Celsee (Tm) Singlecell Chip Can Retrieve Rare Single Cells With 100% Efficiency For Genetic Analysis

Tumors are comprised of heterogeneous cells. Only a specific or rare population of tumor cells is capable of metastasizing through blood. While mapping out the genome of cancer cells, gene expression variations indicative of more aggressive cancer cells might be missed among the noise. Therefore, single cell gene expression and mutation analysis provide a more comprehensive and most precise information about the heterogeneity of cancer progression and metastasis. Although there has been a surge in technologies used for selection and analysis of single cells, single cell analysis of rare cells such as circulating tumor cells (CTCs) is fraught with technical challenges. Among many used techniques to isolate single cells, the most common cell separation method is cell sorting by flow cytometry, which requires cell labeling. The numerous steps involved in cell labelling and centrifugation result in significant cell loss and changes in gene expression. In addition, centrifugation may also cause shear-induced gene expression changes in viable cells. For other single cell analysis platforms, there is a minimum input of cells ranging from 200 - 1000 cells. Rare cells like CTCs are found in the range of 1-10 per mL of blood. Another challenge is that the input volume required for these systems is very low usually in microliters. Here, we introduce a novel microfluidic chip with 250,000 microwells which captures cells at 100% efficiency down to one cell with a dynamic range over 5 logs. The underlying principle of this technology is that the geometric pattern of the microfluidic chip captures a single cell from an initial volume of up to 1 mL of fluid due to cell settling. The unique microwell structure promotes easy fluid exchange without perturbing the cells from their captured locations, thereby eliminating cell loss during multistep downstream processing. Preliminary tests have shown that single or cluster of spiked cancer cells in blood can be immunostained, both live or fixed and can also be retrieved very efficiently from this chip using a micro capillary. The retrieved single cells can further be used for several single cell genetic analysis. We will present data describing cancer gene expression and gene mutation analysis in isolated single cells. Citation Format: Kalyan Handique, Priya Gogoi, William Chow, Kyle Gleason, Auston Payne, Vishal Premdev Sharma, Yixin Wang. Celsee™ SingleCell Chip can retrieve rare single cells with 100% efficiency for genetic analysis [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 4030. doi:10.1158/1538-7445.AM2017-4030