RARITAN, N.J., April 3, 2013 /PRNewswire/ -- Veridex, LLC (Veridex) announced today that the first study of the company's next-generation circulating tumor cell (CTC) technology, developed in collaboration with researchers at Massachusetts General Hospital (MGH), has been published in Science Translational Medicine. The collaboration, initially announced in January 2011, has led to the development of a next-generation CTC (or "liquid biopsy") technology that offers enhanced specificity and sensitivity and enables more extensive characterization of captured cells.
The new technology tests for CTCs from the blood of cancer patients using advanced microfluidic separation techniques integrated with innovative magnetic sorting to isolate a broad spectrum of rare circulating cancer cells. This technology will allow physicians to get information about a patient's cancer at the time treatment is being administered, one of the key components to enabling personalized medicine.
Results from the in vitro study showed the integrated system enabled the processing of large blood volumes with high throughput and efficiency, and also allowed for the ability to isolate CTCs from both epithelial and non-epithelial cancers.
In the study, the technology was used to identify the presence of CTCs in patients with cancers of the lung, prostate, pancreas, breast, as well as melanoma."Veridex is proud to have introduced CELLSEARCH ®, the first and only FDA-cleared CTC test, and we're excited to work with the team at Massachusetts General Hospital on our next-generation test," said Nicholas C. Dracopoli, Ph.D., Vice President and Head of Oncology Biomarkers, Janssen Research & Development, LLC. "Together, Veridex and the MGH team bring more than 25 years of experience in rare cell technology to this project. We're encouraged by the positive results from this study and the potential role this technology may play in helping to advance physicians' ability to monitor their patients and develop more personalized treatment approaches." "These results show the possibility of its use for patients in 'real time' as they are receiving treatment. We hope that this next-generation CTC technology will become an everyday tool for doctors treating patients with cancer," said Mehmet Toner, Ph.D., director of the BioMicroElectroMechanical Systems Resource Center in the Massachusetts General Hospital. How It Works The system used two modes of immunomagnetic sorting to isolate CTCs: a positive selection mode to identify and tag target CTCs based on expression of the epithelial surface marker EpCAM ("epithelial cell adhesion molecule"), and a negative selection mode, in which the blood sample is depleted of leukocytes by tagging them with specific antibodies. The test's ability to isolate CTCs in this manner allows for RNA-based, single cell molecular characterization and expression analysis of CTCs. It will also allow for the test to be used in a broader range of cancers, including cells undergoing epithelial-mesenchymal transition (EMT) and cancer stem cells.