Public Release: 

New test uses human stem cells to identify dangerous side effects of drugs

Imperial College London


IMAGE: The new test uses endothelial cells grown from stem cells in the blood. This image shows these cells stained with fluorescent markers. view more

Credit: Imperial College London

Scientists at Imperial College London have developed a test that uses combinations of cells from a single donor's blood to predict whether a new drug will cause a severe immune reaction in humans.

The test could avert disasters like the 2006 trial of the drug TGN1412, which led to six healthy young men being admitted to intensive care with multiple organ failure. The volunteers receiving TGN1412 experienced a catastrophic inflammatory reaction called a cytokine storm.

Cytokine storm reactions are a particular worry for new biological therapies, or "biologics", which use biological material such as antibodies. Many blockbuster drugs such as the cancer drugs Herceptin and Avastin are biologics, as are around a third of medicines in the pharmaceutical pipeline. Because these medicines are specific to humans, they can cause severe reactions that don't materialise in animal studies, so tests on human cells are essential.

However, cytokine storm side effects are hard to predict with tests were just one cell type is used, since they depend on interactions between blood cells and endothelial cells, which form the lining of blood vessels. But because endothelial cells are deep within the body, they are normally only grown from tissue removed in surgery or post mortem, or from umbilical vessels after birth.

Because of this, current tests use endothelial cells taken from vessels of one donor, and white blood cells from a different donor. When cells from two different donors are used, one may have an immune reaction to the other, meaning the system is already primed for inflammation before the drug is added. This can result in the test falsely showing a severe immune reaction to a drug that is safe.

Researchers at Imperial College London got around this problem by isolating stem cells from the blood of a volunteer, and using them to grow endothelial cells in a dish. They then took white blood cells which they added to the donor's own endothelial cells to recreate the unique conditions found in their blood vessels. When TGN1412 was added to the test tube, the mixture of cells released a cytokine storm, as would happen inside the body.

The new method is better as it only requires blood from one donor and doesn't mix cells from different people, with the advantage of making a more reliable test.

Professor Jane Mitchell, from the National Heart and Lung Institute at Imperial College London, who led the study, said: "As biological therapies become more mainstream, it's more likely that drugs being tested on humans for the first time will have unexpected and potentially catastrophic effects. We've used adult stem cell technology to develop a laboratory test that could prevent another disaster like the TGN1412 trial.

"Drug companies have the technical capacity to start using this test now, but we're working on developing an off-the-shelf kit which will make it easy to use on a large scale."

Dr Daniel Reed, the first author on the study, said: "A further benefit of this new technology is that personalised therapies can be tested to see how safe and effective they will be for an individual."


The Imperial researchers have collaborated with the National Institute for Biological Standards and Control to validate the test and are now working with the clinical trials company Quintiles to develop the technology further. The research is published in the FASEB Journal.

For more information please contact:
Sam Wong
Research Media Officer
Imperial College London
Tel: +44(0)20 7594 2198
Out of hours duty press officer: +44(0)7803 886 248

Notes to editors:

1. D.M. Reed et al. 'An autologous endothelial cell:PBMC assay that detects cytokine storm responses to biologics.' FASEB Journal, 2015. doi:10.1096/fj.14-268144

2. About Imperial College London

Imperial College London is one of the world's leading universities. The College's 14,000 students and 7,500 staff are expanding the frontiers of knowledge in science, medicine, engineering and business, and translating their discoveries into benefits for society.

Founded in 1907, Imperial builds on a distinguished past - having pioneered penicillin, holography and fibre optics - to shape the future. Imperial researchers work across disciplines to improve global health, tackle climate change, develop sustainable energy technology and address security challenges. This blend of academic excellence and its real-world application feeds into Imperial's exceptional learning environment, where students participate in research to push the limits of their degrees.

Imperial nurtures a dynamic enterprise culture, where collaborations with industrial, healthcare and international partners are the norm. In 2007, Imperial College London and Imperial College Healthcare NHS Trust formed the UK's first Academic Health Science Centre. This unique partnership aims to improve the quality of life of patients and populations by taking new discoveries and translating them into new therapies as quickly as possible.

Imperial has nine London campuses, including Imperial West: a new 25 acre research and innovation centre in White City, west London. At Imperial West, researchers, businesses and higher education partners will co-locate to create value from ideas on a global scale.

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