The aim of the new fluorescent probe is to increase cases where 100% of the tumor is removed and thus reduce further operations and the chance the cancer will return.
Researchers describe how they tested the "protease-activated fluorescent probe for imaging cancer" at Duke University Medical Center in Durham, NC, in the journal Science Translational Medicine.
The imaging technology - which uses an injectable blue liquid called LUM015 - was developed by Duke, the Massachusetts Institute of Technology (MIT) and Lumicell Inc.
The paper describes how the probe was able to identify cancerous tissue in live mice with sarcoma and in 15 patients undergoing surgery for soft-tissue sarcoma or breast cancer, without adverse effects.
Current imaging methods like MRI and CT scans do not always detect all the cancerous tissue at the margins of a tumor, so in the first operation some harmful cells can be left behind with the result that patients have to go back for more surgery or undergo radiation therapy.
'A practical, quick technology for scanning the tumor bed during surgery'
Co-senior author David Kirsch, a professor of radiation oncology and pharmacology and cancer biology at Duke, explains that while a pathologist can examine the tissue at the tumor margin under a microscope during surgery, because of the size of the affected area, it is not possible to look at all of it during the operation. He adds:
"The goal is to give surgeons a practical and quick technology that allows them to scan the tumor bed during surgery to look for any residual fluorescence."
The trial is the first to test a fluorescent probe that is protease-activated. The agent, LUMO15, fluoresces in the presence of cathepsin, a protease enzyme that is more common in cancer cells than healthy cells. The cancer cells use the enzyme to remodel their environment so the tumor can grow and spread.
When they tested the LUMO15 probe in mice, the researchers found the agent accumulated in tumors where it fluoresced on average five times more brightly than in regular muscle tissue.
The fluorescence is not visible to the naked eye - it has to be observed through a handheld imaging device that is also under development.
'Could significantly change treatment of sarcoma'
The intention is that when operating on human patients, after the tumor is removed, the surgeon places the handheld imaging device on the cut surface to see if there are any areas that still have residual fluorescent cancer cells.
Co-senior author Dr. Brian Brigman, chief of orthopedic oncology at Duke, says that currently, pathologists have to analyze tumor margins over several days after surgery to determine whether they are clear.
This approach has been in place for decades and is the best available, but it is not as accurate as they would like, explains Dr. Brigman, who is also director of Duke's sarcoma program. He concludes:
"If this technology is successful in subsequent trials, it would significantly change our treatment of sarcoma. If we can increase the cases where 100% of the tumor is removed, we could prevent subsequent operations and potentially cancer recurrence. Knowing where there is residual disease can also guide radiation therapy, or even reduce how much radiation a patient will receive."
Prof. Kirsch says researchers at Massachusetts General Hospital are currently testing the safety and efficacy of LUM015 and the accompanying imaging device in a prospective study of 50 women with breast cancer.
He says it is likely other centers will also carry out studies to see whether the technology decreases the number of patients requiring further surgery following removal of breast tumors.
Lumicell, the company that developed LUM015 and its accompanying imaging device, was started by researchers at MIT. Prof. Kirsch was also involved in the start-up.
Other teams around the world are also experimenting with similar techniques. For example, in early 2014, Medical News Today reported how a team at Washington University School of Medicine in St. Louis, MO, is developing a method where surgeons use high-tech glasses to see cancer cells that also light up with an injectable fluorescent marker.