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Masters Degrees (Medicinal And Biological Chemistry)

We have 37 Masters Degrees (Medicinal And Biological Chemistry)

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Medicinal and Biological Chemistry requires a thorough understanding of molecules, their structures, properties and synthesis, but it also demands the chemical understanding of the nature of biological structures, from macromolecules to cells, the design of pharmaceutical materials in the laboratory and their function in clinical settings. Read more

Medicinal and Biological Chemistry requires a thorough understanding of molecules, their structures, properties and synthesis, but it also demands the chemical understanding of the nature of biological structures, from macromolecules to cells, the design of pharmaceutical materials in the laboratory and their function in clinical settings.

The knowledge and skills acquired in the course will leave graduates well equipped to compete for positions related to 'drug discovery' in chemical, pharmaceutical or biotechnological companies.

The degree consists of advanced lecture courses in:

  • Synthetic Organic Chemistry
  • Chemical Biology
  • Medicinal Chemistry
  • Biophysical Chemistry

These are studied concurrently with a predominantly practical based course offering an introduction to research methods.

Students then proceed to a period of full-time research project work, leading to the submission of their Masters dissertation.

Programme structure

Lectures are given by leading researchers in the area of medicinal and biological chemistry.

The lecture courses are supported by tutorial sessions and assessed by examination in May.

The Introduction to Research Methods course includes an exciting problem solving exercise where you learn important skills such as Communicating Science, Innovation, Dealing with Intellectual Property and Grant Application Writing, together with a literature survey and written report, defining the scope of the subsequent individual research project work.

Learning outcomes

On completion of the course, students should have developed a depth of comprehension and critique in the core elements of their subject area, including:

  • critical analysis and management of data;
  • judging the relationship between theory and methodology;
  • assessment of the appropriate methods of data collection/analysis to address the research question;
  • assessment of relevance of previous studies;
  • critical thinking.

Additionally they will have enhanced their professional/practical skills through:

  • experience of research design and management;
  • advanced instrumentation or techniques;
  • production of scientific reports.

Students will also have the opportunity to develop transferable skills such as:

  • written, visual and oral delivery and dissemination of research findings;
  • interpersonal and communication skills;
  • computing proficiency;
  • organisation skills.

Career opportunities

Graduates are well suited to take up roles in the chemical and pharmaceutical industries, either in research and development or sales and marketing. You will gain valuable work experience in a real-life research environment.

Alternatively, a Masters degree is a precursor to a PhD degree.

Our courses teach students the valuable skills they need to also move into other areas outside chemistry. Careers in IT, management or finance are possibilities after completing your degree.



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The field of medicinal chemistry is becoming increasingly important as we continue to push the boundaries in the discovery of new drugs and applications in healthcare. Read more
The field of medicinal chemistry is becoming increasingly important as we continue to push the boundaries in the discovery of new drugs and applications in healthcare. This MSc in Medicinal Chemistry will allow you to specialise in this area and explore the wider context of drug discovery, business and healthcare.

On the course, you will develop the specific technical knowledge, understanding and laboratory skills needed to design drugs. You will also investigate the relationship between medicinal chemists and drug discovery companies with stakeholders such as patients, investors and governments.

Distinctive features:

• Available on a one year full-time or three year part-time basis.
• Explore medicinal chemistry in a wider industrial context, including how businesses interact with patients and investors.
• Specialise in an area of interest to you with an end of course research project.
• Some industrial and academic placements are available in the UK or abroad for the research project.
• Network and build contacts with industry professionals who are frequently invited to present guest seminars.

Structure

This course may be taken on a one year full-time or three year part-time basis.

There are two parts to the degree. Part one is comprised of core and optional taught modules which you will take during the autumn and spring semesters. In these modules we will provide you with a foundation in the skills required by contemporary medicinal chemists, such as the techniques and trends in modern drug discovery. We will also look in more detail at the modelling of biological macromolecules and drug targets. We will then follow the process of drug development through from laboratory to clinic.

Upon successful completion of part one, you will progress to part two, the summer research project. We will make a range of project options available to you from the field of medicinal chemistry. For this project, depending on the subject you choose, you may work with a research group in the School of Chemistry or our partner, the School of Pharmacy and Pharmaceutical Studies. You may, if available, also be able to complete this project with one of our industrial partners or within another academic institution in the UK or abroad.

Core modules:

Colloquium
Key Skills for Postgraduate Chemists
Drug Discovery Chemistry
Techniques in Drug Discovery
Drug Targets
Drug Development from Laboratory to Clinic
Trends in Drug Discovery
Practical Medicinal Chemistry
Research Project

Optional modules:

Module title Module code Credits
Modelling of Biological Macromolecules
Structure and Mechanism in Organic Chemistry
Biosynthetic Approach to Natural Products
Biocatalysis I - Modern Approaches to Biocatalysts
Biocatalysis II - Industrial Applications of Biocatalysis
Bioinorganic Chemistry
Asymmetric Synthesis of Pharmaceuticals and Natural Products
Advanced Techniques in Organic and Biological Chemistry
Analytical and Structural Techniques in Chemical Biology
Bio-imaging Applications of Coordination Chemistry
Molecular Modelling

Teaching

The methods of teaching we employ will vary from module to module, as appropriate depending on the subject matter and the method of assessment. We teach using a mixture of lectures, workshops, case studies, computer-aided sessions, practicals and tutorials.

Your research project will be carried out in one of our laboratories under supervision of an academic member of staff with interests in a similar field. You may have the opportunity to complete your project during a placement in industry or with one of our academic partner institutions overseas, depending on availability.

Modules relating to computing frequently take place in our computer rooms, while practical work will be undertaken in our laboratories. We will also invite industry experts for seminars with our students within one of the core modules. Students will also benefit of the weekly seminars organized by the School of Chemistry, where leading experts in various scientific fields are invited to present their work.

Support

All of our students are allocated a personal tutor when they enrol on the course. A personal tutor is there to support you during your studies, and can advise you on academic and personal matters that may be affecting you. You should have regular meetings with your personal tutor to ensure that you are fully supported.

You will have access to the Science Library, which holds our collection of chemistry resources, as well as to the other Cardiff University Libraries.

Feedback:

We will provide regular feedback on your workload, written and oral depending on the coursework or assessment you have undertaken. You will usually receive your feedback from the module leader. If you have questions regarding your feedback, module leaders are happy to give advice and guidance on your progress. We aim to provide you with feedback within two weeks of you submitting an assessment.

Assessment

Taught modules are assessed in a variety of different ways depending on the module content and learning outcomes (found in the module descriptions). We use coursework, assessed workshops and presentations or a combination of these to assess your progress on the course.

Your research project at the end of the course will be assessed through a dissertation, a presentation, and an oral exam.

Career prospects

After completing this course there are usually two career streams open to graduates, research or industry. Within these two fields there are a variety of career options. For example, many of our graduates choose to follow up their MSc and decide to complete a PhD research degree with us. Employment opportunities for successful graduates include the expanding worldwide pharmaceutical industry, where many choose to specialise in the research and development of new drugs. Research-related jobs usually require a PhD, for which this programme provides an ideal preparation.

Placements

For the end of course research project we may have some placements available with one of our industrial partners or at another UK or overseas academic institution that we have an agreement with. Please enquire for further details.

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The chemistry of biological processes is the basis of all life on planet Earth. On this course you will develop an understanding of the processes that are core to biological chemistry. Read more
The chemistry of biological processes is the basis of all life on planet Earth. On this course you will develop an understanding of the processes that are core to biological chemistry. We will explore aspects such as biosynthesis, retrosynthetic analysis, molecular biology and the principles of drug development. We will also look at the applications of biological chemistry in catalysts, synthetic methods and spectroscopy, giving our graduates an edge when looking for employment in academia or industry.

Distinctive features:

• Available on a one year full-time or three year part-time basis.

• Explore real life biological systems as well as applications of biological processes, for example in catalysis.

• Specialise in an area of interest to you with an end of course research project.

• Some overseas academic placements may be available for the research project.

Structure

This course may be taken on a one year full-time or three year part-time basis.

There are two parts to the degree. Part one comprises core and optional taught modules which you will take during the autumn and spring semesters. In these modules we will provide you with an understanding of the biological problems and processes at the interface of chemistry and biology. We will study real life systems and explore aspects such as natural product synthesis, biocatalysis, molecular biology, synthetic biology, enzymology, medicinal chemistry and molecular modelling.

Upon successful completion of part one of the degree you will progress to part two, the summer research project. We will make a range of project options available to you from the field of biological chemistry. For this project you may work with a research group in the School of Chemistry. You may also be able to complete this project with one of our academic partner institutions overseas.

If you are on the one year full-time degree option, you will undertake all modules and your research project in one year.

Core modules:

Structure and Mechanism in Organic Chemistry
Biosynthetic Approach to Natural Products
Biocatalysis I - Modern Approaches to Biocatalysts
Colloquium
Biocatalysis II - Industrial Applications of Biocatalysis
Medicinal Chemistry
Bioinorganic Chemistry
Advanced Techniques in Organic and Biological Chemistry
Key Skills for Postgraduate Chemists
Practical Chemical Biology
Research Project

Optional modules:

Modelling of Biological Macromolecules
Asymmetric Synthesis of Pharmaceuticals and Natural Products
Analytical and Structural Techniques in Chemical Biology
Molecular Modelling

Teaching

The methods of teaching we employ will vary from module to module, as appropriate depending on the subject matter and the method of assessment. We teach using a mixture of lectures, workshops, computational sessions, laboratory practicals and tutorials.

Your research project will be carried out in one of our laboratories under supervision of an academic member of staff with interests in a similar field, unless you choose to complete your project during a placement with one of our academic partner institutions overseas, depending on availability.

Modules relating to computing frequently take place in our computer rooms, while practical work will be undertaken in our laboratories. We frequently invite external academic speakers and industry experts to the School for seminars, which our postgraduate students are encouraged to attend.

Support

All of our students are allocated a personal tutor when they enrol on the course. A personal tutor is there to support you during your studies and can advise you on academic and personal matters that may be affecting you. You should have regular meetings with your personal tutor to ensure that you are fully supported.

You will have access to the Science Library, which holds our collection of chemistry resources, as well as to the other Cardiff University Libraries.

Feedback:

We offer written and oral feedback, depending on the coursework or assessment you have undertaken. You will usually receive your feedback from the module leader. If you have questions regarding your feedback, module leaders are usually happy to give advice and guidance on your progress. We aim to provide you with regular feedback on your work after assessments have been submitted.

Assessment

Taught modules are assessed in a variety of ways depending on the module content and learning outcomes (found in the module descriptions). We use course work, assessed workshops, posters and oral presentations or a combination of these to assess your progress on the course.

Your research project at the end of the course will be assessed through a dissertation, a presentation, and an oral exam.

Career prospects

After completing this course there are usually two career streams open to graduates, research or industry. Within these two fields there are a variety of career options. For example, many of our graduates choose to follow up their MSc and decide to complete a PhD research degree with us. Those who have chosen not to continue in academia or teaching have gone on to a wide range of employment in private industries such as Kimberley-Clark group, Thales group, and Imanova Ltd.

Placements

For the end of course research project we may have some placements available with one of our academic partner institutions overseas. Please enquire early for further details

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This programme is designed for graduates in chemistry or closely related discipline who wish to contribute to drug development in the pharmaceutical industry. Read more
This programme is designed for graduates in chemistry or closely related discipline who wish to contribute to drug development in the pharmaceutical industry.

The programme provides training in pharmacokinetics, drug metabolism, drug synthesis, methods to identify potential drug targets and drug candidates, and methods to assess the biological activities of drug compounds.

Additional modules cover the key techniques in analytical chemistry used to support the pharmaceutical sciences.

Core study areas include research methods, pharmacokinetics and drug metabolism, drug targets, drug design and drug synthesis, spectroscopy and structural analysis, professional skills and dissertation and a research training project.

Optional study areas include separation techniques, mass spectrometry and associated techniques, innovations in analytical science and medicinal chemistry.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/chemistry/pharmaceutical-science-medicinal-chemistry/

Programme modules

Compulsory Modules
Semester 1:
- Research Methods
- Pharmacokinetics and Drug Metabolism
- Drug Targets, Drug Design and Drug Synthesis

Semester 2:
- Spectroscopy and Structural Analysis
- Professional Skills and Dissertation
- Research Training Project

Selected Optional Modules
Semester 1:
- Separation Techniques
- Mass Spectrometry and Associated Techniques

Semester 2:
- Innovations in Analytical Science
- Innovations in Medicinal Chemistry

Assessment

Examination and coursework.

Careers and further study

Careers in a variety of industries, particularly the pharmaceutical and related industries, including drug metabolism, medicinal chemistry (organic synthesis), drug screening (action / toxicity), patents and product registration; also as preliminary study for a PhD.

Scholarships and sponsorship

A number of bursaries and scholarships are available to UK and EU students towards tuition fees (excluding Environmental Studies MSc).
Departmental bursaries, in the form of fee reduction, are available to self-funded international students.
The programmes also benefit from industrial sponsorship which provides support in the form of equipment, materials, presenters and project placements.

Why choose chemistry at Loughborough?

The Department of Chemistry has about 350 students studying taught programmes, including around 50 on MSc courses, 10 postdoctoral research fellows, 50 research students (MPhil / PhD), and 25 academic staff, many of whom have strong links with industry.

In recent years, the Chemistry building has undergone extensive refurbishment and provides modern facilities and laboratories for the teaching and research needs of analytical, organic, inorganic and physical chemistry, as well as specialist laboratories for radiochemistry, environmental chemistry, microbiology and molecular pharmacology.

- Facilities
The Department has a number of specialist instruments and facilities, including: 2 x 400 MHz, 500 MHz and solid-state NMR spectrometers, single crystal and powder X-ray diffractometers, a high resolution inductively coupled plasma mass spectrometer, sector field organic MS, GC-MS and linear ion trap LC-mass spectrometers, ion mobility spectrometers and gas and liquid chromatographs.

- Research
The Department typically has well over 50 research students and a dozen postdoctoral researchers. In addition there are usually around 50 MSc students in the department. Many students come to study from abroad, and there are research students and visitors from all over the world currently studying and carrying out research in the department.
The Department is very well equipped to carry out research spanning all the traditional branches of chemistry (analytical, environmental, inorganic, organic and physical) and which contributes to four active research themes (Energy, Environment, Security and Health).

- Career Prospects
90% of our graduates were in employment and/or further study six months after graduating. Graduates can expect to develop their careers in the pharmaceutical and food industry, analytical and environmental laboratories, public and regulatory utilities, industrial laboratories, or go on to study for a PhD.

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/chemistry/pharmaceutical-science-medicinal-chemistry/

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Penn’s Master of Chemical Sciences is designed for your success. Chemistry professionals are at the forefront of the human quest to solve ever-evolving challenges in agriculture, healthcare and the environment. Read more
Penn’s Master of Chemical Sciences is designed for your success
Chemistry professionals are at the forefront of the human quest to solve ever-evolving challenges in agriculture, healthcare and the environment. As new discoveries are made, so are new industries — and new opportunities. Whether you’re currently a chemistry professional or seeking to enter the field, Penn’s rigorous Master of Chemical Sciences (MCS) builds on your level of expertise to prepare you to take advantage of the myriad career possibilities available in the chemical sciences. With a faculty of leading academic researchers and experienced industry consultants, we provide the academic and professional opportunities you need to achieve your unique goals.

The Penn Master of Chemical Sciences connects you with the resources of an Ivy League institution and provides you with theoretical and technical expertise in biological chemistry, inorganic chemistry, organic chemistry, physical chemistry, environmental chemistry and materials. In our various seminar series, you will also regularly hear from chemistry professionals who work in a variety of research and applied settings, allowing you to consider new paths and how best to take advantage of the program itself to prepare for your ideal career.

Preparation for professional success
If you’ve recently graduated from college and have a strong background in chemistry, the Master of Chemical Sciences offers you a exceptional preparation to enter a chemistry profession. In our program, you will gain the skills and confidence to become a competitive candidate for potential employers as you discover and pursue your individual interests within the field of chemistry. Our faculty members bring a wealth of research expertise and industry knowledge to help you define your career direction.

For working professionals in the chemical or pharmaceutical industries, the Master of Chemical Sciences accelerates your career by expanding and refreshing your expertise and enhancing your research experiences. We provide full- and part-time options so you can pursue your education without interrupting your career. You can complete the 10-course program in one and a half to four years, depending on course load.

The culminating element of our curriculum, the capstone project, both tests and defines your program mastery. During the capstone exercise, you will propose and defend a complex project of your choice, that allows you to stake out a new professional niche and demonstrate your abilities to current or prospective employers.

Graduates will pursue fulfilling careers in a variety of cutting-edge jobs across government, education and corporate sectors. As part of the Penn Alumni network, you’ll join a group of professionals that spans the globe and expands your professional horizons.

Courses and Curriculum

The Master of Chemical Sciences degree is designed to give you a well-rounded, mechanistic foundation in a blend of chemistry topics. To that end, the curriculum is structured with a combination of core concentration courses and electives, which allow you to focus on topics best suited to your interests and goals.

As a new student in the Master of Chemical Sciences program, you will meet with your academic advisor to review your previous experiences and your future goals. Based on this discussion, you will create an individualized academic schedule.

The Master of Chemical Sciences requires the minimum completion of 10 course units (c.u.)* as follows:

Pro-Seminar (1 c.u.)
Core concentration courses (4-6 c.u., depending on concentration and advisor recommendations)
Elective courses in Chemistry, such as computational chemistry, environmental chemistry, medicinal chemistry, catalysis and energy (2-4 c.u., depending on concentration and advisor recommendations)
Optional Independent Studies (1 c.u.)
Capstone project (1 c.u.)
Pro-Seminar course (CHEM 599: 1 c.u.)
The Pro-Seminar will review fundamental concepts regarding research design, the scientific method and professional scientific communication. The course will also familiarize students with techniques for searching scientific databases and with the basis of ethical conduct in science.

Concentration courses
The concentration courses allow you to develop specific expertise and also signify your mastery of a field to potential employers.

The number of elective courses you take will depend upon the requirements for your area of concentration, and upon the curriculum that you plan with your academic advisor. These concentration courses allow you to acquire the skills and the critical perspective necessary to master a chemical sciences subdiscipline, and will help prepare you to pursue the final capstone project (below).

You may choose from the following six chemical sciences concentrations:

Biological Chemistry
Inorganic Chemistry
Organic Chemistry
Physical Chemistry
Environmental Chemistry
Materials
Independent Studies
The optional Independent Studies course will be offered each fall and spring semester, giving you an opportunity to participate in one of the research projects being conducted in one of our chemistry laboratories. During the study, you will also learn analytical skills relevant to your capstone research project and career goals. You can participate in the Independent Studies course during your first year in the program as a one-course unit elective course option. (CHEM 910: 1 c.u. maximum)

Capstone project (1 c.u.)

The capstone project is a distinguishing feature of the Master of Chemical Sciences program, blending academic and professional experiences and serving as the culmination of your work in the program. You will develop a project drawing from your learning in and outside of the classroom to demonstrate mastery of an area in the chemical sciences.

The subject of this project is related to your professional concentration and may be selected to complement or further develop a work-related interest. It's an opportunity to showcase your specialization and your unique perspective within the field.

Your capstone component may be a Penn laboratory research project, an off-campus laboratory research project or a literature-based review project. All components will require a completed scientific report. It is expected that the capstone project will take an average of six months to complete. Most students are expected to start at the end of the first academic year in the summer and conclude at the end of fall semester of the second year. Depending on the capstone option selected, students may begin to work on the capstone as early as the spring semester of their first year in the program.

All capstone project proposals must be pre-approved by your concentration advisor, Master of Chemical Sciences Program Director and if applicable, your off-campus project supervisor. If necessary, nondisclosure agreements will be signed by students securing projects with private companies. Additionally, students from private industry may be able to complete a defined capstone project at their current place of employment. All capstone projects culminate in a final written report, to be graded by the student's concentration advisor who is a member of the standing faculty or staff instructor in the Chemistry Department.

*Academic credit is defined by the University of Pennsylvania as a course unit (c.u.). Generally, a 1 c.u. course at Penn is equivalent to a three or four semester hour course elsewhere. In general, the average course offered at Penn is listed as being worth 1 c.u.; courses that include a lecture and a lab are often worth 1.5 c.u.

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Chemical biology is the application of chemical tools and ideas to biological and medical problems. Read more

Chemical biology is the application of chemical tools and ideas to biological and medical problems. This programme is designed to build on an existing knowledge of chemical structure and reactivity to give you a thorough grounding in contemporary chemical biology and drug discovery as well as introducing you to topics from the research frontier.

You’ll be taught by experts from across the Astbury Centre in chemical biology, biophysics and medicinal chemistry using a "problem-based" approach. Visiting lecturers from the pharmaceutical industry will share their expertise in industrially-relevant applications of chemical biology and drug design with you.

Bridging the gap between your undergraduate degree in a core subject, and interdisciplinary research in chemical biology, you’ll develop the skills to solve real-life research problems, benefitting from a multi-million pound investment in fantastic research facilities. Rather than focusing on a single discipline, you’ll learn to use either chemical or biological approaches to tackle the problem in hand.

Accreditation

Royal Society of Chemistry Accreditation

The University of Leeds launched the first taught MSc degree in Chemical Biology in the UK. The course was one of the first two MSc courses in the UK to receive accreditation from the Royal Society of Chemistry; graduates from the programme with an appropriate first degree in chemistry satisfy the academic requirements for the award of Chartered Chemist (CChem) status.

Course content

In the first half of the year you’ll cover a core range of modules designed to build on an existing knowledge of chemical structure and reactivity to give you a thorough understanding of chemical biology and the techniques required for drug design. In the second half of the year you’ll spend the majority of your time working on an interdisciplinary research project which will allow you to work with and gain advice from two supervisors with complementary expertise.

This project will contribute 50% of the mark for your degree. The School will help you to select the project that is right for you, in an area that interests and motivates you. The project will provide you with key research experience to take your career forward. With the core modules behind you, you’ll be ideally positioned to choose an exciting problem to investigate.

The breadth of expertise available at Leeds means that you will be able to combine a wide range of techniques from computational ligand design to synthesis, protein engineering and laser spectroscopy. These techniques might span one of more of the following general areas;

  • Synthesis of biologically active molecules
  • Medicinal chemistry
  • Enzymology and directed evolution
  • Biophysical chemistry
  • Chemical genetics

You’ll receive training in the generic skills that are required for the module, including scientific writing and giving oral presentations. You’ll select your project at the start of the second semester,undertaking a programme of directed reading before writing an initial report. You’ll then spend over four months in your supervisors' research laboratories working alongside PhD students and experienced postdoctoral researchers. During the research project, you’ll have access to the outstanding research facilities in chemical biology that are available in Leeds.

Course structure

Compulsory modules

  • Foundation of Chemical Biology 10 credits
  • Drug Discovery and Development 15 credits
  • Emerging Topics in Chemical Biology 25 credits
  • Extended Laboratory Project for Chemistry-based MSc courses 90 credits

Optional modules

  • Practical Bioinformatics 10 credits
  • Molecular Diagnostics and Drug Delivery 10 credits
  • Advanced Topics in Chemical Biology (40 Credit) 40 credits
  • Advanced Topics in Chemical Biology (30 Credit) 30 credits

For more information on typical modules, read Chemical Biology and Drug Design MSc in the course catalogue

Learning and teaching

You will be taught by experts across the Astbury Centre for Structural Molecular Biology, meaning you’ll learn from both chemists and biologists to gain the skills and knowledge to work in a multidisciplinary environment. You’ll be taught through a series of lectures, small group workshops and practical lab sessions. You will also get involved in student led activities such as literature presentations.

Assessment

The wide range of continual assessment formats will allow you to improve your generic skills, and to hone your ability to solve problems. As part of the continual assessment of modules, you will give a wide range of oral presentations; prepare short articles, essays and research reports; perform computational exercises; and undertake group-based problem solving activities. Your research project will be assessed through your practical work and a written research report.

Career opportunities

On graduation, you’ll be ideally placed to undertake interdisciplinary research in academia and the pharmaceutical or biotechnology industry. You’ll also be in a strong position to pursue a science-related career, such as patent work, scientific publishing or scientific administration.

In addition, this course will leave you well-placed to forge a career at companies working at the interface between chemistry and biology. The pharmaceutical and biotechnology industries are increasingly seeking researchers with a strong interdisciplinary background.

Further study

Many of our graduates have secured positions on Chemical Biology and Medicinal Chemistry PhD programmes in the UK and internationally. The Astbury Centre hosts a wide range of PhD programmes incorporating Chemical Biology and Medicinal Chemistry, offering many opportunities for students graduating from the MSc course. The MSc provides tailored training at the interface between chemistry and the biological sciences, and will enhance your prospects of securing a place on one of these highly competitive postgraduate programmes.

Careers support

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

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



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The Organic Chemistry. Drug Discovery MRes at UCL offers students the opportunity to follow an integrated course of research and interdisciplinary study. Read more
The Organic Chemistry: Drug Discovery MRes at UCL offers students the opportunity to follow an integrated course of research and interdisciplinary study. Students gain outstanding training in synthetic organic chemistry applied to drug design, together with a breadth of experience in several areas of synthetic methodology and chemical biology.

Degree information

The programme provides a thorough foundation in drug design, advanced organic synthesis and molecular modelling, together with modules on research techniques, professional development and entrepreneurship. Students will carry out a substantial research project on organic/medicinal chemistry or chemical biology over a ten-month period.

MRes students undertake modules to the value of 180 credits.

The programme consists of two modules from the Wolfson Institute for Biomedical Research (30 credits), one Master's level chemistry module (15 credits) two transferable/research skills modules (30 credits) and the research project (105 credits).

Core modules - students take 30 credits of transferable/research skills and submit a research dissertation (105 credits).
-Transferable/Research Skills
-Research Dissertation

Optional modules - students take 45 credits from the following options:
-Bioinformatics
-Target Identification
-Cheminformatics
-Biological Molecules
-Biophysical Screening
-Fragment Based Drug Design
-Target Selection (Scientific)
-Target Selection (Commercial)
-Principles of Drug Design
-Biological Chemistry
-Stereochemical Control in Asymmetric Synthesis
-Synthesis and Biosynthesis of Natural Products
-Organometallics and Catalysis
-Structural Methods in Modern Chemistry

Dissertation/report
Students will undertake a laboratory-based research project lasting ten months. An interim report is submitted after five months, and at the end of the project each student writes a dissertation, gives a short presentation and has a viva voce examination.

Teaching and learning
The programme is delivered through a combination of lectures, problem classes, workshops and projects. Assessment is through unseen written examination, coursework, project reports and presentations.

Careers

The MRes has been developed in response to the needs of the pharmaceutical and biotechnology sectors for highly qualified students as leaders in the discovery of new medicines. The pharmaceutical sector is a major employer in the UK and high-quality graduates with an understanding of the sector are always in demand. Our recent graduates have taken up PhD positions, are working in industry and have entered teacher training.

Top career destinations for this degree:
-PHD Chemical Biology, University College London (UCL)
-PhD Radiochemistry, University College London (UCL)

Why study this degree at UCL?

This programme is taught in collaboration with the Wolfson Institute of Biomedical Research (WIBR) which brings together scientists and clinicians from both academic and pharmaceutical industry backgrounds. The institute's strength is in its multidisciplinary approach to research, with the goal of identifying novel targets for drug development.

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Located in Canada's most enterprising city and neighboring one of the nation's best playgrounds - the Rockies - the Department of Chemistry's graduate program offers you the opportunity to collaborate with world-class researchers, work in highly sophisticated labs, and build the skills you need to pursue stimulating careers in both research and industry. Read more
Located in Canada's most enterprising city and neighboring one of the nation's best playgrounds - the Rockies - the Department of Chemistry's graduate program offers you the opportunity to collaborate with world-class researchers, work in highly sophisticated labs, and build the skills you need to pursue stimulating careers in both research and industry.

Among many other things, our 40 faculty members and 100+ graduate students work on advancing knowledge and finding solutions to problems regarding Chemistry for Cleaner Energy, Chemistry for Life and Health and Chemistry for the Quantum-Nano World that involve the following various research themes:
-Biological and Medicinal Chemistry
-Chemical Education Research
-Chemical Synthesis and Catalysis
-Computational Chemistry and Molecular Modeling
-Energy and Environment
-Nanotechnology and Materials Chemistry

The MSc (Thesis-based) is a full-time degree with an average completion time of two years, typically requiring a Bachelor's degree in the same or a closely related discipline.

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The University academic year begins the first week of September, and the academic year is divided into a 13 week first term - September, October, November - and a 14 week (including reading week in mid-February) second term - January, February, March. Read more

Graduate Programs

The University academic year begins the first week of September, and the academic year is divided into a 13 week first term - September, October, November - and a 14 week (including reading week in mid-February) second term - January, February, March. There is a formal examination period scheduled at the end of each term. The four month summer term is devoted to research. The usual period for completing an MSc is two to two and one half years while that for a PhD is about five years. All students accepted for the MSc or PhD will be offered a package of funding which includes a research assistantship and a teaching assistant ship - two years guaranteed for the MSc, five years guaranteed for the PhD.

The normal times for a student to begin their programme of study are September 1 or January 1. It is also possible to begin May 1 upon Departmental approval and agreed supervisor selection.

The Department offers MSc and PhD degrees - each degree requires graduate courses and research work reported in a thesis. Each degree requires 12 credits of course work, unless the candidate already holds an approved MSc. Most courses are worth 3 credits.

Students are generally encouraged to complete all their course requirements in their first year if possible in order to allow a more efficient use of time for their research projects. A one credit pass/fail seminar course is part of the requirements. An individual programme is designed by consultation between the graduate advisor, the student's supervisor (if known), and the student at the time of his or her arrival. There are no entrance or cumulative examinations.

Students accepted into the MSc program may transfer directly to a PhD degree program after one year without completing their MSc, provided they have completed in the first year a minimum of 12 credits of course work with an overall average of at least 80%, 9 credits of 80% standing, and one of the seminar courses CHEM 540A, 540B or 540C.

The progress of each PhD student is evaluated once a year at a meeting of the faculty. A supervisory committee is formed for each student; this committee normally consists of the research supervisor and three other faculty members, one of whom is chosen by the student. In their second year, PhD students are required to pass a comprehensive examination. This exam consists of an oral report of their research progress and questioning on their work and the background related to it - this meeting is normally the last requirement before the thesis and must be passed in one or two attempts to achieve candidacy.

At the completion of the thesis, both MSc and PhD students must defend their results and thesis at a formal oral defense. In the case of PhD students an external examiner, chosen in consultation with the supervisor and the graduate advisor, is also asked by the Faculty of Graduate Studies to review the thesis.

Quick Facts

- Degree: Master of Science
- Specialization: Chemistry
- Subject: Science
- Mode of delivery: On campus
- Program components: Coursework + Thesis required
- Faculty: Faculty of Science

Research focus

Biological & Medicinal Chemistry, Catalytic Processes, Chemical Physics, Chemical Synthesis, Environmental Chemistry, Interfacial and Surface Chemistry, Materials & Polymer Chemistry, Molecular Spectroscopy, Nuclear and Radiochemistry

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The number of industries requiring highly skilled graduates in the biological and biomolecular sciences is rapidly expanding and remains based on the principle that employable graduates should possess a range of key skills. Read more
The number of industries requiring highly skilled graduates in the biological and biomolecular sciences is rapidly expanding and remains based on the principle that employable graduates should possess a range of key skills. The MSc in Biological and Biomolecular Science by Negotiated Learning will afford students the flexibility to broaden their understanding of biological and biomolecular science against a backdrop of learning core technical, methodological and innovation skills relevant to the industry and academia.
Several innovative specialisations are available from a carefully chosen range of modules from the relevant disciplines within the UCD School of Biomolecular & Biomedical Science and the UCD School of Biology and Environmental Science. These provide students with an exciting prospect of studying and researching in the interdisciplinary fields of genetics, cell biology, biochemistry, molecular biology, microbiology and biodata analysis. This diverse offering aims to enhance and develop a student’s current knowledge and skill base using a wide range of taught components and applied research skills. Guidance from expert faculty is provided to tailor a programme that will meet the anticipated requirements of the student’s objectives and career goals.

Key Fact

This MSc in Biological and Biomolecular Science is the first of its kind offered in Ireland by Negotiated Learning. This offers students a unique opportunity to combine skills and learning from several related disciplines with guidance from expert faculty staff, and to deepen their knowledge in one of our specialisations.

Course Content and Structure

The course is divided into the following:
•Core Laboratory Research Skills (30 credits) – including techniques such as RT-PCR, western blotting and imaging studies.
•Core Professional Taught Skills Modules (20 credits) – including career development, quantitative tools, science writing and communication skills.
•Optional Taught modules (40 credits) – involves selecting one of the following specialisations and selecting specific modules within
these that meet the student’s learning objectives.

The Specialisations Available:
• Genetics and Cell Biology: investigates cellular signalling, architecture, imaging, trafficking and transport, genetic basis of disease, model organisms, epigenetics, etc.
• Microbiology and Infection Biology: investigates mechanisms of pathogenic micro-organisms, host response to infection, immunopathologies, host-pathogen interactions, development of diagnostics, applied microbiology, etc.
• Biochemistry and Synthetic Biology: investigates metabolism and disease, protein-protein interactions, cell signalling, protein structure and analysis.

Career Opportunities

This programme will enable you to choose from a wide range of careers and areas of postgraduate study. This multi-disciplinary course provides a solid grounding for careers in industry, health and research, such as Quality Assurance, Quality Control, Microbiology, Process control, Technical Transfer, Research and Development, and Regulatory Affairs, Scientific Editor or Writer, Lab Technician or Analyst roles.

An academic staff member will advise you on a specialisation and module choices based on the opportunities you hope to unlock.

Facilities and Resources

Students on this programme will benefit from the use of a research skills laboratory in the prestigious UCD Conway Institute, as well as state-of-the-art teaching and laboratory facilities in the new O'Brien Centre for Science.

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Train as a pharmaceutical scientist at Liverpool John Moores University on this new, Masters-level Drug Discovery and Design course. Read more
Train as a pharmaceutical scientist at Liverpool John Moores University on this new, Masters-level Drug Discovery and Design course. Gain hands-on laboratory experience, carry out novel research and enjoy excellent employment prospects.

•Complete this masters degree in one year (full time)
•Explore molecular chemistry and the drug creation aspect of the pharmaceutical industry as you train to become a qualified pharmaceutical scientist
•Gain hands-on experience in relevant laboratory techniques with a 12 week research project
•Benefit from LJMU's £12 million investment in state-of-the-art laboratory facilities
•Enjoy excellent graduate employment prospects

Enhance your subject knowledge and gain hands-on experience with this new Masters course, taught by tutors with personal industry experience and strong manufacturing connections.

Completing a PG Cert by the end of the first semester on this course, you will devote the next semester to Diploma level study and then undertake a 12 week laboratory project for the final part of your MSc.
There are opportunities for topic specialisation and the chance to undertake cutting edge research.

You will learn in a supportive, flexible academic environment, studying at the Byrom Street site, right in the heart of Liverpool city centre.

The School's laboratories are currently undergoing a £12 million upgrade. Here you’ll find chromatographic equipment and spectrometers, tableting and particle sizing equipment, computing laboratory and state-of-the-art molecular modelling software, electron spin resonance spectrometers and thermal analysis equipment, including dynamic differential scanning calorimetry plus chromatography, LC-MS and NMR instruments.

In terms of independent study support, the Avril Robarts Library, open 24/7 during semesters, is located just minutes away on Tithebarn Street.

Please see guidance below on core and option modules for further information on what you will study.

Research Methods
Gain the necessary core skills to effectively design, plan, perform and report scientific research.
Analytical Techniques, Structure and Function in Organic Molecules
Understand the application of analytical chemistry to pharmaceutical materials and the effect of functional group chemistry on both the structure and consequent properties of relevant molecules.
Physicochemical Properties of Therapeutic Agents
Understand the physical and chemical properties of both small molecules and macromolecules and how these influence their in vitro and in vivo behaviour as active pharmaceutical ingredients.
Medicinal Chemistry
Understand the application of medicinal chemistry to the drug discovery process and the requirement for a modern synthetic approach to the supply of relevant molecules.
Natural Products
Understand various aspects of chromatographic, spectroscopic and assay techniques and approaches pertinent to natural products drug discovery, and the chemistry of natural products.
Research Project
Complete an independent, in-depth, 12 week scientific study related to the pharmaceutical sciences.

Further guidance on modules

The information listed in the section entitled ‘What you will study’ is an overview of the academic content of the programme that will take the form of either core or option modules. Modules are designated as core or option in accordance with professional body requirements and internal Academic Framework review, so may be subject to change. Students will be required to undertake modules that the University designates as core and will have a choice of designated option modules. Additionally, option modules may be offered subject to meeting minimum student numbers.

Please email if you require further guidance or clarification.

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This programme is offered by the UCL Division of Medicine and the Wolfson Institute for Biomedical Research and is designed for the more research-oriented student, complementing Drug Design MSc. Read more
This programme is offered by the UCL Division of Medicine and the Wolfson Institute for Biomedical Research and is designed for the more research-oriented student, complementing Drug Design MSc. Conducting cutting-edge research within the drug industries and UCL's academic group, it offers opportunities for networking and future career development.

Degree information

This programme teaches students the latest methodologies and approaches and covers all aspects of drug design: drug discovery, computational and structural biology, screening, assay development, medicinal chemistry, and most importantly the industrial practices involved in modern drug design technology.

Students undertake modules to the value of 180 credits.

The programme consists of two core modules (30 credits), three optional modules (45 credits) and a dissertation/report (105 credits).

Optional modules - students will select three from the following Drug Design MSc modules:
-Bioinformatics and Structural Biology as applied to Drug Design
-Biological Molecules as Therapeutics
-Biophysical Screening Methods, X-ray Crystallography, Protein NMR and Phenotypic Screening
-Cheminformatics and Modelling for Drug Design
-Fragment-based Drug Design
-Target Selection – Commercial and Intellectual Property Aspects
-Target Selection – Scientific Grounds

Core modules - plus two taught transferable skills modules delivered by CALT (UCL Centre for the Advancement of Learning and Teaching):
-Investigating Research
-Researcher Professional Development

Dissertation/report
All students undertake an independent research project which culminates in a dissertation of 15,000 to 20,000 words.

Teaching and learning
The programme is delivered through a combination of lectures, seminars, tutorials and problem classes, critical journal clubs and a research project. Assessment is through coursework, practicals, laboratory work, examination, dissertation and oral presentation.

Careers

We expect students graduating from this programme to take leading roles in drug discovery and development worldwide or to undertake further PhD level research. The first cohort of students on the Drug Design MRes graduating in 2015 have found jobs in the pharmaceutical industry as well as PhD studentships in leading universities.

Employability
The advanced knowledge and skill set acquired by taking this programme will enable students to find employment in the pharmaceutical and biotech industries in a global market.

Why study this degree at UCL?

The division hosts research groups in the areas of medicine, pharmaceutical research, cell cycle, neurobiology, mitochondrial function, stem cells and cancer. Underpinning the translational aspects of the biomedical research, we have a medicinal chemistry group which conducts research where chemistry and biology intersect, using the latest techniques and developing new ones for the study of biological systems.

The division collaborates extensively within industry and academia to develop biological tools and therapeutic agents. There are plenty of opportunities to conduct translational research that has an impact on drug discovery.

Pharmaceutical and biotech companies, well established in the West, have been transferring their research and development to the East. Given these substantial developments, particularly in China and India, the programme will have a broad international appeal.

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Clinicians, scientists and students engaged in cancer research at Newcastle share a common purpose. to improve treatment outcomes for patients with cancer. Read more
Clinicians, scientists and students engaged in cancer research at Newcastle share a common purpose: to improve treatment outcomes for patients with cancer. Work covers a broad spectrum - understanding the biological and molecular differences between normal and malignant cells and using this knowledge to develop new anti-cancer drugs.

Our staff and postgraduate students are based in the Northern Institute for Cancer Research (NICR) or the School of Chemistry. The NICR incorporates the Newcastle Cancer Centre, a unique collaboration between Cancer Research UK and the North of England Children's Cancer Research Fund.

We are a major training base for the next generation of cancer researchers. Our Institute covers many areas of cancer research, including:
-Solid tumours and leukaemias
-Childhood and adult cancers
-Drug discovery and early phase clinical trials

We offer approximately 15 MD, PhD and integrated MRes/PhD studentships each year, including the Newcastle Cancer Centre training programme. Projects in all research areas are available to fully-funded international students.

Members of our postgraduate community come from a variety of subject backgrounds including biological and biomedical sciences, chemistry, genetics, pharmacy, medicine, dentistry and veterinary medicine.

We hold regular postgraduate seminars which you will be required to attend and where you will deliver presentations. You will also attend and present your data annually at national cancer research meetings and at least one international meeting.

Placements

Our Institute has close working relationships with companies in the pharmaceutical and biotechnology sectors.

A number of our studentships are direct collaborations with industrial partners, with opportunities to spend placements with these partners.

Facilities

Our staff and postgraduate students are based in the Northern Institute for Cancer Research (NICR) or the School of Chemistry (medicinal chemistry students).

Our laboratories contain a full range of contemporary genomic, bioinformatic, proteomic, synthetic chemistry and pharmacology equipment, and clinical research facilities.

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- https://www.kent.ac.uk/locations/medway/. This programme builds on a very successful in-house training programme implemented by a major pharmaceutical company. Read more

This course will be held at the Medway Campus

- https://www.kent.ac.uk/locations/medway/

This programme builds on a very successful in-house training programme implemented by a major pharmaceutical company.

It was designed and conceived by pharmaceutical industry experts in drug discovery and will be delivered and assessed by experts in this field at the School of Pharmacy.

The MSc covers how fundamental science is applied to the discovery and development of medicines and the main aims are to:

- provide you with the experience of critically appraising the research questions and techniques that are routine in the pharmaceutical industry workplace

- produce graduates trained in the processes by which fundamental science is linked to the design and development of modern medicines

- provide expert preparation for students who wish to pursue a career in drug discovery, or wish to proceed to a PhD.

Visit the website https://www.kent.ac.uk/courses/postgraduate/736/applied-drug-discovery

Duration: One year full-time (campus based), two years part-time (distance learning)

About Medway School of Pharmacy

Medway School of Pharmacy is one of the few regional schools of pharmacy in the UK, a collaboration between the University of Kent and the University of Greenwich.

The impetus for the formation of the Medway School of Pharmacy came from the local community, who recognised the shortage of qualified pharmacists in all branches of the pharmacy profession in Kent.

The School is now recognised as an established school with accreditation from the General Pharmaceutical Council (GPhC) and the Health and Care Professions Council (HCPC). Graduates are employed in health disciplines in Kent and the south-east and more broadly across the UK.

Course structure

This programme is taught as either a classic one year full-time programme with attendance required on Mondays and Tuesdays for 48 weeks plus an additional study day off-campus, or delivered through distance e-learning using an interactive virtual learning environment on a two-year part-time basis.

The programme comprises 60 credits at certificate level, 60 credits at diploma level and 60 credits at Master’s level. You may choose to end your study at any one of these stages.

Modules

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

Assessment

Assessment is by 100% coursework; including scientific reports, assignments, essays, a research project and portfolio entries.

Programme aims

This programme aims to:

- produce graduates trained in the processes by which fundamental science is linked to the design and development of modern medicines

- teach you an understanding of the drug discovery process

- provide you with expanded training in the biological sciences technical skills that underpin the processes of drug discovery

- provide you with the experience of critically appraising the research questions and techniques they use routinely in the workplace

- develop a variety of postgraduate level intellectual and transferable skills

- equip you with lifelong learning skills necessary to keep abreast of developments in drug discovery

- provide you with opportunities for shared multidisciplinary learning in drug discovery

- give you the experience of undertaking an independent research project

- provide expert preparation for students who wish to pursue and/or further a career in drug discovery, or wish to proceed to a higher degree (PhD) in topics related to the drug discovery process

- provide access to as wide a range of students as practicable irrespective of race, background, gender or physical disability from both within the UK and from overseas.

Research areas

- Chemistry and drug delivery

This group has laboratories with dedicated state-ofthe art drug delivery, nanotechnology, spectroscopy, chromatography and organic synthesis facilities. It brings together researchers in medicinal chemistry and drug design, nanotechnology and materials science, drug delivery and pharmaceutics encouraging a multidisciplinary approach to research. Research covers synthesis and biological evaluation of potential anti-cancer agents, structurebased drug design, QSAR predication of ADMET properties, controlled release, particle engineering, powder technology, pharmaceutical technology, and novel drug delivery systems, with a focus on respiratory drug delivery.

- Biological sciences

This group is housed in recently refurbished laboratories with dedicated state-of-the-art molecular biological, electrophysiological, tissue culture and microscopy facilities. The research is divided into four main themes; infectious diseases and allergy; neuroscience; renal and cardiovascular physiology; and pharmacology. Examples of current work include: investigation of the use of non-pathogenic virus ‘pseudotypes’ to study pathogenic RNA, study of the properties of neuronal potassium channels and their modulation and the development of new therapies for patients that have developed acute kidney injury in collaboration with a major pharmaceutical company.

- Pharmacy practice

This group conducts research in two areas: public health and medicines optimisation, with a particular focus on cardiovascular diseases and mental health. Work in public health includes studies in physical exercise, alcohol, cardiovascular screening and spirometry testing, plus pharmacovigilance. Studies in medicines optimisation include work in dementia, bipolar disorder and stroke, with an emphasis on the patient perspective.

Careers

Graduates who obtain their PhD from Kent or Greenwich are highly sought after by prospective employers, both within the UK and overseas. Destinations for doctoral graduates include university academic departments, research institutes and leading pharmaceutical and biotechnological companies.

The taught postgraduate programmes are designed to promote the continuing professional development by providing sought-after skills. The programmes are beneficial for those who wish to develop their skills and/or to take the next step in their career. While the MSc in Applied Drug Discovery produces elite drug discovery personnel, who can pursue a career in the pharmaceutical industry or academia.

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

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- https://www.kent.ac.uk/locations/medway/. Start. At any time but preferably in September. Our research programme in Pharmacy gives you the integrated, broad-based research training needed to exploit current advances in pharmaceutical and biological sciences and pharmacy practice. Read more

This course will be held at the Medway Campus

- https://www.kent.ac.uk/locations/medway/

Start: At any time but preferably in September

Our research programme in Pharmacy gives you the integrated, broad-based research training needed to exploit current advances in pharmaceutical and biological sciences and pharmacy practice.

Within the school we have a number of home, EU and international postgraduate students who are undertaking doctoral research degrees. Graduates who obtain their PhD from Kent or Greenwich are highly sought after by prospective employers, both within the UK and overseas. Destinations for doctoral graduates include university academic departments, research institutes and leading pharmaceutical and biotechnological companies.

Visit the website https://www.kent.ac.uk/courses/postgraduate/171/pharmacy

About Medway School of Pharmacy

Medway School of Pharmacy is one of the few regional schools of pharmacy in the UK, a collaboration between the University of Kent and the University of Greenwich.

The impetus for the formation of the Medway School of Pharmacy came from the local community, who recognised the shortage of qualified pharmacists in all branches of the pharmacy profession in Kent.

The School is now recognised as an established school with accreditation from the General Pharmaceutical Council (GPhC) and the Health and Care Professions Council (HCPC). Graduates are employed in health disciplines in Kent and the south-east and more broadly across the UK.

Study support

- Postgraduate resources

Postgraduate students have access to all the facilities at the Medway School of Pharmacy, including clinical skills labs and a ‘simulation man’. As the School of Pharmacy is a joint venture between the two universities, students have access to facilities at Kent’s Medway and Canterbury campuses, and the University of Greenwich.

- Dynamic publishing culture

Medway School of Pharmacy has a research culture and as such postgraduate students publish regularly and widely in journals, conference proceedings and books. Among others, they have recently contributed to: International Journal of Pharmacy Practice; Nephron Physiology; Acta Physiologica; Purinergic Signalling; and European Journal of Pharmacology.

- Researcher Development Programme

Kent's Graduate School co-ordinates the Researcher Development Programme for research students, which includes workshops focused on research, specialist and transferable skills. The programme is mapped to the national Researcher Development Framework and covers a diverse range of topics, including subjectspecific research skills, research management, personal effectiveness, communication skills, networking and teamworking, and career management skills

Research areas

The Medway School of Pharmacy houses strong and vibrant research groups that span a range of pharmacy-related areas. Staff have a wealth of research experience, and UK and international links with both industry and academic institutions.

- Chemistry and drug delivery

This group has laboratories with dedicated state-ofthe art drug delivery, nanotechnology, spectroscopy, chromatography and organic synthesis facilities. It brings together researchers in medicinal chemistry and drug design, nanotechnology and materials science, drug delivery and pharmaceutics encouraging a multidisciplinary approach to research. Research covers synthesis and biological evaluation of potential anti-cancer agents, structurebased drug design, QSAR predication of ADMET properties, controlled release, particle engineering, powder technology, pharmaceutical technology, and novel drug delivery systems, with a focus on respiratory drug delivery.

- Biological sciences

This group is housed in recently refurbished laboratories with dedicated state-of-the-art molecular biological, electrophysiological, tissue culture and microscopy facilities. The research is divided into four main themes; infectious diseases and allergy; neuroscience; renal and cardiovascular physiology; and pharmacology. Examples of current work include: investigation of the use of non-pathogenic virus ‘pseudotypes’ to study pathogenic RNA, study of the properties of neuronal potassium channels and their modulation and the development of new therapies for patients that have developed acute kidney injury in collaboration with a major pharmaceutical company.

- Pharmacy practice

This group conducts research in two areas: public health and medicines optimisation, with a particular focus on cardiovascular diseases and mental health. Work in public health includes studies in physical exercise, alcohol, cardiovascular screening and spirometry testing, plus pharmacovigilance. Studies in medicines optimisation include work in dementia, bipolar disorder and stroke, with an emphasis on the patient perspective.

Careers

Graduates who obtain their PhD from Kent or Greenwich are highly sought after by prospective employers, both within the UK and overseas. Destinations for doctoral graduates include university academic departments, research institutes and leading pharmaceutical and biotechnological companies.

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

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