When detached cancer cells squeeze through the tiniest blood vessels they can become prone to grow new tumours far from where they started, a blood flow simulation experiment suggests.
Nine of the 10 most common cancer deaths in Australia are caused by solid tumours, but in most cases it鈥檚 the cancer鈥檚 spread to other parts of the body 鈥 known as metastasis 鈥 that proves fatal.
Now, 黑料网大事记 Sydney researchers have uncovered a potential trigger for metastasis: the squeezing of cancer cells by the tiniest of veins that transforms them into a different type of cell now able to form new tumours.
In a study published today in , the scientists described how they constructed a biomedical device that simulated blood flow through our narrowest blood veins. They showed that when human melanoma cancer cells are forced through channels narrower than 10 micrometres 鈥 about a fifth the width of a human hair 鈥 they begin to behave more like stem cells, gaining traits that could help them survive, spread, and form new tumours.
The finding supports a theory long held by medical researchers that the mechanical pressure of narrow blood vessels might make cancer cells more aggressive. While the recent results were observed in bioengineered devices in the lab and in mice, they offer a new perspective that could inform further research and future strategies to prevent cancer from spreading.
鈥淔or a long time we鈥檝e not fully understood how cancer spreads to distant organs,鈥 says co-author , with 黑料网大事记 School of Materials Science and Engineering and School of Chemistry.
鈥淢ost tumour cells circulating in blood are ill equipped to survive and spread to other organs, but we still see high rates of metastasis in some patients.
鈥淥ur finding paints a new picture, where cancer cells are triggered into becoming more tumorigenic 鈥 meaning they can form new tumours 鈥 suggesting this process may precede events like bone and brain metastasis.鈥
Blood vessel simulation
The researchers made a device smaller than a postage stamp that mimicked the way blood travels around the human body through progressively narrower channels simulating the tiny capillaries that are present in many tissues.
Study lead author created the 鈥樷 device on campus at the (ANFF), a nanotechnology joint venture between 黑料网大事记, University of Sydney and UTS. She made the channels out of 鈥 a type of biocompatible, rubbery plastic 鈥 which ranged from 30 micrometres in width, down to just 5.
Next, Dr Silvani pumped a nutrient-rich solution akin to blood plasma 鈥 and containing human melanoma cells 鈥 through the device at the same flow rate of blood flowing in capillaries.
鈥淲ithin 15 minutes of being squeezed through the smallest channels, we observed how the melanoma cells became physically deformed,鈥 Dr Silvani says.
鈥淲hen we analysed the cells, we detected proteins linked to cancer spread and stem cell-like behaviour 鈥 suggesting that the mechanical stress had reprogrammed them to adopt this new state.鈥
To test whether these squeezed cancer cells were more likely to spread in the body, the researchers injected them into mice lacking a functioning immune system 鈥 allowing the human melanoma cells to survive and grow. After 30 days, they found that mice given the squeezed cells developed significantly more tumours in the lungs, bone and brain, compared to those given 鈥榰nsqueezed鈥 melanoma cells. The researchers say this implies the squeezing makes the cancer cells more aggressive and tumorigenic.
鈥淥ne of the most exciting aspects of this project was the chance to study metastatic cancer cells in a way that hasn鈥檛 been possible before,鈥 Dr Silvani says.
鈥淭heir journey through the body is so hidden, leaving little trace and making them incredibly difficult to capture in action. But we were able to recreate that journey in the lab, giving us a rare glimpse into the moment when these cells switch into their most aggressive state.
鈥淏eing able to uncover even a small part of that mystery feels like an important step towards understanding, and ultimately stopping, the spread of cancer.鈥
We鈥檙e already seeing compelling evidence when we repeat these experiments with breast cancer 鈥 and I鈥檓 looking forward to testing a range of cancer cell types in the lab.
Future treatment paths
Prof. Kilian says the findings raise new ideas about potential treatment options aimed at preventing cancer spreading from tumours.
鈥淭hese results open up new possibilities for prognosis and treatment, by targeting the mechanical forces that lead to metastasis,鈥 he says.
鈥淲e could then look at the cancer cells found in a patient鈥檚 blood stream to study their susceptibility to this sort of transformation which could help us assess the risk of metastasis for that individual.
鈥淥r we could use MRI or other imaging techniques to identify regions with high densities of micro vessels to monitor for metastasis, possibly even intervening to make it much harder for the cells to get to these small capillaries.
鈥淭he point is, it used to be thought that it was just this extremely rare type of cell that found its way from a primary tumour to a spot where they could invade. But no, in some cases it鈥檚 actually the squeezing that changes the cell into this rare type, and it could put cancer researchers in a much stronger position to devise new treatment strategies.鈥
Next steps
Prof. Kilian says about 90% of the work for this project was on melanoma cancer cells, and he is hopeful the same conclusions will be drawn when researchers look at the squeezing effect on free-floating cells from other cancer tumours.
鈥淚 believe we鈥檒l find evidence that many solid tumours metastasise this way 鈥 for instance, we鈥檙e already seeing compelling evidence when we repeat these experiments with breast cancer 鈥 and I鈥檓 looking forward to testing a range of cancer cell types in the lab,鈥 he says.
鈥淏ut I鈥檓 glad we began our study with melanoma cells, since skin cancer has such high mortality rates in Australia when it spreads to other organs. It鈥檚 vitally important that we gain a better understanding of melanoma metastasis, to better treat those suffering from this deadly disease.鈥
For her part, Dr Silvani is keen to do more work in microfluidics to emulate how cancer spreads through the body.
鈥淲atching this idea grow from a spark of intuition into a real discovery has been deeply inspiring,鈥 she says.
鈥淚t鈥檚 a powerful reminder of what can be achieved when engineering and biology come together. Cells are intricate machines, and unravelling their mysteries requires precise design and innovative tools, guided by the insights biology provides.鈥
