Biology BSc (Hons)

On this course you'll:

• Perform basic analyses of DNA/protein sequences.
• Apply the principles of recombinant gene technology.
• Interpret genetic data and information relating to inheritance patterns, chromosome behaviour, mutations, and populations.
• Contrast gene organisation and gene expression in prokaryotes and eukaryotes.
• Calculate probabilities associated with inheritance patterns, including appropriate statistical tests to evaluate genetic predictions.
• Interpret phylogenetic trees based on sequence data.

On this course you'll:

• Plan the experimental approach for a scientific investigation, including ethics and risk assessment.
• Demonstrate proficiency in research skills.
• Analyse and interpret scientific data.
• Demonstrate comprehension in molecular biology methods.

On this module you'll:

• Describe and compare major physiological processes
• Describe and compare various morphological and behavioural adaptations in the animal world.
• Discuss the effects of the environment on systems.
• Analyse and evaluate experimental data in animal science

You’ll rapidly build knowledge across disciplines like marketing, finance and project management. You'll become equipped to evaluate and pursue new commercial opportunities. 

Working in teams, you’ll practice skills from communication to negotiation by developing plans for a prospective venture, receiving expert insights from practitioners along the way. With assessments focused on conceiving and presenting an impactful business case, you’ll strengthen abilities to persuade with data-backed reasoning.

On this course you'll:

• Reinforce theory of tissue staining, observation and description and Western blotting using antibodies.
• Explain the mechanisms involved in cell communication.
• Illustrate the cellular and genetic mechanisms of cell-cycle regulation.
• Illustrate the cellular and genetic mechanisms of differentiation.
• Illustrate the cellular and genetic mechanisms of cancer.
• Review the cellular mechanisms of immunity.

It focuses on empirical findings and methodological and theoretical issues in Comparative and Evolutionary Psychology. The current module offers you the opportunity to explore why we behave the way we do by studying the relationship between human and animal psychology.

Developmental Biology investigates the development of multicellular organisms throughout their lifespan, from the start of life and the emergence of the first organs to the changes in external appearance and organ function as well as organ repair and regeneration in the adult. Over the last nine decades, research in the field of developmental biology has led to major discoveries (and Nobel Prizes) and has spurred substantial medical progress (IVF, gene- and stem cell-based therapy, understanding of cancer). However, this progress has also sparked controversy (e.g. on therapeutic cloning, eugenics, xenotransplantation) and has shaken views on human identity and evolution.

You'll explore how, after fertilisation, functional organs and the adult body form emerges in the embryo, and you'll discuss how deviations from these developmental processes may result in major birth defects. You'll also investigate how cells and stem cells repair organs in the adult.

The content of the module will be delivered in lectures and workshops. In addition, you'll learn the basic practical skills of how to handle small samples under a microscope. The workshops support critical and independent thinking about the taught topics and re-emphasise the abstract concepts in developmental biology. In addition, the workshops and the second practical/demo in lecturers' research labs will discuss how scientific discoveries in developmental biology have been made and are being made today, and how we ensure that research aligns with the requirements of research ethics.

On this course you'll:

• Develop a critical understanding of the structure and function of enzymes.
• Analyse enzyme kinetics from practicals and workshops.
• Develop a wide and deep understanding of key metabolic processes.
• Build practice and experience of finding, intepreting and communicating information on enzymes.

You’ll learn core theory underpinning GIS and RS, before applying the theory through the use of industry standard software. You’ll explore the capture, interpretation and analysis of geographical and environmental data from a variety of sources to explore 'real world' problems and challenges.

You’ll get familiar with the big issues and contemporary debates in education studies as well as the role and expectations of a teacher.

You’ll develops fundamental knowledge and skills that teachers require, as well as your capability to structure and critique a lesson plan.

On this course you'll:

• Record, analyse and interpret field-collected data from different types of habitat and in a variety of contexts, including using taxonomic keys to identify and classify specimens
• Use aspects of ecological theory to design field experiments and understand the outcomes thereof
• Present and effectively communicate results and insights from ecological field studies
• Demonstrate an awareness of how ecological interactions, phenotypic traits, biodiversity, phylogeny and coevolution shape and structure ecological communities

On this course you'll:

• Develop a foundational understanding of key marine phyla, with a focus on their morphological and physiological adaptations to various habitats within marine ecosystems.
• Investigate the structure and function of marine ecosystems, with a focus on the interactions among marine organisms and their environment.
• Explore the role of biological, chemical, and physical processes in shaping marine ecosystems and the adaptations of marine organisms to these environmental factors.
• Understand the impacts of climate change and other human activities on marine organisms and ecosystems.
• Develop a foundational understanding of the techniques used to study marine organisms applying principles of taxonomy, systematics, and ecology through laboratory techniques and data analysis.
• Cultivate critical thinking and problem-solving skills by evaluating scientific literature on marine organism¿s biology and ecology, as well as engaging in collaborative learning and discussion.

On this course you'll:

• Show competence in safe and effective handling of microorganisms in the laboratory and be able to independently obtain, analyse and evaluate data.
• Understand the differences between bacteria, archaea, fungi and viruses, appreciate their diversity and different roles in environmental processes, global health and disease.
• Synthesise knowledge of microbial metabolic activities and the environmental effects in functional microbial ecology.
• Recall and understand microbial physiology and growth, and how this effects the environment and industrially relevant applications.
• Critically evaluate and reflect upon the evolution and phylogeny of microbial life.
• Develop an awareness of critical environmental issues in microbiology - such as nutrient cycle alterations associated with climate change and antimicrobial resistance in food chains.

On this course you'll:

• Demonstrate fundamental knowledge of plant structure, ecology, growth and development, genetics, sexual reproduction, systematics, and trait diversity.
• Identify the significance of plants and plant biodiversity to ecosystems at multiple scales.
• Evaluate the biology of plant domestication and the importance of plant diversity for society (e.g., agriculture, biotechnology, ecosystem function).
• Demonstrate, via practical skills (lab and computational), an understanding of plant evolution (morphology and genetics), by analysing and evaluating data from both experimental manipulations and observations.

On this module you'll:

• Outline the basic principles of conservation, including anthropogenic factors.
• Critically evaluate the biogeography and conservation literature.
• Analyse and creatively interpret conservation data.
• Communicate conservation principles effectively, in a style suitable for multiple audiences.

On this course you'll:

• Characterise and critically evaluate key evolutionary and ecological concepts and mechanisms that either create or constrain trait diversity in both animals and plants.
• Critically evaluate the effects of environmental variables, such as climate, on the biology and ecology of natural populations.
• Apply selected contemporary ecological and evolutionary scientific methodologies that are at the forefront of the discipline, as well as discuss the benefits, capabilities, and limits thereof.
• Demonstrate the ability to research and to critically interpret and evaluate relevant scientific literature of a specific evolutionary or ecological topic, and disseminate the broader significance thereof.

On this course you'll:

• Explain the mechanisms by which eukaryotic gene expression can be regulated at different level.
• Diagram processes and concepts in gene regulation.
• Outline methods to investigate gene regulatory mechanisms.
• Evaluate the contribution of the various processes to the regulation of gene expression.
• Compare different approaches for analysing genome organisation and gene expression.
• Interpret experimental data in eukaryotic genome organisation and gene expression.

On this course you'll:

• Critically evaluate strategies to sequence human genomes.
• Evaluate the application of genomics to the analysis of normal and diseased gene function.
• Explain the concept of the transcriptome and the epigenome and how it is used to explain genetic disease.
• Analyse the wider application of genome analysis to complex, polygenic diseases and inherited traits.

On this course you'll:

• Analyse functioning of marine ecosystems using data collection and interpretation.
• Critically evaluate marine ecosystem functions and the key challenges of implementing effective marine conservation, including active restoration.
• Demonstrate early professional level skills in teamwork, information searching, communication and independent thinking.
• Demonstrate a scientific and critical perspective of human impacts on marine ecosystems; biodiversity and function
• Demonstrate scientific knowledge of the ecology of a range of marine habitats

On this course you'll:

• Compare and contrast the major developmental mechanisms in embryos from a range of model organisms.
• Assess the relationship between developmental biology and evolution.
• Propose appropriate experimental systems to investigate specific problems in developmental biology.
• Analyse and interpret data relating to developmental biology
• Critically assess the main lines of reasoning in landmark papers in development biology.
• Identify and access relevant literature and information sources including online databases.

On this course you'll:

• Understand the nature and interactions of whole microbial communities in environmental and host systems
• Gain an overview of modern approaches & techniques to study microbes in their natural habitats
• Appreciate the critical functions of microbes in key Earth and host systems
• Acquire basic skills in bioinformatic/computational analyses of microbiome data
• Prepare a written report of a laboratory investigation, incorporating a critical discussion of the findings and supported by background research

On this course you'll:

• Be able to confidently identify a range of native British flora to species level, including the key diagnostic characteristics of taxonomically difficult groups such as the Poaceae and Asteraceae.
• Critically assess the use of different types of ecological sampling techniques, including an awareness of licenses required for protected species.
• Discuss and critically compare current legislative frameworks used for ecological surveying.
• Evaluate the overall biodiversity of terrestrial habitats using industry standard techniques.