When non-invasive sound waves break apart tumours, they trigger an immune response in mice. By breaking down the cell wall “cloak,” the treatment exposes cancer cell markers that had previously been hidden from the body’s defences, researchers at the University of Michigan have shown. The findings were published in the journal Frontiers in Immunology.
The technique developed at Michigan, known as histotripsy, offers a two-prong approach to attacking cancers: the physical destruction of tumours via sound waves and the kickstarting of the body’s immune response. It could potentially offer medical professionals a treatment option for patients without the harmful side effects of radiation and chemotherapy.
Until now, researchers didn’t understand how histotripsy was activating the immune system. A study from last spring showed that histotripsy breaks down liver tumours in rats, leading to the complete disappearance of the tumour even when sound waves are applied to only 50% to 75% of the mass. The immune response also prevented further spread, with no evidence of recurrence or metastases in more than 80% of the animals.
“We found that histotripsy somehow not only kills cancer cells but causes them to undergo a unique pathway of cell death that draws the attention of the immune system,” said Clifford Cho, the C. Gardner Child Professor of Surgery and vice chair of surgery, whose lab designed immune study protocols and measured immune responses.
The key turned out to be tumour antigens; proteins only found in cancer cells and hidden behind their cell walls. When cells die by chemotherapy or radiation, these antigens are destroyed in the process. In contrast, sound waves kill cancer cells by breaking their cell walls, releasing tumour antigens that then trigger the body’s defence systems.
The immune response occurred throughout the body, not simply in the area where the histotripsy was applied.
“With histotripsy, we’re not destroying the antigens, we’re releasing them while killing the tumour cells,” said Zhen Xu, U-M professor of biomedical engineering and an inventor of the histotripsy approach. “Once they’re no longer hidden, the body can see them and attack them.”
The team was able to discover the mechanism due to the way mice in cancer studies are typically given genetically identical tumours. After breaking up a tumour in one mouse using histotripsy, the team extracted some of that material, homogenized it and injected it into another mouse. Both mice developed immune protection from that cancer.
“Injecting the debris into a second mouse had almost a vaccine-like property,” Xu said. “Mice that received this debris were surprisingly resistant to the growth of cancers.”
Since 2001, Xu’s laboratory at the University of Michigan has pioneered the use of histotripsy in the fight against cancer, leading to the multi-centre clinical trial #HOPE4LIVER sponsored by HistoSonics, a U-M spinoff company. More recently, the group’s research has produced promising results on histotripsy treatment of brain cancer therapy and immunotherapy.
This work was supported by VA Merit Review, the National Institutes of Health, U-M’s Forbes Institute for Discovery, Histosonics-Michigan, and Michigan Medicine-Peking Health Sciences University Joint Institute for Clinical and Translational Research.
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