Our BSc Biochemistry (including foundation year) will be suitable for you if your academic qualifications do not yet meet our entry requirements for the three-year version of this course and you want a programme that improves your skills to support your academic performance.
This four-year course includes a foundation year (known as Year Zero) which is delivered by our Essex Pathways Department, followed by a further three years of study in our School of Life Sciences. During Year Zero, you study three academic subjects relevant to your chosen course as well as a compulsory academic skills module, with additional English language for non-English speakers. After successful completion of Year Zero, you progress to complete your course with our School of Life Sciences.
Your three years with our School of Life Sciences focuses on structure-function relationships of biomolecules which offers insight into the interactions that occur in the complex cellular pathways that control vision and cell death. On this course you will consider molecular-level processes across a range of disciplines including genetics, microbiology, forensics and medicines. Because of this breadth, biochemistry is hugely important, and advanced in this field over the past 100 years have been staggering. It’s an exciting time to be part of this fascinating area of study.
Our teaching is underpinned by research – new ideas and theories are tested in the classroom
We insist on small-group tutorial teaching to complement your formal lectures
You undertake your practical work in our new cutting-edge research labs
Our expert staff
Our Essex Pathways Department is a gateway to the University of Essex, helping students without standard entry requirements to grow in confidence, unlock their potential, and nurture their ambitions so they can progress in academic study.
As one of the largest schools at Essex, our School of Life Sciences offers a lively, friendly and supportive environment with research-led study and high quality teaching, where you will learn from and work alongside our expert staff.
The research undertaken in our School of Life Sciences covers a wide spectrum of biology – from the cell right through to communities and ecosystems. Key academic staff for this course include Dr Jonathan Worrall, who is researching new biotechnological applications of the antibiotic-producing actinobacterium Streptomycetes. The course director for BSc Biochemistry is Dr Brandon Reeder, who focuses on biochemical and biomedical based-research, particularly in the role of proteins in health and disease.
The University of Essex has a Women's Network to support female staff and students, and our School of Life Sciences was awarded the Athena Swan Silver Award in October 2020, which reflects the work carried out by staff in our School to continue to improve equality, including a mentorship scheme, support for postdoctoral research staff, and financial help towards childcare costs for academics who wish to attend conferences.
During Year Zero, you will have access to all of the facilities that the University of Essex has to offer, as well as those provided by our Essex Pathways Department to support you, such as:
computer labs for internet research
classrooms with access to PowerPoint facilities for student presentations
AV facilities for teaching and access to web-based learning materials
the Student Services Hub which will support you and provide information for all your needs
a social space stocked with magazines and newspapers, which provides an informal setting to meet your lecturers, tutors and friends
work in an open and friendly department, with shared staff-student social spaces
conduct your final-year research alongside academics and PhD students in shared labs
use state-of-the-art research facilities, from protein crystallisation robots, protein over-production facilities, to CO2 incubators, to cell imaging microscopes
receive training on using the Oxford Nanopore MinION, a portable handheld device that can sequence genomes in real time
You graduate ready to move into a wide variety of industrial and public sector careers, from the NHS to pharmaceuticals, forensic science, health and safety, teaching.
Our students have gone on to work in a number of laboratory-based roles in the pharmaceutical and biotechnology industries, and in hospitals, clinics and healthcare companies. Others have gone on to work in sales, publishing and management, while others still have chosen to enhance their career opportunities by studying for MSc or PhD degrees.
Biochemistry and biomedical science courses also provide the ideal background for entry onto postgraduate medicine programmes, and many of our graduates have obtained places at medical schools across the UK.
Other recent graduates have gone on to work for the following high-profile organisations:
SAL Cambridge (microbiology samples)
We also work with our University's Student Development Team to help you find out about further work experience, internships, placements, and voluntary opportunities.
All applications for degree courses with a foundation year will be considered individually, whether you
think you might not have the grades to enter the first year of a degree course;
have non-traditional qualifications or experience (e.g. you haven’t studied A-levels or a BTEC);
are returning to university after some time away from education; or
are looking for more support during the transition into university study.
Our standard offer is 72 UCAS tariff points from at least two full A-levels, or equivalent, to include a science subject.
Examples of the above tariff may include:
A-levels: DDD (including a science subject)
BTEC Level 3 Extended Diploma: MMP (in a science subject)
T-levels: Pass with E in core, depending on subject studied - advice on acceptability can be provided.
For this course we require level 3 (i.e. A-level, BTEC, etc.) scientific study.
Considered science subjects from all qualifications include Biology, Chemistry, Physics, Psychology, Maths, Geography, Sports Science and Applied Science.
All applicants must also hold GCSE Maths and Science at grade C/4 or above (or equivalent). We may be able to consider a pass in an OFQUAL regulated Level 2 Functional Skills Maths where you cannot meet the requirements for Maths at GCSE level. However, you are advised to try to retake GCSE Mathematics if possible as this will better prepare you for university study and future employment.
If you are unsure whether you meet the entry criteria, please get in touch for advice.
Mature applicants and non-traditional academic backgrounds:
We welcome applications from mature students (over 21) and students with non-traditional academic backgrounds (might not have gone on from school to take level 3 qualifications). We will consider your educational and employment history, along with your personal statement and reference, to gain a rounded view of your suitability for the course.
We might not need evidence of level 3 scientific study where you have relevant work experience in a scientific field, or where you have previous successful study at degree level.
You will still need to meet our GCSE requirements.
Essex Pathways Department can consider those with EU nationality and residence in the EU. If you would like to know more about the eligibility requirements for Essex Pathways Department, including if we could consider an application from you, please get in touch for advice.
We will require the equivalent of the entry requirements detailed above from an acceptable high school qualification, including a specified grade in Maths and an acceptable science subject.
Essex Pathways Department is unable to accept applications from international students. Foundation pathways for international students are available at the University of Essex International College and are delivered and awarded by Kaplan, in partnership with the University of Essex. Successful completion will enable you to progress to the relevant degree course at the University of Essex.
International & EU entry requirements
We accept a wide range of qualifications from applicants studying in the EU and other countries. Get in touch with any questions you may have about the qualifications we accept. Remember to tell us about the qualifications you have already completed or are currently taking.
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Other English language qualifications may be acceptable so please contact us for further details. If we accept the English component of an international qualification then it will be included in the information given about the academic levels required. Please note that date restrictions may apply to some English language qualifications
If you are an international student requiring a Student visa to study in the UK please see our immigration webpages for the latest Home Office guidance on English language qualifications.
If you do not meet our IELTS requirements then you may be able to complete a pre-sessional English pathway that enables you to start your course without retaking IELTS.
Our Year 0 courses are only open to UK and EU applicants. If you’re an international student, but do not meet the English language or academic requirements for direct admission to your chosen degree, you could prepare and gain entry through a pathway course. Find out more about opportunities available to you at the University of Essex International College.
We offer a flexible course structure with a mixture of core/compulsory modules, and optional modules chosen from lists.
Our research-led teaching is continually evolving to address the latest challenges and breakthroughs in the field, therefore all modules listed as subject to change. To view the compulsory modules and full list of optional modules currently on offer, please view the programme specification via the link below.
We understand that deciding where and what to study is a very important decision for you. We’ll make all reasonable efforts to provide you with the courses, services and facilities as described on our website. However, if we need to make material changes, for example due to significant disruption, or in response to COVID-19, we’ll let our applicants and students know as soon as possible.
Components and modules explained
Components are the blocks of study that make up your course. A component may have a set module which you must study, or a number of modules from which you can choose.
Each component has a status and carries a certain number of credits towards your qualification.
What this means
You must take the set module for this component and you must pass. No failure can be permitted.
Core with Options
You can choose which module to study from the available options for this component but you must pass. No failure can be permitted.
You must take the set module for this component. There may be limited opportunities to continue on the course/be eligible for the qualification if you fail.
Compulsory with Options
You can choose which module to study from the available options for this component. There may be limited opportunities to continue on the course/be eligible for the qualification if you fail.
You can choose which module to study from the available options for this component. There may be limited opportunities to continue on the course/be eligible for the qualification if you fail.
The modules that are available for you to choose for each component will depend on several factors, including which modules you have chosen for other components, which modules you have completed in previous years of your course, and which term the module is taught in.
Modules are the individual units of study for your course. Each module has its own set of learning outcomes and assessment criteria and also carries a certain number of credits.
In most cases you will study one module per component, but in some cases you may need to study more than one module. For example, a 30-credit component may comprise of either one 30-credit module, or two 15-credit modules, depending on the options available.
Modules may be taught at different times of the year and by a different department or school to the one your course is primarily based in. You can find this information from the module code. For example, the module code HR100-4-FY means:
The department or school the module will be taught by.
In this example, the module would be taught by the Department of History.
The module aims to provide you with a general understanding and curiosity about biology with a balance of plant biology, animal biology and microbiology. This involves an understanding of the diversity, lifecycles and evolution of life on Earth, together with the biological processes that enable organisms to live, sense and adapt to the ecosystems that they inhabit. It will develop an appreciation of the relevance of sustainability to all aspects of scientific developments relating to biological sciences.
The module aims to provide you with the knowledge and understanding of chemistry needed to underpin advanced study in biology. This involves an understanding of the basic facts, concepts and terminology of chemistry relevant to modern biology.
The module covers the mathematical skills needed to proceed to any degree course within the School of Life Sciences. The syllabus covers the mathematics of basic arithmetic and algebra, graphs and rates of change as well as statistical distributions and hypothesis testing. The associated work in classes and lab sessions develops the skills used to solve problems applicable to the study of biological sciences, with classwork and online assignments being set and full solutions provided as part of the feedback process.
This blended-learning module is designed to support students in their academic subject disciplines and to strengthen their confidence in key skills areas such as: academic writing, research, academic integrity, collaborative and reflective practices.
The students are supported through the use of subject-specific materials tailored to their chosen degrees with alignment of assessments between academic subject modules and the skills module.
Develop your skillset and boost your CV. This module prepares you for the coursework, laboratory practicals and research projects that you will encounter during undergraduate study. Get to know referencing systems and learn how to effectively communicate scientific information. Use scientific units and simple algebra and demonstrate understanding of logarithms, exponentials, geometry and elementary calculus. Learn how to design experiments, handle data and display, interpret and analyse basic statistics.
Teaching and learning will be through a mixture of lectures, classes, practicals and tutorials, with an emphasis on developing the key transferable skills needed for a career in biosciences.
The building blocks of life, plants and animals depend on the actions of individual cells. Investigate the biochemical characteristics of the small molecules and large macromolecules that allow cells to function. You examine the origins of life, cell structure and function, energy transductions, synthesis of molecules, and the eukaryotic cell cycle.
Microbes are essential for life, and they connect the health of humans, other animals and ecosystems. They help us digest our food, provide us with vitamins and are contribute to our health and wellbeing. Marine microbes provide about one-third of the oxygen we breath. And, by cleaning up pollutants and synthesising valuable products such as antibiotics, microbes are essential for the delivery of the United Nation’s Sustainable Development Goals. On the other hand, some microbes cause devastating diseases. Despite major advances in treatment and prevention, incidences of infectious disease continue to rise. You will learn about the vast diversity and evolution of these mostly beneficial microbes and learn about the pathogenicity of the harmful ones. You will examine how different viruses and bacteria invade, interact and replicate within their hosts. A series of four practical sessions in our new teaching laboratory will give you hands-on experience of growing, observing, purifying, counting and even killing microbes. This will provide you with sought-after skills, such as aseptic technique, serial dilution and data analysis.
Many recent advances in biological research have been born from an increased understanding of the molecules involved in systems and processes. But what do things look like beyond molecular level?<br><br>Study how molecules are formed from individual atoms, and how the properties of these constituent atoms influence molecular structure and reactivity. Examine the fundamental concepts of chemical bonding, electronegativity, acidity, basicity, hydrogen bonding and review the common organic functional groups and different types of isomerism.
Why do we all look different? Are some illnesses hereditary? Are animals born ready-suited to their environment? From the early theories of Mendel to modern studies in molecular genetics, you explore how scientists have answered these questions over the last 150 years.
Examine how the structure and function of DNA allows genetic material to be expressed, replicated and inherited, and consider how genetic variation leads to adaptive evolution. From developing new technologies in gene cloning to the applications for modern medicine, you explore how geneticists are building on the earlier achievements in this fundamentally important field to enhance our understanding of life on earth.
Explore the building blocks of life. From the proteins that make up our genetic code to the lipids that envelope our cells, explore the structure, function and biological role of the major macromolecules.
You investigate the basic principles of protein structural bioinformatics and protein structural evolution, examine how ligand-binding equilibria may form the basis of diverse biological phenomena, learn the structure and properties of monosaccharides and polysaccharides and review the major types of lipids.
This module develops key skills in analysis and interpretation of data, biochemical methodology and calculation of biochemical parameters.
To fully understand the function of biological systems, we must examine their underlying biochemical principles. You explore the importance of molecules which contain the p-block elements of oxygen, nitrogen, sulphur and phosphorus, concentrating on how their electron structure relates to the action of redox enzymes in metabolism. You also look at the biological role of main-group and transition metal cations.<br><br>You will also review the physical elements of biochemical reactions, including kinetics and thermodynamics. You determine reaction rates, reaction orders and activation energies as well as assessing how thermodynamic parameters affect reactions.
You will develop your transferable skills in scientific writing (including referencing and avoiding plagiarism), teamwork and communication through oral presentations, study and research skills (including essay writing, lecture note taking, use of library and databases). Teaching and learning will be through a mixture of lectures, classes, and tutorials. The emphasis will be on small group, tutorial-style teaching and interaction with other students on this module, with assessments tailored to your degree subject area.
Develop your practical and critical thinking skills during this week-long summer module. Basic knowledge gained from molecular biology is now being applied to solve industrial scale biological problems. You will rationally design bacteria by engineering DNA and transforming your microbe in the lab before presenting your results to peers.
Molecular biology is central to our knowledge of how biology "works" at a molecular level. This module explores the breadth of processes involved in the regulation of gene expression and the proteins that are made. You also discover the ever-expanding range of molecular biology techniques, including PCR, cloning and mutagenesis, and how these are applied to investigate and treat disease.
The study of cells is at the centre of modern biology. Learn how cellular components determine cell structure and function, how cells communicate and how signaling pathways regulate cell fate. You also explore the regulation of the cell cycle and cell death and learn about changes that occur in cells that have become cancerous. A solid understanding of cell biology opens doors to more specialist topics, such as plant biotechnology and cancer biology.
Assess the importance of zinc, copper and iron in biological systems and review how they are kept in stable equilibrium. Explore the structure and functions of proteins and enzymes that contain metal cofactors and discuss the diseases and possible treatments associated with both metal deficiency and overload.
Bioinformatics have become an indispensable skill for the next generation of biochemists and biologists in order to retrieve, analyse and interpret data. You will learn how to access, search and extract data from publicly available protein databases, and analyse and display results using appropriate software.
We are in the age of genomics and scientists have devised new technologies that can generate whole genome sequences in days which would once have taken years to achieve. Learn the high-throughput techniques of next-generation sequencing used to study genomes, the proteome and the interactome. Investigate how nucleotide sequences are analysed, applying the analytical tools used by research scientists and understand how new genes are discovered and their functions revealed. You also discover how our knowledge of gene structure is being applied in the emerging field of synthetic biology to create new organisms and modify existing ones by gene editing.
Understanding the shape, structure and folding of proteins can provide the basis for drug targeting in disease processes and enable us to develop a better understanding of specific biological pathways. This module takes a look at particular macromolecular assemblies using the most up-to-date structural biological techniques with a particular emphasis on x-ray crystallography.
This module aims to prepare you for carrying out an individual scientific investigation on a topic relating to your degree. Develop skills to identify a suitable question and then design an experimental approach to obtain data addressing this question. The assessment focuses on your analysis and presentation of these data in a suitable scientific paper format report, on the research, understanding and critical writing about the scientific literature relating to your project. Your oral project presentation skills and response to questions, the planning and management of your project work, your progress reflection and your employability skills will also be evaluated.
Building upon knowledge gained in previous years, you discuss the mathematical and structural models used to gauge enzyme activity, the mechanisms of allostery and the experimental basis on which the various models of allostery may be distinguished. You also explore the mechanism of action of the dehydrogenases and the steady state mechanisms of multi-site enzymes.
How does modern biology affect our day-to-day lives? Consider the impact of recent advances on society. Transgenic crops, ever-increasing (and sometimes unwanted) prolongation of life, cloning of animals – to what extent can science be allowed to manipulate nature? And who has the final say?
Biomembranes are of fundamental importance in determining the organisation and functioning of living cells. Biophysical and biochemical methods to study membranes will be discussed alongside the specific roles of membranes in the signal transduction, ion and solute transport and energy storage in cells.
Energy generation and transformation by membranes is an essential feature of all cells: membrane electron transport processes will be discussed (with particular attention being given to respiratory and photosynthetic processes), together with the chemiosmotic theory for ATP synthesis by membranes. A bottom up approach building from basic thermodynamics to observed macroscopic effects and biological function is taken. Particular emphasis is placed on the quantitative description of chemical free energy changes and electron transfer reactions allowing students to analyse and interpret biophysical data in the context of actual experiments.
The aim of this module is to provide you with current knowledge and understanding of cancer. We will discuss general aspects of cancer biology (cancer statistics and risk factors, origins and multistage nature of cancer, metastasis and angiogenesis). The identification and isolation of oncogenes and tumour suppressors and the mechanism of action of their products will be analysed. We will explore cancer molecular biology and signalling pathways in cancer. We will discuss cell cycle and apoptosis and their role in the maintenance of normal cell populations and in the emergence of cancer. The principles of some of the current approaches in cancer therapy will be discussed.
In our School of Life Sciences, you learn through a combination of lectures, seminars and practical lab sessions, giving you the opportunity to ask questions and develop skills by doing experiments at the laboratory bench.
Fees and funding
Fees will increase for each academic year of study.
Applications for our full-time undergraduate courses should be made through the Universities and Colleges Admissions Service (UCAS). Applications are online at: www.ucas.com. Full details on this process can be obtained from the UCAS website in the how to apply section.
Our UK students, and some of our EU and international students, who are still at school or college, can apply through their school. Your school will be able to check and then submit your completed application to UCAS. Our other international applicants (EU or worldwide) or independent applicants in the UK can also apply online through UCAS Apply.
The UCAS code for our University of Essex is ESSEX E70. The individual campus codes for our Loughton and Southend Campuses are ‘L’ and ‘S’ respectively.
Please note that this course is not open to international applicants.
You can find further information on how to apply, including information on transferring from another university, applying if you are not currently at a school or college, and applying for readmission on our How to apply and entry requirements page.
If you are an undergraduate student residing in the UK who has received an offer to study with us in October 2023, you will receive an email invitation to book onto one of our Applicant Days. Our Colchester Campus Applicant Days run from February to May 2023 on various Wednesdays and Saturdays, and our Southend Campus Applicant Days run from March to June 2023 on various weekdays and Saturdays. Applicant Days provide the opportunity to meet your department, tour our campus and accommodation, and chat to current students. We appreciate that travelling to university events can be expensive. This is why we have increased our Applicant Day Travel Bursary cap, allowing you to claim up to £150 as reimbursement for travel expenses. For further information about Applicant Days, including Terms and Conditions and eligibility criteria for our Travel Bursary, please visit our Applicant Days webpage.
Visit Colchester Campus
Home to 15,000 students from more than 130 countries, our Colchester Campus is the largest of our three sites, making us one of the most internationally diverse campuses on the planet - we like to think of ourselves as the world in one place.
If you live too far away to come to Essex (or have a busy lifestyle), no problem. Our 360 degree virtual tours allows you to explore our University from the comfort of your home. Check out our Colchester virtual tour and Southend virtual tour to see accommodation options, facilities and social spaces.
Our staff travel the world to speak to people about the courses on offer at Essex. Take a look at our list of exhibition dates to see if we’ll be near you in the future.
At Essex we pride ourselves on being a welcoming and inclusive student community. We offer a wide range of support to individuals and groups of student members who may have specific requirements, interests or responsibilities.
The University makes every effort to ensure that this information on its programme specification is accurate and up-to-date. Exceptionally it can be necessary to make changes, for example to courses, facilities or fees. Examples of such reasons might include, but are not limited to: strikes, other industrial action, staff illness, severe weather, fire, civil commotion, riot, invasion, terrorist attack or threat of terrorist attack (whether declared or not), natural disaster, restrictions imposed by government or public authorities, epidemic or pandemic disease, failure of public utilities or transport systems or the withdrawal/reduction of funding. Changes to courses may for example consist of variations to the content and method of delivery of programmes, courses and other services, to discontinue programmes, courses and other services and to merge or combine programmes or courses. The University will endeavour to keep such changes to a minimum, and will also keep students informed appropriately by updating our programme specifications. The University would inform and engage with you if your course was to be discontinued, and would provide you with options, where appropriate, in line with our Compensation and Refund Policy.
The full Procedures, Rules and Regulations of the University governing how it operates are set out in the Charter, Statutes and
Ordinances and in the University Regulations, Policy and Procedures.