• Birmingham City University Featured Masters Courses
  • University of Northampton Featured Masters Courses
  • University of Surrey Featured Masters Courses
  • University of Bristol Featured Masters Courses
  • Xi’an Jiaotong-Liverpool University Featured Masters Courses
  • Northumbria University Featured Masters Courses
  • Cardiff University Featured Masters Courses
University of Nottingham in China Featured Masters Courses
University of Hertfordshire Featured Masters Courses
Cranfield University Featured Masters Courses
Coventry University Featured Masters Courses
University of Bath Featured Masters Courses
"drug" AND "chemistry"×
0 miles

Masters Degrees (Drug Chemistry)

We have 155 Masters Degrees (Drug Chemistry)

  • "drug" AND "chemistry" ×
  • clear all
Showing 1 to 15 of 155
Order by 
This course provides advanced training in modern organic and medicinal chemistry from conception to production of novel drugs. It enables you to understand and experience the way modern small molecule medicine is developing. Read more
This course provides advanced training in modern organic and medicinal chemistry from conception to production of novel drugs. It enables you to understand and experience the way modern small molecule medicine is developing. You will gain hands-on experience of working within a medicinal chemistry team during your research project.

The course is suitable if you have a background in the chemical or pharmaceutical sciences. It includes 120 credits of taught modules and a 60 credit practical project.

Themes include drug design, metabolism and toxicology with an understanding of synthetic organic chemistry. Building on University research strengths, specialist topics include bio-imaging and modern approaches to chemotherapy. You will develop expertise in drug design as practised in the pharmaceutical industry and in academia.

You will also gain knowledge of modern and experimental therapies developing in the Northern Institute for Cancer Research.

Delivery

The course is delivered through the School of Chemistry in collaboration with the Northern Institute of Cancer Research and the Faculty of Medical Sciences. The School will provide personal study support throughout your course.

Your work is in chemistry and biology laboratories using modern analytical equipment with access to computer clusters, specialist computer software, online resources, an extensive library and dedicated study areas. All teaching takes place at the university's campus in the centre of Newcastle upon Tyne.

Facilities

The School of Chemistry has modern teaching and research facilities along with major research strengths in drug and medicinal chemistry. Our new teaching laboratories, costing £1.9 million, have recently opened.

Read less
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/

Read less
Chemistry research at Swansea University is vibrant and covers a wide range of research areas and interests, and will be growing at a fast pace over the next 2-3 years. Read more

Chemistry research at Swansea University is vibrant and covers a wide range of research areas and interests, and will be growing at a fast pace over the next 2-3 years. It is focused on 4 themes: Energy, Health, New and Advanced Molecules and Materials, and Water and the Environment. These research initiatives transcend the traditional discipline boundaries, integrate the core areas of inorganic, organic, physical and analytical chemistries and intersect with other scientific disciplines, engineering and medicine.

Key Features of MSc by Research in Chemistry

The new Department of Chemistry has excellent, purpose-built modern laboratories and has access to a diverse type of laboratories research infrastructures to develop its research. For example, high-quality, high-impact chemistry research is already taking place in World Class Centres based in Swansea such as The Centre for NanoHealthThe Institute of Mass SpectrometryThe Institute of Life SciencesThe Energy Safety Research InstituteMultidisciplinary Nanotechnology CentreThe Centre for Water Advanced Technologies and Environmental Research and The Materials Research Centre. The integration of the new Chemistry Department with Engineering, the Medical School and other departments in the College of Science provides an environment of research excellence and allows our chemistry students and research staff to invent, innovate and develop products in a way that is best suited to research in the 21st century and the need to generate disruptive, step-change advances with impact on current global challenges.

Department of Chemistry Research Group:

Energy: One of the key areas where advances in chemistry will be needed is in providing solutions to the global energy challenge. Chemistry research in Swansea University is participating in fundamental and applied research initiatives focused on: 

  • Conversion and storage of electrochemical and solar energy 
  • Capture, storage, and chemical conversion of carbon dioxide 
  • Development of new molecules, materials and nanotechnologies related to energy production, conversion, transport, and storage and their incorporation into devices.
  • Electron transfer reactions
  • Development and implementation of advanced characterisation techniques for acquiring in-depth understanding of photovoltaics, batteries and processes, which enable improvement in performance.
  • Routes for rapid processing and manufacturing at scale.
  • Optimized utilization of fossil energy 
  • Hydrogen as an energy vector

Health: Chemistry research provides new routes to more effective, cheaper and less toxic therapies and to non-invasive disease detection and diagnosis tools – a requirement to transform the entire landscape of drug discovery, development and healthcare, which is unaffordable and needs to benefit more patients. The chemistry research laboratories for this theme are adjacent to Swansea Medical School – which ranked 1st in the UK for research environment, and 2nd for overall research quality in the REF 2014.

Current chemistry research includes: 

  • Nanoparticle-based drug delivery
  • Antibody-drug conjugates
  • Nanoparticle-enabled chemoimmunotherapy and immunoengineering
  • Chemical systems for cell and tissue imaging
  • Stimuli-responsive and adaptive systems for drug activation and release
  • Construction of biofunctional artificial motor systems
  • Bioelectronic medicines and sensors
  • Mass spectrometric analysis of clinical samples, lipids, proteins and natural products
  • Pharmaceutical analysis and analytical technologies for medical/chemical analysis
  • Magnetic nanoparticles for magnetic resonance and multimodal imaging
  • Silicon processing, microfabrication and microelectronic fabrication
  • Self-assembly of colloids at interfaces and the use of colloids and nanoparticles dispersed in complex biological fluids
  • Microneedles for transdermal blood sampling and drug delivery
  • Biosensors – surface functionalization, fluorescence detection, electrochemistry, chemical sensing and lab-on-a-chip
  • Microfluidics and MEMS 
  • Studying structure, dynamics and function of enzymes as a route to understanding and controlling nature's chemistry
  • Natural products biosynthesis (particularly involving compounds with antibiotic, antifungal, or other medically relevant activity).

New and Advanced Molecules and Materials: There is major interest in synthesing, designing and controllling molecular and macromolecular assemblies at multiple length scales. In Swansea this research involves use of: 

  • Soft condensed matter including surfactants, colloids and polymers
  • Synthesis and characterization of transition metal-based and organic dye molecules for application in dye sensitized solar cells
  • Materials for efficient multiphoton absorption and upconversion 
  • Natural products
  • Molecular recognition and self-assembly to generate novel materials
  • Continuous flow synthesis
  • Molecular scale and nanoscale characterisation of ordered and amorphous assemblies
  • Development of nanocomposites comprising metallic nanoparticles and hydrogels
  • Autonomous and remotely guided micro- and nanoscale objects
  • Studying and tuning the characteristics of nanomaterials and biomaterials 

Water and the Environment: Chemistry at Swansea university has a strong profile in the development of analytical tools for measuring environmental impact, environmental impact assessment of polymer-based materials through their lifetime (including the effects of recycling and biopolymers), technologies for the efficient removal of environmentally harmful materials (and thus reduced emissions per output of discharge), membrane technologies and new methodologies for desalination, and for dewatering and killing pathogens for sanitation applications and the use of new molecules and materials for photocatalytic water splitting and development of self-propelled micro and nanomotor systems for environmental remediation. In collaboration with the Biocontrol and Natural Products (BANP) group in the Department of Biosciences, there is also growing research interest around the characterisation and application of natural products, in particular those derived from fungi and microalgae, to provide therapeutics and nutraceuticals and to act as agents for biocontrol and bioremediation.

Facilities in the Department of Chemistry

Our new state-of-the-art teaching laboratories are being built as part of a multi-million pound investment to create a chemistry hub for the high quality Chemical Sciences research being carried out across the Colleges of Science, Engineering and Medicine.

Careers for Chemistry Graduates

A chemistry qualification opens the door to a wide range of careers options, both in and out of the lab. There are endless interesting and rewarding science-based jobs available – these can be in research, outdoors or in other industries you might not have thought of. Please visit the Royal Society of Chemistry website for details. 

Find out more about the huge range of jobs in chemistry by exploring the job profiles on the Royal Society of Chemistry website (eg Cancer Researcher, Flavourist & Innovation Director, Chief Chemist, Sustainability Manager, Fragrance Chemist, Household Goods Senior Scientist, Analytical Scientist, and many more).



Read less
Help improve human or animal health through creating new or more effective drugs and medicines. Learn the research processes used to identify drug targets and develop new therapeutics. Read more

Help improve human or animal health through creating new or more effective drugs and medicines. Learn the research processes used to identify drug targets and develop new therapeutics.

Your studies will combine the biological sciences with chemistry, giving you the skills to target, design, synthesise, create and assess new drugs. You'll also learn about protecting intellectual property, assessing the financial viability of drugs and the pre-clinical and clinical trial processes.

Tailor your studies to your strengths, interests and career goals. You'll learn a mix of academic and practical skills that are closely aligned to the needs of industry.

The Master of Drug Discovery and Development is best suited to very able students with backgrounds in chemistry or relevant life-science subjects such as biochemistry, biomedical science, pharmacy or pharmacology. It is an intensive one-year taught programme, unique in New Zealand.

Learn from the best

Learn from academics and professionals who are leaders in the field and have experience in successfully taking drugs to market. Each course is taught by at least three academics so you'll be exposed to a wide range of expertise.

Drug Discovery and Development is taught by the Schools of Chemical and Physical Sciences and Biological Sciences in collaboration with the University's Ferrier Research Institute and the Centre for Biodiscovery.

You'll be able to take advantage of the research expertise of the Ferrier Research Institute in drug design and development, and if you're doing a Master's, you'll be working alongside the more than 30 scientists who make up the largest carbohydrate research team in the world. The Institute also has its own manufacturing facility so you'll have the opportunity to observe the drug development process from discovery to product.

You'll also benefit from the programme's links with the Centre for Biodiscovery where you will interact with the research teams that are actively discovering, designing and assessing novel bioactive compounds.

Drugs in the real world

Get wise to the real-world issues facing pharmaceutical development and make the most of the hard-earned experiences of staff who have worked in the local and international biotech industry. Learn not only how to handle chemicals on a large scale, but to develop the mindset to do this in a way that is safe, reliable and robust—so you end up providing medicines that will change people’s lives.

Victoria offers three postgraduate qualifications in Drug Discovery and Development. Choose the one that suits your career goals, time constraints and financial situation.

  • Master of Drug Discovery and Development
  • Postgraduate Diploma in Drug Discovery and Development
  • Postgraduate Certificate in Drug Discovery and Development

If you begin by enrolling in the Certificate or Diploma programme you can continue on to complete your Master's. Or if you enrol in the Master's but can't complete it, for whatever reason, you may have completed enough points to be awarded a Certificate or Diploma.

What you'll study

Each qualification includes the core courses DRGD 401 Chemical Biology and Drug Discovery, and a choice between DRDG 402 Drug Design or CHEM 421 Organic Chemistry and Bio-organic Chemistry.

After that you'll choose from selected courses from the study areas of Drug Discovery and Development, Biomedical Science, Biotechnology, Chemistry, Clinical Research and Microbiology.

All three qualifications give you the opportunity to do at least some research.

Postgraduate Certificate

You'll complete four courses worth 60 points made up of the two core courses and two further choices.

Postgraduate Diploma

You're likely to take seven courses that will include the two core courses, your elective options and the 30-point Research Preparation course.

Master's

You'll study for your Master's in two parts over three trimesters. In Part 1, the first two trimesters, you're likely to take seven courses that will include the core courses and a 30-point Research Preparation course.

In Part 2, you'll complete a full research project. Choose between DRDG 561 Applied Research Project, where you'll complete one or more problem-solving projects, or DRGD 590 Research Project, where you'll focus on medicinal chemistry and the formulation of active pharmaceutical products. In some cases you may be able to replace the research project with the thesis course DRGD 595.

Your Master's may be endorsed with a specialisation in either Drug Discovery, Drug Development or Chemical Biology. Check the requirements to find out what you need to do for these.

Workload and duration

You can expect a workload of 40–45 hours a week for much of your studies.

The MDDD can be completed in 12 months full time, or in two years of part-time study but you'll need to discuss this option with the programme directorfirst. The Diploma will take you two trimesters and the Certificate one trimester.

Location

You'll study at Wellington's Kelburn campus where you will have access to state-of-the-art research facilities. Students doing a research programme will also work in partnership the world-renowned Ferrier Research Institute in Lower Hutt.

Research topics

Be part of a dynamic and collaborative scientific research community. Past students' research areas in drug discovery and development have included:

  • development of a new scaled-up catalytic process for a high value fine chemical
  • isolation and characterisation of a novel bioactive from a New Zealand marine organism
  • formulation of a novel therapeutic for cancer immunotherapy.

Community

Become part of an active community of scientists. Postgraduate study at Victoria will help you build valuable relationships and networks with peers, university staff and future colleagues. You'll have unprecedented access to world industry leaders who visit as guest lecturers and run seminars with students.

Careers

You'll have the broad skills you need to work in drug discovery in companies, universities, research institutes or with drug regulatory authorities. You might work within the pharmaceutical, bioanalytical or chemical industries, or take your skills into nutraceuticals or agrichemicals.



Read less
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.

Read less
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.

About this degree

The programme provides a thorough foundation in drug design, advanced organic synthesis and biological chemistry, 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 five core modules (75 credits) and a research project /dissertation (105 credits).

Core modules

Students take five 15-credit modules including two Master's-level chemistry modules, one transferable/research skills module, one analytical chemistry module, and one professional development module.

  • Transferable/Research Skills
  • Analytical Chemistry
  • Biological Chemistry
  • Principles of Drug Design
  • Professional Development

Optional modules

There are no optional modules for this programme.

Dissertation/report

Students will undertake a laboratory-based research project lasting 10months. 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.

Further information on modules and degree structure is available on the department website: Organic Chemistry: Drug Discovery MRes

Funding

Students can be self-funded or find sponsorship from funding agencies such as research councils, the European Union, industry or charities.

There are also a number of Graduate School Scholarships and departmental bursaries and prizes available.

For a comprehensive list of the funding opportunities available at UCL, including funding relevant to your nationality, please visit the Scholarships and Funding website.

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.

Why study this degree at UCL?

This degree involves a cutting-edge research project in the laboratory a member of research staff at UCL Chemistry. This is one of the leading research departments in the UK with staff undertaking world-leading research in all areas of chemistry and chemical biology.



Read less
This programme is designed to provide comprehensive training in analytical chemistry and its implementation in a variety of fields including biomedical, pharmaceutical, food and environmental analysis. Read more
This programme is designed to provide comprehensive training in analytical chemistry and its implementation in a variety of fields including biomedical, pharmaceutical, food and environmental analysis.

The programme comprises a broad range of modules covering all the major analytical techniques, complemented by studies in transferable and professional skills, with the option to study aspects of medicinal and pharmaceutical chemistry if desired.

Core study areas include research methods, separation techniques, mass spectrometry and associated techniques, spectroscopy and structural analysis, professional skills and dissertation and a research training project.

Optional study areas include sensors, pharmacokinetics and drug metabolism, drug targets, drug design and drug synthesis and innovations in analytical science.

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

Programme modules

Compulsory Modules
Semester 1:
- Research Methods
- Separation Techniques
- Pharmacokinetics and Drug Metabolism

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

Selected Optional Modules
Semester 1:
- Mass Spectrometry and Associated Techniques
- Drug Targets, Drug Design and Drug Synthesis
- Sensors

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

Assessment

Examination and coursework.

Careers and further study

Careers in a variety of industries including pharmaceuticals, chemicals, food, environmental management, contract analysis laboratories, public laboratories, regulatory authorities and instrument manufacturers in either technical or marketing functions or 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/analytical-chemistry/

Read less
- 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/

Read less
DRUG INNOVATION. A UNIQUE PROGRAMME. The Dutch Master's Selection Guide (Keuzegids Masters 2017) ranked this programme as the best in the field of Chemistry in the Netherlands. . Read more

DRUG INNOVATION: A UNIQUE PROGRAMME

The Dutch Master's Selection Guide (Keuzegids Masters 2017) ranked this programme as the best in the field of Chemistry in the Netherlands. 

Drug Innovation is about:

  • developing new drugs to combat drug-resistant microorganisms
  • using gene or protein technologies to create therapies targeted at individual patients
  • finding a way to imprint the immune system to increase tolerance
  • exploring the relationship between gut microbes and brain disease
  • learning how to use proteomics to study stem cell development
  • reducing the side effects of treatment by finding new ways to deliver drugs directly onto the tumor
  • updating and speeding up the drug regulatory process

The Master’s in Drug Innovation programme focuses on diagnostics and the improvement and management of small molecule and biomolecular drugs. Drug innovation covers many topics such as the development of new vaccines and the study of antibodies, gene therapeutics, and medical nutrition. Once developed, a new drug then needs to go through approval, which raises a whole new set of challenges, for example the establishment of new methods and criteria for evaluating the quality, efficacy, safety, and performance of the drug.

INTERDISCIPLINARY PROGRAMME

This broad, interdisciplinary programme is open to graduates from a wide range of disciplines such as chemistry, biology, pharmaceutical sciences, biomedical sciences, or medicine.

MANY ELECTIVE COURSES

Our programme offers a diverse suite of elective courses. This means you can concentrate on the topics of most interest to you. You will also take an internship with one of the research teams working on drug innovation at Utrecht University. This work may lead to publication in scientific journals within the field or new drug patents or protocols.

Graduates of this programme may go on to undertake research in drug innovation at universities, in the pharmaceutical or and biotechnology industry or to work in science or healthcare.

PROGRAMME OBJECTIVE 

Programme

Drug innovation is an interdisciplinary field, which pulls together expertise from chemical, biological and medical sciences. This interdisciplinarity is central to the search for new solutions to currently incurable diseases. You will contribute to this field by undertaking two internships over a total of 15 months and submitting a writing assignment.

Graduated?

After graduation, you will have the skills needed to translate a drug-related problem into a relevant research question and will also be able to design and perform the research needed to solve this question. Finally, you will also be able to critically reflect on your own research and report on it, both verbally and in writing. These skills are highly transferable and will enable you to work independently within a competitive labour market.

TRACKS



Read less
OVERVIEW. The. Oncology Drug Discovery MSc. course is designed to provide an insight into how existing and future drug targets are identified from biological samples isolated from the cancer clinic. Read more

OVERVIEW

The Oncology Drug Discovery MSc course is designed to provide an insight into how existing and future drug targets are identified from biological samples isolated from the cancer clinic. This will include an industrial viewpoint into what makes an interesting target and how, through an iterative process, this target is validated. In addition, lectures will be provided to discuss how ‘hit’ compounds are identified, in both the academic and industrial setting, using compound screen assays and fragment based screening technologies. We will also provide an insight in computational methods for generating chemical ‘hits’. The module will also cover how these ‘hit’ compounds are prosecuted into tool compounds or Lead Optimisation candidates (LO), both historic and modern, that are used to further validate a potential drug target.

During this second module we will provide an insight into the challenges of moving a compound from an LO candidate to a pre-clinical candidate. How bio-marker companion tests are developed, validated and are used to underpin clinical trials. The lectures will also provide a keen insight into novel formulation strategies currently under development within Queen’s University Belfast. In addition, we will also provide an insight into the development of bio-therapeutics, such as antibodies, that are proving to be a powerful alternative to small molecule based therapeutics.

For further information email  or send us a message on WhatsApp

ONCOLOGY DRUG DISCOVERY HIGHLIGHTS

The strong links between us and the biotech and bio-pharmaceutical sectors provides a stimulating translational environment, while also expanding your career opportunities.

GLOBAL OPPORTUNITIES

INDUSTRY LINKS

  • Research projects will be provided by both academic staff and local biotech companies in ground-breaking research areas with a strong focus on clinical applications.

WORLD CLASS FACILITIES

  • The Oncology Drug Discovery course will be taught and mentored within the Centre for Cancer Research and Cell Biology: a purpose-built institute at the heart of the Health Sciences Campus, boasting state-of-the-art research facilities.

INTERNATIONALLY RENOWNED EXPERTS

  • We have an international reputation in this area, achieved through: high-impact peer review publications significant international research funding, the establishment of successful spin-out companies.

 

COURSE STRUCTURE

Research Project

  • You will undertake a lab based project in a number of different facets of the drug development, such as hit identification, hit compound development and therapeutic antibody development pathway working with both academic and biotech groups.Semester 1

Research Translational: from Concept to Commercialisation (Full Year)

  • This module covers the principles of disease biology and new technological developments that increase our understanding of disease processes. It develops an appreciation of the importance of innovation, business awareness and leadership skills in the translation of discovery science to clinical implementation.

Diagnosis and Treatment of Cancer

  • This module provides a comprehensive overview of the diagnosis and treatment of the common solid and haematological malignancies, including breast, ovarian, genitourinary and gastrointestinal cancers as well as the leukaemias

Cancer Biology

  • This module provides a comprehensive overview of the fundamental principles of carcinogenesis, highlighting how normal control processes are bypassed during tumour formation. The pathogenic mechanisms to be discussed will range from genomic alterations in key gene families, to epigenetic mechanisms of gene control, alterations in kinase activities or protein turnover, or activation of aberrant phenotypes such as invasion and angiogenesis.Semester 2

Target Identification and Development in Drug Discovery

  • This module describe how novel drug targets are identified and validated and identifies how biochemical assays are developed and employed in the drug discovery process. It also evaluates the alternative approaches used in the drug discovery to identify new chemical matter. It describes and defines chemical approaches used in developing ‘hit’ chemical compounds and identifies drug target classes and their drug-like pharmacophores.

Drug optimization, drug delivery and clinical trials

  • This module evaluates the issues associated the drug development process and describes the development, validation and use of bio-markers in the drug discovery process. It discusses the practices employed in clinical trials and defines the processes employed in licensing of new chemical equity and the role it plays in the drug discovery process.

For further information email  or send us a message on WhatsApp



Read less
* We still have a position on the course starting in September 2018 – this will lead to a placement in Synthetic Organic Chemistry. Read more

* We still have a position on the course starting in September 2018 – this will lead to a placement in Synthetic Organic Chemistry. Please apply by Friday 29 June *

Overview

Our pioneering two-year MSc programme is unique in the UK, and builds on the foundations of our very successful one-year programme in Drug Discovery and Pharmaceutical Sciences, to equip students with an in-depth knowledge of all aspects of drug discovery, and industry standard training. 

The course is designed to develop graduates who have exceptional scientific understanding and a host of transferable skills, including leadership skills. It is therefore especially recommended to high-achieving and ambitious students seeking an opportunity to gain extensive hands-on training in an industrial environment, working as part of a multidisciplinary team.

The course blends the two fundamental disciplines underpinning drug discovery and provides students with the opportunity to practise background theory within the productive, research-led environments offered by the School of Pharmacy. This school has world-leading expertise in the areas of drug discovery and pharmaceutical science, and students on this course will have the chance to learn directly from staff at the forefront of the field.

The course is technology-rich, using online learning packages to supplement face-to-face teaching and innovative assessment methods.

Placement year

The second year of the course has been developed in conjunction with the pharmaceutical industry to ensure currency and relevance, and to increase the future employability of graduates. Our aim is to train future leaders in the pharmaceutical sector.

The placement year with one of our industrial partners is arranged and guaranteed upon completion of a successful application and interview process. You will pay reduced tuition fees for the second year of the course, as you focus on your industrial training.

Due to limited places available, students who are unable to join the two-year programme will automatically be considered for our Royal Society of Chemistry accredited one-year programme, which includes the same disciplines underpinning drug discovery and research-led environment in which to practise the theory. 

Develop your skills

The overall aim of the MSc is to develop knowledge and understanding, cognitive skills, key skills and practical and professional skills in the area of Drug Discovery and Pharmaceutical Science. The overall drug discovery process from ‘concept to clinic’ provides the reference point for the education and training delivered in the more specific scientific and regulatory aspects.

Students will, therefore, be able to develop an understanding of the scientific principles underlying the main topic areas housed within the arena of drug discovery. In addition, upon completing the degree students will be able to make effective use of electronic communication and information search and retrieval to facilitate development of key critical skills with which to assess and analyse a broad array of scientific literature.

When taken together, the ethos of the programme is therefore to:

  • instil, develop and encourage an independent approach to learning, through initiative and self-motivation
  • provide the education and training required to become a translational scientist; with pertinent knowledge of basic and clinical science that can be applied to drug discovery and development
  • instil a critical understanding of disease/disorder biology and how it impacts upon human health
  • provide the necessary knowledge of chosen areas of normal and abnormal pharmacology and bodily function to equip the student with an understanding of how and why drugs are either rejected or taken forward for future development
  • present physicochemical and pharmacological principles alongside the regulatory processes necessary for new medicine discovery and entry into the clinic
  • contextualise this knowledge and principles to the process of drug design and development and therefore equip the graduate to apply knowledge to practical problems in pharmacology, drug discovery and pharmaceutical science
  • provide students with the practical skills and experience via a year-long training placement to excel in future leadership roles

Please visit the online prospectus for detailed module information.

Application process

Applicants who meet the eligibility criteria will be shortlisted for interview based on their whole application, including the personal statement. Your personal statement should include:

  • Why you are applying for this course, and why to the University of Nottingham in particular
  • Why you wish to pursue a career in drug discovery
  • How this course will help you achieve your long-term career goals, and why the industrial placement is key to this
  • What makes you suitable for this course compared to other applicants

The interview will include a technical component, which will involve questions relating to theoretical organic chemistry, synthesis and retrosynthesis. The final offer of a place will depend on the availability of placements.

To secure your place, you will need to pay a £2000 deposit. This will form part of your conditional offer as there are a limited number of placements offered in advance by providers. Once the deposit is paid and any other offer conditions are met, your place on the course is guaranteed. The deposit will be used to offset your tuition fee for the first year.

If you are unable to secure a place on the two-year course, after meeting initial eligibility criteria, you will be guaranteed an offer for the one-year course (which is accredited by the Royal Society of Chemistry). This course incorporates the same high quality taught module component but replaces the industrial placement year with a three-month research project at the University. 

Careers

Graduates can expect to move into a range of scientific careers, particularly with global pharmaceutical companies and pharmaceutical SMEs. Strong industrial links to the course will further enhance students’ employability.

The MSc also provides a strong grounding for students wishing to subsequently study for a PhD in a related subject area.



Read less
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 the 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 the 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.

About this degree

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 one core modules (15 credits), four optional modules (60 credits) and a dissertation/report (105 credits).

Core module

  • Ethics and Regulation of Research

Optional modules

Students select four of the following.

  • Practical Laboratory Research Skills
  • Bioinformatics and Structural Biology as applied to Drug Design
  • The Biology of Drug Discovery Programmes 1
  • Biological Molecules as Therapeutics - Antibodies, siRNA, and Stem Cells
  • The Biology of Drug Discovery Programmes 2: Latest Advances
  • Fragment-based Drug Design
  • Target Selection - Commercial and Intellectual Property Aspects
  • Target Selection - Scientific Grounds
  • Cheminformatics and Computer Drug Design

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.

Further information on modules and degree structure is available on the department website: Drug Design MRes

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. Drug Design MRes graduates 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.

Research Excellence Framework (REF)

The Research Excellence Framework, or REF, is the system for assessing the quality of research in UK higher education institutions. The 2014 REF was carried out by the UK's higher education funding bodies, and the results used to allocate research funding from 2015/16.

The following REF score was awarded to the department: Division of Medicine

80% rated 4* (‘world-leading’) or 3* (‘internationally excellent’)

Learn more about the scope of UCL's research, and browse case studies, on our Research Impact website.



Read less
Developed in response to the Engineering and Physical Sciences Research Council (EPSRC), and after extensive consultation with industry, this programme is designed for graduates in chemistry or closely related disciplines who wish to contribute to drug development and analysis, a process that requires multidisciplinary skills. Read more
Developed in response to the Engineering and Physical Sciences Research Council (EPSRC), and after extensive consultation with industry, this programme is designed for graduates in chemistry or closely related disciplines who wish to contribute to drug development and analysis, a process that requires multidisciplinary skills.

The programme comprises a broad range of modules covering the major aspects of analytical and pharmaceutical chemistry, complemented by studies in transferable and professional skills.

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

Optional study areas include mass spectrometry and associated techniques, drug targets, drug design and drug synthesis, sensors, innovations in analytical science and medicinal chemistry.

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

Programme modules

Compulsory Modules
Semester 1:
- Research Methods
- Separation Techniques
- Pharmacokinetics and Drug Metabolism

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

Selected Optional Modules
Semester 1:
- Mass Spectrometry and Associated Techniques
- Drug Targets, Drug Design and Drug Synthesis
- Sensors

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

Assessment

Examination and coursework.

Careers and further study

The programme is for those who wish to extend their knowledge in a particular area or broaden their field in order to increase their career prospects.

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/analytical-pharmaceutical-science/

Read less
The principal component of this degree is an intensive novel research project providing 'hands-on' training in methods and techniques at the cutting edge of scientific research. Read more

The principal component of this degree is an intensive novel research project providing 'hands-on' training in methods and techniques at the cutting edge of scientific research. The programme is particularly suitable for those wishing to embark on an academic career, with a strong track record of students moving into graduate research at UCL and elsewhere.

About this degree

Students develop a systematic approach to devising experiments and/or computations and gain familiarity with a broad range of synthetic, analytical and spectroscopic techniques, acquiring skills for the critical analysis of their experimental and computational observations. They also broaden their knowledge of chemistry through a selection of taught courses and are able to tailor the programme to meet their personal interests.

You will undertake Chemistry modules to the value of 180 credits.

The programme consists of core literature (30 credits) and research projects (90 credits), and a research and professional skills development module (15 credits) and optional taught modules (45 credits in total). Optional modules are chosen in consultation with your research advisor.

Core Modules

All students undertake a literature project (30 credits) and a research dissertation (90 credits), which are linked. In addition students take a module (15 credits) to develop their research and professional skills.

  • Literature Project
  • Research Project
  • Transferable Skills for Scientists

Optional Modules

Students choose three optional modules from the following:

  • Advanced Topics in Energy and Environmental Science
  • Advanced Topics in Physical Chemistry
  • Biological Chemistry
  • Concepts in Computational Chemistry
  • Frontiers in Experimental Physical Chemistry
  • Inorganic Rings, Chains and Clusters
  • Intense Radiation Sources in Modern Chemistry
  • Topics in Quantum Mechanics
  • Numerical Methods in Chemistry
  • Pathways, Intermediates and Function in Organic Chemistry
  • Principles of Drug Design
  • Principles and Methods of Organic Synthesis
  • Simulation Methods in Materials Chemistry
  • Stereochemical Control in Asymmetric Total Synthesis
  • Structural Methods in Modern Chemistry
  • Synthesis and Biosynthesis of Natural Products
  • New Directions in Materials Chemistry

Dissertation/Report

All students undertake an independent research project which features an oral examination and culminates in submission of an extended dissertation (90 credits).

Teaching and Learning

The programme is delivered through a combination of lectures, seminars, tutorials, laboratory classes and research supervision. Assessment is through the dissertation, unseen written examinations, research papers, a written literature survey, and an oral examination. All students will be expected to attend research seminars relevant to their broad research interest.

Further information on modules and degree structure is available on the department website: Chemical Research MSc

Careers

This MSc is designed to provide first-hand experience of research at the cutting-edge of chemistry and is particularly suitable for those wishing to embark on an academic career (i.e. doctoral research) in this area, although the research and critical thinking skills developed will be equally valuable in a commercial environment.

Recent career destinations for this degree

  • Project Manager, Jiang Clinic
  • Secondary School Teacher (Chemistry), Loyang Secondary School
  • PhD in Engineering, Imperial College London

Careers data is taken from the ‘Destinations of Leavers from Higher Education’ survey undertaken by HESA looking at the destinations of UK and EU students in the 2013–2015 graduating cohorts six months after graduation.

Why study this degree at UCL?

With departmental research interests and activities spanning the whole spectrum of chemistry, including development of new organic molecules, fundamental theoretical investigations and prediction and synthesis of new materials, students are able to undertake a project that aligns with their existing interests.

Students develop crucial first-hand experience in scientific methods, techniques for reporting science and using leading-edge research tools, as well as further essential skills for a research career.

Research Excellence Framework (REF)

The Research Excellence Framework, or REF, is the system for assessing the quality of research in UK higher education institutions. The 2014 REF was carried out by the UK's higher education funding bodies, and the results used to allocate research funding from 2015/16.

The following REF score was awarded to the department: Chemistry

94% rated 4* (‘world-leading’) or 3* (‘internationally excellent’)

Learn more about the scope of UCL's research, and browse case studies, on our Research Impact website.

Application and next steps

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

Who Can Apply?

The programme is suitable for students wishing to progress to a research degree in chemistry or those seeking to acquire research skills which are valued in a commercial environment.

Application Deadlines

All applicants

27 July 2018

Applicants can select the research projects in Computational, Inorganic, Organic or Physical Chemistry. In the application cover letter students are asked to indicate which area(s) of chemistry they are interested in studying, clearly indicating why they chose this particular area, and indicating (at least) three academic members of staff they are interested in working with.

For more information see our Applications page.



Read less
Unique in Europe, this course combines biomedicine and pharmaceutical science to prepare you for a rewarding career in the pharmaceutical, bioscience or healthcare sectors. Read more
Unique in Europe, this course combines biomedicine and pharmaceutical science to prepare you for a rewarding career in the pharmaceutical, bioscience or healthcare sectors.

If you're interested in a career in the fascinating and challenging world of drug design, this is the course that will take you there.

Rather than presenting just one of the disciplines used in the field, this postgraduate degree, unique in Europe, blends the subjects you need - biomedicine and pharmaceutical science - into one comprehensive course that focuses on the integration of modern organomedicinal chemistry and molecular biology.

You’ll study various steps involved in developing and creating effective drugs, from concept to clinic, including the theories and practical applications of chemical drug design and immunology, pharmacology and molecular biology. Learning will be based on emergent technology from academic research and how it is applied to the drug development process, identification of drug targets, and development of effective drugs via reference to the relevant biological systems and pathways.

See the website http://www.napier.ac.uk/en/Courses/MSc-Drug-Design-and-Biomedical-Science-Postgraduate-FullTime

What you'll learn

This course provides the knowledge, understanding and practical experience you’ll need to forge a rewarding career in research and development in the pharmaceutical, bioscience or healthcare sectors. You’ll develop in-depth understanding of disease processes and molecular targets and an ability to apply this knowledge and theory to key aspects of drug design and biomedical science.

Equipped with the ability to follow developments in the field, you’ll learn to apply them to your work and make innovative contributions to the industry that will benefit others. Complex issues often arise in this field: you’ll acquire the skills necessary to make informed judgements and effectively communicate decisions.

There is an emphasis on developing your practical laboratory skills with various opportunities for hands-on experience in a range of current techniques and practices. In your final trimester you’ll undertake an independent project within a vibrant biomedical or drug design research team, allowing you to apply and further develop your technical, research and professional skills. There may be the opportunity to conduct your research project externally in a relevant organisation or industry in the UK or overseas.

You’ll also develop key skills including communication, problem solving, team work, project management, and leadership. You’ll learn through interactive lectures, workshops, tutorials, site visits and laboratory sessions, and by engaging with guided independent study. A variety of assessment tools are used to enhance and evaluate your learning.

This programme is also available as a Masters by Research: http://www.napier.ac.uk/research-and-innovation/research-degrees/courses

Modules

• Current practice in drug development
• Advanced immunology
• Molecular pharmacology and toxicology
• Research skills
• Quality Control and Pharmaceutical Analysis or Biotechnology and Drug Discovery
• Drug design and chemotherapy
• Research project

Study modules mentioned above are indicative only. Some changes may occur between now and the time that you study.

Careers

The rapidly developing pharmaceutical, bioscience and healthcare sectors all need qualified drug discovery or biomedical scientists. This course is your fastest and most effective route to a successful career in drug design.

You could establish a laboratory-based career with global pharmaceutical companies, developing biotechnology companies, contract drug testing, hospitals, NHS, local government or health and safety divisions.

Alternatively, further studies to PhD level are available at institutions all over the world leading to an academic career.

How to apply

http://www.napier.ac.uk/study-with-us/postgraduate/how-to-apply

SAAS Funding

Nothing should get in the way of furthering your education. Student Awards Agency Scotland (SAAS) awards funding for postgraduate courses, and could provide the help you need to continue your studies. Find out more: http://www.napier.ac.uk/study-with-us/postgraduate/fees-and-funding/saas-funded-courses

Read less

Show 10 15 30 per page



Cookie Policy    X