Animal Science BSc

What major physiology systems are essential for life in animals and humans? In this module you will learn about:

• the body's principle physiological systems including the nervous, respiratory, cardiovascular, reproductive, renal and digestive systems
• the structure and function of the major organs including the function of individual cell types

Through weekly lectures, we will cover topics on genes, proteins and membranes, transport of molecules across membranes, nerve signalling and biorhythms. 

Nutrients are vital to human and animal health, but how do they work? In this module, you’ll be given a comprehensive introduction to the key concepts in the field of nutrition. Depending on your interests, you can study human or animal nutrition, or both. Understand how the food we eat influences our health. Explore how the food eaten by animals impacts on food production and the global food system.

You’ll study:

• micronutrients, including vitamins and minerals
• macronutrients, including proteins, carbohydrates and fats
• metabolism, and how nutrients give us energy
• the influence of nutrition in diseases such as cancer and diabetes

Have you ever wondered how some crops can resist diseases? This module provides you with the fundamentals for understanding biochemical processes in living organisms. You’ll be introduced to the basic structure, properties and functions of the four key biological macromolecules: nucleic acids, proteins, carbohydrates and lipids. You’ll also look at the metabolic pathways occurring in cells, such as respiration, photosynthesis and the biosynthetic pathways for the key macromolecules. In addition to lectures, you’ll have practical laboratory sessions to learn how to use key biochemical techniques for the separation and analysis of macromolecules and measurement of the metabolic process.

Cells are the basic functional units of life, but how do they grow and develop? In this module, you’ll follow the lifecycle of cells. You'll focus on mitosis, meiosis, cell division and differentiation. We’ll put cells not just under the microscope, but use advanced laboratory technologies to explore the ultrastructure of cells. These are the parts of cells too small to be seen through ordinary laboratory equipment. You’ll then put this science to the test, to apply cellular biology to applied genetics.

You’ll study:

• structures and ultrastructures of animal and plant cells
• microscopic features of bacteria and viruses
• gene replication, expression and inheritance
• laboratory methods used to discover how cells work

In a series of lectures, workshops and practicals you’ll further develop your understanding of gene structure, function and regulation and investigate how this knowledge can be applied in recombinant DNA technology through DNA sequencing and genetic engineering. Specialist options within animal, plant and microbial spheres will allow for subject specific applications of genetic techniques and theories which form an underpinning knowledge base for subsequent modules.

This module is intended to enhance your transition into university and guide you through the academic expectations of your degree. This module includes three generic sessions on ‘study skills and plagiarism’, ‘study opportunities’ and ‘career and personal development’, and a series of small group tutorials with your academic tutor to develop generic skills such as finding crucial information, oral presentation, data handling and presentation of results, preparation for examinations, and essay writing skills relevant to biosciences.

How can you use science to help improve global food security? This module introduces you to the issues of global food security and the complexity existing in different parts of our food generation system. Looking across the food supply chain, you’ll cover the evolution of crops, crop and animal production, and the food industry. Importantly, you’ll also look at sustainable nutrition because food security isn’t just about supply – it’s important that people are getting the right kind of food. You’ll learn about these issues through a mix of lectures and practical laboratory sessions. You’ll also develop professional skills to work safely in laboratory situations.

This module introduces the major physiological systems which are essential for life in animals and humans: the nervous, respiratory, cardiovascular, reproductive, renal, and digestive systems. You’ll learn about the structures and functions of the major organs and the functions of individual cell types. Topics covered in the lectures will refer to genes, proteins and membranes, transport of molecules across membranes, nerve signalling and biorhythms. The lectures will be complemented by anatomy practical sessions to help you understand physiological function. These will cover gross and cellular anatomy through tissue dissection and histology. 

In lectures on this module you’ll be introduced to concepts in animal evolution (Darwinian evolution, natural selection, speciation), diversity across the animal kingdom (classification of invertebrates and vertebrates), animal ecology (biodiversity, interactions between species, conservation), animal development (fertilization, gastrulation, organogenesis), animal behaviour (costs and benefits of different innate and learned behaviours), and ethical issues related to animal-human interactions. The module also includes a visit to Twycross Zoo and a practical animal handling session.

A highly applied module, you’ll learn about animal physiology, nutrition and management and use your knowledge to think critically about production systems. Focusing on the nutrition, growth and welfare of farmed animals, you’ll cover a wide range of subjects, including investigating the energy and protein evaluation systems for ruminants and non-ruminants and the differential maturity of individual carcass components. You’ll compare systems of production for all major species of livestock and explore how these different systems integrate with each other and other enterprises on farms. Visits to local livestock farms give you the opportunity to further develop your understanding within a ‘real-life’ context and are a core component of the module.

Building on the physiology of year one, this module considers the physiology and pharmacology of systems involving the principal electrically excitable tissues in the body i.e. the nervous system, musculature and cardiovascular system. You will investigate how the nervous system controls and modulates these tissues (e.g. muscles including cardiac tissue) in an integrated system. You will have lectures and practical classes to learn how to collect, analyse and present real data from the neuromuscular, somatosensory and cardiovascular systems as well as how to perform a quantitative pharmacological investigation.

This module will introduce the major effects of diseases on the body’s physiological and immunological systems. The main types of disease will then be systematically discussed using a range of companion, farm and exotic animal species including poultry, equine, bovine and ovine species. You’ll have lectures and laboratory practicals each week.

You'll cover the core research process and data analysis skills including literature searches, data collection and processing, and statistical analysis. This will prepare you for your third year research project. Research projects are also selected during this module.

Hormones carry signals between different parts of the body. But how do nutrients determine the interaction between hormones and health? In this module, you’ll carry out an in-depth study of the mammalian endocrine system. You'll look at this from cellular, molecular and anatomical perspectives. You'll explore the role that hormones play in controlling homeostasis and metabolism. We use the latest published nutritional research. You'll look at appetite regulation and how endocrine systems determine what, how and when we eat.

You’ll study:

• nutritional energetics and energy expenditure
• appetite regulation by the endocrine system
• homeostasis in relation to the diet

In this module you’ll learn about the development, physiology and regulation of mammalian reproduction, the control of avian reproduction, and lactation. You’ll cover mammalian reproduction, including physiological control, cyclicity and reproductive efficiency. You’ll also consider avian physiology and reproduction in domestic fowl, with an emphasis on the nutritional and metabolic challenges associated with commercial rates of egg lay. Lactation will also be covered, where you’ll learn about the development of mammary tissue, the biochemistry of milk synthesis, the endocrine control of milk secretion, and the metabolic correlates of lactation in dairy ruminants. You’ll have a mix of lectures and practical laboratory sessions for experimental work and dissection.

How important is protein quality in your livestock’s diet? How can you formulate an optimum diet? In this module you’ll learn about diet formulation and food analysis. You’ll examine topics such as: dietary energy and nutritional energetics, protein and amino acid nutrition, and regulation of appetite and energy expenditure. You’ll be able to calculate the different energy requirements of animals in different physiological or pathological states. There will be a mix of lectures, seminars and computer-based workshops to apply what you’ve learnt. 

The module will provide an introduction to viruses and their interactions with their hosts (bacteria, plants and animals including humans) as well as discussing the structure of viruses and their significance including pathogenesis and molecular biology. You’ll spend four hours per week in lectures studying for this module.

In this module you’ll learn about the development, physiology and regulation of mammalian reproduction, the control of avian reproduction, and lactation. You’ll cover mammalian reproduction, including physiological control, cyclicity and reproductive efficiency. You’ll also consider avian physiology and reproduction in domestic fowl, with an emphasis on the nutritional and metabolic challenges associated with commercial rates of egg lay. Lactation will also be covered, where you’ll learn about the development of mammary tissue, the biochemistry of milk synthesis, the endocrine control of milk secretion, and the metabolic correlates of lactation in dairy ruminants. You’ll have a mix of lectures and practical laboratory sessions for experimental work and dissection.

You'll cover the core research process and data analysis skills including literature searches, data collection and processing, and statistical analysis. This will prepare you for your third year research project. Research projects are also selected during this module.

Building on the physiology of year one, this module considers the physiology and pharmacology of systems involving the principal electrically excitable tissues in the body i.e. the nervous system, musculature and cardiovascular system. You will investigate how the nervous system controls and modulates these tissues (e.g. muscles including cardiac tissue) in an integrated system. You will have lectures and practical classes to learn how to collect, analyse and present real data from the neuromuscular, somatosensory and cardiovascular systems as well as how to perform a quantitative pharmacological investigation.

Hormones carry signals between different parts of the body, but how do nutrients determine the interaction between hormones and health? In this module, you’ll carry out an in-depth study of the mammalian endocrine system. You'll look at this from cellular, molecular and anatomical perspectives. You'll explore the role that hormones play in controlling homeostasis and metabolism. We use the latest published nutritional research. You'll study appetite regulation and how endocrine systems determine what, how and when we eat.

You’ll study:

• Nutritional energetics and energy expenditure
• Appetite regulation by the endocrine system
• Homeostasis in relation to the diet

You will learn about the forces determining the distribution and abundance of species and be able to use models to predict the dynamics of populations under a range of conditions. You will recognise how interactions between species can drive co-evolutionary processes leading to an understanding of the organisation of natural systems working systematically from populations through to communities, ecosystems and biogeographical scales.

This module will introduce the major effects of diseases on the body’s physiological and immunological systems. The main types of disease will then be systematically discussed using a range of companion, farm and exotic animal species including poultry, equine, bovine and ovine species. You’ll have lectures and laboratory practicals each week.

Through practical sessions, you will learn the techniques of biological image production and manipulation, including the ability to generate biological images of the highest technical quality and scientific value. You will build an understanding of the principles behind photography and how to get the most out of state of the art photographic and imaging equipment.

Introduces key evolutionary concepts and their application in the animal kingdom. Areas you will study include the history of evolutionary thinking, natural selection versus the neutral theory, sexual selection and human evolution. 

In this module you’ll learn about the development, physiology and regulation of mammalian reproduction, the control of avian reproduction, and lactation. You’ll cover mammalian reproduction, including physiological control, cyclicity and reproductive efficiency. You’ll also consider avian physiology and reproduction in domestic fowl, with an emphasis on the nutritional and metabolic challenges associated with commercial rates of egg lay. Lactation will also be covered, where you’ll learn about the development of mammary tissue, the biochemistry of milk synthesis, the endocrine control of milk secretion, and the metabolic correlates of lactation in dairy ruminants. You’ll have a mix of lectures and practical laboratory sessions for experimental work and dissection.

How important is protein quality in your livestock’s diet? How can you formulate an optimum diet? In this module you’ll learn about diet formulation and food analysis. You’ll examine topics such as: dietary energy and nutritional energetics, protein and amino acid nutrition, and regulation of appetite and energy expenditure. You’ll be able to calculate the different energy requirements of animals in different physiological or pathological states. There will be a mix of lectures, seminars and computer-based workshops to apply what you’ve learnt. 

A highly applied module, you’ll learn about animal physiology, nutrition and management and use your knowledge to think critically about production systems. Focusing on the nutrition, growth and welfare of farmed animals, you’ll cover a wide range of subjects, including investigating the energy and protein evaluation systems for ruminants and non-ruminants and the differential maturity of individual carcass components. You’ll compare systems of production for all major species of livestock and explore how these different systems integrate with each other and other enterprises on farms. Visits to local livestock farms give you the opportunity to further develop your understanding within a ‘real-life’ context and are a core component of the module.

You'll cover the core research process and data analysis skills including literature searches, data collection and processing, and statistical analysis. This will prepare you for your third year research project. Research projects are also selected during this module.

This module will introduce the major effects of diseases on the body’s physiological and immunological systems. The main types of disease will then be systematically discussed using a range of companion, farm and exotic animal species including poultry, equine, bovine and ovine species. You’ll have lectures and laboratory practicals each week.

Hormones carry signals between different parts of the body, but how do nutrients determine the interaction between hormones and health? In this module, you’ll carry out an in-depth study of the mammalian endocrine system. You'll look at this from cellular, molecular and anatomical perspectives. You'll explore the role that hormones play in controlling homeostasis and metabolism. We use the latest published nutritional research. You'll study appetite regulation and how endocrine systems determine what, how and when we eat.

You’ll study:

• Nutritional energetics and energy expenditure
• Appetite regulation by the endocrine system
• Homeostasis in relation to the diet

Building on the physiology of year one, this module considers the physiology and pharmacology of systems involving the principal electrically excitable tissues in the body i.e. the nervous system, musculature and cardiovascular system. You will investigate how the nervous system controls and modulates these tissues (e.g. muscles including cardiac tissue) in an integrated system. You will have lectures and practical classes to learn how to collect, analyse and present real data from the neuromuscular, somatosensory and cardiovascular systems as well as how to perform a quantitative pharmacological investigation.

The nature of agrifood commodities and products creates particular challenges for those buying and selling these goods, with implications for risk, stability and profitability for the agricultural business. This module examines the role of marketing in the successful operation of an agribusiness. Working in teams, you’ll examine how to use marketing to meet the challenges and opportunities faced by today’s agribusinesses.

Economic analysis can help you answer important management questions:

• How much fertiliser should I apply to my wheat?
• If demand for beer is going up, how will that affect the price I receive for my barley?

Through this module you’ll gain an understanding of economic ideas and principles and be able to apply them to a range of problems of interest to agricultural and environmental scientists and managers. You’ll also examine the arguments for government intervention to correct ‘market failures’ with reference to the latest government environmental schemes. 

In this module you’ll learn about the development, physiology and regulation of mammalian reproduction, the control of avian reproduction, and lactation. You’ll cover mammalian reproduction, including physiological control, cyclicity and reproductive efficiency. You’ll also consider avian physiology and reproduction in domestic fowl, with an emphasis on the nutritional and metabolic challenges associated with commercial rates of egg lay. Lactation will also be covered, where you’ll learn about the development of mammary tissue, the biochemistry of milk synthesis, the endocrine control of milk secretion, and the metabolic correlates of lactation in dairy ruminants. You’ll have a mix of lectures and practical laboratory sessions for experimental work and dissection.

Building on the physiology of year one, this module considers the physiology and pharmacology of systems involving the principal electrically excitable tissues in the body i.e. the nervous system, musculature and cardiovascular system. You will investigate how the nervous system controls and modulates these tissues (e.g. muscles including cardiac tissue) in an integrated system. You will have lectures and practical classes to learn how to collect, analyse and present real data from the neuromuscular, somatosensory and cardiovascular systems as well as how to perform a quantitative pharmacological investigation.

This module introduces current concepts of molecular mechanisms in animal development and techniques to study and manipulate animal phenotypes. You will study how developmental programs are remarkably conserved among species, including humans. Insights gained from molecular studies of the fruit fly, zebra fish and chicken are directly relevant to our understanding of mammalian development. Signals and factors regulating key events in establishing the body plan of an animal are discussed. Epigenetic processes in mammals that mediate X-chromosome inactivation and genomic imprinting will be described.

You'll cover the core research process and data analysis skills including literature searches, data collection and processing, and statistical analysis. This will prepare you for your third year research project. Research projects are also selected during this module.

Hormones carry signals between different parts of the body. But how do nutrients determine the interaction between hormones and health? In this module, you’ll carry out an in-depth study of the mammalian endocrine system. You'll look at this from cellular, molecular and anatomical perspectives. You'll explore the role that hormones play in controlling homeostasis and metabolism. We use the latest published nutritional research. You'll look at appetite regulation and how endocrine systems determine what, how and when we eat.

You’ll study:

• nutritional energetics and energy expenditure
• appetite regulation by the endocrine system
• homeostasis in relation to the diet

The module will provide an introduction to viruses and their interactions with their hosts (bacteria, plants and animals including humans) as well as discussing the structure of viruses and their significance including pathogenesis and molecular biology. You’ll spend four hours per week in lectures studying for this module.

How important is protein quality in your livestock’s diet? How can you formulate an optimum diet? In this module you’ll learn about diet formulation and food analysis. You’ll examine topics such as: dietary energy and nutritional energetics, protein and amino acid nutrition, and regulation of appetite and energy expenditure. You’ll be able to calculate the different energy requirements of animals in different physiological or pathological states. There will be a mix of lectures, seminars and computer-based workshops to apply what you’ve learnt. 

This module will introduce the major effects of diseases on the body’s physiological and immunological systems. The main types of disease will then be systematically discussed using a range of companion, farm and exotic animal species including poultry, equine, bovine and ovine species. You’ll have lectures and laboratory practicals each week.

You will undertake a research project under the supervision of an academic member of staff. Your work may involve animals (farm livestock, companion species) or laboratory techniques to study animal physiology, biochemistry, and development at the molecular, tissue, organ, and/or whole animal levels. You may also work on a library-based project that lets you carry out an in-depth study of the scientific literature in an area of your interest. Some projects are undertaken through the University Farm and Dairy centre, while other projects are undertaken offsite; we have links with nearby Twycross Zoo.

Our academics conduct cutting-edge research on reproduction, development, growth and health of domestic animals, including programmes in genetics, nutrition, reproduction, early development, animal biotechnology, neurophysiology, and applied bioethics. You will prepare a dissertation of 5000-6000 words and give a presentation on your project.

How does the brain control physiology and behaviour? In this module you’ll build on your knowledge from previous modules to examine the detailed physiological basis of integrated behaviours in animals. You’ll cover; nervous system control of cardiovascular function, respiration, body temperature, emotion, motivation and their associated behaviours. You’ll have lectures on the above along with practical sessions on the integrative aspects of exercise physiology.

This module will focus on the anatomy and physiology of the limbs in farm and domestic animal species through lectures and hands-on practical sessions. The skeletal structure, arrangement of muscles, and nerve supply in relation to normal and abnormal movement will be covered. Common diseases and injuries of the limbs will also be considered, along with treatment strategies.

The module will develop concepts introduced in year two with a series of lectures, leading to an advanced understanding of how to assess the health of animals. The effects of disease in domesticated animals will be covered including their physiological and immunological responses to disease, and the economic, welfare and legal impacts of disease. Examples from companion, farm and rodent species will be used.

How does the central nervous system sense the environment and react to it? In this module, you’ll learn about central nervous control of sensory and motor pathways and how these systems interact. In particular, you’ll examine the anatomy, physiology and pharmacology of sensory and motor systems and their integration in posture, coordinated movement and protective reflex responses. A strong emphasis will be on the physiology and pharmacology of acute and chronic pain and you’ll study the use of analgesics to treat these conditions. You’ll also gain understanding of the methodology behind a number of neuroscientific techniques and their application in novel research. You’ll have a mix of lectures, computer-based learning and practical laboratory sessions to reinforce and apply your knowledge.

This module will further develop your specialised knowledge of animal nutrition. At an advanced level, you’ll learn about the role of micronutrient and trace minerals and organic micronutrients (including vitamins B, choline and essential fatty acids) in the nutritional requirements for animal health and growth in both ruminant and non-ruminant species. You’ll also examine the various factors involved in the regulation of animal growth and product quality and look at selected examples of metabolic disorders. Using the most up-to-date scientific research, you’ll explore specialist aspects of ruminant nutrition and produce scientific work of your own.

Want to know more about the nutrition of your dog or horse, or maybe what an elephant needs to eat? In this module you’ll study the nutrition, health and welfare of major companion species, including dogs, cats, horses, rabbits and some zoo/exotic species. You’ll learn about the interactions between nutrition, health and longevity within the broad area of ‘clinical nutrition’. Bringing in current research, you’ll look at the problems arising from keeping animals in captivity, and how social interactions between humans and companion animals can impact upon animal health and welfare. You’ll have lectures from current researchers and have a field trip to put what you’ve learnt into practice.

Animal-human interactions raise some prominent ethical issues. In this module, you’ll examine the ethical dimensions concerning animal agriculture, modern biotechnologies and research in the biosciences, in relation to both humans and non-human species. You’ll learn about the ethical frameworks used to analyse specific dilemmas raised by the human use of animals. Using specific animal and biotechnology case studies, you’ll interpret the main ethical theories and principles and apply them to the case studies to inform professional decision-making. You’ll have a mix of lectures and seminars to explore these concepts.

You will undertake a research project under the supervision of an academic member of staff. Your work may involve animals (farm livestock, companion species) or laboratory techniques to study animal physiology, biochemistry, and development at the molecular, tissue, organ, and/or whole animal levels. You may also work on a library-based project that lets you carry out an in-depth study of the scientific literature in an area of your interest. Some projects are undertaken through the University Farm and Dairy centre, while other projects are undertaken offsite; we have links with nearby Twycross Zoo.

Our academics conduct cutting-edge research on reproduction, development, growth and health of domestic animals, including programmes in genetics, nutrition, reproduction, early development, animal biotechnology, neurophysiology, and applied bioethics. You will prepare a dissertation of 5000-6000 words and give a presentation on your project.

Want to know more about the nutrition of your dog or horse, or maybe what an elephant needs to eat? In this module you’ll study the nutrition, health and welfare of major companion species, including dogs, cats, horses, rabbits and some zoo/exotic species. You’ll learn about the interactions between nutrition, health and longevity within the broad area of ‘clinical nutrition’. Bringing in current research, you’ll look at the problems arising from keeping animals in captivity, and how social interactions between humans and companion animals can impact upon animal health and welfare. You’ll have lectures from current researchers and have a field trip to put what you’ve learnt into practice.

Consider a range of approaches to conservation biology, such as the measurement and monitoring of biodiversity, and the legal frameworks and management strategies that exist to protect it. You will discuss particular threats to biodiversity, such as habitat loss and invasive species. You will spend around four hours per week in lectures and have four three-hour practicals to study for this module.

Considers current knowledge of, and research into, the ecological causes and evolutionary processes that govern natural selection, adaptation and microevolution in natural populations. You will examine three approaches to the study of evolutionary ecology: theoretical and optimality models; the comparative method; and direct measurement of natural selection in the wild. You will have two-to three hours of lectures each week in this module.

Consider the genetic effects of reduced population size, especially relating to the conservation of endangered species. You will study topics including genetic drift and inbreeding in depth, from theoretical and practical standpoints. You will spend around one and a half hours per week in lectures studying this module, plus a two and a half hour computer practical.

Building on Applied Bioethics 1, you’ll investigate widely accepted ethical principles and apply your insights to contemporary ethical issues in agricultural, food and environmental sciences. You’ll explore the ethical dimensions of prominent issues raised by the agricultural practices (including the use of biotechnology and GM crops) designed to meet the nutritional needs of the global population. You’ll also learn about how ethical theory can inform professional choices and public policies related to food production and environmental management. You’ll have a mix of lectures, tutorials and team-based exercises to develop a sound understanding of ethical principles.

Animal-human interactions raise some prominent ethical issues. In this module, you’ll examine the ethical dimensions concerning animal agriculture, modern biotechnologies and research in the biosciences, in relation to both humans and non-human species. You’ll learn about the ethical frameworks used to analyse specific dilemmas raised by the human use of animals. Using specific animal and biotechnology case studies, you’ll interpret the main ethical theories and principles and apply them to the case studies to inform professional decision-making. You’ll have a mix of lectures and seminars to explore these concepts.

You will undertake a research project under the supervision of an academic member of staff. Your work may involve animals (farm livestock, companion species) or laboratory techniques to study animal physiology, biochemistry, and development at the molecular, tissue, organ, and/or whole animal levels. You may also work on a library-based project that lets you carry out an in-depth study of the scientific literature in an area of your interest. Some projects are undertaken through the University Farm and Dairy centre, while other projects are undertaken offsite; we have links with nearby Twycross Zoo.

Our academics conduct cutting-edge research on reproduction, development, growth and health of domestic animals, including programmes in genetics, nutrition, reproduction, early development, animal biotechnology, neurophysiology, and applied bioethics. You will prepare a dissertation of 5000-6000 words and give a presentation on your project.

How can production systems be adapted to meet demands for animal products in contrasting global markets? In this module, you’ll use your knowledge of physiology, nutrition, genetics, health, welfare and management to study the production of meat, milk and eggs, and the wellbeing of the animals in these production systems. You’ll undertake a detailed study of the integration of the production, nutrition, product quality, management and health of beef and dairy cattle, sheep, pigs and poultry at UK and global scales. You’ll be able to critically analyse key performance indicators and provide solutions to problems encountered in livestock production enterprises. You’ll have a mix of lectures, group work and farm visits to develop and apply your knowledge.

This module will further develop your specialised knowledge of animal nutrition. At an advanced level, you’ll learn about the role of micronutrient and trace minerals and organic micronutrients (including vitamins B, choline and essential fatty acids) in the nutritional requirements for animal health and growth in both ruminant and non-ruminant species. You’ll also examine the various factors involved in the regulation of animal growth and product quality and look at selected examples of metabolic disorders. Using the most up-to-date scientific research, you’ll explore specialist aspects of ruminant nutrition and produce scientific work of your own.

Want to know more about the nutrition of your dog or horse, or maybe what an elephant needs to eat? In this module you’ll study the nutrition, health and welfare of major companion species, including dogs, cats, horses, rabbits and some zoo/exotic species. You’ll learn about the interactions between nutrition, health and longevity within the broad area of ‘clinical nutrition’. Bringing in current research, you’ll look at the problems arising from keeping animals in captivity, and how social interactions between humans and companion animals can impact upon animal health and welfare. You’ll have lectures from current researchers and have a field trip to put what you’ve learnt into practice.

The module will develop concepts introduced in year two with a series of lectures, leading to an advanced understanding of how to assess the health of animals. The effects of disease in domesticated animals will be covered including their physiological and immunological responses to disease, and the economic, welfare and legal impacts of disease. Examples from companion, farm and rodent species will be used.

Animal-human interactions raise some prominent ethical issues. In this module, you’ll examine the ethical dimensions concerning animal agriculture, modern biotechnologies and research in the biosciences, in relation to both humans and non-human species. You’ll learn about the ethical frameworks used to analyse specific dilemmas raised by the human use of animals. Using specific animal and biotechnology case studies, you’ll interpret the main ethical theories and principles and apply them to the case studies to inform professional decision-making. You’ll have a mix of lectures and seminars to explore these concepts.

You will undertake a research project under the supervision of an academic member of staff. Your work may involve animals (farm livestock, companion species) or laboratory techniques to study animal physiology, biochemistry, and development at the molecular, tissue, organ, and/or whole animal levels. You may also work on a library-based project that lets you carry out an in-depth study of the scientific literature in an area of your interest. Some projects are undertaken through the University Farm and Dairy centre, while other projects are undertaken offsite; we have links with nearby Twycross Zoo.

Our academics conduct cutting-edge research on reproduction, development, growth and health of domestic animals, including programmes in genetics, nutrition, reproduction, early development, animal biotechnology, neurophysiology, and applied bioethics. You will prepare a dissertation of 5000-6000 words and give a presentation on your project.

How does the brain control physiology and behaviour? In this module you’ll build on your knowledge from previous modules to examine the detailed physiological basis of integrated behaviours in animals. You’ll cover; nervous system control of cardiovascular function, respiration, body temperature, emotion, motivation and their associated behaviours. You’ll have lectures on the above along with practical sessions on the integrative aspects of exercise physiology.

Building on the principles of animal development from earlier modules, you will be introduced to the world of the biotechnology industry, the techniques involved, and to the opportunities offered by this growing sector. You’ll learn about the genetic and epigenetic basis of gene regulation, and how this knowledge is used for developing new disease treatments and for improving livestock production and animal welfare.

How does the central nervous system sense the environment and react to it? In this module, you’ll learn about central nervous control of sensory and motor pathways and how these systems interact. In particular, you’ll examine the anatomy, physiology and pharmacology of sensory and motor systems and their integration in posture, coordinated movement and protective reflex responses. A strong emphasis will be on the physiology and pharmacology of acute and chronic pain and you’ll study the use of analgesics to treat these conditions. You’ll also gain understanding of the methodology behind a number of neuroscientific techniques and their application in novel research. You’ll have a mix of lectures, computer-based learning and practical laboratory sessions to reinforce and apply your knowledge.

This module will examine the concept of metabolic control at the gene, cell and tissue level with particular reference to the role of nutrients in regulating this process. Selected processes by which nutrients and hormones act via receptors and their signal transduction pathways to regulate tissue growth and metabolism will be described along with the mechanisms by which nutrients can act directly on the processes controlling gene expression. You’ll have a mix of lectures and practical sessions for this module.

Building on Applied Bioethics 1, you’ll investigate widely accepted ethical principles and apply your insights to contemporary ethical issues in agricultural, food and environmental sciences. You’ll explore the ethical dimensions of prominent issues raised by the agricultural practices (including the use of biotechnology and GM crops) designed to meet the nutritional needs of the global population. You’ll also learn about how ethical theory can inform professional choices and public policies related to food production and environmental management. You’ll have a mix of lectures, tutorials and team-based exercises to develop a sound understanding of ethical principles.

The module will develop concepts introduced in year two with a series of lectures, leading to an advanced understanding of how to assess the health of animals. The effects of disease in domesticated animals will be covered including their physiological and immunological responses to disease, and the economic, welfare and legal impacts of disease. Examples from companion, farm and rodent species will be used.

Animal-human interactions raise some prominent ethical issues. In this module, you’ll examine the ethical dimensions concerning animal agriculture, modern biotechnologies and research in the biosciences, in relation to both humans and non-human species. You’ll learn about the ethical frameworks used to analyse specific dilemmas raised by the human use of animals. Using specific animal and biotechnology case studies, you’ll interpret the main ethical theories and principles and apply them to the case studies to inform professional decision-making. You’ll have a mix of lectures and seminars to explore these concepts.