June 13, 2016
Molecular imaging is used to monitor a novel immunotherapy that aims to hamper tumors’ ability to turn off cancer-fighting immune cells
San Diego, Calif. (Embargoed until 11:30 AM on Monday, June 13) – Non-small cell lung cancers (NSCLC) have a collective reputation for not responding very well to chemotherapy. Researchers at the 2016 Annual Meeting of the Society of Nuclear Medicine and Molecular Imaging (SNMMI) are presenting a means of evaluating an immunotherapy that fights off NSCLC by strengthening a patient’s own immune system.
NSCLC accounts for as much as 85 percent of all lung cancers. Due to NSCLC’s relative insensitivity to chemotherapy, researchers have been increasing the use of immunotherapies, including a class of monoclonal antibodies that serve as immune checkpoint blockade inhibitors. Essentially, these drugs stop malignant tumor cells from hijacking aspects of the immune system that keep cancer cells from proliferating out of control. Here, researchers investigated a relatively new drug called atezolizumab, which inhibits activity between the programmed death 1 (PD-1) receptor expressed on certain immune cells—most notably killer T cells—and the programmed death-ligand 1 (PD-L1), a transmembrane protein found on the surface of tumor cells. Cancer and other antigen-bearing cells wield this protein to bind with and deactivate cancer-specific T cells and effectively suppress immune response to malignant cells.
Researchers tracked the ability of atezolizumab to bolster immunity against NSCLC with positron emission tomography (PET), which provides a visualization of physiological functions of the body with the aid of an injected imaging agent combining a tiny amount of radioactive material and a molecular compound called fluorine-18 fluorodeoxyglucose (F-18 FDG). This radiotracer mimics glucose as it is taken up as fuel by the body. FDG-PET allows clinicians to see areas of increased metabolic activity in cells, also known as hypermetabolism, a hallmark of malignant tissues, and change in metabolic activity following drug treatment.
“This study is the first to prospectively evaluate FDG-PET imaging in a phase II trial of lung cancer patients receiving the novel immune checkpoint inhibitor atezolizumab,” said Jill Fredrickson, PhD, a clinical imaging scientist in the Department of Early Clinical Development at Genentech in San Francisco, Calif. “These findings help define the potential role of FDG-PET as a prognostic and predictive biomarker in the treatment of lung cancer with such immuno-therapeutics.”
This multi-center study included a total of 138 patients with NSCLC from 28 clinical institutions in five different countries. All subjects received 1200 mg of atezolizumab administered intravenously in three-week intervals. Researchers used quantitative PET that measured FDG retention as a sign of metabolic activity, both at baseline before study treatment, and again after six weeks of treatment with atezolizumab.
The study revealed that higher baseline tumor volumes of FDG were predictive of reduced patient survival, meaning that greater active tumor volume at the start of therapy was a sign of lower survival. In addition, a further increase in tumor volume at six weeks was a sign of decreased patient survival. Although atezolizumab and other immune checkpoint inhibitors work differently than conventional chemotherapy, FDG-PET may be used with either treatment to help doctors evaluate how NSCLC patients may respond to therapy.
Scientific Paper 134: “Utility of FDG-PET in immunotherapy: results from a Phase II study of NSCLC patients undergoing therapy with the PD-L1 inhibitor, atezolizumab (MPDL3280A),” J. Fredrickson, R. Funke, S. Sanabria, A. de Crespigny, Genentech, South San Francisco, CA; J. Callahan, R. J. Hicks. Peter MacCallum Cancer Inst, East Melbourne, Australia; W. Weber, Memorial Sloan Kettering Cancer Center, New York, NY, SNMMI’s 63rd Annual Meeting, June 11–15, 2016, San Diego, Calif.
About the Society of Nuclear Medicine and Molecular Imaging
The Society of Nuclear Medicine and Molecular Imaging (SNMMI) is an international scientific and medical organization dedicated to raising public awareness about nuclear medicine and molecular imaging, a vital element of today’s medical practice that adds an additional dimension to diagnosis, changing the way common and devastating diseases are understood and treated and helping provide patients with the best health care possible.
SNMMI’s more than 17,000 members set the standard for molecular imaging and nuclear medicine practice by creating guidelines, sharing information through journals and meetings and leading advocacy on key issues that affect molecular imaging and therapy research and practice. For more information, visit www.snmmi.org.