Course details
- A level requirements: ABB
- UCAS code: C500
- Study mode: Full-time
- Length: 3 years
Return to top
Our BSc Microbiology course involves the study of microorganisms with particular emphasis on the biology of bacteria, viruses and fungi. In spite of their size, the impact of microorganisms on the planet is so extensive that life as we know it could not exist without them.
You’ll study a broad range of modules which cover areas such as molecular microbiology, infectious disease and global health, immunology, therapeutics and genomics with the opportunity to specialise and carry out your own research project.
We also offer support for making career choices right from the beginning and you will have the opportunity to consider potential career pathways within and outside the field of Microbiology and Infection.
You’ll learn and develop those important transferable skills in communication, team working, project management and computing with practical sessions and group work.
We’re proud to announce we’ve been awarded a Gold rating for educational excellence.
Discover what you'll learn, what you'll study, and how you'll be taught and assessed.
In this first year, you’ll gain an understanding of core concepts of biology as well as the fundamental principles of immunity, infection, and therapy. You will also study how organisms develop and function and learn about ecology and the global environment. You will develop practical skills, and you will discover how to utilise quantitative skills and study techniques.
The transition into higher education can be a challenging one. This module aims to aid students in their journey from further education learners into higher education students of the Biosciences. To truly appreciate the disciplines which make up the Biosciences we must first develop an understanding and appreciation of their commonalities. This module brings together the core concepts of biology at the macro through the micro levels. This will provide students with the opportunity to develop and enhance their knowledge of the Biosciences and the possible pathways which they wish to study further. A mix of learning & teaching methods will be used in this module which will include, but are not limited to lectures, active learning, and learning through assessment, plus the use of directed reading/multimedia resources. This module will be assessed by a midterm assessment comprising mixed multiple choice, multiple answer and matching item questions (30%). There will also be an end of module assessment which is split into two parts: Part A which will be a similar format to the midterm assessment (35%) and Part B which will comprise a data interpretation assessment (35%).
In this module students will study in three blocks, the first is embryology and development of organ systems. The students will then continue to develop their knowledge of organ function in invertebrate and vertebrate animals (including humans) and compare these with organisms who have adapted their function to meet the challenges of a range of environments, in the second block. This approach has been taken to aid in our understanding of organ function from its commonalities to its varied differences. A cellular & molecular approach is used as students focus on the control, regulation, development and function of organs, organ systems & organisms. The third and final block has a focus on infection, immunity and microbial diversity.
The overall aim of this module is to facilitate the study of how cells develop and work together to form functional tissues and organs, and how this is imperative to the normal functioning of organisms and their adaptation, response and defence mechanisms.
The module will be taught through a combination of lectures and workshops, which will be supported with directed learning resources (reading/ multimedia).
There are three assessments. This module will be assessed by two in-course assessments, scheduled outside of the School of Biosciences two cycle assessment strategy and an end of module exam.
This is the first practical module that students will take in the School of Biosciences. The variety of experimental, quantitative and transferable skills that students acquire will be required for future practical modules that they will take in Year 1 Semester 2, during Year 2 and will prepare them for their Year 3 research project and for their subsequent career. This module is designed to teach the basic multidisciplinary skills required in the field of life sciences, provide an understanding of basic lab practice and safety and to allow application of theoretical knowledge to solve practical challenges. It will be taught through a combination of lectures, practical sessions, workshops and self directed learning.
This module will be assessed via three methods: continual assessment to assess understanding of practical skills (experimental, technical and computational/quantitative statistics), a practical skills observational assessment to improve research and experimental skills and a written scientific abstract to assess overall understanding and communication of research outputs through scientific writing.
Ecology explores the intricacies of our living environment, encompassing the spatial and temporal distribution of organisms, their dispersal patterns, population dynamics, interspecies interactions, community development over time, and the formation and functioning of diverse ecosystems. Evolutionary ecology explores the biological variations among species within this natural context, examining phenomena like rapid life cycles or long lifespans. This course provides a comprehensive overview of both foundational ecology and evolutionary ecology, addressing the challenges that natural populations and ecosystems face in our dynamic world.
The module will be delivered through, research-connected lectures by research active scientists. There are two assessments which assess students in interpreting scientific publications, while online tests assess their grasp of the covered topics. These assessments collectively contribute to evaluating students’ knowledge and understanding of the subject matter.
This module will develop students’ transferable skills. It will focus on improving the students’ written, communication, presentation and employability skills via a series of fortnightly tutorials and lectures. As this module is taken by students on all programmes, to allow students to explore their interests different essay titles, journal papers and discussion topics relevant to students programme area of interest will be offered. Students will complete tasks that count towards a Portfolio and three larger assessments.
Biology is a practical science, whether you want to study disease in microbes, plants, invertebrate and vertebrate animals (including humans), understand the function of a gene, or how the behaviour of organisms can shape an ecosystem. In the first half of this module, all students will learn fundamental practical techniques that every biologist should be familiar with. Alongside the experimental skills, students will learn practical computational and bioinformatic methods that can be used to support and advance scientific understanding of the lab techniques. In the second half, students will split into three topical strands: Molecular Research, Anatomical & Physiological Research or Whole Organism Field Research. Students in each strand will learn a set of skills and techniques that are particularly useful for degree course, with a focus on their specific discipline. All students will learn how to safely and effectively carry out practical biology, skills that will be vital throughout the rest of your degree.
Learning and teaching is created and delivered by research-active scientists, ensuring that teaching is informed by the latest research and advancements in the biosciences, and is designed to be accessible, inclusive, and representative of the student cohort.
This practical will be assessed via three methods: a computer-based assessment to assess understanding of bioinformatic and computational skills; an individual practical skills assessment in the form of observation or online assessment to assess knowledge, understanding and application of knowledge; a written scientific report to assess data analyses and communication of research outputs through scientific writing.
In your second year you’ll expand your range of knowledge, building those essential research skills, experimental design and analysis together with professional skills preparing you for a career within or outside the area of Microbiology and Infection. You will study molecular microbiology and therapeutics, genetics and immunology, cell signalling and explore the relationship between hosts and parasites. In addition, you will have optional modules enabling you to follow your interests in drug discovery and development, physiology or metabolism.
The science of genetics, including gene-editing and genome sequencing is a fast-moving and exciting area for biosciences study. In this module we will explore the fundamentals of genetics and genomics such that students can apply cutting-edge knowledge to the areas of the biosciences that interest them most. Students will be asked to consider the relevant ethical implications of current knowledge and technologies in genomics and genetics. In addition, we will expand the horizons of the module toward understanding of disease, by looking at the genomic, and physiological bases of immune defences against microbial enemies. The module is taught via a set of workshops in which students explore and develop their comprehensions working with groups, and their tutor. Students will be assessed by creating their own teaching materials (e.g. videos, powerpoint slides) as well as an end-of-module examination
This practical skills module is designed to give you hands-on experience in a range of essential laboratory techniques, building on foundational practical skills developed in the first year of study. From protein purification to nucleic acid quantification and the use of general model systems, this module covers a variety of techniques that you need to further your practical development within the breadth of the Biosciences disciplines.
Through a series of interactive experimental sessions and live synchronous workshops, you will gain practical experience in a variety of analytical and quantitative experimental practices. You will also learn the underpinning knowledge behind some of the methodologies and the intricacies of experimental design, all the while supplementing your wider theoretical learning through experimental application of techniques to tackle problems across the Biosciences disciplines. Students will learn how to analyse collected data and communicate the findings effectively, with the opportunity to apply your newly acquired skills to research projects tailored towards your programme and fields of interest. This module will be assessed via a computer-based assessment to assess understanding of quantitative and computational skills, a group research output focused on experimental design and a written scientific report to assess communication of research outputs through scientific writing.
This module will expand your laboratory skills and allow the advancement of practical experiences in a range of essential techniques and equip you with the skills and knowledge you need to prepare you for your honours dissertation projects.
This module will continue to develop students’ transferable skills and will build on the year 1 skills module. It will focus on improving the students’ written, communication, and employability skills. As this module is taken by students on all programmes, to allow students to explore their interests different essay titles, journal papers and discussion topics relevant to students programme area of interest will be offered. Students will complete four assessments which include an essay, a written critique of lay science communication, an individual report and group digital pitch, and a portfolio. The module is based on fortnightly small-group tutorials with an Academic Advisor. Each tutorial will have a topic that relates to a small task which students need to complete either before or after the tutorial. The topics will be introduced within plenary lectures. In addition to the plenary lectures relating to skills development and employability, students will also receive lectures and seminars relating to programme specific content. These lectures will form the basis for discussions in programme specific tutorials
This practical module aims to provide students with an opportunity to learn and apply a range of microbiology and infection biology practical and laboratory techniques, in order to develop your ability to plan and execute research projects and tackle scientific problems related to infection, health & disease. The module will address areas of research-connected infection biology teaching, across areas of broad relevance to infectious diseases in a variety of hosts. Topics will focus on the diagnosis and surveillance, treatment and prevention of infectious diseases and will enable students to understand the impact of infectious diseases on society.
Through a series of interactive experimental sessions and live synchronous workshops, you will gain practical experience in a variety of analytical and quantitative experimental practices. You will also learn the underpinning knowledge behind some of the methodologies and intricacies of experimental design, all the while supplementing your wider theoretical learning through experimental application of microbiological techniques to tackle problems related to infectious disease, with application to the wider Life Sciences disciplines. You will learn how to collect and analyse data and communicate the findings effectively, with the opportunity to enhance your skills in research projects tailored towards your programme and fields of interest.
There are two assessments in the module: 1) a resource development related to communication of a contemporary scientific development in biomedicine and biotechnology; 2) a written scientific report related to experimental lab practicals, to analyse and present current research findings.
Cell signalling underlies the ability of cells to sense their environment and respond. In multicellular organisms, individual cells receive and integrate vast amounts of information that they use to modify their behaviour to ensure the development and survival of the organism as a whole. Disruption in these lines of communication underlies almost all disease.
Despite the apparent complexity, diverse signalling processes are carried out by very similar sets of molecular components that interact in common patterns. This module will be taught via lectures which focus on the common molecular themes and concepts that underlie normal cell signalling. This will be interspersed with disease case studies that show how disruption of these processes affect cells, tissues, and the whole organism.
Assessment will include open-book on-line assessments which will focus on the evaluation of case studies, data analysis/interpretation.
Understanding how microorganisms interact with their host, and the environment, is fundamental for the understanding and developing treatment for microbial disease. On this module students will explore the molecular mechanisms that lead to microbial infection for bacteria, viruses and fungi. This knowledge will then be applied to help students gain insight of various therapeutic strategies used to control microbial infections and the challenges associated with this. The module will be delivered via lectures and workshops, utilising active-learning delivery methods to enhance student engagement. Teaching material will be hosted in the University virtual learning environment (VLE) to aid development of digital fluency and promote assimilation and appraisal of the module content. The module will be assessed by online tests combining MCQs, MAQs and short answer questions.
This module is about the parasites and pathogens that normally infect wild animals and plants and which cause disease in
people and livestock. The module will consider the different types of parasites and pathogens; how, when, and where they
infect hosts; the evolution (and co-evolution) of parasites and hosts, and host responses and adaptation to infection. The
module is taught through lectures and workshops, giving students the opportunity to discuss concepts and practice
problem solving. The assessment consists of producing a poster (or equivalent) on an example parasite or pathogen and a
Briefing Note on a real-world infection scenario.
Chemistry for Biosciences is designed for students who have studied chemistry at Level 3, and builds on prior knowledge to develop an understanding of the chemical principles that underlie the structure and function of macromolecules such as proteins, nucleic acids and polysaccharides, as well as their interactions with small molecule metabolites and drugs. The module is required for students studying Biochemistry, Pharmacology and Biomedical Sciences, and an option for other students with the relevant chemistry background from, for example, Microbiology and Biological Sciences.
The module will begin with an exercise in which students will study a set of representations of macromolecules and small molecules and use their prior knowledge to build a catalogue of the chemical processes relevant to understanding the molecules’ structure and function. These principles (including thermodynamics, kinetics, organic structure and mechanism, acids and bases and basic spectroscopy) will then be developed in later lecture sessions and workshops, which will involve the use of self-assessment questions to test understanding.
The module will be assessed in exam format using technical problems applying the methods addressed, along with interpretation of case studies of biological molecules and their interactions in short answer format.
The module explores the major animal and plant metabolic pathways that sustain life and, in some cases, those that account for disease. How plants create key nutrients and how animals use these to sustain life. How macromolecules (sugars, proteins, fats) and other useful metabolites are also created by animals and how plants can be used to harness new useful molecules. How metabolism is biologically integrated and linked to healthy lifestyles such as exercise and a balanced diet and how it is also linked to diseases such as cancer. Introduction to metabolomics and other techniques for studying metabolism such as bioinformatics. The module will be taught through a combination of lectures and workshops. and assessed by short answer exercises and an extended written piece.
Knowledge of the molecular physiology of cells and the physiology of organs on a systems level provides a fundamental basis for our understanding of the healthy body as well as disease-related mechanisms. Students will learn about a range of cellular functions, the roles of subcellular compartments, ranging from the nucleus to intracellular membrane compartments, plasma membrane and extracellular matrix, as well as dynamic molecular mechanisms like intracellular trafficking processes. Taking general cell biology to the organ systems level, this module will develop knowledge about the specialised functions of cells in specific human tissues and how the body regulates the various organ functions through communication pathways in a systemic way to achieve homeostasis. You will encounter various examples, including the digestive, renal, respiratory and neuroendocrine organs among others. Furthermore, you will be learning about a number of techniques and methods that are used to study the molecular biology of cells and the systems physiology of the body, including imaging techniques.
The module is taught through lectures and workshops, which are supported through directed reading/ multimedia.
There are two assessment in this module. The first assessment is a midterm assessment (40%) comprising a mixture of Multiple answer, multiple choice and extended matching item questions. The second assessment consists of two parts: Section 1 – assessing cellular and systems physiology concepts (30%) and Section 2 – Data interpretation and understanding (30%)
Drug discovery & development is risky: only 1 in 7 drugs entering clinical development obtained approval between 2000 and 2015. This module is designed to give students a broad understanding of the fundamental principles of drug discovery & development. The curriculum includes all important aspects of drug discovery & development, including target identification, drug design, safety assessment, clinical trials, and health economy. A highlight of this module is it will introduce some relevant mathematical modelling – (e.g., bioinformatics, computational chemistry and pharmacodynamics) which will prepare the students with necessary quantitative skills. Teaching will be via formal lectures and workshop and the module will be assessed by a multiple-choice question (MCQ) examination (40%) and written exam assessment (60%).
Year three will provide an unparalleled opportunity for you to learn at the cutting edge of microbiology and infection research and be taught by world-leading academics in the subjects of genomics, infectious diseases, and global challenges in infection. In addition, you will have optional modules enabling to follow your interests in cell signalling or immunology and veterinary pathology. You will also have the opportunity to take a physical or virtual placement. Central to this year is the research project where you will plan and execute your own research, analyse and critically evaluate data and communicate your research findings in your chosen specialisation.
The Research Project module is taken by all students studying a Biosciences BSc or MBiol degree. This 30-credit module runs throughout the Level 6 year and gives students the opportunity to experience authentic Biosciences research, applying the knowledge and skills that they have developed through the first two years, supported by the Research Methods module (BIOS303) in Semester 1 of Level 6 and under the guidance of an individual named supervisor. Students may work as a group to develop related or collaborative projects, although the assessment is always individual.
A large diversity of projects is available to students, including but not limited to lab-based (in research labs), field research, bioinformatics, mathematical modelling, computer analysis, meta-analysis, systematic review, education research, outreach, school-based projects. Students express a preference for keywords describing project content and style of project, and projects are allocated to optimise the fit between student preference and available projects.
Students meet their supervisor at the start of Semester 1 and develop a proposal for their project, including a literature review, aims and proposed methodology, with regular meetings with and guidance from their supervisor throughout the semester. Students are also instructed in relevant aspects of safety. The proposal is presented at the end of Semester 1 as an assessed negotiated communication (poster, live or video presentation), with discussion. This development of the proposal is supported by the concurrent Research Methods module, in which students will develop their skills in critical analysis of literature and appreciation of research ethics and will choose to study relevant research methodologies and associated analytical methods from a menu of options.
The substantive experimental work for the project is carried out in the first half of Semester 2, followed by the writing of the final project report, which is the primary assessed output of the project.
The student’s approach and development of skills throughout the project will be recorded in a reflective log consisting of an ongoing project record book followed by a marked written reflective piece at the end of the project period.
Successful completion of the Research project module will equip students with the organisational, technical and communication skills to carry out individual project work in their future careers.
This 15-credit year three module acts as a steppingstone for students into the world of work. The module will utilise and develop knowledge, understanding, and skills that students have acquired during their first five semesters of study. Incorporating a placement, it will provide an opportunity for students to improve skills that are particularly sought after by employers, such as problem solving, teamwork, and communication, and will train them to better recognise, evidence, and articulate their skillset to future employers. The module will be assessed via a reflective portfolio, that they will develop throughout their engagement with the module activities.
For those students undertaking a placement external to the university, costs may be associated with travel to and from the student’s placement site, and (temporary) accommodation if the student has to stay away from their normal term-time accommodation whilst attending the placement. Students will be made fully aware of these expenses, and the possibility of reimbursement will be considered on individual basis, where appropriate.
This module aims to provide a set of critical reflection and data communication skills in a subject-specific context. These skills will support students in the execution and presentation of their research projects (BIOS301), in the critical analysis of literature including a grounding in research ethics, and in the development of a repertoire of skills in experimental design, analysis and reporting of results specifically relevant to their project work. The module is taught through lectures, seminars and tutorials, as well as a collection of online materials, and has a strong emphasis on independent learning.
In the first part of the module students will be introduced to the key principles of critical thinking and will apply their skills to perform critical analyses of the scientific literature, in workshops in small groups drawn from their subject area. For assessment, they will produce a peer review for a sample article in their subject area. These skills will be directly applicable to the production of a research proposal for BIOS301, which involves a review of the literature forming the background to their project topic, and which is submitted at the end of semester 1.
In the second part students, in collaboration with their project supervisor, will select three examples most appropriate to their projects from a catalogue of experimental and associated analytical (including statistical) methods. They will develop their understanding using online material and drop-in workshops. The assessment will require the production of publication-quality figures reporting sample data or equivalent acquired using the relevant methods, with appropriate figure legends and explanatory text. The skills gained here will be directly applicable to the students’ project work and the production of their final report, submitted at the end of semester 2.
This is a 15 credit third year module that allows students to develop knowledge, skills, and techniques for investigating and controlling human and animal disease outbreaks. As part of the module, students will take part in a simulated disease outbreak scenario, where they will be responsible for determining the source and what approaches to take to control the outbreak. The module will build on the knowledge and skills they have developed over the course of their studies and allow them to apply this to control of disease outbreaks. The importance of developing knowledge and skills in this area is evidenced by the Covid-19 pandemic. The module comprises lectures, seminars, and workshops led by academics with expertise in the investigation of, and control of outbreaks.
The module will be assessed by a group poster presentation on a disease outbreak, a 5 minute individual pitch where students’ reflect on their role in the disease outbreak scenario and a piece of written science communication known as a POSTnote
This module is designed to offer a thorough introduction to the genomics and evolution of microbes. It will delve into how microbes adapt in response to both biotic and abiotic factors. The module will explore fundamental concepts in microbial genomics, comparative genomics, and microbial evolution, with a particular focus on the evolution of pathogenic and symbiotic lifestyles within host and microbial communities. A central theme will be the significance and application of genomics and bioinformatics in deciphering the genetics and mechanisms of evolution. The module will employ various teaching methods, including in-person lectures, tutorials, laboratory and computer workshops, supplemented with recorded content and recommended reading materials. Assessment will be practical, involving the completion of reports and papers on data handling.
This module serves as a focal subject for students on the BSc Microbiology and Infection. The module introduces students to key concepts of infectious disease particularly relating to emerging infections, outbreaks and pandemics as well as the medical challenges faced globally by these events. The research-connected teaching will focus on major pathogens and the features of disease, limiting transmission and treatment of infectious disease.
The module comprises lectures, workshops and seminars and uses active-learning delivery methods to ensure students can synthesise and evaluate relative merits, attributes, issues and applications of the topics. Teaching materials will be included on the VLE to develop digital fluency and promote assimilation and appraisal of the module content. The module will be assessed by use of a video blog, and an extended answer question with debate.
Cell signalling networks allow individual cells to communicate with each other to coordinate their behaviour, maintain homeostasis, and respond to changes in their environment. This transfer of information from one cell to another, through the use of signalling molecules such as hormones, neurotransmitters, and growth factors is fundamental to modern ideas in cellular dynamics, biophysics and cell signalling in both health and disease.
This module will provide students with the ability to access, collate and discuss the modern literature in cell signalling from a systems physiology perspective by active research staff using relevant examples from their own research. Successful students will develop the skills required for interpretation of experimental cell signalling data. The module will be taught through a series of lectures and tutorials and will be assessed by both open book assessments. Cycle one will be an online assessment, with a focus on data analysis and interpretation; cycle 2 will be continuous assessment, under examination conditions, in the form of an extended piece of writing.
Delve into the fascinating world of veterinary diseases across different species, led by experts in their field.
Explore pathology variations in diverse veterinary diseases, analysing and describing them in detail. Uncover the intricate cellular and immunological responses exhibited across different species. Investigate the underlying cellular and molecular mechanisms that drive veterinary diseases, gaining insights into the fundamental processes governing pathology and immunology.
Immerse yourself in a captivating learning environment, featuring dynamic lectures enriched with real-world examples. Lectures will be complemented with interactive online practical sessions, online resources, guided reading, and regular formative assessment exercises designed to gauge and strengthen your understanding. The module will be assessed by coursework, which are research-connected and allow for the student to showcase their critical thinking and problem-solving skills.
You’ll learn through a balanced mix of lectures, workshops, field work, seminars and tutorials as well as hands-on, practical laboratory sessions, working individually and in small groups.
Assessed work includes essays, presentations, group work, digital communications, qualitative and experimental reports and formal examinations with results from years two and three contributing to your final degree classification.
We have a distinctive approach to education, the Liverpool Curriculum Framework, which focuses on research-connected teaching, active learning, and authentic assessment to ensure our students graduate as digitally fluent and confident global citizens.
Studying with us means you can tailor your degree to suit you. Here's what is available on this course.
We have a distinctive approach to education, the Liverpool Curriculum Framework, which focuses on research-connected teaching, active learning, and authentic assessment to ensure our students graduate as digitally fluent and confident global citizens.
From arrival to alumni, we’re with you all the way:
Want to find out more about student life?
Chat with our student ambassadors and ask any questions you have.
As a Biosciences graduate from the University of Liverpool, you will have an excellent set of career options ahead of you.
Typical types of roles/routes our graduates have gone on include:
Your tuition fees, funding your studies, and other costs to consider.
UK fees (applies to Channel Islands, Isle of Man and Republic of Ireland) | |
---|---|
Full-time place, per year | £9,535 |
Year in industry fee | £1,850 |
Year abroad fee | £1,385 |
International fees | |
---|---|
Full-time place, per year | £29,100 |
Year in industry fee | £1,850 |
Year abroad fee | £14,550 |
Tuition fees cover the cost of your teaching and assessment, operating facilities such as libraries, IT equipment, and access to academic and personal support. Learn more about fees and funding.
We understand that budgeting for your time at university is important, and we want to make sure you understand any course-related costs that are not covered by your tuition fee. This includes the costs associated with placements or internships, and the optional field course in Uganda.
Find out more about the additional study costs that may apply to this course.
We offer a range of scholarships and bursaries that could help pay your tuition and living expenses.
We've set the country or region your qualifications are from as United Kingdom. Change it here
The qualifications and exam results you'll need to apply for this course.
We've set the country or region your qualifications are from as United Kingdom. Change it here
Your qualification | Requirements |
---|---|
A levels |
ABB includig Biology and a second science, preferably Chemistry, at A level. Applicants with the Extended Project Qualification (EPQ) are eligible for a reduction in grade requirements. For this course, the offer is BBB with A in the EPQ. You may automatically qualify for reduced entry requirements through our contextual offers scheme. If you don't meet the entry requirements, you may be able to complete a foundation year which would allow you to progress to this course. Available foundation years: |
T levels | |
GCSE | 4/C in English and 4/C in Mathematics |
Subject requirements |
Also accepted as a second science: Environmental Science, Mathematics, Physics, Geography, Psychology, Geology and Applied Science. For applicants from England, where A levels in Biology, Chemistry or Physics have been taken, we will also require a pass in the Practical Endorsement. |
BTEC Level 3 National Extended Diploma |
D*DD in Applied Science with a selection of preferred units in Biology and Chemistry, to include Distinction in Units 1 and 5 (Principles and Applications of Science I and II). For previous BTEC (QCF) qualification: D*DD in Applied Science with a selection of preferred units in Biology and Chemistry, with at least 120 Level 3 credits at Distinction. Please note alternative BTEC subjects are not acceptable for this programme. |
BTEC Applied Science unit requirements | |
International Baccalaureate |
33 points including 6 in Higher Level Biology and 5 in Higher Level Chemistry (or second science). |
Irish Leaving Certificate | H1, H2, H2, H2, H3, H3 |
Scottish Higher/Advanced Higher |
Not accepted without Advanced Highers at grades ABB. |
Welsh Baccalaureate Advanced | Accepted at grade B as equivalent to a third non-science A level at grade B. |
Access | 45 Level 3 credits in graded units in a relevant Diploma, including 30 at Distinction and a further 15 with at least Merit. 15 Distinctions are required in each of Biology and Chemistry. GCSE Mathematics and English grade C/4 also required. |
International qualifications |
Many countries have a different education system to that of the UK, meaning your qualifications may not meet our entry requirements. Completing your Foundation Certificate, such as that offered by the University of Liverpool International College, means you're guaranteed a place on your chosen course. |
You'll need to demonstrate competence in the use of English language, unless you’re from a majority English speaking country.
We accept a variety of international language tests and country-specific qualifications.
International applicants who do not meet the minimum required standard of English language can complete one of our Pre-Sessional English courses to achieve the required level.
English language qualification | Requirements |
---|---|
IELTS | 6.5 overall, with no component below 5.5 |
TOEFL iBT | 88 overall, with minimum scores of listening 17, writing 17, reading 17 and speaking 19. TOEFL Home Edition not accepted. |
Duolingo English Test | 120 overall, with no component below 95 |
Pearson PTE Academic | 61 overall, with no component below 59 |
LanguageCert Academic | 70 overall, with no skill below 60 |
Cambridge IGCSE First Language English 0500 | Grade C overall, with a minimum of grade 2 in speaking and listening. Speaking and listening must be separately endorsed on the certificate. |
Cambridge IGCSE First Language English 0990 | Grade 4 overall, with Merit in speaking and listening |
Cambridge IGCSE Second Language English 0510/0511 | 0510: Grade B overall, with a minimum of grade 2 in speaking. Speaking must be separately endorsed on the certificate. 0511: Grade B overall. |
Cambridge IGCSE Second Language English 0993/0991 | 0993: Grade 6 overall, with a minimum of grade 2 in speaking. Speaking must be separately endorsed on the certificate. 0991: Grade 6 overall. |
International Baccalaureate English A: Literature or Language & Literature | Grade 5 at Standard Level or grade 5 at Higher Level |
International Baccalaureate English B | Grade 7 at Standard Level or grade 6 at Higher Level |
Cambridge ESOL Level 2/3 Advanced | 176 overall, with no paper below 162 |
Do you need to complete a Pre-Sessional English course to meet the English language requirements for this course?
The length of Pre-Sessional English course you’ll need to take depends on your current level of English language ability.
Find out the length of Pre-Sessional English course you may require for this degree.
Have a question about this course or studying with us? Our dedicated enquiries team can help.
Last updated 25 November 2024 / / Programme terms and conditions