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Masters Degrees (Protein Synthesis)

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The Master’s programme Organic Synthesis and Medicinal Chemistry provides knowledge on the design, synthesis and evaluation of low-weight organic substances. Read more

The Master’s programme Organic Synthesis and Medicinal Chemistry provides knowledge on the design, synthesis and evaluation of low-weight organic substances. It also covers protein chemistry and biomolecular design, preparing you for a career in the pharmaceutical industry.

Biologically active substances with low molecular weight represent the core of life-science research. Knowledge of molecular structures and their properties are crucial to our understanding of vast scientific areas, from pharmaceutically active compounds in designer drugs to organic electronics and their incorporation into diagnostic tools such as biosensors. Our research facilities are well equipped with all the necessary analytical and diagnostic tools found in industrial research facilities, which will advance your practical capabilities.

Organic and medicinal chemistry

This master’s programme aims to provide students with knowledge on the design, synthesis and evaluation of low molecular weight biologically active organic substances. The programme begins with courses in organic chemistry and organic synthesis, building from the basic concepts to the advanced level, followed by an introduction in medicinal chemistry and pharmaceutical technology. It also covers protein chemistry and biomolecular design, which broadens your knowledge in the field of bio-organic chemistry. A key part of the programme is a one-year degree project, undertaken either in a research group at LiU or in industry.



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Why study at Roehampton. Ideal if you are interested in focusing on a specific research area at Masters level and provides an excellent platform for progression to PhD-level study. Read more

Why study at Roehampton

  • Ideal if you are interested in focusing on a specific research area at Masters level and provides an excellent platform for progression to PhD-level study.
  • Benefit from excellent access to state-of-the-art laboratory facilities in which you can conduct your research.
  • Examine critically the theoretical bases of assessment methods and their practical application within physiology, psychology and biomechanics.
  • Roehampton is ranked best modern university in London (Sunday Times Good University Guide 2015).

Course summary

Produce high quality original research in the areas of sport, exercise, nutritional and health sciences. This programme provides an excellent platform for progression to PhD-level study as well as other related career paths.

This programme is for students who want to focus on a research topic with a view to create new knowledge within the growing area of sport and exercise science. You will be guided by experts in the field who will support you to produce high quality original research.

You will have the opportunity to work with state-of-the-art equipment in the laboratories. Our expertise will allow students to employ the latest techniques in the pursuit of producing significant and original research that is publishable. Some of the techniques include modified ELISA’s, Real-Time PCR, Western Blot, isotope methodology for metabolism, 2-3D motion analysis using MaxTRAQ and Vicon, force analysis using Kistler force plates and isokinetic dynamometers, muscle ultrasound, and neuromuscular electrical stimulation.

You will automatically gain access to our research community in the Sport and Exercise Science Research Centre (SESRC) and Health Sciences Research Centre (HSRC). The research centres are active in researching diabetes, obesity, diseased and healthy metabolism, neuromuscular function, biomechanics in elite and pathological populations, environmental physiology, nutrition in athletic and chronic diseased populations, protein synthesis and muscle growth, sport & exercise psychology and performance and well-being. 

Content

The key modules on this course revolve around you producing a high-level independent research project, which will prepare you for higher levels of research and study.

The course begins with a research methods module which will equip you with a comprehensive understanding of different approaches to research, allowing you to choose the correct method for your project, depending on your specific area of interest. You will study key philosophical questions as to the nature of science and knowledge, and develop a critical awareness of the principles and practice of qualitative and quantitative approaches and techniques. You will also be introduced to the management of ethical issues associated with collecting and analysing data on human participants. 

You will also be guided on the development of your research proposal, and be invited to attend the Sport Science Seminars Series to frame your understanding of current sport-related research.

Other modules on the programme allow you to study more in-depth knowledge and gain relevant practical skill in biomechanics, psychology, and/or physiology that are invaluable for your dissertation project. 

Modules

Here are the examples of modules:

  • MRes Research Dissertation
  • Research Methods
  • Psychology of Physical Activity, Health and Injury
  • Physiological Assessment
  • Biomechanical Measurement and Technology

Career options

Pathways include teaching, coaching, sport public relations and promotion, sports consultant and lecturer, further academic study.

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Research in the School of Biosciences revolves around understanding systems and processes in the living cell. It has a strong molecular focus with leading-edge activities that are synergistic with one another and complementary to the teaching provision. Read more
Research in the School of Biosciences revolves around understanding systems and processes in the living cell. It has a strong molecular focus with leading-edge activities that are synergistic with one another and complementary to the teaching provision.

Our expertise in disciplines such as biochemistry, microbiology and biomedical science allows us to exploit technology and develop groundbreaking ideas in the fields of genetics, molecular biology, protein science, biophysics and computational biologoy. Fields of enquiry encompass a range of molecular processes from cell division, transcription and translation through to molecular motors, molecular diagnostics and the production of biotherapeutics and bioenergy.

Visit the website https://www.kent.ac.uk/courses/postgraduate/1235/biochemistry

About the School of Biosciences

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

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

Research areas

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

The School’s research has three main themes:

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

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

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

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

Associated centres

- Kent Fungal Group

The Kent Fungal Group (KFG) brings together a number of research groups in the School of Biosciences that primarily use yeasts or other fungi as ‘model systems’ for their research. One strength of the KFG is the range of model fungi being exploited for both fundamental and medical/translational research. These include Bakers’ yeast (Saccharomyces cerevisiae) and Fission yeast (Schizosaccharomyces pombe) and yeasts associated with human disease, specifically Candida albicans and Cryptococcus neoformans.

In addition to studying key cellular processes in the fungal cell such as protein synthesis, amyloids and cell division, members of the KFG are also using yeast to explore the molecular basis of human diseases such as Alzheimer’s, Creutzfeldt-Jakob, Huntington’s and Parkinson’s diseases as well as ageing. The KFG not only provides support for both fundamental and medical/translational fungal research, but also provides an excellent training environment for young fungal researchers.

- Industrial Biotechnology Centre

The School houses one of the University’s flagship research centres – the Industrial Biotechnology Centre (IBC). Here, staff from Biosciences, Mathematics, Chemistry, Physics, Computing and Engineering combine their expertise into a pioneering interdisciplinary biosciences programme at Kent, in order to unlock the secrets of some of the essential life processes. These approaches are leading to a more integrated understanding of biology in health and disease. In the Centre, ideas and technology embodied in different disciplines are being employed in some of the remaining challenges in bioscience. With such an approach, new discoveries and creative ideas are generated through the formation of new collaborative teams. In this environment, the IBC is broadening and enriching the training of students and staff in science and technology.

- The Centre for Interdisciplinary Studies of Reproduction (CISoR)

The centre comprises several like-minded academics dedicated to the study of reproduction in all its forms. Drawing on a range of academic disciplines, CISoR's core philosophy is that the study of this fascinating field will advance further through a multidisciplinary approach. Impactful, excellent research forms the basis of CISoR’s activities including scientific advance, new products and processes, contribution to public policy, and public engagement.

Careers

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

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

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

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. Research profile. Pursuing a research degree at the School of Chemistry could be one of the best experiences of your life. Read more

Research profile

Pursuing a research degree at the School of Chemistry could be one of the best experiences of your life.

In addition to gaining research skills, making friends, meeting eminent researchers and being part of the research community, a research degree will help you to develop invaluable transferable skills which you can apply to academic life or a variety of professions outside of academia.

The Chemistry/Biology Interface

This is a broad area, with particular strengths in the areas of protein structure and function, mechanistic enzymology, proteomics, peptide and protein synthesis, protein folding, recombinant and synthetic DNA methodology, biologically targeted synthesis and the application of high throughput and combinatorial approaches. We also focus on biophysical chemistry, the development and application of physicochemical techniques to biological systems. This includes mass spectrometry, advanced spectroscopy and microscopy, as applied to proteins, enzymes, DNA, membranes and biosensors.

Experimental & Theoretical Chemical Physics

This is the fundamental study of molecular properties and processes. Areas of expertise include probing molecular structure in the gas phase, clusters and nanoparticles, the development and application of physicochemical techniques such as mass spectoscropy to molecular systems and the EaStCHEM surface science group, who study complex molecules on surfaces, probing the structure property-relationships employed in heterogeneous catalysis. A major feature is in Silico Scotland, a world-class research computing facility.

Synthesis

This research area encompasses the synthesis and characterisation of organic and inorganic compounds, including those with application in homogeneous catalysis, nanotechnology, coordination chemistry, ligand design and supramolecular chemistry, asymmetric catalysis, heterocyclic chemistry and the development of synthetic methods and strategies leading to the synthesis of biologically important molecules (including drug discovery). The development of innovative synthetic and characterisation methodologies (particularly in structural chemistry) is a key feature, and we specialise in structural chemistry at extremely high pressures.

Materials Chemistry

The EaStCHEM Materials group is one of the largest in the UK. Areas of strength include the design, synthesis and characterisation of functional (for example magnetic, superconducting and electronic) materials; strongly correlated electronic materials, battery and fuel cell materials and devices, porous solids, fundamental and applied electrochemistry polymer microarray technologies and technique development for materials and nanomaterials analysis.

Training and support

Students attend regular research talks, visiting speaker symposia, an annual residential meeting in the Scottish Highlands, and lecture courses on specialised techniques and safety. Students are encouraged to participate in transferable skills and computing courses, public awareness of science activities, undergraduate teaching and to represent the School at national and international conferences.

Facilities

Our facilities are among the best in the world, offering an outstanding range of capabilities. You’ll be working in recently refurbished laboratories that meet the highest possible standards, packed with state-of-the-art equipment for both analysis and synthesis.

For NMR in the solution and solid state, we have 10 spectrometers at field strengths from 200-800 MHz; mass spectrometry utilises EI, ESI, APCI, MALDI and FAB instrumentation, including LC and GC interfaces. New combinatorial chemistry laboratories, equipped with a modern fermentation unit, are available. We have excellent facilities for the synthesis and characterisation of bio-molecules, including advanced mass spectrometry and NMR stopped-flow spectrometers, EPR, HPLC, FPLC, AA.

World-class facilities are available for small molecule and macromolecular X-ray diffraction, utilising both single crystal and powder methods. Application of diffraction methods at high pressures is a particular strength, and we enjoy strong links to central facilities for neutron, muon and synchrotron science in the UK and further afield. We are one of the world's leading centres for gas-phase electron diffraction.

Also available are instruments for magnetic and electronic characterisation of materials (SQUID), electron microscopy (SEM, TEM), force-probe microscopy, high-resolution FTRaman and FT-IR, XPS and thermal analysis. We have also recently installed a new 1,000- tonne pressure chamber, to be used for the synthesis of materials at high pressures and temperatures. Fluorescence spectroscopy and microscopy instruments are available within the COSMIC Centre. Dedicated computational infrastructure is available, and we benefit from close links with the Edinburgh Parallel Computing Centre.



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Research in the School of Biosciences revolves around understanding systems and processes in the living cell. It has a strong molecular focus with leading-edge activities that are synergistic with one another and complementary to the teaching provision. Read more
Research in the School of Biosciences revolves around understanding systems and processes in the living cell. It has a strong molecular focus with leading-edge activities that are synergistic with one another and complementary to the teaching provision.

Our expertise in disciplines such as biochemistry, microbiology and biomedical science allows us to exploit technology and develop groundbreaking ideas in the fields of genetics, molecular biology, protein science, biophysics and computational biology. Fields of enquiry encompass a range of molecular processes from cell division, transcription and translation through to molecular motors, molecular diagnostics and the production of biotherapeutics and bioenergy.

Visit the website https://www.kent.ac.uk/courses/postgraduate/1238/genetics#!overview

About the School of Biosciences

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

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

Course structure

Our research degrees are based around lab-based and computational research projects. MScs are based around one-year research projects (Full Time). In all our research degrees you undertake a single, focused, research project from day one, and attend only certain components of our transferable skills modules. Our research degree students are supervised by supervisory teams which comprise their main supervisor(s) as well as supervisory chairs that give independent advice on progression.

You can select topics for the MSc from any of the research areas covered in the Research Areas section.

Research areas

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

The School’s research has three main themes:

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

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

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

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

Associated centres

- Kent Fungal Group

The Kent Fungal Group (KFG) brings together a number of research groups in the School of Biosciences that primarily use yeasts or other fungi as ‘model systems’ for their research. One strength of the KFG is the range of model fungi being exploited for both fundamental and medical/translational research. These include Bakers’ yeast (Saccharomyces cerevisiae) and Fission yeast (Schizosaccharomyces pombe) and yeasts associated with human disease, specifically Candida albicans and Cryptococcus neoformans.

In addition to studying key cellular processes in the fungal cell such as protein synthesis, amyloids and cell division, members of the KFG are also using yeast to explore the molecular basis of human diseases such as Alzheimer’s, Creutzfeldt-Jakob, Huntington’s and Parkinson’s diseases as well as ageing. The KFG not only provides support for both fundamental and medical/translational fungal research, but also provides an excellent training environment for young fungal researchers.

- Industrial Biotechnology Centre

The School houses one of the University’s flagship research centres – the Industrial Biotechnology Centre (IBC). Here, staff from Biosciences, Mathematics, Chemistry, Physics, Computing and Engineering combine their expertise into a pioneering interdisciplinary biosciences programme at Kent, in order to unlock the secrets of some of the essential life processes. These approaches are leading to a more integrated understanding of biology in health and disease. In the Centre, ideas and technology embodied in different disciplines are being employed in some of the remaining challenges in bioscience. With such an approach, new discoveries and creative ideas are generated through the formation of new collaborative teams. In this environment, the Centre is broadening and enriching the training of students and staff in science and technology.

- The Centre for Interdisciplinary Studies of Reproduction (CISoR)

The centre comprises several like-minded academics dedicated to the study of reproduction in all its forms. Drawing on a range of academic disciplines, CISoR's core philosophy is that the study of this fascinating field will advance further through a multidisciplinary approach. Impactful, excellent research forms the basis of CISoR’s activities including scientific advance, new products and processes, contribution to public policy, and public engagement.

Careers

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

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

Find out how to apply here - https://www.kent.ac.uk/courses/postgraduate/apply-online/1238

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This programme will give you hands-on practical experience of both laboratory and bioinformatics techniques. You will also be trained in biotechnology research strategies. Read more
This programme will give you hands-on practical experience of both laboratory and bioinformatics techniques. You will also be trained in biotechnology research strategies. A strong practical foundation is provided in the first semester (Semester A) when you study two modules: 'Cellular Molecular Biology' and 'Core Genetics and Protein Biology'. These modules concentrate on the basic principles and the techniques used in modern molecular biology investigations, and on aspects of cellular molecular biology and development.

The second semester (Semester B) has a problem-based learning approach to the application of the knowledge you gained in Semester A. You will study two modules: 'Industrial Biotechnology' and 'Molecular Biotechnology'. These modules will give you an in depth understanding of the application of molecular biological approaches to the production of industrial and medicinal proteins. You will also learn how to apply and design industrial and environmental biotechnology processes, such as process kinetics and design, reactor design and oxygen transfer, sterilization kinetics and the application of biotechnology processes for the bioremediation of contaminated sites.

In the third semester (Semester C) you undertake a research project to develop your expertise further. The research project falls into different areas and may include aspects of fermentation biotechnology, genetic manipulation and protein engineering, bioinformatics, microbial physiology and environmental biotechnology.

Why choose this course?

-This course gives in-depth knowledge of biotechnology and molecular biology for biosciences or biological chemistry graduates
-It has a strong practical basis giving you training in biotechnology research strategies and hand-on experience of laboratory and bioinformatics techniques
-It equips you for research and development positions in the biotechnology and pharmaceutical industries, as well as a wide range of non-research roles in industry
-Biosciences research facilities cover fermentation biotechnology, high performance liquid chromatography, (HPLC), cell culture, molecular biology and pharmacology
-There are excellent facilities for chemical and biomedical analysis, genetics and cell biology studies and students have access to the latest equipment for chemical synthesis and purification, PCR, qPCR and 2D protein gel analysis systems for use during their final year projects
-The School of Life and Medical Science will move into a brand new science building opening in September 2015 providing us with world class laboratories for our teaching and research. At a cost of £50M the new building provides spacious naturally lit laboratories and social spaces creating an environment that fosters multi-disciplinary learning and research

Careers

On successful completion of the programme you will be well qualified for research and development positions in the biotechnology and pharmaceutical industries, to progress to a research degree or to consider non-research roles in industry such as management, manufacturing and marketing.

Teaching methods

The course consists of five modules including a research project:
-Cellular Molecular Biology
-Core Genetics and Protein Biology
-Industrial Biotechnology
-Molecular Biotechnology
-Biosciences Research Methods for Masters
-Research project

All modules are 100% assessed by coursework which includes in-course tests.

Structure

Core Modules
-Biosciences Research Methods for Masters
-Cellular Molecular Biology
-Core Genetics and Protein Biology
-Industrial Biotechnology
-Molecular Biotechnology
-Project-Mol Biology, Biotechnology, Pharmacology

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The MPhil is offered by the Department of Chemistry as a full-time period of research and introduces students to research skills and specialist knowledge. Read more
The MPhil is offered by the Department of Chemistry as a full-time period of research and introduces students to research skills and specialist knowledge. Students are integrated into the research culture of the Department by joining a research group, supervised by one of our academic staff, in one of the following areas of Chemistry:

Biological:

with a focus on enzymes, nucleic acids, protein folding and misfolding, and physical techniques; with relevance to health and disease, drug discovery, sensors, nanotechnology, ageing and energy research applications.

Materials Chemistry:

including surfaces, interfaces, polymers, nanoparticles and nanoporous materials, self assembly, and biomaterials, with applications relevant to: oil recovery and separation, catalysis, photovoltaics, fuel cells and batteries, crystallization and pharmaceutical formulation, gas sorption, energy, functional materials, biocompatible materials, computer memory, and sensors.

Physical Chemistry:

including atmospheric sciences, surfaces and interfaces, materials, and physical and chemical aspects of the behaviour of biopolymers and other soft systems.

Synthetic Chemistry:

including complex molecule synthesis, synthetic catalysis, synthetic assembly, synthetic biology and medicine, new technology for efficient synthesis, green synthesis, and preparation of new materials.

Theory, Modelling and Informatics:

including quantum dynamics, modelling soft materials, protein folding and binding, biomolecules in motion, pharmacological activity, molecular switches, redox chemistry, designing bioactive molecule and drugs, chemical biology, crystallography, and simulation of spectroscopic studies.

Potential supervisors and their area of research expertise may be found at Department of Chemistry (Research): http://www.ch.cam.ac.uk/research

Visit the website: http://www.graduate.study.cam.ac.uk/courses/directory/pcchmpmch

Course detail

Educational aims of the MPhil programme:

- to give students with relevant experience at first degree level the opportunity to carry out focussed research in the discipline under close supervision; and

- to give students the opportunity to acquire or develop skills and expertise relevant to their research interests and a broader set of transferable skills.

Learning Outcomes

By the end of the programme, students will have:

- a comprehensive understanding of techniques, and a thorough knowledge of the literature, applicable to their own research;
- demonstrated originality in the application of knowledge, together with a practical understanding of how research and enquiry are used to create and interpret knowledge in their field;
- shown abilities in the critical evaluation of current research and research techniques and methodologies;
- demonstrated some self-direction and originality in tackling and solving problems, and acted autonomously in the planning and implementation of research.

Format

The MPhil involves minimal formal teaching. Students may attend the Department's programme of research seminars and other graduate courses, including the Transferable Skills programme that forms part of the PhD programme. Informal opportunities to develop research skills also exist through mentoring and other opportunities by fellow students and members of staff. However, most research training is provided within the research group structure and all students are assigned a research supervisor.

All graduate students receive termly reports written by their supervisors.

Assessment

The scheme of examination for the MPhil in Chemistry shall consist of a thesis, of not more than 15,000 words in length, exclusive of tables, footnotes, bibliography, and appendices, on a subject approved by the Degree Committee for the Faculty of Physics and Chemistry, submitted for examination at the end of 11 months. The examination shall include an oral examination on the thesis and on the general field of knowledge within which it falls. The thesis shall provide evidence to satisfy the Examiners that a candidate can design and carry out investigations, assess and interpret the results obtained, and place the work in the wider perspectives of the subject.

Continuing

The Department offers a PhD in Chemistry course and MPhil students can apply to continue as a graduate student on this course.

MPhil students currently studying a relevant course at the University of Cambridge will need to pass their MPhil course (if examined only by thesis) or obtain a minimum merit (if there is a marked element) in order to be eligible to continue onto the PhD in Chemistry.

How to apply: http://www.graduate.study.cam.ac.uk/applying

Funding Opportunities

There are no specific funding opportunities advertised for this course. For information on more general funding opportunities, please follow the link below.

General Funding Opportunities http://www.graduate.study.cam.ac.uk/finance/funding

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Chemical & Biological Engineering is a discipline that integrates chemistry and biology at the molecular level and uses this broad foundation along with engineering fundamentals to study the synthesis of new processes and products. Read more
Chemical & Biological Engineering is a discipline that integrates chemistry and biology at the molecular level and uses this broad foundation along with engineering fundamentals to study the synthesis of new processes and products. Our graduate program in Chemical and Biological Engineering is an interdisciplinary program that combines chemical engineering fundamentals and systems biology to meet the research challenges of the future.

Current faculty projects and research interests:

• Drug Discovery
• Tissue Engineering
• Plant Biotechnology
• Protein-Protein Interactions
• Protein Folding
• Process Dynamics, Control and Optimization
• Systems Engineering
• Catalysis
• Supercritical Fluids
• Synthesis of Nanostructured Materials
• Fuel Cells and Sustainable Development
• Computational Fluid Dynamics
• Polymer Science and Engineering

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This course is designed with industry in mind. We have also partnered with Engineering Materials and Physics to encompass the breadth of modern polymer science and technology. Read more

About the course

This course is designed with industry in mind. We have also partnered with Engineering Materials and Physics to encompass the breadth of modern polymer science and technology. You’ll become the kind of high-calibre polymer science graduate needed to develop new products and processes in a variety of industries.

Through a combination of theory and practice, we’ll teach you about polymer synthesis, physics, characterisation and the latest developments in polymer research. When you design and conduct your own extended research project, you can look in more detail at the areas you’re most interested in and learn how to communicate your science to the chemical community.

Your future

Our graduates are highly valued in the chemical and pharmaceutical sector. They work all over the world for companies including AkzoNobel, Amgen, AstraZeneca, Corus, Dow Chemicals, GSK, Smith and Nephew and Syngenta. Many move on to PhD study, then careers in research or teaching.

Chemistry is vital to the way we live. It helps power industry and drive economic growth. Polymer science contributes to advances in everything from biology to engineering and medicine. As a researcher in industry or academia you could be involved in work that improves lives and changes the way we see the world.

Learn from world-class research

Top-quality research directly informs our teaching. The 2014 Research Excellence Framework (REF) rates 98 per cent of our work world-class or internationally excellent. You’ll learn about the very latest developments from experts in theory and spectroscopy, synthesis, analytical science, chemical biology and materials.

Labs, equipment and training

We’ll train you to use our modern analytical instrumentation. We have NMR spectroscopy, mass spectrometry, x-ray crystallography, polymer characterisation methods and advanced microscopy. We also have a team of technicians to assist with spectroscopic services. There are labs for molecular biology, protein chemistry, polymer/colloid synthesis and materials characterisation.

Core modules

Fundamental Polymer Chemistry; The Physics of Polymers; Biopolymers and Biomaterials; Polymer Characterisation and Analysis; Research and Presentation Skills and Polymer Laboratory Skills; Extended Research Project.

Examples of optional modules

Smart Polymers and Polymeric Materials; Polymers with Controlled Structures; Design and Manufacture of Composites; Polymer Fibre Composite Materials; Macromolecules at Interfaces and Structured Organic Films; Electronics and Photonics.

Teaching and assessment

We use a mixture of lectures, practicals, workshops and individual research projects. The optional modules in the second semester enable you to specialise in two specific areas of polymer science. You can also tailor your research project to your particular interests.

For all taught modules, written exams contribute 75 per cent towards your final grade. The other 25 per cent comes from continuous assessment, which might include essays on specialised topics or assessed workshops. You also produce a 15,000-word dissertation based on your research project.

Your research project

This can be based in an academic group at the University, or in industry. If it’s industry- based, the topic is usually suggested by the company you’re working with. You may be expected to liaise closely with the company to organise your project.

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This course offers both taught components and extensive research experience for students with backgrounds in biological, chemical and physical sciences. Read more
This course offers both taught components and extensive research experience for students with backgrounds in biological, chemical and physical sciences. It is particularly suitable for those who wish to gain both theoretical and practical research experience in the techniques of structural biology or biocomputing.

Our research areas include:

Molecular chaperones, amyloid fibrils, pore-forming toxins
M. tuberculosis, cytoskeletal proteins
Signal transduction, bacterial pathogenesis and DNA replication
Electron microscopy, cytoskeletal dynamics and function
Electron cryo-microscopy; electron tomography and image processing; development of methods for recognition and separation of heterogeneous molecular complexes; bacteriophage assembly; structural analysis of the transcription factor p53
Hsp90, the kinetochore
DNA repair
Protein folding and misfolding, in particular at the point of synthesis on intact ribosomes
Viral protein-nucleic acid interactions.

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About the course. This 12-month course is ideal if you want to develop skills in a range of areas. It includes project work and an introduction to research-level theory. Read more

About the course

This 12-month course is ideal if you want to develop skills in a range of areas. It includes project work and an introduction to research-level theory. You’ll take taught classes for the first two semesters. In the third semester, you’ll work on an extended research project of your own.

Employers value this kind of experience. By the time you graduate, you’ll have proved you can work within a research group, organise your own research, complete a project and communicate your findings.

Your future

Our graduates are highly valued in the chemical and pharmaceutical sector. They work all over the world for companies including AkzoNobel, Amgen, AstraZeneca, Corus, Dow Chemicals, GSK, Smith and Nephew and Syngenta. Many move on to PhD study, then careers in research or teaching.

Chemistry is vital to the way we live. It helps power industry and drive economic growth. Polymer science contributes to advances in everything from biology to engineering and medicine. As a researcher in industry or academia you could be involved in work that improves lives and changes the way we see the world.

Learn from world-class research

Top-quality research directly informs our teaching. The 2014 Research Excellence Framework (REF) rates 98 per cent of our work world-class or internationally excellent. You’ll learn about the very latest developments from experts in theory and spectroscopy, synthesis, analytical science, chemical biology and materials.

Labs, equipment and training

We’ll train you to use our modern analytical instrumentation. We have NMR spectroscopy, mass spectrometry, x-ray crystallography, polymer characterisation methods and advanced microscopy. We also have a team of technicians to assist with spectroscopic services. There are labs for molecular biology, protein chemistry, polymer/colloid synthesis and materials characterisation.

Core modules

You’ll carry out two smaller laboratory projects prior to starting your main research project, to develop practical and scientific communication skill. You also undertake a Research and Presentation Skills module to further develop the higher level skills needed for research.

Examples of optional modules

Lectured modules consist of a wide range of segments, spanning the breadth of chemistry, from which you can choose, to tailor your MSc to your strengths and interests.

Teaching and assessment

We use a mixture of lectures, laboratory practicals, workshops and individual research projects. You may tailor the area of your research project to your particular interests. Assessment of taught modules is through examination, laboratory reports and coursework. Assessment of the project is through a 15,000-word dissertation, oral presentation and viva, as well as assessed performance during the project.



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Advances in technology depends more and more on the discovery and development of new materials having particular desired properties. Read more
Advances in technology depends more and more on the discovery and development of new materials having particular desired properties. In addition to mechanical strength, various structural, optical, electrical, magnetic and thermal properties are demanded from materials depending on the application. The field of Materials Science and Engineering investigates different classes of materials -metals, ceramics, polymers, electronic materials, biomaterials- with an emphasis on the relationships between the underlying structure and the processing, properties, and performance of the materials.
Understanding various material properties is the first step in finding ways to tailor these properties to meet some particular need or application, and for creating entirely new materials having particular desired properties. The M.S. program in Material Science & Engineering at Koç University is an interdisciplinary program with the objective of giving the students the fundamental physical and chemical knowledge required for material synthesis, structure-property characterization and processing; and complementing this with practical laboratory experience.

Current faculty projects and research interests:

• Nanostructured materials
• Photonics & laser materials
• Polymeric materials & composites
• Fuel cells & hydrogen storage materials
• Processing & device applications
• Protein biochemistry & biotechnology
• Micro-optics & micro-nano system Technologies

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You'll receive the highest-quality teaching in the leading Institute of Pharmacy & Biomedical Sciences in Scotland by staff dedicated to your personal and scientific development. Read more
You'll receive the highest-quality teaching in the leading Institute of Pharmacy & Biomedical Sciences in Scotland by staff dedicated to your personal and scientific development.

This course will provide you with a comprehensive three-part postgraduate life sciences training.

First, unlike many MSc courses, we offer you dedicated training in a broad suite of practical laboratory skills.

Secondly, this is complemented by two unique classes that develop your transferable skills in statistics, presentations, career development, and ethics, as well as honing your science writing skills and your ability to design experiments and analyse sophisticated datasets.

Thirdly, our taught classes capture the excitement of cutting-edge research fields and you will be taught by active researchers or practising clinical professionals. There is a choice of classes that allows you to select a pathway to suit your future aspirations.

Our MSc Molecular Microbiology focuses on the molecular biology of important microbial pathogens and industrial microorganisms.

Students study the molecular mechanisms by which bacteria cause disease or can be exploited for the synthesis of biotechnologically important products.

The course content and research projects are driven by the expertise in microbial genomics, genetics and biochemistry research that exists within the institute.

State-of-the-art research facilities, such as our own genome sequencer, protein purification facilities, mass spectrometers and fluorescence microscopes means that students obtain first-hand experience in the latest molecular microbiological techniques.

Together, the course provides the perfect springboard to future training at PhD level or gives you a range of skills and experience that will prove attractive to employers from industry or the health-care provision sector.

You'll study

-Vital transferable skills in statistics, communication, ethics, science writing and critical analysis of data
-Two semesters of postgraduate laboratories, giving you the practical abilities and interpretational skills that will prepare you for your project and future career
-Short optional classes in in vivo biology or drug discovery
-A compulsory Microbiology class together with a choice of either – Clinical Microbiology or Applied Microbiology
-A summer research project in molecular microbiology in an active research laboratory

Facilities

The course is taught in the Strathclyde Institute for Pharmacy & Biomedical Sciences. It’s located in our new building with state-of-the-art laboratories.

Course content

Compulsory classes
-Generic Skills for Biomedical & Pharmaceutical Students
-Entrepreneurship
-Statistics
-Advanced Techniques in Biomedical Research 1 & 2
-Postgraduate Studies in Microbiology
-Research project

Elective classes
-In Vivo Biology
-Drug Discovery
-Postgraduate Studies in Clinical Biochemistry
-Postgraduate Studies in Applied Microbiology

The course is delivered through lectures, tutorials and hands-on practical sessions.

If you successfully complete the required taught classes you may undertake a laboratory project for the MSc.

Assessment of taught classes is through multiple choice tests, computer quizzes, problem-solving scenarios, poster and oral presentations, essays, and formal written exams.

The laboratory project is assessed through a written thesis.

Careers

After graduating you should be ideally qualified for positions in biotechnology and pharmaceutical industries as well as hospitals and universities.

You may wish to continue studies for an MPhil or PhD.

This course provides the background training for a career in:
-Pharmaceutical & biotechnology industry laboratory research posts
-Laboratory technical support
-Medical/pharmaceutical/life science sales
-Academia – following a further PhD route

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