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WHAT YOU WILL GAIN. - Practical guidance from biomedical engineering experts in the field. - 'Hands on' knowledge from the extensive experience of the lecturers, rather than from only the theoretical information gained from books and college reading. Read more
WHAT YOU WILL GAIN

- Practical guidance from biomedical engineering experts in the field
- 'Hands on' knowledge from the extensive experience of the lecturers, rather than from only the theoretical information gained from books and college reading
- Credibility as a biomedical engineering expert in your firm
- Skills and know-how in the latest technologies in biomedical engineering
- Networking contacts in the industry
- Improved career prospects and income
- An EIT Advanced Diploma of Biomedical Engineering

Next intake is scheduled for June 06, 2017. Applications are now open; places are limited.

INTRODUCTION

Biomedical engineering is the synergy of many facets of applied science and engineering. The advanced diploma in biomedical engineering provides the knowledge and skills in electrical, electronic engineering required to service and maintain healthcare equipment. You will develop a wide range of skills that may be applied to develop software, instrumentation, image processing and mathematical models for simulation. Biomedical engineers are employed in hospitals, clinical laboratories, medical equipment manufacturing companies, medical equipment service and maintenance companies, pharmaceutical manufacturing companies, assistive technology and rehabilitation engineering manufacturing companies, research centres. Medical technology industry is one of the fast-growing sectors in engineering field. Join the next generation of biomedical engineers and technicians and embrace a well paid, intensive yet enjoyable career by embarking on this comprehensive and practical program. It provides a solid overview of the current state of biomedical engineering and is presented in a practical and useful manner - all theory covered is tied to a practical outcomes. Leading biomedical/electronic engineers with several years of experience in biomedical engineering present the program over the web using the latest distance learning techniques.

There is a great shortage of biomedical engineers and technicians in every part of the world due to retirement, restructuring and rapid growth in new industries and technologies. Many companies employ electrical, electronic engineers to fill the vacancy and provide on the job training to learn about biomedical engineering. The aim of this 18-month eLearning program is to provide you with core biomedical engineering skills to enhance your career prospects and to benefit your company/institution. Often universities and colleges do a brilliant job of teaching the theoretical topics, but fail to actively engage in the 'real world' application of the theory with biomedical engineering. This advanced diploma is presented by lecturers who are highly experienced engineers, having worked in the biomedical engineering industry. When doing any program today, a mix of both extensive experience and teaching prowess is essential. All our lecturers have been carefully selected and are seasoned professionals.

This practical program avoids weighty theory. This is rarely needed in the real world of industry where time is short and immediate results, based on hard-hitting and useful know-how, is a minimum requirement. The topics that will be covered are derived from the acclaimed IDC Technologies' programs attended by over 500,000 engineers and technicians throughout the world during the past 20 years. And, due to the global nature of biomedical engineering today, you will be exposed to international standards.

This program is not intended as a substitute for a 4 or 5 year engineering degree, nor is it aimed at an accomplished and experienced professional biomedical engineer who is working at the leading edge of technology in these varied fields. It is, however, intended to be the distillation of the key skills and know how in practical, state-of-the-art biomedical engineering. It should also be noted that learning is not only about attending programs, but also involves practical hands-on work with your peers, mentors, suppliers and clients.

WHO WOULD BENEFIT

- Electrical and Electronic Engineers
- Electrical and Electronic Technicians
- Biomedical Equipment/Engineering Technician
- Field Technicians
- Healthcare equipment service technicians
- Project Engineers and Managers
- Design Engineers
- Instrumentation Engineers
- Control Engineers
- Maintenance Engineers and Supervisors
- Consulting Engineers
- Production Managers
- Mechanical Engineers
- Medical Sales Engineers

In fact, anyone who wants to gain solid knowledge of the key elements of biomedical engineering in order to improve work skills and to create further job prospects. Even individuals who are working in the healthcare industry may find it useful to attend to gain key, up to date perspectives.

COURSE STRUCTURE

The program is composed of 18 modules. These cover the basics of electrical, electronic and software knowledge and skills to provide you with maximum practical coverage in the biomedical engineering field.

The 18 modules will be completed in the following order:

- Basic Electrical Engineering
- Technical and Specification Writing
- Fundamentals of Professional Engineering
- Engineering Drawings
- Printed Circuit Board Design
- Anatomy and Physiology for Engineering
- Power Electronics and Power Supplies
- Shielding, EMC/EMI, Noise Reduction and Grounding/Earthing
- Troubleshooting Electronic Components and Circuits
- Biomedical Instrumentation
- Biomedical Signal Processing
- C++ Programming
- Embedded Microcontrollers
- Biomedical Modelling and Simulation
- Biomedical Equipment and Engineering Practices
- Biomedical Image Processing
- Biomechanics and Assistive Technology
- Medical Informatics and Telemedicine

COURSE FEES

What are the fees for my country?

The Engineering Institute of Technology (EIT) provides distance education to students located almost anywhere in the world – it is one of the very few truly global training institutes. Course fees are paid in a currency that is determined by the student’s location. A full list of fees in a currency appropriate for every country would be complex to navigate and, with today’s exchange rate fluctuations, difficult to maintain. Instead we aim to give you a rapid response regarding fees that is customised to your individual circumstances.

We understand that cost is a major consideration before a student commences study. For a rapid reply to your enquiry regarding courses fees and payment options, please enquire via the below button and we will respond within 2 business days.

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

Why this programme

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

Programme structure

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

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

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

Projects

◾To complete the MSc degree you must undertake a project worth 60 credits.
◾The project will integrate subject knowledge and skills that you acquire during the MSc programme.
◾The project is an important part of your MSc where you can apply your newly learned skills and show to future employers that you have been working on cutting edge projects relevant to the industry.
◾You can choose a topic from a list of MSc projects in Biomedical Engineering. Alternatively, should you have your own idea for a project, department members are always open to discussion of topics.

Example projects
Examples of projects can be found online

*Posters shown are for illustrative purposes

[[Accreditation ]]
The MSc Biomedical Engineering is accredited in the “Further Learning” category accredited by the Institution of Engineering and Technology (IET) and the Institute of Physics and Engineering in Medicine (IPEM).

This means that a student with an accredited BEng undergraduate degree can take the accredited "Further Learning" MSc to top-up their academic qualifications in order to meet the full academic requirements for conferral of the title of Chartered Engineer. This is an alternative route to the 5-year undergraduate MEng route.

Industry links and employability

◾The MSc in Biomedical Engineering has been developed for students with different backgrounds in engineering who wish to enter the field of Biomedical Engineering; and it is particularly suitable if you intend to work in Biomedical Engineering industries.
◾The School of Engineering has extensive contacts with industrial partners who contribute to several of their taught courses, through active teaching, curriculum development, and panel discussion.
◾During the programme students have an opportunity to develop and practice relevant professional and transferrable skills, and to meet and learn from employers about working in a wide range of industries.

Career prospects

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

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Engineers are the key to the development of society and solving the problems the world currently faces. They have the power to make the world fundamentally different. Read more
Engineers are the key to the development of society and solving the problems the world currently faces. They have the power to make the world fundamentally different.

The Master of Advanced Engineering is the key transitional stage in your career, transforming you into a global leader. Gain a depth of knowledge, mastering the crucial skills to become a leading contributor in your field.

Customise your degree - the Master of Advanced Engineering offers flexibility to complete your Master degree in just one year, or you can choose a two year option.

This course is designed to extend your knowledge in your chosen specialisation area and advance your leadership and complex problem-solving skills in a cross cultural environment.

Understand, reflect critically upon and apply methods in at least one specialist engineering area to design solutions to complex, multifaceted engineering problems.

Common core units will develop crucial skills in areas such as data analysis and entrepreneurship, translating theory into engineering practice. In discipline core units you will identify, interpret and critically appraise current developments and technologies within your specialisation.

Enhancement units are designed to provide breadth and are taken from either another engineering specialisation or in complementary areas such as information technology and business.

In addition, the two year version of the program offers a range of technical electives that will deepen your understanding of a specific topic, and two, year- long engineering project units. You will work closely with an academic on a topic of your choice and immerse yourself in a multidisciplinary design project.

The Master of Advanced Engineering could also be your stepping stone to a research degree. All of this in highly interactive, expert led classes.

Visit the website http://www.study.monash/courses/find-a-course/2016/advanced-engineering-e6001?domestic=true

Overview

Please select a specialisation for more details:

Chemical engineering

Your qualification will be a Master of Advanced Chemical Engineering

Please note that this specialisation is available only in Clayton.

The Master of Advanced Chemical Engineering allows you to engage in the areas of study including advanced reaction engineering, process design and optimization, conversion of bioresources into fuel, materials and specialty chemicals, and nanostructured membranes for sustainable separations and energy production with an emphasis on the latest developments in the field. In this course, you will develop specialised knowledge and skills that are important to Chemical Engineers in industry and research. This course provides graduates with enhanced opportunities for advancement in their careers.

Civil engineering (Infrastructure systems)

Your qualification will be a Master of Advanced Civil Engineering (Infrastructure Systems)

The Master of Advanced Civil Engineering (Infrastructure Systems) will equip graduates to work with in the area of infrastructure engineering and management. It will provide the fundamental knowledge associated with interfacing both structural and geotechnical designs for infrastructure systems. The program is designed to equip you with advanced skills necessary for managing the challenges posed by ageing and leading designs of new complex infrastructure systems. The course is suitable for new graduates, professionals and managers who are keen to upgrade their existing design and management skills, as well as to develop theoretical and applied knowledge in the area of infrastructure engineering and management.

Civil engineering (Transport)

Your qualification will be a Master of Advanced Civil Engineering (Transport)

Please note that this specialisation is available only in Clayton.

The Master of Advanced Civil Engineering (Transport) program deals with the fundamental knowledge associated with transport engineering and management, traffic engineering, intelligent transport systems and transport planning. The program in is a response to the growing need for engineers with broad awareness of the characteristics and significance of transport, including its technological, economic and social impact. At the same time, the program outlines the state-of-the-art of transport engineering, as it may be applied to the solution of real problems in the planning, design, management and operation of transport facilities. The course is suitable for new graduates, professionals and managers who are keen to upgrade their existing design and management skills as well as to develop theoretical and applied knowledge in the area of transport engineering and management.

Civil engineering (Water)

Your qualification will be a Master of Advanced Civil Engineering (Water)

Please note that this specialisation is available only in Clayton.

The Master of Advanced Civil Engineering (Water) allows you to major in water resources engineering and management. This program deals with the fundamental knowledge associated with surface and ground water flow, stormwater management, water quality, flood forecasting and mitigation. The program is designed to equip you with advanced skills necessary for managing the challenges posed by changing climatic condition on water resource management. The course is suitable for new graduates, professionals and managers who are keen to upgrade their existing design and management skills as well as to develop theoretical and applied knowledge in the area of water resources engineering and management.

Electrical engineering

Your qualification will be a Master of Advanced Electrical Engineering

Please note that this specialisation is available only in Clayton.

The Master of Advanced Electrical Engineering will give you a broad introduction to advanced techniques in signal processing, communications, digital systems and electronics. The units have been chosen around the common theme of embedded systems: special purpose computing systems designed for specific applications. They are found just about everywhere including in consumer electronics, transportation systems, medical equipment and sensor networks. The course will mix theory and practice and will contain a significant amount of hands-on learning in laboratories and team-based design projects.

Energy and sustainability engineering

Your qualification will be a Master of Advanced Engineering (Energy and Sustainability)

Please note that this specialisation is available only in Malaysia.

The Master of Advanced Engineering (Energy and Sustainability) is designed for qualified engineers keen to deepen their knowledge in the energy and sustainability area. The course provides foundations in general engineering through engineering analysis and entrepreneurship units. Students can major in this program by examining energy and sustainability area from a multi-disciplinary perspective. Students can also choose elective units such as environment and air pollution control and smart grids to further enhance their knowledge in this area or undertake a minor research work to pursue a topic of interest related to this area.

Materials engineering

Your qualification will be a Master of Advanced Materials Engineering

Please note that this specialisation is available only in Clayton.

The Master of Advanced Materials Engineering encompasses practical aspects of the key classes of materials such as metals, polymers, biomaterials, nanomaterials and energy-related materials. This program particularly focuses on the most up-to-date aspects of the field, along with the utilisation of materials and their electronic, chemical and mechanical properties as underpinned by the microstructures that are revealed by modern characterisation techniques. This program is designed to prepare students to appreciate and exploit the central role of materials in addressing the present technical, economic and environmental problems involved in the design and construction of engineering structures, processes and devices. This course is ideally suited for new graduates as well as professional engineers who are eager to advance their applied knowledge in the area of Materials Engineering.

Mechanical engineering

Your qualification will be a Master of Advanced Mechanical Engineering

Please note that this specialisation is available only in Clayton.

Most modern engineering projects are multidisciplinary in nature and require a broad range of skills, proficiencies and perspectives to accomplish the task. The Master of Advanced Mechanical Engineering takes a systems approach to the design, monitoring and performance of complex mechanical engineering systems in the fields of renewable energy, aerospace, buildings, transportation, and biomedical devices. The systems approach also permeates the design of the course: four discipline-based core units are vertically integrated so that common problems are examined from different perspectives, culminating in a sustainable systems unit.

For more information visit the faculty website - http://www.study.monash/media/links/faculty-websites/engineering

Find out how to apply here - http://www.study.monash/courses/find-a-course/2016/advanced-engineering-e6001?domestic=true#making-the-application

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The Engineering faculties of the Universiteit Gent and Vrije Universiteit Brussel organize the interuniversitary Master of Biomedical Engineering and this in a close collaboration with the Medical faculties of both universities. Read more

About the programme

The Engineering faculties of the Universiteit Gent and Vrije Universiteit Brussel organize the interuniversitary Master of Biomedical Engineering and this in a close collaboration with the Medical faculties of both universities. As a result of recent evolutions towards internationalization, we also offer a complete English master program in biomedical engineering. Both the Dutch and English masters are two-year programs and lead to a joint degree from UGent and VUB. Students study either in Ghent or in Brussels upon their own choice.

Tackle complex problems in biology, medicine and health sciences

Biomedical Engineering is a branch of Engineering where students acquire knowledge and skills which can be applied to tackle complex problems in biology, medicine and health sciences. The biomedical engineer herein strives towards a solution in balance with technological, economical and ethical constraints.

Learning outcomes

Graduated students master the fundamentals of current biomedical engineering and have a thorough knowledge of the basic concepts and an overview of the main applications in various fields of biomedical engineering (medical imaging, medical signal processing, medical physics, medical device technology, tissue engineering, biomaterials...). The graduated student has acquired the necessary research skills which allow him or her to independently analyze and solve a problem, and recognizes the importance of permanent learning in a continuously evolving domain.

Work in multidsciplinary teams:
The biomedical engineer is trained to work in multidisciplinary teams (influx of students with different bachelor backgrounds, lecturers from various faculties and scientific domains, multi-disciplinary projects) and has the required communication skills.

Awareness of ethical and socio-medical aspects:
The biomedical engineer is aware of the ethical and socio-economic aspects of biomedical engineering and healthcare, and of the social responsibility of a master in engineering.

Career possibilities:
In this master's course, knowledge and skills in all fields in biomedical engineering will be given, so when you finished the Master's programme, you can be employed as generalist, and you will also be specialised in one particular field of biomedical engineering.

As a student, you are able to select any field within biomedical engineering. You will be trained to work in interdisciplinary project teams, composed of engineers and medical specialists. To prepare further for interdisciplinary teams, students and scholars are treated as equals. To train for working in a European setting, you will get knowledge in the health care situation in several countries in Europe, and you will be trained in cultural differences between European countries.

In summary, the goal of this course is to acquire the ability to:
- work in interdisciplinary (engineering – medical) teams
- work in international and thus intercultural (European) teams
- communicate effectively with experts in (bio)medicine and technology
- perform fundamental research in Biomedical Engineering.
- design innovative devices to improve diagnostics and treatment of patients
- follow a post-Master’s training in Biomedical Engineering
- perform a PhD study
- train continuously (life-long-learning)

Curriculum

Available on http://www.vub.ac.be/en/study/biomedical-engineering/programme

The programme consists of 120 credits, evenly distributed over 4 semesters of each 12 weeks. The specific part of the master involves six basic courses for a total of 30 credits (Quantitative cell biology, Modelling of Physiological Systems, From Genome to Organism, Biomechanics, Bio-electronics and Biomaterials) and 42 credits dedicated to specialist courses in biomedical engineering (Biomedical Imaging, Neuromodulation and Imaging, Medical Physics, Medical Equipment, Biomedical Product Development, Artificial Organs: Technology and Design, Health Care Organization and Informatics, Human and Environment, Safety and Regulations* and Seminars: Innovations in Biomedical Engineering). The programme is further complemented with a master thesis (24 credits) and elective courses for a total of 24 credits.

Internships and Project Work

Students are encouraged to do an internship with a company or hospital in Belgium or abroad during the summer holiday period. Internships can be valorised in the curriculum, with an internship of 4 weeks accounting for an elective course of 3 credits, and an internship of minimally 6 weeks accounting for 6 credits. A maximum of 6 credits is allowed. In addition, students can opt for the elective 3 credit course “Multidisciplinary Biomedical Project” during which they can work on an assignment or a project.

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1. Big Challenges being addressed by this programme – motivation. Human health and quality of life is one of the most critical challenges facing humanity. Read more

About the Course

1. Big Challenges being addressed by this programme – motivation

• Human health and quality of life is one of the most critical challenges facing humanity.
• The challenge is all the greater due to a rapidly increasing and rapidly aging global population that now exceeds 7 billion.
• Biomedical Engineering addresses these issues directly, with engineers innovating, analysing, designing and manufacturing new medical implants, devices and therapies for the treatment of disease, injuries and conditions of the human body, to restore health and improve quality of life.
• CNN lists Biomedical Engineering as No. 1 in the “Best Jobs in America” 2013.

2. Programme objectives & purpose

The objective of the programme is to generate graduates with a sound grounding in engineering fundamentals (analysis, design and problem solving), but who also have the multi-disciplinary breadth that includes knowledge of human biology and clinical needs and applications, to be able to make an immediate impact in the field on graduation, in either the academic research or medical technology industry domains. Ultimately the programme aims to generate the future leaders of the national and international medical technology industry, and of academic research and teaching in biomedical engineering.

3. What’s special about CoEI/NUIG in this area:

• NUI Galway pioneered the development of educational programmes in Biomedical Engineering in Ireland, introducing the country’s first bachelor’s degree in Biomedical Engineering in 1998, that was the first to achieve professional accreditation from Engineers Ireland in 2004, and at the graduate level with the Structured PhD programme in Biomedical Engineering and Regenerative Medicine (BMERM) in 2011.
• NUI Galway has been at the forefront of world-class research in biomedical engineering for over 20 years and has pioneered multi-disciplinary research in biomedical engineering and science, with the establishment of the National Centre for Biomedical Engineering Science (NCBES) in 1999, and up to the present day with the announcement of NUI Galway as the lead institution in a new Science Foundation Ireland funded Centre for Research in Medical Devices (CÚRAM).
• NUI Galway has a very close and deep relationship with the medical device industry locally, nationally and internationally, at many levels, from industry visits, guest lectures and student placements, up to major research collaborations.
• Many of our engineering graduates now occupy senior management and technical positions in the medical device industry nationally and internationally.

4. Programme Structure – ECTS weights and split over semester; core/elective, etc.:

• 90ECTS programme
• one full year in duration, beginning September and finishing August
• comprises:
- Foundational taught modules (20 ECTS)
- Advanced taught modules (40 ECTS)
- Research/Industry Project (30 ECTS).

5. Programme Content – module names

Sample Modules:

Advanced Finite Element Methods
Advanced Computational Biomechanics
Advanced Biomaterials
Mechanobiology
Bioinstrumentation Design
Medical and Surgical Practice
Stem Cells and Gene Therapy
Translational Medicine
Polymer Engineering
Advanced Engineering Statistics
Systems Reliability
Lean Systems
Research Methods for Engineers
Financial Management
Regulatory Affairs and Case Studies
Technology, Innovation and Entrepreneurship

6. Any special funding arrangements – e.g. Irish Aid

Comment (PMcH): CoEI scholarships a great idea.

7. Opportunity for number of Industrial & Research internships.

Students enrolled on this programme will have an opportunity to apply for a one-year post-graduation internship in either a related industry or research group in Ireland.

8. Testimonials.

“The Biomedical Engineering programme at NUI Galway has given me the fundamental engineering skills and multi-disciplinary background in biology and clinical application that I needed to be able to make an immediate impact in industry and to be able to design and develop new medical implants and devices. My graduate education through my PhD in bone biomechanics was also very important in this because I directly combined engineering and biological analysis techniques to better understand how stem cells generate new bone, showing me how biomedical engineers can play a critically important role in generating new knowledge on how the body works, and how new treatments can be developed for diseases and injuries, such as osteoporosis.” Evelyn Birmingham, BE Biomedical Engineering (2009), PhD Biomedical Engineering (2014), R&D Engineer, Medtronic Vascular, Galway.

For further details

visit http://nuigalway.ie/engineering-informatics/internationalpostgraduatestudents/

How to Apply:

Applications are made online via the Postgraduate Applications Centre (PAC): https://www.pac.ie
Please use the following PAC application code for your programme:

M.Sc. Biomedical Engineering - PAC code GYE24

Scholarships :

Please visit our website for more information on scholarships: http://www.nuigalway.ie/engineering-informatics/internationalpostgraduatestudents/feesandscholarships/

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Make future breakthroughs within healthcare with the MSc Biomedical Engineering with Healthcare Technology Management course. This course is for inquisitive students who want to design, develop, apply or even manage the use of cutting-edge methods and devices that will revolutionise healthcare. Read more
Make future breakthroughs within healthcare with the MSc Biomedical Engineering with Healthcare Technology Management course.

Who is it for?

This course is for inquisitive students who want to design, develop, apply or even manage the use of cutting-edge methods and devices that will revolutionise healthcare. It is open to science and engineering graduates and those working within hospitals or related industry who want to work in healthcare organisations, in the medical devices industry, or in biomedical engineering research.

The course will suit recent graduates and/or clinical engineers with a technical background or those working in healthcare who want to move into a management position.

Objectives

With several medical conditions requiring extensive and continuous monitoring and early and accurate diagnosis becoming increasingly desirable, technology for biomedical applications is rapidly becoming one of the key ingredients of today and tomorrow’s medical care.

From miniaturised home diagnostic instruments to therapeutic devices and to large scale hospital imaging and monitoring systems, healthcare is becoming increasingly dependent on technology. This course meets the growing need for biomedical and clinical engineers across the world by focusing on the design of medical devices from conception to application.

One of the few accredited courses of its kind in London, the programme concentrates on the use of biomedical-driven engineering design and technology in healthcare settings so you can approach this multidisciplinary topic from the biological and medical perspective; the technological design and development perspective; and from the perspective of managing the organisation and maintenance of large scale equipment and IT systems in a hospital.

This MSc in Biomedical Engineering with Healthcare Technology Management course has been created in consultation and close collaboration with clinicians, biomedical engineering researchers and medical technology industrial partners. The programme fosters close links with the NHS and internationally-renowned hospitals including St. Bartholomew's (Barts) and the Royal London Hospital and Great Ormond street so that you can gain a comprehensive insight into the applied use and the management of medical technology and apply your knowledge in real-world clinical settings.

Placements

In the last few years there have been some limited opportunities for our top students to carry out their projects through placements within hospital-based healthcare technology groups or specialist London-based biomedical technology companies. Placement-based projects are also offered to selected students in City’s leading Research Centre for Biomedical Engineering (RCBE). As we continue our cutting-edge research and industrial and clinical collaborations, you will also have this opportunity.

Academic facilities

As a student on this course you will have the opportunity to work with cutting-edge test and measurement instrumentation – oscilloscopes, function generators, analysers – as well as specialist signal generators and analysers. The equipment is predominantly provided by the world-leading test and measurement equipment manufacturer Keysight, who have partnered with City to provide branding to our electronics laboratories. You also have access to brand new teaching labs and a dedicated postgraduate teaching lab. And as part of the University of London you can also become a member of Senate House Library for free with your student ID card.

Teaching and learning

You will be taught through face-to-face lectures in small groups, where there is a lot of interaction and feedback. Laboratory sessions run alongside the lectures, giving you the opportunity to develop your problem-solving and design skills. You also learn software skills in certain modules, which are taught inside computer labs. We also arrange hospital visits so you gain hands-on experience of different clinical environments.

We arrange tutorials for setting coursework, highlight important subject areas, conduct practical demonstrations, and offer support with revision. You are assessed by written examinations at the end of each term, and coursework assignments, which are set at various times throughout the term.

You also work towards an individual project, which is assessed in the form of a written thesis and an oral examination at the end of the summer. The project can be based on any area of biomedical engineering, telemedicine or technology management and will be supervised by an academic or clinical scientist with expertise in the subject area. Many projects are based in hospital clinical engineering departments, or if you are a part-time student, you can base the project on your own workplace. You will have regular contact with the supervisor to make sure the project progresses satisfactorily. Some of the programme’s current students are working on a project focusing on devices that use brain signals to move external objects such as a remote control car and a prosthetic arm.

Some of the previous projects students have worked on include:
-A cursor controller based on electrooculography (EOG)
-Modelling a closed-loop automated anaesthesia system
-Design of a movement artefact-resistant wearable heart rate/activity monitor
-Review of progress towards a fully autonomous artificial mechanical heart
-Design of smartphone-based healthcare diagnostic devices and sensors.

If you successfully complete eight modules and the dissertation you will be awarded 180 credits and a Masters level qualification. Alternatively, if you do not complete the dissertation but have successfully completed eight modules, you will be awarded 120 credits and a postgraduate diploma. Completing four modules (60 credits) will lead to a postgraduate certificate.

Modules

Along with the 60 credit dissertation eight core modules cover diverse subject areas including biomedical electronics and instrumentation, technology infrastructure management, as well as the latest advances in medical imaging and patient monitoring.

The course includes a special module which gives you an introduction to anatomy, physiology and pathology designed for non-clinical science graduates.

The most innovative areas of biomedical and clinical engineering are covered and the content draws from our research expertise in biomedical sensors, bio-optics, medical imaging, signal processing and modelling. You will learn from academic lecturers as well as clinical scientists drawn from our collaborating institutions and departments, which include:
-Charing Cross Hospital, London
-The Royal London Hospital
-St Bartholomew's Hospital, London
-Basildon Hospital
-Department of Radiography, School of Community and Health Sciences, City, University of London

Modules
-Anatomy, Physiology and Pathology (15 credits)
-Physiological Measurement (15 credits)
-Biomedical Instrumentation (15 credits)
-Medical Electronics (15 credits)
-Cardiovascular Diagnostics and Therapy (15 credits)
-Medical Imaging Modalities (15 credits)
-Clinical Engineering Practice (15 credits)
-Healthcare Technology Management (15 credits)

Career prospects

This exciting MSc programme offers a well-rounded background and specialised knowledge for those seeking a professional career as biomedical engineers in medical technology companies or research groups but is also uniquely placed for offering skills to clinical engineers in the NHS and international healthcare organisations.

Alumnus Alex Serdaris is now working as field clinical engineer for E&E Medical and alumna Despoina Sklia is working as a technical support specialist at Royal Brompton & Harefield NHS Foundation Trust. Other Alumni are carrying out research in City’s Research Centre for Biomedical Engineering (RCBE).

Applicants may wish to apply for vacancies in the NHS, private sector or international healthcare organisations. Students are encouraged to become members of the Institute of Physics and Engineering in Medicine (IPEM) where they will be put in touch with the Clinical Engineering community and any opportunities that arise around the UK during their studies. Application to the Clinical Scientist training programme is encouraged and fully supported.

The Careers, Student Development & Outreach team provides a professional, high quality careers and information service for students and recent graduates of City, University of London, in collaboration with employers and other institutional academic and service departments. The course also prepares graduates who plan to work in biomedical engineering research and work within an academic setting.

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The two MSc programmes in Biomedical Engineering draw on the wide experience of academic staff at Brunel's College of Engineering, Design and Physical Sciences, that ranges from the development of equipment and experiments for use in space, to research carried out in collaboration with hospitals, biomedical companies and research institutions. Read more

About the course

The two MSc programmes in Biomedical Engineering draw on the wide experience of academic staff at Brunel's College of Engineering, Design and Physical Sciences, that ranges from the development of equipment and experiments for use in space, to research carried out in collaboration with hospitals, biomedical companies and research institutions.

The programmes consist of four compulsory taught modules and two optional streams. You can apply to one of the two named degree title awards:

Biomedical, Genetics and Tissue Engineering or
Biomedical, Biomechanics and Bioelectronics Engineering

As well as giving a solid scientific understanding, the course also addresses commercial, ehtical, legal and regulatory requirements, aided by extensive research.

Students who successfully complete the course will have acquired skills that are essential to the modern biomedical and healthcare industry, together with the expertise required to enter into management, product innovation, development and research

Aims

Understanding how the human body works isn’t just required learning for sports coaches, specialists in biomedical engineering can help in the design, development and operation of complex medical devices. They are used in the prevention, diagnosis and treatment, to the characterisation of tissue.

This programme has a strong research and development emphasis. It aims to provide an overall knowledge base, skills and competencies, which are required in biomedical engineering, research activities and in related fields. Students will develop expertise in advanced product development and research.

Course Content

The MSc programmes in Biomedical Engineering are full-time courses, lasting one academic year of 12 consecutive months, from September to September.

The programmes consist of four core (compulsory) taught modules and two optional streams. The Biomedical, Genetics and Tissue Engineering stream has three optional modules. The second stream, Biomedical, Biomechanics and Bioelectrionics Engineering, consists of five optional modules. Students choosing this latter option will be requires to choose 60 credit worth of modules. See below.

The taught modules are delivered to students over two terms; Term 1 (September – December) and Term 2 (January – April) of each academic year. The taught modules are examined at the end of each term, and the students begin working on their dissertations on a part-time basis in term 2, then full-time during the months of May to September.

Compulsory Modules:

Compulsory Modules
Biomechanics and Biomaterials
Biomedical Engineering Principles
Design and Manufacture
Innovation and Management and Research Methods
Dissertation

Optional Modules:

Optional Modules
Applied Sensors Instrumentation and Control
Artificial Organs
Biofluid Mechanics
Biomedical Imaging
Design of Mechatronic Systems
Group Project

Special Features

Industry relevance
Scientific understanding is just one part of medical engineering – and the course addresses commercial, ethical, legal and regulatory requirements, with input from Brunel’s extensive industrial contacts.

Excellent facilities
We have extensive and well-equipped laboratories – with notable strength in fluid and biofluid mechanics, IC engines, vibrations, building service engineering, and structural testing. Our computing facilities are diverse and are readily available to all students. The University is fully networked with both Sun workstations and PCs. Advanced software is available for finite and boundary element modelling of structures, finite volume modelling of flows, and for the simulation of varied control systems, flow machines, combustion
engines, suspensions, built environment, and other systems of interest to the research groups.

Foundation course at Brunel
The Pre-Masters is a full-time 14-week course for international students who have marginally fallen below the postgraduate direct entry level and would like to progress onto a Master's degree course in the College of Engineering, Design and Physical Sciences. It combines academic study, intensive English language preparation, study skills and an orientation programme.

Women in Engineering and Computing Programme

Brunel’s Women in Engineering and Computing mentoring scheme provides our female students with invaluable help and support from their industry mentors.

Accreditation

This programme is seeking accreditation by the Institution of Mechanical Engineers (IMechE) post the recent change in available degree routes. The IMechE formerly accredited the MSc Biomedical Engineering and we anticipate no problems in extending this accreditation to the new routes.

Teaching

The taught modules are delivered to students over two terms; Term 1 (September – December) and Term 2 (January – April) of each academic year. The taught modules are examined at the end of each term, and the students begin working on their dissertations on a part-time basis in term 2, then full-time during the months of May to September.

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Take advantage of one of our 100 Master’s Scholarships to study Chemical Engineering at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study Chemical Engineering at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

Key Features of MSc in Chemical Engineering

The MSc Chemical Engineering course is built upon the wide range of research in chemical engineering at Swansea University. This includes engineering applications of nanotechnology, bioengineering, biomedical engineering, cell and tissue engineering, chemical engineering, colloid science and engineering, desalination, pharmaceutical engineering, polymer engineering, rheology, separation processes, transport processes, and water and wastewater engineering.

The MSc Chemical Engineering research project provides an opportunity to work with a member of academic staff in one of the above, or related, area of research. The project may also involve collaboration with industry.

The taught component of the MSc Chemical Engineering course covers specific areas of advanced chemical engineering as well as the complex regulations that are found in the engineering workplace. It also provides an opportunity for the development of personal and transferable skills such as project planning, communication skills, and entrepreneurship.

As a student on the Master's course in Chemical Engineering, you will advance your technical knowledge, which can lead to further research or a career in chemical engineering.

Modules

Modules on the MSc Chemical Engineering course typically include:

Complex Fluids and Rheology
Entrepreneurship for Engineers
Colloid and Interface Science
Communication Skills for Research Engineers
Water and Wastewater Engineering
Membrane Technology
Environmental Analysis and Legislation
Optimisation
Desalination
Polymers: Properties and Design
Principles of Nanomedicine
Nanoscale Structures and Devices
Pollutant Transport by Groundwater Flows
MSc Research Practice
MSc Dissertation - Chemical Engineering

Accreditation

The MSc Chemical Engineering at Swansea University is accredited by the Institution of Chemical Engineers (IChemE).

The MSc Chemical Engineering degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng(Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree.

Accreditation is a mark of assurance that the degree meets the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC). An accredited degree will provide you with some or all of the underpinning knowledge, understanding and skills for eventual registration as an Incorporated (IEng) or Chartered Engineer (CEng). Some employers recruit preferentially from accredited degrees, and an accredited degree is likely to be recognised by other countries that are signatories to international accords.

Links with Industry

One of the major strengths of Chemical Engineering at Swansea University is the close and extensive involvement with local, national and international engineering companies. The companies include:

Acordis
Astra Zeneca
Avecia
BP Chemicals
Bulmers
Dow Corning
GlaxoSmithKline
Nestle
Murco
Phillips 66
Unilever
Valero

Swansea staff have research links with local, national, and international companies. An industrial advisory board, consisting of eight industrialists from a range of chemical engineering backgrounds, ensure our courses maintain their industrial relevance.

Facilities

Our new home at the innovative Bay Campus provides some of the best university facilities in the UK, in an outstanding location.

Careers

The demand for Chemical Engineering graduates remains excellent with the highest starting salaries out of all engineering disciplines.

Chemical engineers find employment in a variety of public and private sector industries, applying the principles of chemical engineering to health, energy, food, the environment, medicine, petrochemicals and pharmaceuticals.

Research

The Research Excellence Framework (REF) 2014 ranks Engineering at Swansea as 10th in the UK for the combined score in research quality across the Engineering disciplines.

The REF assesses the quality of research in the UK Higher Education sector, assuring us of the standards we strive for.

World-Leading Research

The REF shows that 94% of research produced by our academic staff is of World-Leading (4*) or Internationally Excellent (3*) quality. This has increased from 73% in the 2008 RAE.

Research pioneered at the College of Engineering harnesses the expertise of academic staff within the department. This ground-breaking multidisciplinary research informs our world-class teaching with several of our staff leaders in their fields.

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The two MSc programmes in Biomedical Engineering draw on the wide experience of Brunel's academic staff, which ranges from the development of equipment and experiments for use in space, to research carried out in collaboration with hospitals, biomedical companies and research institutions. Read more

About the course

The two MSc programmes in Biomedical Engineering draw on the wide experience of Brunel's academic staff, which ranges from the development of equipment and experiments for use in space, to research carried out in collaboration with hospitals, biomedical companies and research institutions.

Four (compulsory) taught modules and two optional streams are available. Students can apply to one of the two named degree title awards - 'Biomedical, Genetics and Tissue Engineering' or 'Biomedical, Biomechanics and Bioelectronics Engineering'.

The programme has a strong research and development emphasis and students will develop expertise in advanced product development and research. It aims to provide an overall knowledge base, skills and competencies, which are required in biomedical engineering, research activities and in related fields.

Aims

The modern healthcare industry is commercially-driven and fast moving – putting a premium on recruits who bring strong research experience. Biomedical engineering is a new and rapidly emerging field of engineering to biological and clinical problems. It relies on the methodologies and techniques developed in more traditional engineering fields, further advanced and adapted to the particular complexity associated with biological systems.

These applications vary from design, development and operation of complex medical devices, used in the prevention, diagnosis and treatment, to the characterisation of tissue behaviour in health and disease, and theoretical models that enhance the understanding of complex biomedical issues.

As well as giving a solid scientific understanding, this course provides students with an understanding of the commercial, ethical, legal and regulatory requirements of the industry.

Graduates acquire the skills that are essential to the modern biomedical and healthcare industry, gaining expertise in management, product innovation, development and research.

Our students benefit from the University’s strong industrial partnerships and pioneering research activities.

Staff at Brunel generate numerous publications, conference presentations and patents, and have links with a wide range of institutions both within and outside the UK.

Course Content

The MSc programmes in Biomedical Engineering are full-time, one academic year (12 consecutive months).

Compulsory Modules:

Biomechanics and Biomaterials
Biomedical Engineering Principles
Design and Manufacture
Innovation and Management and Research Methods
Dissertation

Optional Modules:

Genomic Technologies
Molecular Mechanisms of Human Disease
Tissue Engineering

Special Features

Industry relevance
Scientific understanding is just one part of medical engineering and this course also addresses commercial, ethical, legal and regulatory requirements, with input from Brunel's extensive industrial contacts.

Excellent facilities
We have extensive and well-equipped laboratories - with notable strengths in fluid and biofluid mechanics, IC engines, vibrations, building service engineering, and structural testing. Our computing facilities are diverse and are readily available to all students. The University is fully networked with both Sun workstations and PCs. Advanced software is available for finite and boundary element modelling of structures, finite volume modelling of flows, and for the simulation of varied control systems, flow machines, combustion engines, suspensions, built environment, and other systems of interest to the research groups.

Foundation course available
The  Pre-Masters is a full-time 14-week course for international students who have marginally fallen below the postgraduate direct entry level and would like to progress onto a Master's degree course in the College of Engineering, Design and Physical Sciences. It combines academic study, intensive English Language preparation, study skills and an orientation programme.

Women in Engineering and Computing Programme

Brunel’s Women in Engineering and Computing mentoring scheme provides our female students with invaluable help and support from their industry mentors.

Accreditation

This programme is seeking accreditation by the Institution of Mechanical Engineers (IMechE) post the recent change in available degree routes. The IMechE formerly accredited the MSc Biomedical Engineering and we anticipate no problems in extending this accreditation to the new routes.

Teaching

The taught modules are delivered to students over two terms; Term 1 (September – December) and Term 2 (January – April) of each academic year. The taught modules are examined at the end of each term, and the students begin working on their dissertations on a part-time basis in term 2, then full-time during the months of May to September.

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

This MSc programmes in Biomedical Engineering is a 1 calendar year conversion programme that is part of a suite of programmes offered in Biomedical Engineering at Queen Mary University of London. This MSc conversion programme is aimed at students who already have an in depth knowledge of an area of Science (e.g. Maths, Physics, Biology or Chemistry), and who wish to convert to a career in Biomedical Engineering

This MSc programme aims to prepare specialists with advanced knowledge and transferable skills in the field of Biomedical Engineering, covering the following topics:

Fundamentals of human physiology;
Ethics and regulatory affairs in the biomedical field;
Advanced aspects of tissue engineering, regenerative medicine and biomaterials;
Advanced techniques to synthesize and/or characterise materials for biomedical engineering;
Mechanics of tissues, cells and sub-cellular components;
Biocompatibility of implantable materials and devices;
Materials and techniques for nanotechnology and nanomedicine.
The programme has strong roots within the well-recognised expertise of the academics that deliver the lectures, who have international standing in cutting-edge research on Biomedical Engineering and Materials. This fact ensures that the programme is delivered with the highest standards in the field. The students also benefit from access to state-of-the-art facilities and instrumentation in the areas of Biomedical Engineering and Materials, while undertaking research projects in brand-new large laboratories that are the result of a recent multi-million investment from QMUL.

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

* All new courses are required to undergo a two-stage internal review and approval process before being advertised to students. Courses that are marked "subject to approval" have successfully completed the first stage of this process. Applications are welcome but we will not make formal offers for this course until it has passed this second (and final) stage.

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The programme provides the student with an Engineering education applied to medical and biological issues, through deep basic and specialist training in various biomedical topics. Read more

Mission and goals

The programme provides the student with an Engineering education applied to medical and biological issues, through deep basic and specialist training in various biomedical topics. The educational path is intended to train students for designing equipment, devices, materials and procedures and for a correct introduction, development and management of biomedical technologies inside Companies and Health Structures, as well as freelance. The peculiar multidisciplinary structure of the programme allows developing a strong knowledge in electronics and informatics, mechanical, chemical and material engineering and promotes the integration of technical studies with life science disciplines (biology, physiology and medicine).

See the website http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/biomedical-engineering/

Career opportunities

Graduated biomedical engineers find employment for the design, development and commercialization of biomedical devices, as well as in the pharmaceutical sector. Career opportunities are found: 1) in manufacturing companies which are active on health-care market with systems for prevention, diagnostics, therapy and rehabilitation; 2) in public and private hospitals for the management of health technologies; 3) in medical plant and equipment service companies; 4) in specialised biomedical laboratories; 5) in biomedical research 6) as freelance.
For a more specific training in scientific research in the area, a Ph.D. in Bioengineering is available.

The programme has 4 advised paths (besides the possibility to develop a personal path with some constraints):
- Clinical Engineering
- Electronic Technologies
- Biomechanics and Biomaterials
- Cell, Tissue and Biotechnology Engineering

Presentation

See http://www.polinternational.polimi.it/uploads/media/Biomedical_Engineering_01.pdf
This postgraduate programme provides students with an engineering education applied to medical and biological issues. The educational path is intended to train students in the design of biomedical equipment, devices, materials and procedures and to offer a correct introduction to the management of biomedical technologies in companies and health bodies. The peculiar multidisciplinary structure of the programme allows the development of a strong knowledge in electronics and informatics, in mechanical, chemical and material engineering and promotes the integration of technical studies with life science disciplines like biology, physiology and
medicine. The programme is taught in English.

Subjects

Four specializations available:
- Clinical Engineering
- Electronic Technologies
- Biomechanics and Biomaterials
- Cell, Tissue and Biotechnology Engineering

Mandatory courses for all areas:
- mathematical and digital methods for engineering
- bioengineering of the motor system
- mechanics of biological structures
- bioengineering of autonomic control and respiratory systems
- biofluid dynamics
- biomechanical design
- biomachines (with laboratory)
- biomaterials
- endoprostheses
- biomimetics and tissue engineering
- biotechnological applications and bioreactors
- design of life support systems
- laboratory of tissue characterization
- laboratory of biomaterials + lab. of instrumental analysis
- laboratory of biofluid dynamics
- laboratory of biomechanical design
- computational biomechanics laboratory

See the website http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/biomedical-engineering/

For contact information see here http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/biomedical-engineering/

Find out how to apply here http://www.polinternational.polimi.it/how-to-apply/

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The programme is a full-time taught postgraduate degree course leading to the degree of MSc in Biomedical Engineering. Read more
The programme is a full-time taught postgraduate degree course leading to the degree of MSc in Biomedical Engineering. It has an international dimension, providing an important opportunity for postgraduate engineers to study the principles and state-of-the-art technologies in biomedical engineering with a particular emphasis on applications in advanced instrumentation for medicine and surgery.

Why study Biomedical Engineering at Dundee?

Biomedical engineers apply engineering principles and design methods to improve our understanding of living systems and to create new techniques and instruments in medicine and surgery.

The taught modules in this course expose students to the leading edge of modern medical and surgical technologies. The course also provides 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.

UK qualifications are recognised and respected throughout the world. 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'.

Links with Universities in China:

This course can be taken in association with partner universities in China with part of the course taken at the home institution before coming to Dundee to complete your studies. For students from elsewhere it is possible to take the entire course at Dundee.

What's so good about Biomedical Engineering at Dundee?

The University of Dundee has had an active research programme in biomedical engineering for over 20 years.

The Biomedical 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.

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.

This course has two start dates - September or January, 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 biomedical 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 towards at the beginning of second semester of the course.

What you will study

The course is divided into two parts:

Part I (60 Credits):

Bioinstrumentation (10 Credits)
Biomechanical Systems (20 Credits)
Biomaterials (20 credits)
Introduction to Medical Sciences (10 Credits)
Part II (120 Credits) has one taught module and a research project module. It starts at the beginning of the University of Dundee's Semester 2, which is in mid-January:

The taught module, Advanced Medical and Surgical Instrumentation (30 Credits), exposes students to the leading edge of modern medical and surgical technologies. It will also give concepts and understanding of the role of entrepreneurship, business development and intellectual property exploitation in the biomedical industry, with case examples.
The research project (90 Credits) will allow students to work in a research area of their own particular interest and to learn skills in presentation, critical thinking and problem-solving. Project topics will be offered to students before Part II of the course. We shall do our best to provide all students with a project of their choice.
The time spent in Dundee will also give students a valuable educational and cultural experience.

How you will be assessed

The course is assessed by coursework and examination, plus dissertation.

Careers

An MSc degree in Biomedical Engineering will prepare you for a challenging and rewarding career in one of many sectors: the rapidly growing medical technology industry, academic institutions, hospitals and government departments.

A wide range of employment possibilities exist including engineer, professor, research scientist, teacher, manager, salesperson or CEO.

The programme also provides the ideal academic grounding to undertake a PhD degree leading to a career in academic research.

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Biomedical engineers work at the interface of engineering, biology, and medicine, combining their engineering expertise with an understanding of human biology and medical needs to make the world a healthier place. Read more

Summary

Biomedical engineers work at the interface of engineering, biology, and medicine, combining their engineering expertise with an understanding of human biology and medical needs to make the world a healthier place. This masters course will equip students with the specialist knowledge, expertise and skills to integrate biology and medicine with engineering to solve problems related to living systems.

The MSc Biomedical Engineering is designed for engineering, and physical science graduates who want to specialise in this vibrant area of engineering. There is high demand for biomedical engineers, and this masters has been developed with our graduates’ employability in mind.

During this course, students will learn the fundamental scientific and technical aspects of biomedical engineering, alongside developing your knowledge of the relevant aspects of human biology in health and disease. This interdisciplinary course draws on expertise from leading departments within the University of Southampton, brought together through the Institute for Life Sciences; Engineering and the Environment, Medicine, Health Sciences, Natural and Environmental Sciences, and Electronics and Computer Science.

Modules

Compulsory modules: Human Biology and Systems Physiology, Introduction to Biomedical Engineering, Translational Medicine, MSc Research Project.
Optional modules: a wide variety of optional modules are available. If you choose to, you will be able to specialise in your chosen area of biomedical engineering through themed areas of application: musculoskeletal, cardiovascular, imaging, diagnostic systems and audiology.

Visit our website for further information...



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

This MSc programme covers the following topics:

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

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

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

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

Read less
Running continuously for over 50 years, our Masters in Biomedical Engineering is one of the longest-established in the world, giving a breadth of expertise with a focus on solving real-world, biomedical problems. Read more
Running continuously for over 50 years, our Masters in Biomedical Engineering is one of the longest-established in the world, giving a breadth of expertise with a focus on solving real-world, biomedical problems.

You’ll benefit from access to world-leading experts and teaching in state-of-the-art facilities, such as the new £12m “Engineering for Health” facility.

PROGRAMME OVERVIEW

In the first semester of the programme, graduates from a range of backgrounds are brought up-to-speed on core knowledge in engineering, biology and research practice.

This is followed by specialist modules in the second semester on human movement analysis, prostheses, implants, physiological measurements and rehabilitation, as well as numerous computer methods applied across the discipline.

The course makes use of different approaches to teaching, including traditional lectures and tutorials, off-site visits to museums and hospitals, and lab work (particularly in the Human Movement and Instrumentation modules).

The core lecturing team is supplemented by leading figures from hospitals and industry.

PROGRAMME STRUCTURE

This programme is studied full-time over one academic year and part-time over two academic years. It consists of eight taught modules and a research project.

All modules are taught on the University main campus, with the exception of visits to the health care industry (e.g. commercial companies and NHS hospitals). The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.
-Human Biology Compulsory
-Instrumentation Compulsory
-Biomechanics Compulsory
-Professional and Research Skills
-Computer Methods in Biomedical Research
-Medical Implants and Biomaterial Applications
-Human Movement and Rehabilitation
-Biomedical Sensors and Signals
-Research Project

EDUCATIONAL AIMS OF THE PROGRAMME

The course aims:
-To educate engineering, physical science, life science, medical and paramedical graduates in the broad base of knowledge required for a Biomedical Engineering career in industry, healthcare or research in the United Kingdom, Europe and the rest of the world
-To underpin the knowledge base with a wide range of practical sessions including laboratory/experimental work and applied visits to expert health care facilities and biomedical engineering industry
-To develop skills in critical review and evaluation of the current approaches in biomedical engineering
-To build on these through an MSc research project in which further experimental, analytical, computational, and/or design skills will be acquired

PROGRAMME LEARNING OUTCOMES

The programme provides opportunities for students to develop and demonstrate knowledge and understanding, skills, qualities and other attributes in the following areas:

Knowledge and understanding
-Demonstrate breadth and depth of awareness and understanding of issues at the forefront of Biomedical Engineering
-Demonstrate broad knowledge in Human Biology, Instrumentation, Biomechanics, and Professional and Research skills
-Demonstrate specialist knowledge in Implants, Motion analysis and rehabilitation, and Medical signals
-Understand how to apply engineering principles to conceptually challenging (bio)medical problems
-Appreciate the limitations in the current understanding of clinical problems and inherent in adopted solutions
-Understand routes/requirements for personal development in biomedical engineering including state registration
-Understand key elements of the concept of ethics and patient-professional relationships, recognise, analyse and respond to the complex ethical issues

Intellectual / cognitive skills
-Evaluate a wide range of applied engineering and clinical measurement and assessment tools
-Design and implement a personal research project; this includes an ability to accurately assess/report on own/others work with justification and relate them to existing knowledge structures and methodologies, showing insight and understanding of alternative points of view
-Carry out such research in a flexible, effective and productive manner, optimising use of available support, supervisory and equipment resources, demonstrating understanding of the complex underlying issues
-Apply appropriate theory and quantitative methods to analyse problems

Professional practical skills
-Make effective and accurate use of referencing across a range of different types of sources in line with standard conventions
-Use/ apply basic and applied instrumentation hardware and software
-Correctly use anthropometric measurement equipment and interpret results in the clinical context
-Use/apply fundamental statistical analysis tools
-Use advanced movement analysis hardware and software and interpret results in the clinical context
-Use advanced finite element packages and other engineering software for computer simulation
-Program in a high-level programming language and use built-in functions to tackle a range of problems
-Use further specialist skills (laboratory-experimental, analytical, and computational) developed through the personal research project

Key / transferable skills
-Identify, select, plan for, use and evaluate ICT applications and strategies to enhance the achievement of aims and desired outcomes
-Undertake independent review, and research and development projects
-Communicate effectively between engineering, scientific and clinical disciplines
-Prepare relevant, clear project reports and presentations, selecting and adapting the appropriate format and style to convey information, attitudes and ideas to an appropriate standard and in such a way as to enhance understanding and engagement by academic/ professional audiences

GLOBAL OPPORTUNITIES

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

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

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