The latest version of a microfluidic device for capturing rare circulating tumor cells (CTCs) is the first designed specifically to capture clusters of two or more cells, rather than single cells. The new device, called the Cluster-Chip, was developed by the same Massachusetts General Hospital (MGH) research team that created previous microchip-based devices. Recent studies by MGH investigators and others have suggested that CTC clusters are significantly more likely to cause metastases than single circulating tumor cells.
The device is described in a Nature Methods paper that was published online May 18. Among the members of the research team is Fatih Sarioglu, now an assistant professor in the School of Electrical and Computer Engineering at Georgia Tech.
“Early theories of cancer metastasis were based on clumps of tumor cells traveling through the bloodstream, but given that CTC clusters are even rarer in the blood than single CTCs, they have attracted minimal attention for several decades,” explained Mehmet Toner, PhD, director of the BioMicroElectroMechanical Systems Resource Center in the MGH Center for Engineering in Medicine, the paper's senior author. “The ability to isolate intact clusters will enable is to investigate carefully their role in the metastatic process, and understanding metastasis really is the ‘holy grail’ of cancer research.”
CTCs are living solid tumor cells found in the bloodstream at extremely low levels – about one in a billion cells. Starting in 2007, MGH researchers have developed three microchip-based devices that capture CTCs in ways that preserve molecular information that can help guide clinical treatment. The first two versions used antibodies directed at specific proteins on the surface of tumor cells, which limited the ability to capture cells that may have lost those marker proteins during the process of metastasis. The third version, developed in 2013, uses antigen-independent methods of isolating CTCs, which is also the case for the Cluster-Chip.
“Cancer is an extremely heterogeneous disease, and even within the same tumor you can find cells with different surface antigens,” said Sarioglu, co-lead author of the Nature Methods paper. “Since we are capturing clusters because of their physical properties, this chip is directly applicable to all types of cancer.”
Sarioglu explained that the strategy behind the design of the chip is based on the physical properties of clusters of cells. The 3- by 1 ½-inch plastic chip through which a blood sample is passed consists of rows of triangular microposts arranged in such a way that clusters passing between two posts will become trapped on the apex of a third central post and held in place by the balanced flow of fluid on either side. Single CTCs and blood cells will pass right through without being captured. In addition, passing the sample through the device at a slow rate minimizes the possibility that clusters will be broken, distorted or escape.
Initial testing of the Cluster-Chip with blood samples to which artificially formed tumor cell clusters had been introduced helped to determine the optimal flow rate to capture the most clusters in the least time. The researchers then compared the new device to the second-generation HBCTC-Chip, which relies on known cell-surface markers and was the first to isolate CTC clusters. The Cluster-Chip proved to be 40 to 50 percent better at finding clusters of cells expressing targeted markers and 100 percent better at capturing cells without target antigens.
While initial attempts to release captured clusters from the device by simply reversing the fluid flow had limited success, the investigators found that reducing the temperature of the device itself to 4 degrees Celsius (39 F) not only released 80 percent of clusters, but also improved the purity of the captured material by reducing the undesired capture of white blood cells.
Use of the Cluster-Clip to test blood samples from 60 patients with either breast cancer, melanoma or prostate cancer successfully captured CTC clusters in from 30 to 40 percent of samples. Analysis of captured clusters revealed they consisted of cells with significant molecular differences, some actively proliferating and other relatively quiescent, and were often accompanied by immune cells, an observation that could have important implications with the increased attention to immune-system-based cancer therapies.
“Testing of patient blood samples also revealed that there were significantly more CTC clusters in the blood than was previously believed,” said Toner. “We now are looking at ways to improve further the release of captured clusters, but we are only at the beginning of our quest to understand the role and biology of CTC clusters. Eventually we could develop ways to target clusters therapeutically as well as using them as a source of diagnostic information.” Toner is the the Benedict Professor of Surgery at Harvard Medical School.
“This new isolation device will be particularly useful in isolating clusters of CTCs, which seem to be the most malignant and metastasis-prone types of cancer cells in the blood,” said Daniel Haber, MD, director of the MGH Cancer Center and a co-author of the Nature Methods paper. “I’m particularly excited by the way in which the device was created – starting from a clinical and biological observation about the importance of these CTC clusters and then designing a specific microfluidic device to capture these cells, which will make it possible to study them in greater detail.”
Nicola Aceto, PhD, of the MGH Cancer Center is co-lead author of the Nature Methods paper. Support for the current study includes grants from the National Institutes of Health, the National Institute of Biomedical Imaging and Bioengineering, a “dream team” grant from Stand Up to Cancer, the Howard Hughes Medical Institute, the Prostate Cancer Foundation, the Charles Evans Foundation, and Johnson and Johnson. The MGH has filed a patent application for the Cluster-Chip.
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Article written by Massachusetts General Hospital.
Close-up image shows the microfluidic device designed to capture cancer cell clusters in blood samples. The fluid shown in the device is a colored liquid designed to simulate the appearance of blood. (Credit: Rob Felt)
Microfluidic device for capturing cancer cell clusters2
A three-cell circulating tumor cell cluster is captured and held by the balanced fluid flow on either side of the triangular microposts on the Cluster-Chip. (Credit: BioMEMS Resource Center, Massachusetts General Hospital)
Cluster-Chip capturing cancer cell cluster
Fatih Sarioglu, an assistant professor in the Georgia Tech School of Electrical and Computer Engineering, is shown in his laboratory, where microfluidic devices are fabricated and tested. (Credit: Rob Felt)
Fatih Sarioglu in lab
Fatih Sarioglu, an assistant professor in the Georgia Tech School of Electrical and Computer Engineering, is shown examining a microfluidic device designed to capture cancer cell clusters. An image of the chip is projected onto his shirt. (Credit: Rob Felt)
Fatih Sarioglu in lab2
Circulating tumor cell clusters can be captured from patient blood samples passed through the more than 4,000 parallel trapping paths in the Cluster-Chip. (Credit: BioMEMS Resource Center, Massachusetts General Hospital)
On the Cluster-Chip, multiple rows of triangular microposts can capture circulating tumor cell clusters in a blood sample. (Credit: BioMEMS Resource Center, Massachusetts General Hospital)
Microfluidic trap for catching cancer cell clusters
Last revised August 1, 2017