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Drug Discovery Science
School of Mathematical and Physical Sciences,
Faculty of Science
Course description
This course covers the drug discovery and design techniques used in the pharmaceutical industry. You’ll study topics such as pharmacology, toxicology and genomics, as you learn how target molecules to treat specific diseases are identified, characterised and optimised for potential clinical trials.
Taught by world-leading scientists from across chemistry, biology and medicine, our Drug Discover Science MSc gives you access to state-of-the-art screening and analysis facilities.
Your training will cover the fundamental chemistry and biology of protein interactions, their role in disease and how drugs affect the human body. You’ll learn about computer-aided drug design techniques, used to predict how well a potential drug might work, and screening technologies for testing a drug’s effect on its molecular targets.
Modules
Core modules:
- Statistics and laboratory techniques
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The module covers techniques and analytical methods commonly used by most researchers in molecular biology and drug discovery sciences. Students learn the importance of experimental design and application of statistical methods for power and significance calculations for different types of experiment. In practical laboratory classes, students are shown how to perform a series of techniques that are frequently used in biology and chemistry and analyse their data statistically and present results in a formal laboratory notebook.
15 credits - Research, Presentation and Professional Skills
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This module aims to prepare students to become professional scientific researchers ready to conduct a research project. Students will be taught how to retrieve and critically assess the existing literature on a particular research topic and to communicate this as a scientific review. They will learn about the attributes of an ethical researcher, scientific method and how to undertake research safely and responsibly and how to manage data. In addition, students will acquire professional skills relevant to their future employability and learn how to present scientific information. Students will undertake a training needs analysis supported by an experienced researcher so that they can take charge of their own development. This will allow them to tailor their subsequent training to the project they are about to undertake and to their wider individual professional and researcher development. On completion of the module students will have produced a portfolio of work that will form the foundations of their training as a professional researcher.
30 credits - Drug Design, Pharmacology & Medicinal Chemistry
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This module will provide an in-depth discussion of relevant disease mechanisms and strategies that can be used to optimise the pharmacodynamic, pharmacokinetic properties of drugs; and how drugs/analogues can be designed using computer-aided drug design (CADD) software.
30 credits - Drug Discovery Research Project
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For this module, students complete an extended and independent research project working as a member of a team to solve a problem at the cutting edge of drug discovery. They receive specialist training to help them develop the advanced practical skills they need for their project, and have access to state-of-the-art equipment and facilities. They also put their previous research training and transferable skills into practice through literature searches, communicating their work and presenting their findings
60 credits
Optional modules:
A student will take 45 credits (three modules) from this group.
- The Biotech and Pharmaceutical Industry
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This lecture module will be taught by professionals from a wide range of companies in the drug industry and from the business services team here at the University of 91̽»¨. The course will teach students the major steps in the drug discovery process including; screening, development, testing, small molecule manufacture, venture capital funding, patent law, the growing field of contract research and the roles each company has within this industry. Students will learn directly from specialists within these fields. From the 91̽»¨ business team, the students will learn how new ventures are started from University and the process of generating new spin out companies.
15 credits - Genomic Approaches to Drug Discovery
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The module will teach students the basis of small molecule and functional genetic screens, focusing on human disease. Students will learn about the theory and practice of automated small molecule and genetic screens. Examples of screening methods that will be covered include traditional small molecule screens, modern functional genomics and high throughput phenotypic screens. The emphasis will be to appreciate every step that is involved in this process, from automation to analysis. The student will learn how the biotech, academic and pharmaceutical industry use these techniques to identify new candidates for potential therapies.
15 credits - Cancer Biology
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The unit will provide a description of the nature of genomic complexity as revealed using next generation sequencing technology. It will explore cancer genotypes and phenotypes in the context of 8 essential characteristics that are common to all cancers, and which collectively dictate malignant growth. These characteristics are : self-sufficiency in growth signals, insensitivity to growth-inhibitory signals, evasion of programmed cell death, limitless replicative potential, sustained angiogenesis, tissue invasion/metastasis, avoidance of immune destruction, and de-regulated cellular energetics. It will discuss how genome instability arises, and together with tumour-promoting inflammation, how these enable the emergence of all other cancer characteristics. It will utilize this conceptual framework to discuss recent and future developments in cancer therapeutics. A brief review of fundamental principles in genetics and molecular cell biology will be given. Nevertheless, students should have a basic understanding of genetics, molecular biology and cell biology.
15 credits - Chemical Biology
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The ability to synthesise biomolecules has led to many of the most significant developments in molecular and chemical biology and to the development of biopharmaceuticals. This module looks at how biomolecules are created, from both biological and chemical perspectives. Student's knowledge will build up from understanding the central dogma and basic chemistry of life, to exploring important chemical biology techniques such as DNA sequencing, polymerase chain reaction, protein overproduction and site directed mutagenesis. Topics also include the production of novel biomolecules for bioconjugation, rational design, directed evolution, antibody production, and the new discoveries that synthetic biology might open the door to.
15 credits - Medicinal Chemistry and Drug Synthesis
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This module will provide an overview of how medicinal chemistry emerged, how biological mechanisms of disease are identified, how chemistry is used to target these mechanisms, and how drugs are synthesised.
15 credits
The content of our courses is reviewed annually to make sure it's up-to-date and relevant. Individual modules are occasionally updated or withdrawn. This is in response to discoveries through our world-leading research; funding changes; professional accreditation requirements; student or employer feedback; outcomes of reviews; and variations in staff or student numbers. In the event of any change we'll consult and inform students in good time and take reasonable steps to minimise disruption.
Open days
An open day gives you the best opportunity to hear first-hand from our current students and staff about our courses.
Duration
1 year full-time
Teaching
Our Drug Discovery Science MSc is taught by our academics and research experts in a multi-disciplinary approach. You’ll develop your expertise in a range of settings, including lectures, group workshops, laboratory practicals, and individual research projects.
You’ll typically spend around 12 weeks working on either an individual or cohort research project supervised by experts in the field to tackle a specific drug discovery problem. Here you’ll gain first-hand experience as a researcher, and have access to the outstanding research facilities at the University of 91̽»¨.
Assessment
You’ll be assessed through coursework, examinations, a literature review, a dissertation and a viva.
Our assessment methods are designed to support the achievement of learning outcomes and develop your professional skills, giving you confidence and experience in a range of activities. Regular feedback is provided, so you can understand your own development throughout the course.
Your career
Our graduates have the professional skills that employers value. This course is designed to train you for roles working on drug discovery in the pharmaceutical industry. University of 91̽»¨ graduates have been hired by major pharmaceutical companies such as GSK, Pfizer and AstraZeneca.
Our Drug Discovery Science MSc is also excellent training for a PhD in medicinal science. 91̽»¨ chemistry graduates have secured postgraduate research positions at many of the world's top 100 universities.
Facilities
You'll have access to expertise and equipment in the state-of-art research facilities and centres, including:
- 91̽»¨ RNAi Screening Facility, where researchers can perform whole-genome screening experiments using Drosophila cells
- Centre for Stem Cell Biology, where scientists are using pluripotent stem cells as a route to new drugs and treatments
- , which has a dedicated Drug Discovery Suite and new technologies based on robotics and AI
- Biological Mass Spectrometry Facility, with equipment and expertise in proteomics, metabolomics and isotope ratio analysis
- Wolfson Light Microscopy Facility, which has confocal, widefield, light-sheet fluorescence and super-resolution light microscopy systems
Collaborators
You'll benefit directly from the expertise of our partners in the drug discovery industry. Computer-aided drug design training is provided by , a drug discovery company and charity organisation. , a computer-aided drug design software company, provides introductory teaching and software licenses for our students.
School
School of Mathematical and Physical Sciences
The School of Mathematical and Physical Sciences is leading the way with groundbreaking research and innovative teaching.
Our chemistry researchers are focusing on some of society’s most pressing challenges, from antimicrobial resistance to environmental sustainability.
In the Research Excellence Framework 2021, 95 percent of our chemistry research was rated in the highest two categories as world-leading or internationally excellent.
We collaborate closely with industry to find solutions and develop innovative new technologies. Many of our academics bring first-hand industrial and business experience to their teaching, with many involved in current spin-out companies and collaboration with industrial partners.
We’re home to state-of-the-art chemistry laboratories and several multi-million pound materials science facilities. These include, the Lord Porter Ultrafast Laser Spectroscopy Laboratory, which is used in studies ranging from energy transport in molecules and materials to artificial photosynthesis; the Soft Matter Analytical Laboratory, where scientists can study samples that are 100 times smaller than a human hair; and an array of state-of-the-art instrumentation in the 91̽»¨ Surface Analysis Centre.
Four Nobel Prize winners have been 91̽»¨ chemistry students or researchers, and several of our academics have been named Fellows of the Royal Society or been awarded prizes from other prestigious organisations such as the Royal Society of Chemistry
Entry requirements
Minimum 2:1 undergraduate honours degree in a relevant subject.
Subject requirements
We accept degrees in the following subject areas:
- Chemistry
- Medicinal Chemistry
- Pharmacy
- Pharmaceutical Engineering
- Traditional Chinese Medicine
- Traditional Chinese Pharmacy
We can accept degrees in the following subject areas if they meet the module requirements below:
- Biochemistry
- Biomedical Sciences
- Biosciences
- Biotechnology
- Clinical Pharmacy
- Forensic Science
- Pharmaceutical Analysis
- Pharmaceutical Engineering
- Pharmaceutical Sciences
- Pharmacology
Module requirements
If required, you should have studied at least one module from Area 1 and one module from Area 2:
Area 1:
- General Chemistry
- Medicinal Chemistry
- Natural Product Chemistry
- Organic Chemistry
- Pharmaceutical Chemistry
Area 2:
- Analytical Chemistry
- Biochemistry
- Microbiology
- Pharmacology
- Toxicology
English language requirements
IELTS 6.5 (with 6 in each component) or University equivalent.
If you have any questions about entry requirements, please contact the school/department.
Fees and funding
Alumni discount
Save up to £2,500 on your course fees
Are you a 91̽»¨ graduate? You could save up to £2,500 on your postgraduate taught course fees, subject to eligibility.
Apply
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Contact
Any supervisors and research areas listed are indicative and may change before the start of the course.
Recognition of professional qualifications: from 1 January 2021, in order to have any UK professional qualifications recognised for work in an EU country across a number of regulated and other professions you need to apply to the host country for recognition. Read and the .