Winston-Salem, N.C. - Jan. 20, 2015 - With the goal of making it easier for surgeons to detect malignant tissue during surgery and hopefully reduce the rate of cancer recurrence, scientists have invented a new imaging system that causes tumors to "light up" when a hand-held laser is directed at them.
"A surgeon's goal during cancer surgery is to remove the tumor, as well as enough surrounding tissue to ensure that malignant cells are not left behind," said Aaron Mohs, Ph.D., assistant professor of regenerative medicine at Wake Forest Baptist Medical Center and a co-inventor of the system. "But how do they know when they've removed enough tissue? Our goal is to provide better real-time information to guide the surgery."
Published online ahead of print in IEEE Transactions on Biomedical Engineering (TBME), Mohs and co-authors report on their prototype system that combines a fluorescent dye that localizes in tumors with a real-time imaging system that allows the surgeon to simply view a screen to distinguish between normal tissue and the "lighted" malignant tissue.
In both mice and companion dogs with tumors, the scientists found that the fluorescent dye accumulated at higher levels in tumors than in the surrounding tissue and the system was able to detect a distinct boundary between normal and tumor tissue. Canine tumors are known to be similar to human tumors in architecture and canines get the same types of tumors as humans.
The scientists are working to further develop the system so it can be evaluated in human patients.
Current technology allows cancer surgeons to scan tumors prior to surgery with magnetic resonance imaging and other systems. However, to scan the tumor during surgery involves moving the patient from the operating table and into the machinery -which prolongs the surgery.
"Being able to quickly scan a tumor during surgery to visualize tumor tissue from non-tumor tissue is an unmet clinical need," said Mohs. "Pathology techniques that examine tumor tissue during surgery can take up to 20 minutes and they focus on the tissue removed during surgery, not the tissue that remains in the body."
In TBME, the authors noted that the ideal system would find tumor boundaries with high sensitivity, have minimal impact on operative time and surgical technique, present findings in an intuitive manner and avoid the use of ionizing radiation or a specialized imaging environment, such as MRI machines.
The system, invented by Mohs, Michael C. Mancini at Spectropath Inc., and Shuming Nie with Emory University and Georgia Institute of Technology, combines two types of imaging. A surgeon-controlled laser can be directed at any area of interest. In addition, an imaging system with three cameras sits above the surgical field. The images recorded by both systems are processed to display a composite image.
Using this system, a surgeon would scan the tumor prior to surgery to determine its boundaries. The tumor would then be surgically removed and the area would be re-scanned to assess for any remaining malignant tissue. If diseased tissue is found, it would be removed, and the process would be repeated until diseased tissue could no longer be detected.
In the prototype system reported in TBME, the scientists used indocyanine green dye as the source of fluorescence. They noted that future studies will focus on higher performance fluorescent dyes and nanoparticles that can be targeted to specific tumors.
Recently, Mohs was awarded a $1.37 million research grant from the National Institute of Biomedical Imaging and Bioengineering for a project to optimize the system and to test it in rodents.
Under the four-year project, Mohs' team will develop nanoparticles based on hyaluronic acid, a substance naturally present in the human body. These nanoparticles will have the ability to entrap near infrared fluorescent dyes. The research will investigate invasive ductal carcinoma, the most common type of breast cancer.
Under the project, the researchers will focus on optimizing the loading of the dye, determining how fluorescence can be activated and performing studies in rodents to evaluate safety and whether disease recurrence is reduced.
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Members of the research team, all from Wake Forest Baptist, are: Edward Levine, M.D., Surgical Sciences - Oncology; Frank Marini, Ph.D., and Graca Almeida Porada, M.D., Ph.D., Institute for Regenerative Medicine; Ralph D'Agostino, Ph.D., Biostatistics; and King Li, M.D., Division of Radiologic Science. (Grant Number: 1R01EB019449-01)
Co-authors on the TBME paper, in addition to the inventors, were James M. Provenzale, M.D., Duke University Medical Center and Emory University; and Corey F. Saba, D.V.M., Karen K. Cornell, D.V.M., Ph.D., and Elizabeth W. Howerth, D.V.M., Ph.D., University of Georgia.
Media Contacts: Karen Richardson, krchrdsn@wakehealth.edu, (336) 716-4453) or Main Number (336) 716-4587.
Wake Forest Baptist Medical Center (http://www.wakehealth.edu) is a nationally recognized academic medical center in Winston-Salem, N.C., with an integrated enterprise including educational and research facilities, hospitals, clinics, diagnostic centers and other primary and specialty care facilities serving 24 counties in northwest North Carolina and southwest Virginia. Its divisions are Wake Forest Baptist Health, a regional clinical system with close to 175 locations, 900 physicians and 1,000 acute care beds; Wake Forest School of Medicine, an established leader in medical education and research; and Wake Forest Innovations, which promotes the commercialization of research discoveries and operates Wake Forest Innovation Quarter, an urban research and business park specializing in biotechnology, materials science and information technology. Wake Forest Baptist clinical, research and educational programs are annually ranked among the best in the country by U.S. News & World Report.
Journal
IEEE Transactions on Biomedical Engineering