Radiation Physics: Interactions and Dosimetry
-Medical Imaging
-Clinical Practice
-Treatment with Ionising Radiation
-Medical Electronics and Control
-Bioengineering
-Optics in Medicine
-Computing in Medicine
-Medical Devices and Applications
-Foundations and Anatomy and Scientific Computing
-Image Processing
-Computational Modelling in Biomedical Imaging
-Programming Foundations for Medical Image Analysis
-Information Processing in Medical Imaging
-Image-Directed Analysis and Therapy

Dissertation/report
All students undertake a research project.

Careers

Our graduates typically find work in academia, the NHS, and in industry.

Why study this degree at UCL?

The department is one of the largest medical physics and bioengineering departments in Europe, with links to a large number of active teaching hospitals. We have arguably the widest range of research of any similar department, and work closely with other world-leading institutions.

Students on the programme will form part of an interactive network of researchers across many disciplines and will benefit from the strengths of UCL in the healthcare field.

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The MSc Design for Medical Technologies is aimed at providing the key knowledge and experience to allow you to pursue a career in bioengineering, healthcare or biotechnology. Read more
The MSc Design for Medical Technologies is aimed at providing the key knowledge and experience to allow you to pursue a career in bioengineering, healthcare or biotechnology. The course will expose you to the leading edge of modern medical and surgical technologies, as well as exploring the role of entrepreneurship, business development and intellectual property exploitation.

Why study Design for Medical Technologies at Dundee?

The unique environments of medicine and biotechnology offer exacting challenges in the design of high technology products for use in these fields. Engineers and product designers involved in the development of new biomedical instrumentation, surgical tools or biotechnology products must understand the constrictions placed on them by this environment. As a result, bioengineering has been established as the fusion of engineering and ergonomics with a deep understanding of medical science.

Benefits of the programme include:
Knowledge and understanding of medical and surgical engineering and technology
Skills in research methods, communications, teamwork and management
Appreciation of entrepreneurship and the global 'Medtech' industry
Participation in research activities of world renowned research groups
Preparation for careers in industry, academia and commerce

What's great about Design for Medical Technologies at Dundee?

The University of Dundee is one of the top UK universities, with a powerful research reputation, particularly in the medical and biomedical sciences. It has previously been named Scottish University of the Year and short-listed for the Sunday Times UK University of the year.

The Mechanical Engineering group has a high international research standing with expertise in medical instrumentation, signal processing, biomaterials, tissue engineering, advanced design in minimally invasive surgery and rehabilitation engineering.

Links and research partnerships:

We have extensive links and research partnerships with clinicians at Ninewells Hospital (largest teaching hospital in Europe) and with world renowned scientists from the University's College of Life Sciences.

The new Institute of Medical Science and Technology (IMSaT) at the University has been established as a multidisciplinary research 'hothouse' which seeks to commercialise and exploit advanced medical technologies leading to business opportunities.

The start date is September each year, and lasts for 12 months.

How you will be taught

The structure of the MSc course is divided into two parts. The taught modules expose students to the leading edge of modern medical and surgical technologies. The course gives concepts and understanding of the role of entrepreneurship, business development and intellectual property exploitation in the biomedical industry, with case examples.

The research project allows students to work in a research area of their own particular interest, learning skills in presentation, critical thinking and problem-solving. Project topics are offered to students during the first semester of the course.

What you will study

The three taught modules are:
Imaging and Instrumentation for Medicine and Surgery (30 Credits)
Biomechanics and Biomedical (30 Credits)
Advanced Medical and Surgical Instrumentation (30 Credits)

These modules are followed by the biomedical research project (90 credits).

How you will be assessed

The course is assessed by coursework and examination, plus research project.

Careers

The MSc Design for Medical Technologies is aimed at providing the key knowledge and experience to allow you to pursue a career in bioengineering, healthcare or biotechnology. This opens up a vast range of opportunities for employment in these industries as a design, development or product engineer, research scientist, sales and marketing manager or Director of a start-up company. The programme also provides the ideal academic grounding to undertake a PhD degree leading to a career in academic research.

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