Researchers discover new tool to investigate more effective cancer treatment
Researchers at Queen鈥檚 University Belfast have discovered a new tool, which will help to investigate more effective forms of cancer treatment.
Using high-power lasers, the experts have been able to generate a 鈥榩ure beam鈥 of carbon ion with unique properties.
This bright, ultrashort particle source can be used to investigate how biological samples respond to radiation under extreme conditions. They say this could pave the way for advanced and more effective radiotherapy approaches.
Innovative
Professor Marco Borghesi from the School of Mathematics and Physics at Queen鈥檚, led the project and worked closely with experts from the University of Strathclyde, Imperial College London, and the Science and Technology Facilities Council鈥檚 (STFC) Central Laser Facility (CLF). The project was funded by the Engineering and Physical Research Council (EPSRC) 鈥 both EPSRC and STFC are part of UK Research and Innovation.
Professor Borghesi explains: 鈥淐urrently radiotherapy is used to treat many forms of cancer, and while this is usually done using x-rays, more advanced and more costly forms of treatment use particle beams. Carbon ions, in particular, are very effective in treating types of tumours which are resistant to other forms of radiation.
鈥淎 current, promising development in radiotherapy is the 鈥楩LASH鈥 approach where radiation is delivered in short, intense bursts. This leads to reduced side effects and potentially more effective treatment.
鈥淭here is therefore great interest in investigating the response of human cells - healthy and cancerous - after exposure to ultrafast ion irradiation. Through our research we have produced an ultrashort carbon beam that can deposit its energy in nanosecond bursts, or less. This is very innovative and important in advancing the science behind cancer treatment. We have now started cell irradiation experiments using this beam, in collaboration with our colleagues in the Patrick G. Johnston Centre for Cancer Research at Queen鈥檚.鈥
Short burst of light
Dr Aodhan McIlvenny, a Queen鈥檚 University researcher and lead author of the study, explains: 鈥淲hen we shine a short burst of light 鈥 a laser - on a very thin object, we can push it forward at very high speeds. Typically, the energy transferred by the laser is carried away by particles we don't want, and we aren鈥檛 able to use it.
鈥淗owever, we have now discovered that by heating the object extremely quickly, we can remove these unwanted particles before hitting the object with the intense laser pulse.
鈥淭his means that we are then able to produce almost pure beams of the particle type we are interested in 鈥 in this instance it is carbon ions. This gives us the ability to select a specific type of radiation and use it for targeted irradiation experiments in new areas that we have not yet explored.鈥
Major step forward
Professor Kevin Prise from the Patrick G. Johnston Centre for Cancer Research at Queen鈥檚 said: 鈥淭his a major step forward in our ability to test new beams for future radiotherapy applications and it allows us to now explore potential new biology, which will help to explore ways to advance cancer treatment.鈥
EPSRC Director for Research Base Jane Nicholson said: 鈥淭his innovative new approach demonstrates the impact cutting-edge physical sciences research can have in improving healthcare technologies, such as more effective radiotherapy treatments for cancer.
鈥淭he inventive, discovery-led work of the UK鈥檚 researchers, supported by EPSRC, will play a key role in pushing forward the frontiers of knowledge and addressing challenges across healthcare to deliver a better quality of life.鈥
The full findings have been published in .
Dr Aodhan McIlvenny
Media
For media inquiries, please contact Emma Gallagher emma.gallagher@qub.ac.uk