Course options
Key information
Duration: 3 years full time
UCAS code: B990
Institution code: R72
Campus: Egham
The course
Biomedical Sciences (BSc)
Gain a thorough grounding in the basis, prevention, diagnosis and treatment of disease by studying Biomedical Sciences at Royal Holloway, University of London.
This comprehensive course will prepare you to join the ranks of biomedical researchers at the forefront of human health investigation. You’ll study biochemistry, physiology, cell biology, molecular biology and genetics before choosing from a range of optional modules in years 2 and 3, allowing you to specialise and follow your own particular interests.
As a 2nd and 3rd-year student, you’ll receive specialist teaching from local health professionals, allowing you to learn more about subjects including neuroscience and clinical diagnosis of disease. You’ll have the option to embark on a lab-based individual research project in your 3rd year, joining a renowned research culture that has seen former students contribute to published scientific papers. 100% of our research impact in the Department of Biological Sciences was judged to be 4* and 3* world-leading and internationally excellent in terms of its originality, significance and rigour in the latest Research Excellence Framework (REF21). This places the department in the top 25% of departments nationally for research impact.
You’ll benefit from facilities that include state-of-the-art equipment for bioinformatics, mass spectrometry and protein and gene sequencing, as well as our excellent imaging facilities, including confocal laser scanning microscopes for 3D live-cell imaging.
Through your studies you will gain an impressive portfolio of transferable skills, making you an attractive prospect for potential employers. Invaluable lab experience, specialist learning and communication skills will help you to join our alumni in sectors including medical research, biotechnology and clinical trials coordination.
- Explore the function and integration of selected human physiological systems in normal physiology and disease.
- Become familiar with molecular biology techniques.
- Develop an understanding of the theory, technology, and clinical practice of human molecular genetics.
- Carry out an individual laboratory or theoretical investigation under supervision.
From time to time, we make changes to our courses to improve the student and learning experience. If we make a significant change to your chosen course, we’ll let you know as soon as possible.
Course structure
Core Modules
Year 1
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In this module you will develop an understanding of key scientific concepts and effective science communication. You will learn how to process and critique different forms of information, and how to communicate science to both scientific and non-scientific audiences using diverse media, forms and methods. You will also examine ethical issues surrounding research and intervention.
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In this module you will develop an understanding of prokaryotic and eukaryotic cell biology and the key functions of these structures and organelles. You will look at the origin of life and the principles of natural selection and evolution. You will also learn the practical technique involved in microscopy, including fixation techniques for the analysis of cell ultrastructure and aseptic techniques for bacterial culture.
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In this module you will develop an understanding of genes and their behaviour in individuals organisms, in populations, and at the molecular level within the cell. You will look cellular genetics with respect to mitosis, meiosis, inheritance and recombination, and consider the fundamentals of gene expression, its control, and DNA replication. You will examine genome organisation, transcription, and translation, and gain practical experience of using techniques in microscopy, including slide preparation for the observation of chromosomes.
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In this module you will develop an understanding of the fundamental chemistry of life processes and laboratory experiments. You will look at the basics of biological chemistry, including the chemical bonding and reactivity of important biomolecules, intermolecular forces, 3D structure and isomerism. You will analyse equilibria in acid/base biochemistry and solve related problems. You will also learn the basic biochemical lab techniques and carry out consequent data analysis.
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In this module you will develop an understanding of the basics of biochemistry. You will look at some of the key techniques for biochemical analysis, including spectroscopy, and the fundamentals of protein structure. You will examine structure / function relationships in myoglobin, hemoglobin and the serine proteases, and learn to solve biochemical kinetic problems using the Michaelis-Menten equation. You will also consider how to solve thermodynamic problems, including equilibrium constants.
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In this module you will develop an understanding of the main concepts of classic protein biochemistry including protein purification, enzyme kinetics, and enzyme structure. You will look at the basic principles behind a number of protein purification techniques, and consider basic enzyme kinetics using the Michaelis-Menten equation and derived methods to analyse kinetic data. You will examine the underlying biochemistry of a variety of analytical methods and their applications in research and diagnostics, gaining practical experience in performing some of these methods in laboratory practicals. You will also analyse the concept of biochemical buffers and learn how to make these from stock solutions.
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In this module you will develop an understanding of the fundamental physiological systems that are required to maintain complex multi-cellular animals, specifically those involved in communication, transport and homeostasis. You will look at how systems and specialised organs have evolved and interact to obtain oxygen from the environment whilst maintaining optimal internal conditions for cellular function. You will consider the mechanisms, organisation, functions and integration of the nervous and endocrine systems to show how neural (somatic and autonomic) and hormonal signalling enable an animal to sense and respond both consciously (e.g. movement) and unconsciously (e.g. internal homeostasis). You will also examine the evolution of the closed circulatory system, separated into pulmonary and systemic circuits and driven by a four-chambered heart, essential for the body-wide distribution of nutrients, oxygen and hormones, and for the removal of waste products.
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This module will explain the function of some organ systems in humans and illustrates the consequence of disease on physiological function. The module will begin by explaining the structure, organisation and function of key brain structures, and how special sensory systems convert light, sound and position/movement into electrical signals that are transmitted to the brain: including how our ability to sense the environment can be disrupted by disease. This will be followed by an explanation of the function and regulation of the mammalian kidney and the lungs, and the roles of the adrenal gland. The module then covers aspects of basic haematology; the fluid and formed elements of blood and their role in inflammation and the control of bleeding following vessel damage. The module will end with an introduction to skeletal muscle function and its neural regulation, how movement is controlled and sensed by the somatic nervous system.This module will explain the function of some organ systems in humans and illustrates the consequence of disease on physiological function. The module will begin by explaining the structure, organisation and function of key brain structures, and how special sensory systems convert light, sound and position/movement into electrical signals that are transmitted to the brain: including how our ability to sense the environment can be disrupted by disease. This will be followed by an explanation of the function and regulation of the mammalian kidney and the lungs, and the roles of the adrenal gland. The module then covers aspects of basic haematology; the fluid and formed elements of blood and their role in inflammation and the control of bleeding following vessel damage. The module will end with an introduction to skeletal muscle function and its neural regulation, how movement is controlled and sensed by the somatic nervous system.
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This module will describe the key principles of academic integrity, focusing on university assignments. Plagiarism, collusion and commissioning will be described as activities that undermine academic integrity, and the possible consequences of engaging in such activities will be described. Activities, with feedback, will provide you with opportunities to reflect and develop your understanding of academic integrity principles.
Year 2
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In this module you will develop an understanding of the function and integration of selected human physiological systems in normal physiology and disease. You will look at endocrine control in the human body, specifically the role of the hypothalamo-pituitary axis and the function and regulation of thyroid hormones. You will examine the organisation and integration of the nervous, cardiovascular, respiratory and systems and the principles of whole muscle physiology. You will also consider the composition and functions of blood and haemostasis, and the analysis and interpretation of physiological experiments.
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In this module you will develop an understanding of the chemical structure of DNA and RNA, and how genes are organised and expressed. You will look at gene characterisation using recombinant DNA technology, and will consider DNA as a template for RNA synthesis. You will also become familiar with molecular biology techniques that are widely used in the life sciences, including the preparation and handling of purified DNA, restriction enzyme digestions, and polymerase chain reaction.
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In this module you will develop an understanding of the mammalian immune systems at cellular and molecular levels, and how this is determined by antibody structure and function, the complement system, and the impact of immunoglobulin genetics. You will look at the role of T cells as effectors and regulators of immune responses, allergic reactions, transplant rejection, and the HIV virus and the pathogenesis of AIDS on the immune system. You will examine antipody antigen reaction techniques used in immunology, and consider the isolation and purification of lymphocytes, their morphology and abundance.
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In this module you will develop an understanding of the structure of the nervous system, including the main types of cells and the transmission of signals within neuronal networks. You will look at the process of synaptic transmission, including both electrical and chemical synapses. You will examine the different types of neurotransmitters and receptors and the mechanism of intracellular signaling, considering the role of second messenger signaling pathways. You will also enhance your practical skills, such as isolating and characterising synaptosomes and using these for the study of transmitter metabolism.
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In this module you will develop an understanding of drug-receptor interactions and the methods used to characterise drug action. You will look at the factors that influence drug action and drug toxicity within the body, examining the concepts of drug absorption, distribution, metabolism, and excretion. You will consider the pharmacology of a number of major drug classes, including antihypertensives, antidepressants, analgesics, general and local anaesthetics and drugs affecting the autonomic system.
Year 3
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You will carry out an individual laboratory or theoretical investigation, supervised by an appropriate member of staff, who will provide guidance throughout. You will apply the knowledge and skills learned throughout your studies, and learn to organise data in a logical, presentable and persuasive way. You will produce a report, around 8,000 words in length, and will deliver an oral presentation with a summary of your findings.
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In this module you will develop an understanding of the theory, technology, and clinical practice of human molecular genetics. You will look at a range of genetic disorders and inborn errors of metabolism such as muscular dystrophies, cystic fibrosis, haemophilia, lysosomal storage disorders, haemoglobinopathies, mitochondrial respiratory chain disorders, neurotransmitter synthesis disorders, lipoprotein diseases and primary immunodeficiencies. You will examine the concepts and significance of human inherited disease gene mapping and consider the importance of the human genome project.
Optional Modules
There are a number of optional course modules available during your degree studies. The following is a selection of optional course modules that are likely to be available. Please note that although the College will keep changes to a minimum, new modules may be offered or existing modules may be withdrawn, for example, in response to a change in staff. Applicants will be informed if any significant changes need to be made.
Year 1
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All modules are core
Year 2
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In this module you will develop an understanding of some of the key concepts in microbiology, including the study of bacteria, viruses, and eukaryotic microbes. You will look at how microbes are distinguished and classified, and discuss bacterial growth and differentiation. You will examine the importance of microorganisms in health and disease, including human welfare issues such as opportunistic infections and the role of microorganisms in cancer.
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In this module you will develop an understanding of the key methologies used in cell biology, becoming familar with modern microscopy techniques and live cell imaging studies. You will look at the basic mechanisms that regulate the cell cycle and the regulatory mechanisms for DNA synthesis and mitosis. You will examine mitochondria and chlorpolast organelle functions, and the principles of polar bodies and asymmetric cell division. You will assess the basic mechanisms underlying cell shape and mobility, and consider the evolutionary constrains of cellular functions.
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In this module you will develop an understanding of the processes that lead from a fertilised egg into complex tissues and organisms with well-defined body plans. You will look at the basic cellular and genetic mechanisms that regulate development, and the evolutionary outcomes of developmental changes. You will examine model organisms in which both embryological and genetic approaches have been developed, and will explore axis establishment, segmentation, cellular differentiation, organ development, and the widely-shared signalling pathways that underpin them.
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In this module you will develop an understanding of the major pathways for electron transfer and energy conversion in living systems. You will look at how energy is utilised in biosynthesis, and the role of enzymes, coenzymes and metabolic intermediates. You will examine the priniciple of flux control and metabolic regulation and the mechanisms that balance the activity of key pathways to physiological demands. You will also consider the main features of human energy metabolism and their relationship to obesity and diabetes, and analyse the importance of protein glycosylation and how protein glycans are biosynthesised.
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In this module you will develop an understanding of protein structure, protein folding in vivo, and the principles of protein engineering and protein-protein interaction. You will look at methods for the separation, purification, detection, and structural analysis of proteins, gaining practical experience in using techniques such as SDS-PAGE and Western blotting. You will also examine mechanisms of enzyme catalysis and regulation.
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You will carry out a literature research project on a biological or biochemical topic of your choice, producing a written report around 5000 words in length. You will critically evaluate recent scientific publications on your chosen topic, highlighting how data has been used to generate and test hypotheses.
Year 3
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In this module you will develop an understanding of the principles of parasitism and the protective mechanisms used by immuno-competent hosts to limit the spread of infection. You will look at the biological strategies used by a range of unicellular and multicellular organisms to colonise host causing disease in human and non-human hosts. You will consider studies on the pathology and the cellular immunity elicited by various parasites, and the immune evasion strategies used by widely distributed human parasites to protect themselves from immune attack. You will also address the principles and prospects of anti-parasitic vaccination in the 21st Century.
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Why do we get sick? Why are pregnancies complicated? Why do we grow old? Why do infectious diseases have a disproportionate effect in men and women? These fascinating questions are the core of evolutionary medicine. Through case studies, we will explore contemporary issues in health and disease –ones that we confront on a regular basis– and ask how evolutionary concepts –e.g., life history theory, cooperation and conflict, constraints and trade-offs, coevolution– help us to understand, mitigate, or combat those issues. We will answer questions like: How does understanding human evolutionary history inform us of the causes of common diseases? What role does evolution play in reproductive health and chronic diseases? Why is cancer an evolutionary process that can avoid the action of chemotherapy? What are the consequences of pathogen evolution for disease outcomes, treatment, and control? What are some strategies for overcoming or circumventing pathogen evolution in response to medical intervention? Can we predict the next disease that will emerge in humans?
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In this module you will develop an understanding of human metabolism, physiology and immunology. You will look at the main features of human energy metabolism, including nutrition, the importance of vitamins, and the biochemical basis of specific disorders, such as diabetes, hypercholesterolemia and obesity. You will consider the disorders associated with lipid dysfunction and examine other metabolic disorders such as hypercholesterolemia.
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In this module you will develop an understanding of medical microbiology with particular reference to bacteria and pathogenic eukaryotes. You will look at pathogen mechanisms for infection, the host immune response to infection, vaccine development, gastrointestinal health and disease, resistance to antibiotics, anti-parasite chemotherapy and the genetic and biochemical validation of parasite drug targets in the kinetoplastidae. You will examine the role of probiotics in health and disease, and consider a range of microbiological and molecular diagnostics techniques.
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The ability to manipulate genes provides one of the most important advances in modern research since the discovery of the structure and function of DNA. This process, called genetic engineering, is critical for biomedical research since it has enabled an improved understanding of the role of proteins at both a cellular and organismal level – through gene deletion or through the introduction or removal of disease-associated mutations. This module will provide an advanced-level course on Genetic Engineering. The module will focus on the use of Genetic Engineering in a range of systems including a simple non-animal model (Dictyostelium), and both in vitro and in vivo animal systems. The course will describe the use of these models for Genetic Engineering research, the underlying principles in the research, and the practical application of this research in areas of human health and disease, with a particular focus on current advances in these areas.
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In this module you will develop an understanding of advanced concepts and recent advances in fundamentally important areas of cell biology relevant to cancer, including developments in microscopy, imaging and molecular genetic techniques. You will look at current concepts in molecular cell biology, such as cell-cell adhesion and signaling, stem cells in development and in diseases, and cancer and the role of the cytoskeleton. You will examine topics in cancer biology including oncogenes, tumour suppressor genes and caretaker genes, and the signaling and regulatory pathways these are involved in. You will also examine the diagnosis and rationale of cancer therapies.
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In this module you will develop an understanding of the structure-function relationships in proteins, and how new technologies are being used to exploit protein sequence data. You will look at how genome-wide analyses can be used to examine regulation in biological systems, and consider modes of specific recognition in mediating protein interactions.
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In this module you will develop an understanding of human embryos and the development and function of particular endocrine systems. You will look at embryonic development, including gastrulation and specification of the axes, and the initial steps in the formation and patterning of the brain and spinal cord. You will examine craniofacial development, pharyngeal gland formation and sex determination, analysing the cellular and molecular processes involved in detail. You will also consider some of the birth defects that can arise, the genetic and environmental insults that cause them, and investigations which inform their prevention.
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In this module you will develop an understanding of the basic principles of brain development and the molecular mechanisms which regulate this, including the synthesis, storage and release of neurotransmitters. You will look at the molecular basis of learning and memory, considering brain disorders such as Alzheimer’s disease, epilepsy and bipolar disorder. You will assess the problem of brain damage in preterm babies and infants, and the methods available to help provide neuroprotection, with insights from a clinical practitioner.
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This module is taught by clinicians from Ashford and St Peter’s Hospital, who are experts in their field and work at the patient interface. You will develop an understanding of the physiology of smooth muscle and the function of the intestine, disorders of the pelvic floor and complications of childbirth, and the causes and treatment of colon cancer. You will look at the normal physiology of bone, including its formation and function, and examine bone disorders such as calcium homeostasis, metabolic defects, fractures, healing and ageing. You will also consider the normal structure and function of soft tissues, including muscles, tendons, ligaments and cartilage.
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In this module you will develop an understanding of how physiology, biochemistry and biochemical methodologies can be applied to the investigation of disease and monitoring of treatment. You will look at the chemical pathology of a range of physiological systems, including kidney, liver, heart, thyroid and bone, and clinical biochemical aspects of cancer diagnosis, infertility and epilepsy. You will examine the rationale behind the analyses used in the biochemical investigation of disease, and consider the clinical aspects of disorders affecting the various organs and systems.
Teaching & assessment
Each year you will take modules worth a total of 120 credits, with most individual modules worth 15 credits. In your final year, your Individual Research Project is worth 30 credits.
The first year is formative, while outcomes of your second and third year contribute one third and two-thirds of your final degree classification respectively.
You will attend a mixture of lectures, seminars and small-group tutorials, with class sizes that range from 6 to 180 students. Practical classes are a major part of all first and second year modules, and include experiments that are integral to the subject, helping to familarise you with the material and augment your understanding of key topics. These are either laboratory-based or field-based with laboratory follow-up. In your third year, you will complete an individual research project supervised by one of our academics, and you may have the opportunity to contribute towards a published scientific paper. The individual research project is assessed on the basis of a written report, supervisor assessment, and an oral presentation.
During your first and second years, you will complete essays and reports, and sit written examinations. In your third year, assignments include a range of activities, such as preparation of posters, oral presentations, creation of leaflets and podcasts, coursework essays, mock research grant applications and scientific news-and-views articles, as well as analysis of data from online repositories in mini-research projects.
Entry requirements
A Levels: BBB-BBC
Required subjects:
- Biology plus another science from either Chemistry, Maths or Physics. A Pass is required in the practical element of all Science A-levels taken.
- At least five GCSEs at grade A*-C or 9-4 including English and Mathematics.
English language requirements
All teaching at Royal Holloway is in English. You will therefore need to have good enough written and spoken English to cope with your studies right from the start.
The scores we require
- IELTS: 6.5 overall, with no subscore lower than 5.5.
- Pearson Test of English: 61 overall. No subscore lower than 51.
- Trinity College London Integrated Skills in English (ISE): ISE III.
- Cambridge English: Advanced (CAE) grade C.
Country-specific requirements
For more information about country-specific entry requirements for your country please visit here.
Undergraduate preparation programme
For international students who do not meet the direct entry requirements, for this undergraduate degree, the Royal Holloway International Study Centre offers an International Foundation Year programme designed to develop your academic and English language skills.
Upon successful completion, you can progress to this degree at Royal Holloway, University of London.
Your future career
Biomedical Sciences at Royal Holloway, University of London is structured to help students progress to further biomedical research. You’ll gain the invaluable skills and experience you need to work in a wide range of sectors, with a combination of lab experience and independent research making you an attractive prospect for potential employers.
The Department of Biological Sciences is a close-knit community, with our alumni regularly returning to share their knowledge and experience with current students. Our alumni have gone on to careers in sectors including pharmaceuticals, biotechnology and medical research.
- 96% of Life Sciences graduates in work or further education within six months of graduating.
- A close-knit graduate network to draw on, with alumni often visiting Royal Holloway to share their experiences.
- Summer placements offered to help students gain invaluable work experience.
Fees, funding & scholarships
Home (UK) students tuition fee per year*: £9,250
EU and international students tuition fee per year**: £28,900
Other essential costs***: Students are recommended to purchase a laptop before starting their course, to assist with their studies.
How do I pay for it? Find out more about funding options, including loans, scholarships and bursaries. UK students who have already taken out a tuition fee loan for undergraduate study should check their eligibility for additional funding directly with the relevant awards body.
*The tuition fee for UK undergraduates is controlled by Government regulations. The fee for the academic year 2024/25 is £9,250 and is provided here as a guide. The fee for UK undergraduates starting in 2025/26 has not yet been set, but will be advertised here once confirmed.
**This figure is the fee for EU and international students starting a degree in the academic year 2025/26.
Royal Holloway reserves the right to increase tuition fees annually for overseas fee-paying students. The increase for continuing students who start their degree in 2025/26 will be 5%. For further information see fees and funding and the terms and conditions.
*** These estimated costs relate to studying this particular degree at Royal Holloway during the 2025/26 academic year and are included as a guide. Costs, such as accommodation, food, books and other learning materials and printing, have not been included.