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Molecular Medicine
School of Medicine and Population Health,
Faculty of Health
Course description
Our Molecular Medicine MSc brings together the most recent advances in the molecular and cellular understanding of diseases, enabling you to comprehend human diseases in detail at the most fundamental level.
It covers the cellular, molecular, and genetic factors behind a wide range of illnesses and demonstrates how new technologies are revolutionising scientific discovery, diagnosis, and treatment.You will investigate diseases caused by single gene defects and explore the intricate molecular mechanisms leading to cancer and chronic diseases with overlapping causes that affect the ageing populations.
Additionally, you will study the crucial role of the immune system, and in the laboratory, you will examine models of the immune system in both healthy and diseased states.
You will receive training in RNA and DNA sequencing technology, mass spectrometry techniques, and the use of these methods to process large volumes of bioinformatic data. This training will enhance your understanding of the changes that lead to the transition from a healthy to a diseased state.
In our state-of-the-art computational laboratories, you will gain hands-on experience in mapping genetic sequences, designing precise PCR reactions for detailed data analysis, and identifying genetic variations in patients. Additionally, you have the option to take an introductory course on utilising computer programming to manage and analyse extensive bioinformatic datasets.
This course simplifies the principles and offers examples illustrating how studying diseases at a molecular level can lead to novel treatments for patients. You'll explore various biological therapies developed in the biotechnology and pharmaceutical industries, and learn about the process of identifying, designing, and testing potential new drugs.
As part of the course, you will undergo a comprehensive research skills training program.
Upon finishing the taught component, you'll embark on a 20-week full-time research project. Collaborating with a team of seasoned scientists, you'll explore hypotheses, devise experiments, analyse data, and communicate your discoveries effectively.
Example research projects
- Precision Therapy in an Infantile Genetic Disorder (NBAS-related)
- Role of MisS in colonisation and antimicrobial resistance in Neisseria gonorrhoeae
- Molecular Mechanisms for Overcoming Chemotherapy-Resistance by Targeting Cancer Dormancy
- Investigating the Role of Candidate Deubiquitinases in Driving Cancer Metastasis in a Zebrafish Tumour Xenograft Model
- Bioinspired cancer-killing nanoparticles
- The (re)solution to Inflammatory Disease: Controlling RNA Stability in Neutrophils as a Therapeutic Mechanism
- Understanding the role of CFTR-Interacting Proteins in Innate Immunity, using a Zebrafish model
- Adapting Biosensors to Monitor G Protein-Coupled Receptor Signalling
- Improving Efficacy of Immunotherapy in Cancer-Induced Bone Metastasis through Targeting Transforming Growth Factor Beta
- Unravelling the DNA processing activities of the human PIF1 helicase, a promising cancer therapy target
We have an extensive list of research projects beyond the ones showcased here. If you're interested in exploring more opportunities or finding a project that aligns with your specific interests, email m.nicklin@sheffield.ac.uk for more information
Do you have a question? Talk to us
Book a 15-minute online meeting with our course tutor to find out more information and ask further questions.
Modules
A selection of modules are available each year - some examples are below. There may be changes before you start your course. From May of the year of entry, formal programme regulations will be available in our Programme Regulations Finder
- Research Skills
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This module aims to develop your skills in information literacy, oral presentation, scientific writing, critical analysis, data analysis, statistics, ethics, research integrity and basic laboratory techniques. These are all skills that support subsequent modules, the laboratory project and dissertation writing, and are also transferable skills useful in many future careers.
15 credits
The module consists of lectures, tutorials, active (interactive) teaching and group work, followed by taster sessions in various different laboratory techniques. - Molecular and Cellular Pathogenesis of Human Diseases
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Understanding the molecular and cellular pathogenesis of human diseases is critical for developing new strategies for disease prevention, diagnosis, and treatment.
15 credits
Students will learn about the current field of Molecular Medicine, using relevant examples of specific diseases that are understood at both the molecular and cellular level, and that are the areas of expertise of our teachers. Students will gain knowledge about a spectrum of diseases, ranging from the relatively simple examples that are caused by a single gene defect, to those where a frequent variant of a gene makes a substantial contribution to causing disease, and then on to disorders that share molecular mechanisms but where there is no specific evidence for an inherited genetic susceptibility. These will often include the ultimate 'disorder of the genome', cancer, where the primary defect is the loss of the cell's normal capability to maintain the stability of its own genes. Students will investigate the consequent changes that can drive progression and spread of cancer, and discuss programmed cell death, its failure in cancer and in infectious and autoimmune diseases. The emerging understanding of the role of the microbiome of skin and gut in maintaining human health and how an imbalance in the microbiome may contribute to diseases, including autoimmunity inflammatory diseases and the progression of cancer, will also be explored.
Teaching will be through a combination of lectures and tutorials. To support students' understanding of our teaching and the background literature, we will include discussion of cellular and molecular processes and methods for interfering with the function of specific entities within cells. We will also provide optional extra teaching to provide more background in relevant techniques and molecular processes for students who feel that they would benefit from them. - Immunology in Human Diseases
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This module will provide students with a comprehensive understanding of the human immune system and its role in disease. Students will learn about the different components of the immune system and the mechanisms involved in protecting the body against pathogens, and how disruption of these can lead to chronic inflammatory and infectious diseases. Additionally, students will be taught using examples of primary research to illustrate how the immune system is involved in the development and progression of diseases such as cancer, autoimmune disorders, and infectious diseases.
15 credits
The use of appropriate model systems to study the immune system, including in silico, in vitro and in vivo models, will also be covered in this module. Students will learn about the advantages and limitations of different models and how they can be used to study the immune system in both healthy and diseased states. They will have the opportunity to visit our laboratory facilities and observe demonstrations of these models, and will learn how to apply their knowledge of the immune system to critically evaluate the methods and results of laboratory based and clinical research studies.
Teaching will be through a combination of lectures, tutorials, and discussions, as well as visits to laboratories, clinical research facilities, and clinical departments. - Mining Bioinformatic Data
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Modern experimental programmes often deliver massive datasets because we are now able to deliver high throughput data economically. This falls principally into high throughput sequencing of RNA and DNA and mass spectrometry of proteins. This information is seldom interpreted from scratch but can be mapped onto the massive data held on public archives. The first of these is the human reference genome. Students will learn how the most significant current nucleic acid sequencing methods operate and how mass spectrometry is used to analyse the entire protein content of a cell and how the same methods can be adapted to read the phenotype of single cells within a tissue.
15 credits
Students will learn in computer classes how to map sequence onto genomes and other reference genomes, design PCR reactions, identify previously known and unknown genetic variations from database information. In the field of infectious diseases students will use sequence data to classify pathogens.
Students will learn and experience hands-on, in computer classes, how raw sequence data are analysed. Students will be introduced to the programming language R and will learn to use it to analyse and display data sets. With preconfigured software, students will identify networks of activated genes in human cells and identify resistance genes in pathogens. - Mechanisms in Chronic and Age-Related Diseases
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Students will discover how chronic diseases, especially those that are common in the aging population have shared features with many overlapping causes and consequently patients are often co-morbid for several disorders. The module will explore how specific disorders have been studied, focussing particularly on the use of model systems to explore the molecular and cellular basis of disease to the point of identifying potential drug targets. Students will learn to assess critically the primary scientific literature that supports the identification of significant pathogenic processes. Areas of focus will be inflammation and inflammatory diseases, metabolic syndrome and its consequences and pathways in neurodegeneration.
15 credits - Molecular Basis of Cancer and Cancer Diagnosis
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The module focuses on the genetic and phenotypic changes that evolving cancer cells commonly undergo as they become more malignant and metastatic and how, if they are 'successful', they significantly influence their environment and the phenotype and behaviour of bystander cells including components of the immune system to favour disease progression. Central to this understanding is our ability to identify the mutations that drive progression in individual cells and the unusual expression of proteins that results from genetic change. If we can identify common driver pathways between individual cancers, then it allows us to improve prognosis and design and apply targeted therapies.
15 credits - Small Drugs for Chronic Disorders
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Orally available small molecules are the primary goal of the pharmaceutical industry and in wealthier health systems, agents that need to be continually supplied to treat a chronic condition are the most attractive. Traditionally, the efficacy of drugs in treating human disorders was discovered before the drug's biomolecular target was understood. Recent developments in protein structural analysis and modelling has allowed 'lead' molecules to be selected and optimised for specificity by computer design. Drugs, however, are subject to unpredictable absorbtion, metabolism (which will vary between patients), import into cells, export from cells and excretion. The drug's target molecule can sometimes have an additional, unrecognised function. Small molecules are also likely to interact to an unknown extent with other off-target molecules and activate the metabolism of other drugs causing drug-drug 'interactions' and side effects. A phased programme of drug testing is therefore ethically justified and legally required and as a consequence of failures during testing, the majority of tested drugs are abandoned.
15 credits
In infectious diseases and in cancer, known efficacious drugs can become non-efficaceous as a result of changes in the target, whether this is a tumour cell or a microbial pathogen. Small molecules can be redesigned at random and tested against known variants or molecules can be re-designed in a computer model to re-target a specific variant. Individual responses to drugs also depend upon the patient's genetics, comorbidities or metabolic state and specific drugs may be effective in one patient but not another.
This module uses seminars to introduce students to the pharmaceutical industry's approach to new drug design.
Students will receive hand-on introduction to computer based molecular docking of small molecules with protein targets. Students will be led through a number of examples of promising, validated and/or efficacious smal molecule treatments that have been developed in collaborations involving the University of Sheffield. Students will be introduced to programmes of drug testing and of the potential use of genetic profiling to predict drug efficacy. - Biologic Therapy
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Re-engineered protein molecules, expressed in bulk in industrial-scale cell culture systems, engineered virus-like particles that can carry corrected human genes, modified-RNA vaccines and re-programmed immune cells from patients are among the agents categorised as 'biologic' that are currently used to a greater or lesser extent in human therapy.
15 credits
Fledgling biotech companies (in the 1980s) regarded protein therapeutics as a temporary step towards the development of highly specific small molecule therapies, yet recombinant proteins and particularly, antibodies, remain a hugely important and still growing field of pharmaceutical development. In replacing the failed products of dysfunctional genes or missing cells, protein therapeutics cannot be substituted with small molecules. As antigens for use in vaccines or vectors for expressing the genetic code of a pathogen, biologics are irreplaceable. The specificity of recombinant antibodies to target a disease-related agent can justify their enormous cost, relative to small molecules, when the small moleule therapies fail. The number of recombinant antibody therapeutics is still expanding.. Reprogramming patients' immune cells to target their own cancers is a very promising new approach to destroying incurable aggressive cancers. The module introduces students to all of these therapeutic approaches, how biologics are developed and how they produced. Biologics are generally limited in their global reach because of their physical and chemical instability, their need to be injected often in a hospital environment and their very high cost. The module will discuss how these concerns are being partially addressed. - Research Project
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The module allows students to develop as a research scientist in an area of research fitting the area of their degree and often diectly developing themes from previous teaching.
60 credits
Students experience the scientific process of hypothesis testing, developing the relevant hands-on skills (in the laboratory) and/or understanding of the experimental process (if a non-laboratory project is chosen). With supervision, students will learn to analyse results and will eventually formulate their own experiments and have the opportunity to develop new hypotheses.
Students will choose several from an extensive list of individual projects. The list will contain an informative title and include links to an extensive abstract and references that students may explore. Students are expected to meet their candidate supervisors before selecting their projects. Students will be assigned one of their selected projects.
Students carry out an individual 20-week research project and complete three activities for assessment with guidance from their individual supervisor. [1] Students prepare a poster, outlining the scientific background of their project.[2] After several weeks engaged in the project, students will present the background, the hypothesis, their experimental procedures and any results that they might have at this stage. [3] By the end of the project period, students will produce a dissertation which will include a survey of relevant background knowledge, a clear statement of the hypothesis or hypotheses that the student's work addressed, a report of the methods used, results achieved and a discussion of the implications of the results for the hypothesis and the significance of the results in relation to the field.
[4] A further marked component will consist of an assessment of the student's practical skills and their engagement with the research team during the project.
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.
Book a space on our next open day on Wednesday 27 November
This course is in our Medical Science session, which is about MSc courses that focus on the science of human health and disease, and the research that underpins a wide range of treatments and interventions.
Duration
1 year full-time. We are unable to offer a part-time or distance learning study option for this course at present.
Teaching
You will be taught through lectures, seminars, tutorials, practical classes, independent study and your research project.
Assessment
You will be assessed through written assignments, posters, presentations and a laboratory skills assessment. The research project is also assessed through a dissertation and may be assessed through a viva voce examination.
Your career
This course is great preparation for a career in medical science research and research management. Many of our graduates complete PhDs and work at top universities and research institutes. Others work as researchers in the biotechnology or pharmaceutical industries.
Student profiles
The medical school where my department is based is one of the best in the UK. This combined with the guest lecturers from the best academics and researchers in their respective fields made University of Sheffield my best choice for pursuing my master’s degree.
My understanding of the molecular mechanisms of various diseases and disorders combined with the knowledge of emerging technologies in medicine would enable me to improve the understanding of various disease which would help in development of novel therapies in the field of medicine.
Amanpreet Kaur Bains
MSc Molecular Medicine
Entry requirements
Minimum 2:1 undergraduate honours degree in a relevant subject.
Subject requirements
We accept degrees in any subject including a substantial element of human or animal biology.
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
Apply
You can apply now using our Postgraduate Online Application Form. It's a quick and easy process.
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 information from the UK government and the EU Regulated Professions Database.