Zebrafish in tanks

Research using animals

The welfare of animals in our research is important to us 鈥 learn how we're making sure science and animal welfare go hand-in-hand

Only a small part of our research requires the use of animals.

Whenever possible, we use alternative methods, such as cells grown in the laboratory and computer models, but some research involving animals remains essential. This is because the use of animals is continuing to make a vital contribution to the understanding, treatments and cure of major human and animal diseases.

We're committed to being clear and open about when, how and why we use animals in research, and to providing the best standards of animal welfare.

And because we believe that good science and good animal welfare are not mutually exclusive, we're one of 81 organisations from the UK bioscience community that signed the Concordat on Openness in Animal Research in 2014. The Concordat commits us to:

  • being clear about when, how and why we use animals in research
  • enhancing our communications with the media and the public about our research using animals
  • being proactive in providing opportunities for the public to find out about research using animals
  • reporting on progress annually and sharing our experiences

As part of our , we also adhere to the '3 Rs of Animal Research'. These are:

  • to replace the use of animals with alternative techniques, or avoid the use of animals altogether.
  • to reduce the number of animals used to a minimum, to obtain information from fewer animals or more information from the same number of animals.
  • to refine the way we perform experiments, to make animal welfare a priority. This includes better housing and improvements to procedures with animal welfare in mind.

About the animals we use in our research

The animals used in our research are mainly mice and frogs. And while they may seem very distinct from human beings at first glance, they actually share many basic cellular, developmental and disease processes with humans. That's why they're used as models for the study of human illness.

We house our animals in excellent conditions, as required by the , and ensure they receive the best possible care from our team of experienced vets and technicians.

How animal research is making a difference

Research on animals has been essential for major advances in both human and veterinary medicine. We're now able to prevent and treat diseases and conditions which were once fatal, and major operations such as organ transplants, and procedures such as kidney dialysis and blood transfusions, are now possible.

Research on animals has allowed the investigation of some of the more challenging medical conditions such as heart disease, depression, HIV and many cancers, while also offering hope to millions who have life-threatening diseases.

In veterinary medicine, animal research has led to the development of vaccines for major animal diseases, such as canine parvovirus and feline leukaemia.

Some of our research investigates diseases of the nervous, muscular and circulatory systems that are involved in conditions such as muscular dystrophy and Alzheimer鈥檚, and our developmental biologists are examining the basic processes of life so that we can understand the nature of diseases.

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Case Studies

Professor of Molecular Medicine, , and his team in the School of Medicine, Pharmacy and Biomedical Sciences, are working to find a treatment that will delay the onset and slow down the progression of muscle degeneration in people with Duchenne muscular dystrophy, the most common and severe of all muscular dystrophies.

The condition is caused by a lack of dystrophin, a protein which acts like scaffolding and an anchor in muscle cells and without which these cells become damaged and then progressively lost, resulting in death of young adults.

There are also brain forms of dystrophin that, when mutated, are responsible for the severe cognitive problems sometimes also seen in this condition. There is no cure for this disease and treatments are urgently needed.

Working with mice, the research team has already identified a molecule present in dystrophic muscle cells (called P2X7) that contributes to muscle damage. By manipulating this molecule, the scientists have been able to relieve disease symptoms.

Professor Gorecki says: 鈥淚f we can achieve improvement in the mouse model of Duchenne muscular dystrophy, then there is a good chance that the same treatment may work in human patients, though of course, it will still need to be tested in clinical trials.鈥

The team鈥檚 success at manipulating P2X7 and their plans for further research have received strong endorsement from a panel of the world鈥檚 leading experts in muscular dystrophy.

The research conducted by , Professor of Cellular Neurophysiology, and his colleagues is focused on the ageing brain and diseases such as dementia and multiple sclerosis. The team use mice to study mechanisms in the brain that may cause degenerative conditions.

They have found a protein that is a key element in controlling special cells in the brain and spinal cord that form myelin, a substance which insulates the brain鈥檚 wiring. They discovered that the protein is critical to ensuring that these cells, known as oligodendrocytes, function well.

, fellow member of the cellular neurophysiology group, is using the same type of methodology to investigate multiple sclerosis (MS). Symptoms of the disease, which include memory and emotional problems as well as effects on the body, are the result of lesions on the brain鈥檚 white matter caused by damage to myelin and to oligodendrocytes.

The discovery of the protein could lead to better treatments for MS and dementia. There is also the potential in the future for a diagnostic tool for clinicians to use to predict Alzheimer鈥檚 and dementia.

Professor Butt says: 鈥淭hrough investigating the signals used by the brain to control these functions we hope to gain further insight into the ageing brain and better understand diseases such as Alzheimer鈥檚 and dementia.鈥

, Professor of Developmental Biology, leads the Xenopus Resource Centre, which is the largest frog facility in the world. Xenopus are fully aquatic South African clawed frogs whose eggs are used to investigate the basic processes of life so that the fundamental nature of diseases can be understood.

鈥淥ur work involves examining how genes are switched on and off again, a process that is the same in cells of both frogs and humans. We have found that structures in DNA, rather than the DNA sequence itself, control some critical parts of the genome and this now opens up a whole new area of research to discover whether any diseases are caused by changes in these structures.

鈥淚t is also possible to use Xenopus as a tool to study particular human diseases, and we have worked with to understand some genetic changes in the dystrophin complex (responsible for muscular dystrophy) that cannot be modelled in mice.

"We are currently developing frogs that allow our collaborators to study heart, vascular, muscle and kidney disease. These frogs will reduce the need for mice to be used in such studies,鈥 says Matt.

Animal welfare and ethical review body (AWERB)

The most recent Understanding Animal Research survey (2020) shows that approximately three quarters (73%) of adults support the use of animals in research as long as it is for medical research purposes, there is no unnecessary suffering, and there is no alternative.

That's the case with our research, and all work involving animals (as defined by the Animals (Scientific Procedures) Act 1986) by University staff is reviewed by the Animal welfare and ethical review body (AWERB), irrespective of a requirement by the Home Office for a licence.

The AWERB includes a vet, key animal technicians, experienced project licence holders and members of the University鈥檚 senior management team, together with lay members, some of whom are independent of the University.

In addition to ensuring that all work involving animals is scientifically and ethically justified, for licensed projects, the AWERB considers annually the scientific progress made in each project, together with how the use of animals in that project has been replaced, reduced and refined (the 3Rs). It disseminates best practice and acts as a forum to update animal users on advances that address the 3Rs, thereby keeping the use of animals in research to a minimum.

The University and its researchers are subject to inspection by the Home Office, which examines all aspects of animal research, care and welfare. Under Home Office categorisation our experimental procedures on animals are generally classified as 鈥渕ild鈥.

We fully support and endorse the ARRIVE (Animal Research: Reporting In Vivo Experiments) guidelines developed as part of a (National Centre for the Replacement, Refinement and Reduction of Animals in Research).

The guidelines, a checklist of 10 items, aim to ensure all work with animals is carried out thoroughly and transparently. Following these guidelines means that where possible the results of one study can be used for multiple purposes, which in turn leads to lower animal use.

How many animals are used in our research?

As part of the University's commitment to openness and transparency in all areas of our research, the numbers of animals used in research during the last year are listed here. They're grouped by the type of procedure they experienced.

2023 figures 鈥 actual severity classification by species

 

Species Sub-threshold Non-recovery Mild Moderate Severe Total

Mice

1232

8

17

0

0

1257

Xenopus

7823

0

2199

0

21

10043

Zebrafish

1016

0

0

0

0

1016

TOTAL

10071

8

2216

0

21

12316

 

The figures are part of the annual statistical returns required by the Home Office of all Project Licence Holders. These statistics are incorporated into a collection of national statistics published annually to inform the development of policies on animal use in scientific work and to inform the scientific community, animal welfare organisations and the general public.

The majority of mice and Xenopus (frogs) we use are genetically altered animals that have been modified either to have a similar mutation to that found in a human genetic disease or to allow a developmental process or disease to be followed in living animals non-invasively (for example fluorescent heart muscle).

The majority of these animals show no clinical signs of pain or distress and are indistinguishable in their daily appearance from normal non-genetically altered animals. This is why they are such useful models for scientific investigations.

Procedure groups explained

The table below breaks down animal numbers into five groups of procedures, as follows:

  1. Sub-threshold: These are procedures that are less painful to the animals than an injection, such as breeding non-harmful genetically altered animals. We do this as part of our research into degenerative brain disease and muscular dystrophy. We use these results to identify new potential drug targets for treating such diseases in the longer term.
  2. Mild: Most of these procedures are injections, such as introducing a potential drug into mice or inducing frogs to lay eggs. Our researchers making new models of human genetic diseases manipulate the genome of these animals.
  3. Moderate: Most of these procedures involve stressing the animals, for example, by them spending a short time in a small space. One of the reasons that our scientists do this is to understand which mechanisms cause the brain to be damaged by stress.
  4. Non-recovery: This is where we place animals under general anaesthetic and the experiment does not require them to recover. Therefore, to prevent them suffering, we kill them humanely before they regain consciousness.
  5. Severe: We have no procedures that are pre-judged to be 鈥榮evere鈥欌 so, the only severe procedures listed in our figures are those that cause animals to die unexpectedly. We label these 鈥榮evere鈥 by default. If this happens, a post mortem is carried out on the animal and the exact circumstances of the death are investigated. A report is then submitted to the Home Office.