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Biomedical Science
School of Biosciences,
Faculty of Science
Course description
Biomedical science research aims to understand how the human body functions both in health and disease, and strives to develop treatments that can improve and save lives.
Through your choice of specialist pathway in either Stem Cell and Regenerative Medicine or Cell Biology and Drug Development, this MSc offers the combination of a flexible and specialist module choice to equip you with the knowledge, technical skills and professional attributes to lead innovation in the biomedicine sector that interests you.
Our Stem Cell and Regenerative Medicine pathway is designed to train our students in current academic and practical aspects of stem cell biology and regenerative medicine. You will develop practical skills in cell and 3D tissue culture, genome editing techniques and manipulation of animal models used in stem cell biology.
Students are also offered a choice of lecture modules in the principles of regenerative medicine and tissue engineering, modelling human disease and dysfunction, stem cell and cancer biology to reinforce their theoretical knowledge in the field of regenerative medicine.
Our Cell Biology and Drug Development pathway is for students that would like to understand the cell and animal models of disease and techniques that underpin the drug discovery industry. Practical modules will allow you to develop skills from robotics and automation to cell culture, animal models of disease and biomedical assays.
Our lecture module choices include subjects such as cellular mechanisms, membrane receptors, cancer pathways, cell signalling, sensory neuroscience, the analysis of biotechnology and pharmaceutical industry practices and current trends in new therapeutics.
In both pathways, you will study a core collection of modules focussing on the development of your scientific, analytical and critical thinking skills. Here we will teach you how to present your science in writing and in other media, use the R statistical analysis software, critically interpret scientific literature and understand the role of ethics in research.
The most substantial part of the course is your research project, where you will spend up to five months embedded within one of our internationally recognised research laboratories. Here you'll be working closely with world-leading academics and scientists and using our state-of-the-art facilities to perform your own cutting-edge biomedicine research project.
The School of Biosciences is home to state-of-the-art light microscopy and electron microscopy facilities, a purpose-built zebrafish facility, a fly facility, and proteomics and single cell omics facilities and you may be working in our Bateson Centre, where studies of model organisms are enabling researchers to understand human disease pathways at the physiological and molecular level.
Example past research projects include:
- The use of cell penetrating peptides in Ovarian Cancer.
- In vitro generation of cardiac neural crest from human pluripotent stem cells
- Characterisation of subpopulations of otic progenitors derived from human Embryonic Stem Cells (hESCs)
- Elucidating the role of SNAP29 in endocytic trafficking using CRISPR/Cas9 based approaches
- Understanding the relationship between heart tube rotation and extracellular matrix regionalization during cardiac looping in transgenic zebrafish models.
Modules
You'll study all of the following in both pathways:
- Advanced Scientific Skills
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This module builds on existing, and further develops, generic scientific skills to equip postgraduate taught students with strong competences in presenting and reporting their research work using written and oral formats, in analysing data and the scientific literature, and in acquiring and extending their critical analysis skills. Teaching will be delivered using a blended approach with a combination of lectures, workshops, tutorials and seminars together with independent study and on-line teaching.
15 credits
Taught throughout the academic year, the module will be articulated around three units addressing:
Unit 1) Scientific presentation skills. In this unit, students will explore how to develop their academic (writing and oral) presentation skills. Some of the topics taught may include how to formulate a research question and hypothesis, how to find information, and how to structure a scientific essay or report. Students will learn how to communicate effectively their research to a scientific, as well as lay, audience. Emphasis will be placed on short oral communications and poster preparation and presentation. The learning objectives will be acquired through lectures, workshops, tutorials and independent study.
Unit 2) Critical analysis skills. This unit prepares students to develop their ability to analyse and appraise the scientific value of the published and unpublished literature. Workshops and lectures will introduce students to the process of critical appraisal of scientific work.
Unit 3) Statistics and data analysis skills. In this unit, students will learn methods to gather and analyse large datasets. In particular, workshops and lectures will teach students the basics of R coding and statistics for application in biosciences. The unit may also deliver other forms of data analysis relevant to the programme of study. Teaching within this unit will be delivered mainly through on-line material, lectures and workshops. Independent study will be essential to complete the acquisition of skills. - Critical Analysis of Current Science
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This module is designed to develop the student's ability to read and understand the scientific literature relating to their own research area and also enable them to integrate their own work into the wider scientific field. The module consists of the following components; a seminar and seminar analysis programme designed to develop student skills in listening, understanding and appraising scientific research presented by external invited speakers; contribution, preparation and presentation of journal clubs reporting on the literature published in the field of biomedical science. In the latter component, students will be expected to demonstrate critical analysis skills, which will be encouraged through questions and discussions in classes. Each component is assessed through formal examination and oral presentation.
15 credits - Literature Review and Research Proposal
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This unit involves an in-depth survey of the current literature relevant to the student's research project. Students will carry out an exhaustive search of the literature relevant to their project using the resources of the University, including appropriate databases and specialist search engines, as well as paper-based resources in the University Library. Based on primary research articles, review articles and textbooks, students will work independently under the supervision of the project supervisor to produce a document reporting on the background literature underpinning their research project. The literature review should demonstrate an ability to comprehend and synthesise the experimental evidence presented in the literature, to critically appraise previous studies and identify gaps in the knowledge, and to describe the experimental design of the research project. To prepare their literature review, students will meet at regular intervals with their supervisors to discuss their progress.
15 credits - Research Project
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The module aims to provide students with experience of conducting a research project, and develop analytical and organisational skills required for a career in science. Students undertake a research project which reflects the research activities in the Department/Faculty/University. Projects will be supervised by a member of the academic staff, although students may have additional contact with various staff contributing to their training. Students will gain experience of experimental design, and in execution, collation, interpretation and presentation of scientific data.
60 credits
Assessment of the project will be based on a written dissertation, an evaluation of the research skills developed during the tenure of the project, including keeping a lab book, and delivery of an individual poster presentation.
For the Stem Cell and Regenerative Medicine pathway, a student will take the practical module
- Practical Developmental Genetics
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The practical unit aims to provide students with experience of research techniques in developmental biology. Students will perform experiments designed to reveal molecular and cellular principles underpinning developmental mechanisms. Emphasis will be placed on exploiting classical genetic and molecular resources available in model organisms such as zebrafish, Drosophila melanogaster, and chick for studying gene function in development. Students will gain experience of performing experimental work, data collection and interpretation of results.
15 credits
And will take 60 credits from this group
- 3D Tissue Culture and Genome Editing
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Many of the major pharmaceutical companies are using 3D models of disease and most use genome editing. This practical module will instruct students how to grow cells including 3D tumour spheroids in culture using different growth conditions. Students will learn how to transfect plasmid constructs to induce gene expression changes and use plasmids as molecular reporters of pathway activity. They will experience how to treat cells with RNAi and small molecules and measure the effect of gene expression. Students will grow 3D tissues and 3D tumours in this practical module and perform targeted gene studies. The students will use FACS for cell type selection and use CRISPR genome editing and knock-out techniques to build models of disease. At the end of this module students will have an extensive knowledge of 3D cell culture and the genome editing tools used in drug discovery and how to use them in screening campaigns.
15 credits - Stem Cell Biology
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This lecture course will provide a thorough grounding in the biology of stem cells and regenerative medicine, with special reference to the molecular and genetic control of cell fate specification and differentiation. Students will also be enouraged to consider the clinical use of stem cells and their derivatives as well as the ethical issues that these raise. As this is a rapidly developing field, strong emphasis will be placed on understanding the current controversies in the literature.
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 - Modelling Human Disease and Dysfunction
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The module will provide students with an understanding of how post-genomic biology impacts on our ability to understand, and treat, chronic diseases of the body. Students will be introduced to major experimental systems and approaches that are pertinent to disease modelling. These include genetically-tractable animal model and in vitro cellular systems (including stem cells). We will explore the principles involved in how these systems are exploited to develop new strategies for intervention, including new therapeutics. Critical evaluation of research papers will allow students to gain experience of analysing experimental work, data presentation and interpretation of results.
15 credits - Principles of Regenerative Medicine and Tissue Engineering
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This unit will provide students with an overview of the multidisciplinary concepts underpinning regenerative medicine and tissue engineering. Through detailed examples of regenerative medicine and tissue engineering strategies for replacing specific organs and tissues, students will be introduced to the key steps of the regenerative medicine and tissue engineering process from bench to bedside. The course will present topical research in regenerative medicine and tissue engineering and enable students to critically assess the current limitations and potential applications of regenerative medicine and tissue engineering for medical applications, drug discovery and food manufacturing. The unit will provide an overview of the central topics of regenerative medicine and tissue engineering, including cell sourcing, biomaterial properties and design, and cell-material interactions. Particular emphasis will be given to the recent cutting-edge examples of applying regenerative medicine and tissue engineering to restore function of various organ systems.
15 credits
For the Cell Biology and Drug Development pathway, a student will take the practical module:
- Practical Cell Biology
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The practical unit will provide students with experience of practical cell biology. Students will be given the opportunity to establish and optimise ELISA-based assays for fundamental cellular processes, specifically the endocytic pathway. Particular emphasis will be placed on the development, execution and interpretation of experimental protocols as is standard practice in a research laboratory.
15 credits
And will take 60 credits from this group
- Small Molecule and Functional Genomic Screening
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This practical module will teach students how to perform small molecule and functional genetic screens, focused on human disease. Emphasis will be placed on how to select the right off-the-shelf assay and if one is not available how to build a new assay specific for their study. Students will take part in experimental screens of small molecules and genetic knock-down 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 laboratory automation to analysis. The students will learn robotics, in particular programming the Hamilton Star liquid handling robot.
15 credits - 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 Sheffield. 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 Sheffield business team, the students will learn how new ventures are started from University and the process of generating new spin out companies.
15 credits - Membrane Receptors
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The module will examine the main families of integral membrane proteins that act as surface receptors to sense the extracellular environment and signal this information to produce changes in cell function. Specific emphasis is placed on receptors which are therapeutic targets for the treatment of common human diseases, including allergy and chronic inflammatory diseases, cancer and cardiovascular diseases and neurological disorders. This module explores the latest concepts and ideas in our understanding of the molecular structure and signalling underpinning membrane receptor function, the experimental approaches used to gain this understanding and ultimately how this knowledge may be used to develop novel therapeutics for the treatment of disease. The module is taught by research active academics with a wide spectrum of experience in this field. We will base our teaching around current research and hope you find the material interesting and enjoyable.
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
-
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 - Sensory Neuroscience
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This module covers the adult function and functional development of the auditory system, including sensory transduction and information processing. It will focus primarily on the periphery but will include representation of information in central pathways, with attention to mammalian animal models. The aims will be to show how physiological and developmental mechanisms combine to create the exquisite structural and functional tuning of the auditory system to the external world and how complex sensory information is encoded in the nervous system.
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.
Find out what makes us special at our next online open day on Wednesday 17 April 2024.
You may also be able to pre-book a department visit as part of a campus tour.Open days and campus tours
Duration
1 year full-time
Teaching
Throughout your degree, you’ll be taught through lectures, practical sessions, lab placements, tutorials and seminars. In small group teaching classes you’ll discuss, debate and present on scientific and ethical topics.
Your research project will last for up to five months, where you’ll be working alongside experts in your field to give you first-hand experience of designing your own experiments, analysing results and culminating in you presenting your findings to colleagues.
Assessment
Assessment is by formal examinations, coursework assignments, debates, poster presentations and a dissertation.
Your career
This course is structured so that the specialist training you receive makes you highly employable when applying roles across the breadth of biomedicine. Some of the fantastic careers of previous students include:
- Clinical Research Executive, B Braun Group
- Research Assistant, University of Oxford
- Research Technician, MRC Epidemiology Unit
- Associate Scientist, SIRPant Immunotherapeutics
- Biology Research Scientist, Cellular Agriculture Ltd
- Research Officer, National Cancer Centre Singapore
- Flow Cytometrist, The Babraham Institute
- Scientist, Regend Therapeutics
- Medical Writer, PharmaReview Ltd
If you choose to continue your research training, you’ll be ready to pursue a PhD and students from this course have gone on to PhD training in:
- Stem cell biology
- Biomedical science
- Translational neuroscience
- Osteoarthritis
- Oncology
- Tissue regeneration
- Restorative gene therapy in auditory disease
- Chronic pain management
Department
School of Biosciences
The School of Biosciences brings together more than 100 years of teaching and research expertise across the breadth of biology.
It's home to over 120 lecturers who are actively involved in research at the cutting edge of their field, sharing their knowledge with more than 1,500 undergraduate and 300 postgraduate students.
Our expertise spans the breadth and depth of bioscience, including molecular and cell biology, genetics, development, human physiology and pharmacology through to evolution, ecology, biodiversity conservation and sustainability. This makes us one of the broadest and largest groupings of the discipline and allows us to train the next generation of biologists in the latest research techniques and discoveries.
Entry requirements
Minimum 2:1 undergraduate honours degree in a biomedical-related subject.
We also accept medical students who wish to intercalate their studies.
Overall IELTS score of 6.5 with a minimum of 6.0 in each component, or equivalent.
If you have any questions about entry requirements, please contact the department.
Fees and funding
Apply
You can apply now using our Postgraduate Online Application Form. It's a quick and easy process.
Contact
biosciences-pgt@sheffield.ac.uk
+44 114 222 2341
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.