• Xi’an Jiaotong-Liverpool University Featured Masters Courses
  • Regent’s University London Featured Masters Courses
  • Imperial College London Featured Masters Courses
  • Swansea University Featured Masters Courses
  • University of Edinburgh Featured Masters Courses
  • University of York Featured Masters Courses
  • Leeds Beckett University Featured Masters Courses
De Montfort University Featured Masters Courses
Institute for Advanced Architecture of Catalonia Featured Masters Courses
Cardiff University Featured Masters Courses
University of Leeds Featured Masters Courses
University of Birmingham Featured Masters Courses
"stem" AND "cells" AND "r…×
0 miles

Masters Degrees (Stem Cells And Regeneration)

  • "stem" AND "cells" AND "regeneration" ×
  • clear all
Showing 1 to 15 of 15
Order by 
This innovative distance-learning programme is taught online and will provide you with knowledge and understanding in the highly topical and exciting field of stem cell biology and regeneration. Read more
This innovative distance-learning programme is taught online and will provide you with knowledge and understanding in the highly topical and exciting field of stem cell biology and regeneration. You will be guided from the origins of this field through to its application (and potential applications) in treating human disease, covering the latest tools and technologies available for study in this area. Programme content is delivered by researchers active in the field, ensuring that the latest breakthroughs are communicated.

Using a creative distance-learning model, the programme delivers lectures, online discussions and assessments over the internet. This offers you more flexibility than traditional campus-based courses as you can study in your own environment. You will only be required to visit Bristol for your formal examinations at the end of the academic year. This distance-learning model, together with a part-time study option, makes the programme particularly appealing to those students who wish to combine full-time employment with study.

Programme structure

Core units
-Introduction to Stem Cells and Regeneration
-Neurodegeneration and Ophthalmic Disorders
-Molecular Tools in Stem Cells and Regeneration
-Peripheral Neuropathy and Spine
-Cell Signalling
-Biomaterials and their Use in the Skeletal System
-Stem Cells in Cardiac Systems
-Research Project/Dissertation

Careers

The programme can open up a number of different career opportunities. It can be used as a pathway to further studies (eg PhD) which in turn could lead to a research or academic career in the field. It can also open up opportunities in private industry, for example:
-Biotechnology sector research/sales
-Stem cell business development
-Stem cell banking
-Stem cell patents
-Stem cell clinical translation
-Charity research development
-Pharmaceutical industry
-Stem cell regulatory bodies

Read less
Academic, practical and research teaching covering all aspects of the latest developments in regenerative dentistry including dental stem cell culture, iPS and ES cells, tooth bioengineering, the role of stem cells in tooth repair and regeneration. Read more
Academic, practical and research teaching covering all aspects of the latest developments in regenerative dentistry including dental stem cell culture, iPS and ES cells, tooth bioengineering, the role of stem cells in tooth repair and regeneration. A major feature of the course is a research project carried out in one of our research labs and supported by practical demonstrations and evaluation of research publication.

Key benefits

• Training in research methodologies and the critical evaluation of data.
• Taught course on the very latest advances of stem cell research.
• World renowned department.
• Original research project.

Visit the website: http://www.kcl.ac.uk/study/postgraduate/taught-courses/regenerative-dentistry-msc.aspx

Course detail

- Description -

Taught course elements include: Introduction to stem cells, ES and iPS, Dental stem cells, Endogenous dentine repair, Endodontic applications of stem cells, Whole tooth regeneration, Scaffolds and bone regeneration, Salivary gland regeneration, Periodontal ligament restoration, GMP cell culture.

Research and practical elements include a research project, practical demonstrations of dental pulp stem cell culture combined with critical evaluation of research methods and approaches in dental stem cell biology.

Examples of research projects:

- Salivary gland stem cells
- Stem cells in the middle ear and their role in homeostasis and repair
- Development of replacement teeth: location of stem cell niches in a range of species
- A chemical genetics screen for regulators of cranial muscle stem cells
- Dental pulp stem cells in tooth repair
- Exploring the relationship between surface free energy and osseointegration with modifiable ceramic coatings
- Human Embryonic tooth mesenchymal cells and bio-tooth engineering
- Periodontal tissue regeneration - evaluating different human dental stem cell populations
- Neural crest stem cells and ossification of the mandible

- Course purpose -

Regenerative dentistry is for both dentists and biological scientists who desire to learn more about the latest advances in cell and molecule-based dentistry and also gain experience in carrying out laboratory-based, cutting-edge research in dental stem cell biology.

- Course format and assessment -

Written exam, practical tests and written reports, seminar presentation.

How to apply: http://www.kcl.ac.uk/study/postgraduate/apply/taught-courses.aspx

About Postgraduate Study at King’s College London:

To study for a postgraduate degree at King’s College London is to study at the city’s most central university and at one of the top 20 universities worldwide (2015/16 QS World Rankings). Graduates will benefit from close connections with the UK’s professional, political, legal, commercial, scientific and cultural life, while the excellent reputation of our MA and MRes programmes ensures our postgraduate alumni are highly sought after by some of the world’s most prestigious employers. We provide graduates with skills that are highly valued in business, government, academia and the professions.

Scholarships & Funding:

All current PGT offer-holders and new PGT applicants are welcome to apply for the scholarships. For more information and to learn how to apply visit: http://www.kcl.ac.uk/study/pg/funding/sources

Free language tuition with the Modern Language Centre:

If you are studying for any postgraduate taught degree at King’s you can take a module from a choice of over 25 languages without any additional cost. Visit: http://www.kcl.ac.uk/mlc

Read less
Dementia (including a raft of neurodegenerative diseases such as Alzheimer’s Disease) has recently become the leading cause of death in the UK. Read more
Dementia (including a raft of neurodegenerative diseases such as Alzheimer’s Disease) has recently become the leading cause of death in the UK. Stem cells are a novel and relatively young branch of scientific research that hold the potential for not only therapies but to be able to accurately model these distinctly human diseases.

This unique programme will offer students real-world perspectives from patients, carers, scientists and a range of health care professionals including world-leading experts on the impact of neurological diseases. The programme offers cutting edge translational neuroscience focused on stem cells, neurodegenerative diseases, regeneration and models (both animal and cell). Furthermore the inclusion of patients and importantly their carers and the real-life impacts of these diseases on individuals will be a common thread running throughout this programme making it truly unique and exceptionally novel.

This programme is designed for medical and/or scientific professionals and aims to introduce students to the fields of neurodegenerative diseases, stem cells, industry and emerging therapeutic opportunities in regenerative / translational neurology. Overall students will gain the knowledge and understanding of the clinical, real-life impact and scientific realities of these fields and thus advance their own learning and be able to carry this forward into their future careers.

Therefore students will be introduced to a range of topics as they progress through the programme from introducing the basic anatomy, structure and development of the central nervous system, a critical understanding of stem cells including sources, locations and roles, an introduction to multiple neurodegenerative diseases (such as Alzheimer’s, Motor Neurone Disease and Parkinson’s disease), from both clinical and patient angles, before being introduced to in vitro and in vivo modelling of these diseases, neuroimaging techniques, stem cells and industry.

Within the programme, students can progress from Postgraduate Certificate (60 credits), to Postgraduate Diploma (120credits) and to Master of Science degrees (180 credits) as they successfully complete the required number of credits for each level and can therefore stop at any stage or continue onwards depending on their situation.

Postgraduate Certificate

Composed of 4 core courses to provide the fundamental foundations for the Diploma and MSc but can also be taken as a self-contained PGCert. It will cover fundamental areas including key basic research skills (such as how to critically evaluate scientific manuscripts, as well as a basic understanding of statistics) whilst introducing students to the central nervous system, its basic anatomy and development and stem cells. In parallel students would cover an introduction to neurodegenerative diseases (that would include Alzheimer’s Disease, Parkinson’s Disease and Motor Neurone Disease) before being introduced to in vitro and in vivo modelling of these diseases. Finally students would also learn about neuroimaging and its potential roles for scientific research.

Postgraduate Diploma

Expands on the PGCert courses as well as introducing greater depth to novel areas such as the roles of pharma and industry with respect to stem cells. A proportion of the Diploma credits are elective and students will be assisted in choosing appropriate options from across the broad spectrum available from Edinburgh University that are relevant to their own situation, employment and career goals.

MSc

Students have the opportunity to explore a specialist area from within the broad spectrum of stem cells, regeneration and translational neuroscience in the form of either a dissertation, or, a structured project (the student would themselves have to source this if desired), which would aim to deliver a ‘real world’ project with a direct impact for an employer, organisation or personal goal. A third option available for students is a choice of 60 fully taught credits.

The minimum recommended time for completion of the full Masters programme is three years, and the maximum time for completion is six years. The Certificate and Diploma can be completed on a pro rata basis.

Postgraduate Professional Development (PPD)

Postgraduate Professional Development from The College of Medicine and Veterinary Medicine is aimed at working professionals who want to advance their knowledge through a postgraduate-level course, without the time- or financial-commitment of a full Masters, Diploma or Certificate.

We offer short, focussed credit-bearing courses which provide very specific training on particular subjects and can lead to a University of Edinburgh Postgraduate Award. The courses are offered through an interactive online distance learning medium enabling participants to study in their own time. You may take a maximum of 50 credits worth of courses through our Postgraduate Professional Development (PPD) scheme. These credits will be recognised in their own right as a postgraduate-level award, or may be put towards gaining a higher award, such as a Postgraduate Certificate, Postgraduate Diploma or MSc.

Online learning

This part-time, fully online programme will support the need for up-to-date knowledge, skills and theory in a wide variety by the use of not only world leading clinical and scientific experts but also by using the real-life impacts as viewed by patients, the people who care for them and the frontline health professionals. All of this expertise will be presented utilising a range of techniques including: online lectures, practical studies, directed readings and other video and audio resources.

Discussion boards will provide directed assessment tasks while input from expert guest lecturers and tutors offer students opportunity for collaborative critical discourse and debate of current issues.

Career opportunities

Potential career paths, exits routes and employers are very diverse and depend on the students chosen carer. For students working in a clinical environment this programme would offer them career advancement/specialism within their clinical setting.

For students coming from a scientific background there is the opportunity to improve carer prospects in laboratory research settings or alternatively to help in progressing to a PhD.

Read less
The MRes offers exciting opportunities to develop advanced scientific, research and transferable skills required to become an independent researcher. Read more

Course Description

The MRes offers exciting opportunities to develop advanced scientific, research and transferable skills required to become an independent researcher.

The MRes is organised by the Centre for Human Development, Stem Cells & Regeneration (CHDSCR) which undertakes fundamental research into early development and stem cells, together with applied translational research targeting the NHS and patient benefit.

Through research projects totalling 32 weeks, you will develop a broad range of laboratory skills and work in different research environments. You will be supervised by internationally recognised academic researchers. In addition to providing broader training in scientific research, the course will develop your transferable skills including time and project management, public speaking, critical appraisal and scientific writing, thus aiding employability for a variety of careers.

Key Information

The intake for this MRes is 15-20 students.

What does this MRes provide?

During the one year, full time programme that commences in September/October, MRes students undertake taught modules in Research Skills in Biomedical Sciences, Stem Cells, Development & Regenerative Medicine, and Advanced Scientific Skills. Students also undertake two research projects totalling 32 weeks, to develop a broad range of laboratory skills and gain experience of working in different research environments. Students are supervised by internationally recognised Academic researchers in the CHDSCR.

Why study this MRes at the University of Southampton?

The University of Southampton is consistently ranked in the top 10 national and the top 100 international Universities. We are a world leading research intensive university, with a strong emphasis on education and are renowned for our innovation and enterprise. The CHDSCR is a Centre for excellence and strategic importance. Students work within vibrant and thriving interdisciplinary research programmes that harness the translational strength of the University, together with an outstanding clinical infrastructure and enterprise to translate pioneering developmental and stem cell science for patient benefit.

Who should apply?

High-achieving Biological/Biomedical Science graduates interested in developing further laboratory based research skills and subject specific knowledge before committing to a PhD programme, or a career in academia, industry, government policy or science journalism.

How will this MRes enhance your career prospects?

In addition to providing broader training in the intellectual basis of scientific research in Stem Cells, Development and Regenerative Medicine, the course will develop your transferable skills including time and project management, public speaking, critical appraisal and scientific writing, thus aiding employability for a variety of careers.

What will you learn in the modules?

i) Stem Cells, Development & Regenerative Medicine module
Students are introduced to core concepts through a series of facilitator-led workshops focussing on key research publications. Students critically appraise primary research papers and develop the skills required to understand, critique and interpret research findings. Integral to these workshops is the requirement for students to present their thoughts and participate in group discussions with both their peers and academic facilitators.

ii) Research Skills in Biomedical Sciences (RSBS) module
A combination of taught and practical sessions are used to introduce students to the core concepts underlying statistical analysis and study design that support students in handling their own data and critically appraising data published by others.

iii) Advanced Scientific Skills module
A series of taught and practical sessions introduce students to additional core concepts used in Biomedical Sciences such as the analysis and critical appraisal of large data sets. In addition, key principles required to relay research to both a scientific and lay audience are introduced. Students write both a scientific and lay abstract for a published primary paper and give a research presentation suitable for a lay audience. Thus, students develop the skills required to communicate their research to both scientists and non-specialists.

iv) Research Project modules
In the two research projects, students are introduced to a range of laboratory skills gaining valuable practical experience of research methodology, experimental design, data interpretation, viva voce, scientific writing, oral and poster presentations.

What teaching and learning methods will be used?

A variety of methods are used including lectures, research seminars, small group discussions, journal club presentations, analysis of large data sets and in depth research projects which incorporate the evaluation and presentation of research findings within the field of stem cell biology. A range of summative and formative assessment methods are used to assess student performance. These include oral presentation, poster presentation, written assignments/critical review, viva voce, laboratory proficiency, analysis of large datasets, lay/scientific abstracts and preparation of a research proposal.

What are the entry requirements for this MRes?

The minimum classification normally expected for a degree entrant is at least a second class upper division (1st or 2:1) in Biological/Biomedical Sciences or a closely related subject from any approved University.

Qualifications from non-UK institutions must be of an equivalent standard to those of UK Universities. Before commencing the course, non-UK applicants should obtain an overall IELTS score of 7.0, with a minimum of 6.0 in each component.

What are the fees for this MRes?

Home/EU: £5,900 tuition fee + £5,100 bench fee

Overseas: £18,800 tuition fee + £5,100 bench fee

Scholarships

The University of Southampton offers a number of Scholarships. Please refer to: http://www.southampton.ac.uk/uni-life/fees-funding/international-fees-funding/funding-by-country.page

To Apply

Please click on the “Apply Now” button on our website
Please state Faculty of Medicine in the drop down menu as this Programme is delivered by the Faculty of Medicine. Or click on the link below

https://studentrecords.soton.ac.uk/BNNRPROD/bzsksrch.P_Login?pos=7009&majr=7009&term=201617#_ga=1.107238786.1658067525.1460548452

To register interest, or for further Programme information please contact:

Programme Leader: Dr Franchesca Houghton
Deputy Programme Leader: Dr Rahul Tare

Email:

For general enquiries please contact:

Email:

Read less
This programme aims to provide a high level of scientific knowledge and understanding of stem cell biology and regenerative medicine - from the molecular to the whole system level. Read more
This programme aims to provide a high level of scientific knowledge and understanding of stem cell biology and regenerative medicine - from the molecular to the whole system level.

Course Outline & Modules

This programme aims to provide a high level of scientific knowledge and understanding of stem cell biology and regenerative medicine - from the molecular to the whole system level. The programme aims to enable students to develop an informed and critical appreciation of recent scientific developments in these areas of modern biomedical sciences and its clinical and industrial application, as well as a practical skill set for further research and learning, e.g. PhD studies.

The opportunity to undertake a work experience placement will enable students to further their employability and transferable skills and develop links with participating clinical and industrial partners.

This course offers a flexible framework of core and optional modules. The core modules are:
-Advanced Laboratory Skills with data analysis and interpretation
-Understanding Professional Practice & Enhancing your Employability
-Mammalian Cell Biology and Culture
-Stem Cells and Tissue Engineering Technology
-Tissue Formation, Function and Repair
-Models of Regeneration I

Optional modules include, but are not limited to:
-Ageing and Regenerative Medicine
-Transplantation Biology
-Finance and Business Management

Note that not all options may be available in any one year and that options will not proceed if the minimum student intake number is not reached.

Learning, Teaching & Assessment

The programme is delivered using a combination of lectures, practical classes, tutorials and seminars. Some modules will include group work. The core employability module will use visiting lecturers from industry to illustrate the potential employment avenues for graduates of this course. The course includes a research project, this is likely to be a laboratory-based project where students will collect and analyse their own data. Assessment methods employed include examinations and continuous assessment through coursework; these will differ for individual modules.

Career Opportunities

Completion of this course prepares students for a research-focussed role in industry, including the developing clinical field of stem cell therapies of regenerative medicine, or academia. Graduates can therefore expect to enter further research, in the form of a PhD or research assistant, or may undertake a career in the commercial or clinical sector.

Personal Development

Completion of this course prepares students for a research-focussed role in industry, including the developing clinical field of stem cell therapies of regenerative medicine, or academia. Graduates can therefore expect to enter further research, in the form of a PhD or research assistant, or may undertake a career in the commercial or clinical sector.

Read less
Regenerative Medicine is a vibrant area of endeavour involving multidisciplinary interactions and strong employment opportunities for those trained in the field. Read more

The Exciting Area of Regenerative Medicine

Regenerative Medicine is a vibrant area of endeavour involving multidisciplinary interactions and strong employment opportunities for those trained in the field. It encompasses many areas of life science and medicine, including a range of pharmaceutical-related approaches, as well as the use of cell-based therapies, to include also various types of stem-cells, bioactive scaffolds and drug delivery modalities. Whilst gaining a growing interest from the commercial sector and from the healthcare systems world-wide, Regenerative Medicine is still a rich area for fundamental, question-driven research. This 21st Century Medicine holds the promise of contributing to the development of alternatives to long-term, high-cost care approaches for many degenerative and age-related diseases. Nevertheless, it investigates the complexity of stem cell characteristics and properties, regeneration mechanisms and in vivo integration of in vitro-regenerated tissues

About the Course

The MSc Regenerative Medicine (taught masters) will provide students with a multidisciplinary approach to gaining a critical knowledge and training in the biological and chemical basis of tissue regeneration, stem cell biology; as well as knowledge of the basics of intellectual property law, regulatory affairs, ethical issues, all of which are key components of the global regenerative medicine industry. It is a vibrant area of endeavour involving multidisciplinary interactions and strong employment opportunities for those trained in the field.

The MSc Regenerative Medicine (taught masters) will provide you with a multidisciplinary approach to gaining a critical knowledge and training in the biological and chemical basis of tissue regeneration, stem cell biology; as well as knowledge of the basics of intellectual property law, regulatory affairs, ethical issues, all of which are key components of the Regenerative Medicine sector.
Ultimately, the course aims to produce postgraduates capable of making a significant contribution within the Regenerative Medicine area at large. Master Graduates will be well placed to secure jobs in academic research, however the transferable skills developed during the course will equip you for a wide range of careers outside the laboratory, for example within biotechnology business, legal sciences, and science communication. Additionally, the course prepares students for higher levels of study, for example at PhD level.

Module on this Course

The delivery of the course Comprises a mixture of structured taught modules, practical activities and self-directed study. Students are set regular tasks and formative assessments helping strengthening skills of communication, team working, and self-evaluation. The Master degree culminates with a research project dissertation providing you with the opportunity to fully engage with contemporary research in the field; numerous opportunities for conducting part or the entirety of this research project outside the University or abroad can be discussed as required.

These are the Modules on this Course:
• Cell Biology and Biotechnology
• Developmental Biology and regeneration
• Advanced Laboratory Skills
• Research Methods
• Stem Cell Biology
• Cell Therapy and Tissue Engineering
• Dissertation Project

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

Overview

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

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

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

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


Taught Modules (15 credits each)

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

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


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

Read less
This programme offers a fascinating range of subjects, including molecular biology, genetics, biochemistry, microbiology, immunology, tissue engineering, clinical medicine, laboratory management and statistics. Read more
This programme offers a fascinating range of subjects, including molecular biology, genetics, biochemistry, microbiology, immunology, tissue engineering, clinical medicine, laboratory management and statistics.

It is accredited by the Institute of Biomedical Science and is based at one of the largest transfusion centres in the world, enabling visits to manufacturing, testing and tissue typing sections. You will learn from specialist lecturers based at the University, NHS Blood and Transplant (NHSBT), and NHS hospitals, and have an opportunity to become fully embedded in an NHS environment while you develop your knowledge.

The programme will give you extensive practical experience of transfusion and transplantation, allowing you to gain skills that directly relate to your future career. As well as being academically interesting, this continually developing area of healthcare science has a major impact on patients' quality of life.

The programme:
-Is one of just two specialist full-time courses in transfusion and transplantation, and is a recommended course at level seven in the Career Framework for Health.
-Gives you the opportunity to carry out your MSc project with NHSBT research staff within the transfusion centre.
-Has high contact hours, with teaching each day and practical classes.
-Includes a large skills component (eg writing in different formats, conference and publication skills, assignments with specific study aims).
-Includes laboratory management, a key skill required at level seven.
-Attracts a diverse range of students (about 50 per cent overseas students), including new graduates, those working in blood centres or blood transfusion/haematology in hospitals, or training to lecture in transfusion.

Programme structure

The programme comprises eight taught units that run from September to March and a research project that begins in May and runs until August. Example project topics have included:
-A study on red cell antibody formation in trauma patients
-Optimisation of platelet antigen detection using recombinant proteins
-Expression of red cell membrane proteins during large-scale red cell culture
-A comparison of stem cell mobilisation drugs for stem cell transplantation

Taught units
-Transfusion and Transplantation Science:
-Pathology of Transfusion and Transplantation Science
-Provision of Blood, Cells, Tissues and Organs
-Clinical Transfusion and Transplantation
-Transfusion and Transplantation in Practice (two units)
-Biostatistics
-Research and Laboratory Management

Assessments are designed to teach skills such as comprehension, scientific writing in different formats and conference skills, and to further knowledge in subject areas not covered in the lectures. Students must pass the taught component to be able to progress to the project.

Part-time students complete the Postgraduate Certificate components in their first year and the Postgraduate Diploma in the second. The project is usually taken during year three to complete the MSc.

Careers

Some of the career paths that graduates have followed include: blood transfusion and fetal medicine research, working for a bone marrow donor laboratory or bone marrow registry, biostatistics, graduate entry to medical school, NHS Clinical Scientist Training programme, and progression to PhD study in several areas including cancer biology and stem cell regeneration.

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

Degree information

This programme will equip students with a critical understanding of:
-How nanotechnology can be harnessed for the improved detection and treatment of disease.
-The use of stem cells in medicine.
-Tissue engineering strategies for tissue regeneration.
-Improving biomaterials for directing cell behaviour.
-The regulatory, ethical and commercial hurdles for the translation of these emerging technologies.

Students undertake modules to the value of 180 credits.

The programme consists of five core modules (75 credits), one optional module (15 credits) and a research project (90 credits). A Postgraduate Certificate (60 credits) is offered. The programme consists of two core modules (30 credits) and two optional modules (30 credits).

Core modules
-Nanotechnology in Medicine *
-Applied Tissue Engineering *
-Biomaterials
-Research Methodologies
-Practical Bio-Nanotechnology and Regenerative Medicine
-*PG Cert - compulsory modules

Optional modules - choose one of the following options; attendance at the other module is possible but will not be assessed.
-Stem Cells in Medicine and their Applications in Surgery
-Translation of Nanotechnology and Regenerative Medicine

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

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

Careers

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

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

Recent career destinations include:
-PhD or Medicine at UCL, Imperial College London and Universities of Oxford and Cambridge
-Clinical PhD training programmes
-NHS hospitals in the UK
-EU and overseas hospitals and research facilities

Top career destinations for this degree:
-Health Careers Program, Harvard University
-PhD Medicine, Queen's University, Belfast
-PhD Bioengineering, Imperial College London
-PhD Nanomedicine, UCL
-DPhil Researcher (Biomedical Sciences), University of Oxford and studying MSc Nanotechnology and Regenerative Medicine, -University College London (UCL)

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

Why study this degree at UCL?

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

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

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

Read less
Developmental biology is aimed at understanding how a fertilised egg gives rise to a complex multicellular organism. Read more

Course Description

Developmental biology is aimed at understanding how a fertilised egg gives rise to a complex multicellular organism. The Developmental Biology MSc will give a thorough training in this subject area with opportunities to undertake research placements in the labs of leading researchers working on a range of model organisms and diverse areas of developmental biology. Some of the major areas of research undertaken at The University of Manchester are as follows:

Studies of gene expression and cell signalling in model organisms, such as Drosophila, Xenopus, and mouse are illuminating the mechanisms by which different cell types and tissues arise during development. Findings obtained from these studies serve as general principles relating to human development.

The ways in which misregulation of developmental mechanisms leads to human diseases, e.g. cancer, are being explored using various models.

The mechanisms regulating stem cell maintenance and differentiation are being investigated, in order to harness the therapeutic potential of stem cells.

The healing process is being studied to improve wound repair and in the longer term regeneration of organs.

This is a research focused Masters course. We do not teach Developmental Biology using a traditional lecture-based format; instead we use an interactive approach where you learn through seminars, workshops, small group tutorials and during your research placements.

Read less
As well as giving a solid scientific understanding, the course also addresses commercial, ethical, legal and regulatory requirements, aided by extensive industrial contacts. Read more
As well as giving a solid scientific understanding, the course also addresses commercial, ethical, legal and regulatory requirements, aided by extensive industrial contacts.

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.

Programme Structure

The MSc programmes in Biomedical Engineering are full-time, one academic year (12 consecutive months). The programmes consist of 4 core (compulsory) taught modules and two optional streams. Biomedical, Genetics and Tissue Engineering stream has 3 modules, all compulsory (see below). The second option, Biomedical, Biomechanics and Bioelectronics Engineering stream consists of 5 modules. Students choosing this option will be required to choose 60 credit worth of modules. See individual course pages.

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.

Core Modules
Biomechanics and Biomaterials (15 credit)
Design and Manufacture (15 credit)
Biomedical Engineering Principles (15 credit)
Innovation, Management and Research Methods (15 credit)

Additional Compulsory Programme Modules
Tissue Engineering and Regenerative Medicine (15 credit)
Genomic Technologies (15 credit)
Molecular Mechanisms of Human Disease (30 credit)
Dissertation (60 credit)

Module Descriptions

Biomechanics and Biomaterials

Main topics include: review of biomechanical principles; introduction to biomedical materials; stability of biomedical materials; biocompatibility; materials for adhesion and joining; applications of biomedical materials; implant design.

Biomedical Engineering Principles

Main topics include: bone structure and composition; the mechanical properties of bone, cartilage and tendon; the cardiovascular function and the cardiac cycle; body fluids and organs; organisation of the nervous system; sensory systems; biomechanical principles; biomedical materials; biofluid mechanics principles, the cardiovascular system, blood structure and composition, modelling of biofluid systems.

Design and Manufacture

Main topics include: design and materials optimisation; management and manufacturing strategies; improving clinical medical and industrial interaction; meeting product liability, ethical, legal and commercial needs.

Genomic Technologies

Main topics: General knowledge of genomic and proteomic technology; Microarrary technology; Transgenic technology. Drug discovery technology; Translational experiment-design and interpretation; Sequencing in microbiology research

Innovation and Management and Research Methods

Main topics include: company structure and organisation will be considered (with particular reference to the United Kingdom), together with the interfacing between hospital, clinical and healthcare sectors; review of existing practice: examination of existing equipment and devices; consideration of current procedures for integrating engineering expertise into the biomedical environment. Discussion of management techniques; design of biomedical equipment: statistical Procedures and Data Handling; matching of equipment to biomedical systems; quality assurance requirements in clinical technology; patient safety requirements and protection; sterilisation procedures and infection control; failure criteria and fail-safe design; maintainability and whole life provision; public and environmental considerations: environmental and hygenic topics in the provision of hospital services; legal and ethical requirements; product development: innovation in the company environment, innovation in the clinical environment; cash flow and capital provision; testing and validation; product development criteria and strategies.

Molecular Mechanisms of Human Disease

Main topics: The module will focus on the following subject material with emphasis on how these processes are altered in a variety of human diseases. Where appropriate, therapeutic intervention in these processes will be highlighted. Signalling pathways resulting from activation of membrane, intracellular or nuclear receptors will be discussed. Examples include: Mammalian iron, copper and zinc metabolism, G-Protein coupled receptor signalling, Wnt signalling, JAK/STAT signalling and cytokine signalling, Steroid signalling

Tissue Engineering and Regenerative Medicine

Main topics: Fundamentals of tissue structure, function and pathology. Tissue regeneration. Tissue engineering substitutes. Cells, cell culture, stem cells, cell and gene therapy. Extracellular matrix, structure, scaffolds. Cell signalling, growth factors, cytokines, neurotransmitters, receptors and other signalling molecules. Bioreactors, ex-vivo and in-vivo. Engineering host tissue responses.

Dissertation

The choice of Dissertation topic will be made by the student in consultation with academic staff and (where applicable) with the sponsoring company. The topic agreed is also subject to approval by the Module Co-ordinator. The primary requirement for the topic is that it must have sufficient scope to allow the student to demonstrate his or her ability to conduct a well-founded programme of investigation and research. It is not only the outcome that is important since the topic chosen must be such that the whole process of investigation can be clearly demonstrated throughout the project. In industrially sponsored projects the potential differences between industrial and academic expectations must be clearly understood.

Read less
Developmental biology is aimed at understanding how a fertilised egg gives rise to a complex multicellular organism. Read more
Developmental biology is aimed at understanding how a fertilised egg gives rise to a complex multicellular organism. The Developmental Biology MSc will give a thorough training in this subject area with opportunities to undertake research placements in the labs of leading researchers working on a range of model organisms and diverse areas of developmental biology. Some of the major areas of research undertaken at The University of Manchester are as follows:
-Studies of gene expression and cell signalling in model organisms, such as Drosophila, Xenopus, and mouse are illuminating the mechanisms by which different cell types and tissues arise during development. Findings obtained from these studies serve as general principles relating to human development.
-The ways in which misregulation of developmental mechanisms leads to human diseases, e.g. cancer, are being explored using various models.
-The mechanisms regulating stem cell maintenance and differentiation are being investigated, in order to harness the therapeutic potential of stem cells.
-The healing process is being studied to improve wound repair and in the longer term regeneration of organs.

This is a research focused master's course. We do not teach Developmental Biology using a traditional lecture-based format; instead we use an interactive approach where you learn through seminars, workshops, small group tutorials and during your research placements.

Teaching and learning

The programme comprises four compulsory components:
Research projects: Your two projects will provide experience in carrying through a substantive research project including the planning, execution and communication of original scientific research. They are assessed by written report.

Tutorials and Workshop Unit : Tutorials give you the opportunity to learn about research being carried out in the Faculty of Biology, Medicine and Health and thereby to acquire a broad knowledge of biological sciences.The Bioethics Workshop gives you experience of exploring and debating some of the ethical issues that surround current scientific research. Activities for the Tutorials and Bioethics unit include preparative directed reading, private study and preparation of oral presentations.This unit is assessed by members of staff for the tutorial session and staff assessment of oral presentation during the tutorial and written reports.

Science Communication Unit: This unit allows you to acquire the ability to listen to a presentation, understand the key concepts and record important details, and then summarise its contents in a brief written report. Activities include private study and preparation of written assignment. For each of 5 seminar presentations, a 500 word precis has to be written. You are assessed on these assignments plus a poster and an oral presentation.

Experimental Design and Statistics Unit: This unit aims to introduce you to the procedures and tools used in the design of experiments and the methods and tools used in statistical data analysis. Activities include lectures, workshops, group discussions and e-learning. Assessment is through multiple choice exam, critical assessment of literature and online statistics exercises.

Career opportunities

MSc graduates acquire a vast array of subject specific and transferable skills and gain extensive laboratory research experience. The University of Manchester has a strong record of placing students in PhD programmes at Manchester and other universities and several of our graduates have pursued research careers in industry.

Read less
The MSc by Research in Integrative Neuroscience is a one-year, full-time research programme covering all levels of modern neuroscience, which makes it an ideal programme to prepare you for a PhD. Read more

Research profile

The MSc by Research in Integrative Neuroscience is a one-year, full-time research programme covering all levels of modern neuroscience, which makes it an ideal programme to prepare you for a PhD.

We include molecular, cellular, systems, regenerative, cognitive, clinical and computational neuroscience. We also allow you to choose your specialty right from the start, allowing you to shape your learning around your interests and career goals.

Programme structure

You start with a taught component in the first 12 weeks, and attend ‘themed weeks’ which run in parallel with elective from which you choose your optional courses. The Elective optional courses include:

-Developmental Neurobiology
-Neural Circuits
-Neurodegeneration and Regeneration

The elective courses run during the first 12 weeks on two half days per week. These will give you a deeper insight into the concepts and methodology of a specific field of interest.

For your research you can choose available projects or contact principal investigators from more than 120 groups in the Edinburgh Neuroscience community to develop your own project, which can range from psychology to nanoscience. Examples of completed projects are:

- Axon Initial Segment plasticity in a mouse model of Fragile X Syndrome (Peter Kind)

- Cognitive and motor functions in neurodegenerative diseases (Thomas Bak)

- Interactions of amyloid beta and tau in causing cognitive decline in a novel Alzheimer’s disease model (Tara Spires-Jones)

- Role of primary cilia in the development of stem cells during development of the cerebral cortex (Thomas Theil)

Career opportunities

This programme is designed to help you in your research career. Over 90% of students on the MSc by Research in Integrative Neuroscience have positive next destinations, including PhD, research or clinical career paths.

Read less
Regenerative Medicine aims to generate therapeutics for repair and regeneration of damaged and diseased organs. These therapeutics are based on stem cells, gene therapy and engineered tissues. Read more
Regenerative Medicine aims to generate therapeutics for repair and regeneration of damaged and diseased organs. These therapeutics are based on stem cells, gene therapy and engineered tissues.
The M.Sc. in Regenerative Medicine at National University of Ireland in Galway, aims to provide students with the skills necessary for a career in this emerging discipline or within other areas of biomedical research. Taught modules will address the science behind regenerative medicine, its application to human disease and its importance to modern society. Students will then undertake a laboratory-based individual research project for four-5 months.
For more information see http://www.nuigalway.ie/courses/taught-postgraduate-courses/regenerative-medicine.html and http://www.remedi.ie/education/taught-msc-regenerative-medicine-0

Read less
Taught at our Parkgate Road Campus in Chester, this course is designed to give a comprehensive training in the research and analytical skills in cell and molecular biology. Read more
Taught at our Parkgate Road Campus in Chester, this course is designed to give a comprehensive training in the research and analytical skills in cell and molecular biology.

This MRes has been designed to enhance knowledge of recent advancements in cellular and molecular biology, as well as to develop subject-specific practical and analytical skills. In addition, you will gain experience of undertaking an extended period of research (6-7 months), which will aid your career progression as a molecular bio-scientist.

The programme will involve undertaking two core 20 credit taught modules, followed by an extended period of laboratory research, and submission of a Research report and review, 140 credits.

Why Study Cell and Molecular Biology Pathway with us?

Our lecturers range from enthusiastic early career academics through to internationally acknowledged senior researchers. We are actively involved in undertaking innovative research projects using ‘cutting-edge’ approaches, within the field of molecular and cellular life sciences.

Some of our current projects are listed below:
- Environmental toxicology
- Protection against the ageing
- Calcium signalling
- Biochemistry & pharmacology of intracellular Ca2+ transporters
- Stem cells
- Tissue regeneration
- Pathology of bone disease
- Progression of kidney and bladder cancers
- Novel drug delivery systems via nanoparticles and cell penetrating peptides
- Molecular basis of cancer development
- Novel approaches to cancer therapies
- Molecular immunology
- Development of analytical approaches to detect biomarkers of disease

What will I learn?

The MRes will involve undertaking two core 20 credit taught modules which consists of a mixture of lectures, workshops and practical classes in:
- Advances in Cell and Molecular Biology (BI7144)
- Skills for Molecular and Cellular Bioscientists (BI7145)

Followed by an extended period of laboratory research (140 credits) in an area that allies with the interests of our academic staff.

How will I be taught?

The two taught modules will each comprise of a series of lectures, small group discussion sessions, workshops and practical classes. Nominally each taught module has about 30-40 of contact hours associated with them. The rest of the time allocated for these modules will be for further reading, coursework preparation and revision.

The remainder of the programme will comprise of the 6 to 7 month research project which will involve regular meetings and guidance with your research supervisor. This is followed by the preparation of two reports.

How will I be assessed?

The research dissertation will be assessed by the production of a research report in the format of a scientific paper and a research review (80%).

The taught modules will be assessed by the production of practical and theoretical reports and class tests (20%).

Postgraduate Visit Opportunities

If you are interested in this courses we have a number of opportunities to visit us and our campuses. To find out more about these options and to book a visit, please go to: https://www1.chester.ac.uk/study/postgraduate/postgraduate-visit-opportunities

Request a Prospectus

If you would like to know more about the University please request a prospectus at: http://prospectus.chester.ac.uk/form.php

Read less

  • 1
Show 10 15 30 per page


Share this page:

Cookie Policy    X