Real-time imaging of lung lesions during surgery helps localize tumors and improve precision

Real-time imaging of lung lesions during surgery helps localize tumors and improve precision
Intraoperative imaging detects a lung adenocarcinoma during a pulmonary resection. Credit: The Journal of Thoracic and Cardiovascular Surgery

More than 80,000 people undergo resection of a pulmonary tumor each year, and currently the only method to determine if the tumor is malignant is histologic analysis. A new study reports that a targeted molecular contrast agent can be used successfully to cause lung adenocarcinomas to fluoresce during pulmonary surgery. This enables real-time optical imaging during surgery and the identification of cancer cells. The results are reported in The Journal of Thoracic and Cardiovascular Surgery, the official publication of the American Association for Thoracic Surgery (AATS).

"This approach may allow surgeons to perform resections with confidence that the entire tumor burden has been eliminated. In the future, with improved devices and molecular , this approach may reduce the local recurrence rate and improve intraoperative identification of metastatic ," explained lead investigator Sunil Singhal, MD, of the Department of Surgery, University of Pennsylvania Perelman School of Medicine (Philadelphia).

In this proof-of-concept study, 50 patients (ages 25-85 years) with diagnosed adenocarcinoma received 0.1 mg/kg of a fluorescent folate receptor alpha (FRα)-targeted molecular contrast agent (On Target Laboratories) four hours before surgery. This agent binds to folate receptor α, a protein found on the surface of most cells. This resulted in fluorescence of 92% of pulmonary adenocarcinomas, allowing surgeons to visually identify tumor cells during surgery.

Upon opening the chest cavity, the primary lesion was located using traditional methods of visual inspection and manual palpation. The cancer was imaged and photo-documented with a specialized imaging system [Artemis Fluorescence Imaging System (Quest Medical Imaging) and the FloCam system (developed in their laboratory)].

In seven of the 50 cases (14%), the tumor could easily be identified by its fluorescence. The tumors ranged in size from 1.1 to 8.0 cm, but size did not influence fluorescence. All of these tumors were within 1.2 cm of the surface.

Of the remaining 43 tumors, 39 appeared fluorescent after the overlying tissue was opened and the tumor exposed. The fluorescence was uniform across the tumor's surface, and the demarcation between tumor and normal surrounding tissue was clearly visible. On average, the optical imaging was quick, ranging from five to 15 minutes.

The technique proved to be particularly helpful in two cases. In a 50-year old man thought to have a 2.1 cm primary lung adenocarcinoma in the right upper pulmonary lobe, molecular imaging of the excised lobe identified a second pulmonary nodule that was fluorescent, leading to re-staging of the patient. In another patient, who was thought to have no evidence of metastatic disease, showed evidence of cancer elsewhere.

Four tumors (8%) did not exhibit fluorescence, and further analysis showed that these tumors did not express FRα antigens to allow localization of the contrast agent to the tumor. Thus, the FRα imaging agent is not useful for all lung adenocarcinomas.

"This technology is safe," stated Dr. Singhal. "The use of a visible-wavelength fluorophore avoids ionizing radiation and confers no risk to the patient, surgeon, or operating room personnel. In our experience, only one patient had a mild allergic reaction to the contrast agent that was easily managed with diphenhydramine. With miniaturization of imaging devices, this method will be particularly useful in minimally invasive surgery, such as VATS and robotic surgery."

"What Okusanya and colleagues have discovered is that they can make 92% of all adenocarcinomas glow to the naked eye, requiring no special training at all," noted Michael I. Ebright, MD, of the Section of Thoracic Surgery, New York-Presbyterian/Columbia University Medical Center (New York) in an accompanying editorial. "The Achilles' heel of the technique is tumor depth beneath the pleural surface," as fluorescence was not detectable to the operating surgeon in tumors buried within the lung. However, he added that "this study should be viewed as a launching pad rather than be judged solely on practicality in its current form." Dr. Ebright looks forward to modification of the system so that it can be used in minimally invasive surgery.

Lung cancer is the leading cause of cancer deaths, with approximately 221,200 deaths due to lung cancer anticipated in 2015. About 85% of lung cancers are non-small cell lung cancers (NSCLC), and adenocarcinoma of the lung is one of the most common forms of NSCLC, in both smokers and nonsmokers.


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More information: "Intraoperative molecular imaging can identify lung adenocarcinomas during pulmonary resection," by Olugbenga T. Okusanya, MD, Elizabeth M. DeJesus, BA, Jack X. Jiang, BS, Ryan P. Judy, BA, Ollin G. Venegas, BA, Charuhas G. Deshpande, MD, Daniel F. Heitjan, PhD, Shuming Nie, PhD, Philip S. Low, PhD, and Sunil Singhal, MD. dx.doi.org/10.1016/j.jtcvs.2015.05.0164
Provided by American Association for Thoracic Surgery
Citation: Real-time imaging of lung lesions during surgery helps localize tumors and improve precision (2015, July 29) retrieved 24 September 2021 from https://medicalxpress.com/news/2015-07-real-time-imaging-lung-lesions-surgery.html
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