|Study location||United Kingdom, Birmingham|
|Type||Bachelor courses, full-time|
|Nominal duration||3 years|
|Tuition fee||To be confirmed|
Undergraduate diploma (or higher)
A level Chemistry and a second science°. Minimum of five GCSEs to include Mathematics, English and double award science at grade 4/C.
The entry qualification documents are accepted in the following languages: English.
Often you can get a suitable transcript from your school. If this is not the case, you will need official translations along with verified copies of the original.
IELTS: 6.0 (with a minimum of 5.5 in each component)
At least 1 reference(s) must be provided.
A motivation letter must be added to your application.
The point where chemistry, biology and medicine meet, biochemistry deals with the molecular nuts and bolts of living organisms and diseases.
Advances in the biosciences are having a profound impact on our daily lives, from human health to conservation, making it a hugely rewarding area to study and work in. With 96.4% of our graduates in employment or further study 6 months after completing their studies with us (2015/16 Destination of Leavers from Higher Education survey), biochemistry provides huge potential for your future career path. Studying at Birmingham means you’ll benefit from high-technology facilities and teaching from world-renowned experts in their field. You’ll also be able to tailor your course to match your own interests and goals, and have the opportunity to join one of our research groups, working on live research projects.
First year modules
Fundamentals of Biochemistry – Fundamental biochemical processes taking place inside cells
Cell Biology and Physiology – Tissues, organelles, reproduction and development
Chemistry I – Inorganic and organic chemistry, including practical training.
Genetics I – Storage of genetic information, gene expression and regulation, mitosis and meiosis, gene linkage and chromosome mapping.
Metabolism – Enzyme catalysis and regulation, metabolism of carbohydrates and vitamins, experimental techniques to study metabolic reactions.
Physical Biochemistry – The fundamental laws governing biochemical reactions and how we can explore them experimentally.
Second year modules
Core modules (taken by all students on the Biochemistry programme)
Proteins and Enzymes – Protein structure and evolution, mechanisms of enzyme catalysis, techniques to determine protein structures.
Membranes, Energy and Metabolism – Biological membranes and their role in energy metabolism, regulation of metabolism by hormones and other factors
Molecular Biology and its Applications – Genetic analysis and gene cloning, DNA fingerprinting and forensics, genomics and computational approaches to genetics
Chemistry II – Spectroscopic techniques, synthesis of peptides, oligonucleotide and aromatic compounds, determining structures of simple organic molecules.
Communications and Skills in Biosciences – Science communication in videography, writing and speaking, ethics in science, analysis of the scientific literature.
Choose two optional modules
Example optional modules may include:
Cell and Developmental Biology – Development of multicellular organisms, interaction between cells and the cellular matrix, regulation of stem cell function.
Topics in Medical Biosciences – Neurobiology and neurotransmitters, pharmacology and anaesthetics, blood constituents and haemostasis, complement and immunity.
Genetics II – Organisation of genes and genomes, generation of genetic diversity, gene transmission and analysis of problems in transmission and molecular genetics.
Microbes and Man – The impact of microbes on humans, bacteria, fungi and viruses, common themes of infectious disease mechanisms.
Final year modules
Experimental Design, Analysis and Interpretation of Biochemical Data – Lectures and practicals focussing on analysing data from biochemical experiments, from considering experimental design, to preparing reagents to composing an experimental report.
Choose three optional modules*
Example optional modules may include:
Structures of Destruction – Bacterial and viral pathogens explored from the perspective of their molecular structures, protein misfolding and amyloid diseases.
Bacterial Gene Regulation – How genes are switched on or off in response to external stimuli, how control of gene expression can be explored experimentally.
Cellular Signalling** – Signal transduction in and between cells, G-protein coupled receptors, phospholipid and Ca2+ signalling, ligand-gated ion channels and electrical responses.
Cancer Biology – Regulation of cell division and aberrations in malignant tumours, genetic bases of tumourigenesis, programmed cell death.
Molecular and Cellular Immunology | Watch video – Evolution of the immune system, innate immunity, cell biology of immunity, structural basis of discrimination between self and non-self.
Molecular Basis of Bacterial Infection | Watch video – Evolution of bacterial virulence, antibiotics and antibiotics resistance, genomic data in analysing pathogenicity.
Genetics III – Genetic variation in humans and model organisms, dynamics of chromosome organisation during mitosis and meiosis, genome instability.
Applied and Environmental Microbiology – Microbial communities, how they compete, and behave socially.
Cellular Neurobiology** | Watch video – Neuronal function and neural development, synaptic function, transmitter receptors and ion channels.
Eukaryotic Gene Expression – The central processes in gene expression are transcription and translation. Control of gene expression plays an important role in development, homeostasis and disease. This module explores the molecular mechanisms used to control gene expression, including transcription initiation, post-transcriptional control and epigenetic.
Plant Sciences in the 21st Century | Watch video – Plant growth and development in relation to food supply, biofuels and climate change. Research-based module with emphasis on analysis of the current research literature.
Advances in the biosciences are having a profound impact on our daily lives in areas from human health to conservation. Biotechnology, biological pharmaceuticals, and personalised medicine are key growth areas in the health sector. Over the next decade our increasing understanding of how genomes are regulated will revolutionise how we interact with the natural world. Environmental remediation, climate change and related themes pose multi-faceted challenges for the coming decades. Expert knowledge in biology and the life sciences will be in high demand for the foreseeable future, with excellent prospects for exciting and rewarding careers in research, education, media, industry, the NHS and the public sector.
A significant number of our graduates choose to take a further degree, a postgraduate Masters or PhD. For many career paths, a further degree is an essential stepping-stone, including (but not limited to) careers in research. While many of our graduates remain in Birmingham and join one of our prestigious research groups, they are also highly sought after by universities around the world.
We are currently NOT ACCEPTING applications from NON-EU countries, except Georgia and Serbia.