Cambridge breakthrough to reduce animal experiments
Millions of animals could be spared lab experimentation in future thanks to medical technology innovation from liver disease experts at Cambridge University.
Dr Meritxell Huch from the UK’s Gurdon Institute has found one of the research world’s Holy Grails – a way to test 1,000 compounds using cells that come from only one mouse.
Typically a study to investigate one potential drug compound to treat one form of liver disease would require up to 50 live animals per experiment – so testing 1,000 compounds would need 50,000 mice.
“By using the liver culture system I developed, we can test 1000 compounds using cells that come from only one mouse, resulting in a significant reduction in animal use,” said Dr Huch.
“If other laboratories adopt this method then the impact on animal use in the liver research field would be immediate. A vast library of potential drug compounds could be narrowed down to just one or two very quickly and cheaply, which can then be tested further in an animal study.”
For the first time Dr Huch has successfully grown ‘mini-livers’ from adult mouse stem cells – an advance that has earned her the UK's international prize for the scientific and technological advance with the most potential to replace, reduce or refine the use of animals in science (the 3Rs). The competition was sponsored by GlaxoSmithKline, which was highly impressed with the advance.
The new method enables adult mouse stem cells to grow and expand into fully functioning three-dimensional liver tissue. Growing hepatocytes (liver cells) in the laboratory has been attempted by liver biologists for many years, since it would reduce their reliance on using mice to study liver disease and would open up new opportunities in medical research and drug safety testing. Until now no laboratory has been successful in deciphering how to isolate and grow these cells.
Liver stem cells are typically found in a dormant state in the liver, only becoming active following injury to produce new liver cells and bile ducts. Dr Huch and colleagues at the Netherlands' Hubrecht Institute located the specific type of stem cells responsible for this regeneration, which are recognised by a key surface protein (Lgr5+) that they share with similar stem cells in the intestine, stomach and hair follicles.
By isolating these cells and placing them in a culture medium with the right conditions, the researchers were able to grow small liver organoids, which survive and expand for over a year in a laboratory environment. When implanted back into mice with liver disease they continued to grow, ameliorating the disease and extending the survival of the mice.
Having further refined the process using cells from rats and dogs, Dr Huch is now moving onto testing it with human cells, which would not only be more relevant to research into human disease, but also translate to the development of a patient's own liver tissue for transplantation.
Dr Vicky Robinson, chief executive of the NC3Rs is excited by the discovery. She said: “Growing functioning liver cells in culture has been the Holy Grail for liver biologists for many years, so a limitless supply of hepatocytes could have a huge 3Rs impact both on basic research to understand liver disease and for the screening and safety testing of pharmaceuticals.
“Researchers need to utilise this alternative technology as soon as possible to ensure the benefits to animals and human health are fully realised.”