Implantable decoy could limit metastatic breast cancer
A small device implanted under the skin can improve breast cancer survival by catching cancer cells, slowing the development of metastatic tumors in other organs and allowing time to intervene with surgery or other therapies.
A small device implanted under the skin shows promise for improving breast cancer survival by catching cancer cells and slowing the development of metastatic tumors in other organs.
These findings, based on experiments in mice and reported in the journal Cancer Research, suggest a path for identifying metastatic cancer early and intervening to improve outcomes.
“This study shows that in the metastatic setting, early detection combined with a therapeutic intervention can improve outcomes. Early detection of a primary tumor is generally associated with improved outcomes. But that’s not necessarily been tested in metastatic cancer,” says study author Lonnie D. Shea, Ph.D., the William and Valerie Hall Department Chair of Biomedical Engineering at the University of Michigan.
The study found 64 percent fewer metastatic cancer cells in the liver and 75 percent fewer metastatic cancer cells in the brains of mice implanted with the devices compared to mice without them, five days after both groups underwent surgery to remove cancerous tumors. This suggests that the presence of the device slows the progress of metastatic disease.
The device is a scaffold is made of FDA-approved material commonly used in sutures and wound dressings. It’s biodegradable and could last up to two years within a patient. The researchers envision it would be implanted under the skin, monitored with non-invasive imaging and removed upon signs of cancer cell colonization, at which point additional treatment could be administered.
The scaffold is designed to mimic the environment in other organs before cancer cells migrate there. The scaffold attracts the body’s immune cells, and the immune cells draw in the cancer cells. This then limits the immune cells from heading to the lung, liver or brain, where breast cancer commonly spreads.
“Typically, immune cells initially colonize a metastatic site and then pave the way for cancer cells to spread to that organ,” Shea said. “Our results suggest that bringing immune cells into the scaffold limits the ability of those immune cells to prepare the metastatic sites for the cancer cells. Having more immune cells in the scaffold attracts more cancer cells to this engineered environment.”The new research expands on previous work from the team showing that the implantable scaffold device effectively captures metastatic cancer cells. Here, the researchers improve upon their device and show that surgery prior to the first signs of metastatic cancer improved survival.
“Currently, early signs of metastasis can be difficult to detect. Imaging may be done once a patient experiences symptoms, but that implies the burden of disease may already be substantial,” said study author Jacqueline S. Jeruss, M.D., Ph.D., associate professor of surgery and biomedical engineering and director of the Breast Care Center at the University of Michigan Comprehensive Cancer Center. “Improved detection methods are needed to identify metastasis at a point when targeted treatments can have a significant beneficial impact on slowing disease progression.”
Researchers tested the device by implanting it into a group of mice, then injecting both the implanted mice and a control group with tumors. At day 5 after tumor initiation, the researchers found a detectable percentage of tumor cells within the scaffold but none in the lung, liver or brain, suggesting that the cancer cells hit the scaffold first.
The researchers removed the tumors at day 10, which is after detection but before substantial spreading, and found the mice that had the scaffold in place survived longer than mice that did not have a scaffold.
At 15 days after tumor initiation, they found 64 percent fewer cancer cells in the liver and 75 percent fewer cancer cells in the brains of mice with scaffolds compared to mice without scaffolds. This suggests that the presence of the scaffold slows the progress of metastatic disease.
While surgery was the primary intervention in this study, the researchers suggest that additional medical treatments might also be tested as early interventions. In addition, researchers hope that by removing the scaffold and examining the cancer cells within it, they can use precision medicine techniques to target the treatment most likely to have an impact.
This system is early detection and treatment, not a cure, the researchers emphasize. The scaffold won’t prevent metastatic disease or reverse disease progression for patients with established metastatic cancer.
The team will develop a clinical trial protocol using the scaffold to monitor for metastasis in patients treated for early stage breast cancer. In time, the researchers hope it could also be used to monitor for breast cancer in people who are at high risk due to genetic susceptibility. They are also testing the device in other types of cancer.