Molecular profiling using next generation sequencing with high-purity enrichment of circulating tumor cells.

Abstract

e15054 Background: In the field of liquid biopsy, coupled with next generation sequencing (NGS), circulating tumor cells (CTCs) and circulating tumor DNA (ctDNA) can serve as an alternative substrate to tumor tissue for mutation detection and companion diagnostic purpose. Emerging evidence suggests that complementary sequential CTCs and ctDNA profiling offers promising benefits for prognosis and treatment. In contrast to well-established ctDNA extraction methods, the process of isolation of intact CTCs for NGS analysis has not yet been fully elucidated. Here we show that isolation and harvesting of viable CTCs using CytoGen's Smart Biopsy™ System achieves high CTC purity for NGS analysis in breast cancer and non-small cell lung cancer (NSCLC). Methods: Targeted panel sequencing for CTC was developed to detect representative mutated genes using the Oncomine™ Comprehensive Assay Plus (501 genes) and the Oncomine™ Pan-Cancer Cell-Free Assay (52 genes). Analytical validation was performed with breast cancer cells MDA-MB-231 (50 to 5 cells) and NSCLC cells H358 (10 and 5 cells) which were spiked into 5 mL of healthy blood to mimic CTCs. CytoGen's Smart Biopsy™ System was applied to isolate the CTCs. Subsequently, CD45 depletion and whole genome amplification were performed. Sequencing was performed on Ion S5™ XL Systems using an Ion 550™ chip kit. The sequencing data were then analyzed using the Ion Torrent software with the default configurations. Results: As a result of targeted panel sequencing with Oncomine™ Comprehensive Assay Plus, representative breast cancer mutation genes (BRAF, KRAS, TP53, NF2 and NOTCH3) were detected in at least 20 MDA-MB-231 cells. In the results using Oncomine™ Pan-Cancer Cell-Free Assay, mutated genes (BRAF, KRAS and TP53) were successfully detected in as few as 5 MDA-MB-231 cells and, in addition, KRAS mutation was detected even with only 5 H358 cells. These results suggest that CytoGen's Smart Biopsy™ System could be applied to detect representative mutated genes in clinical breast cancer and NSCLC patient samples with detection technology that require high sensitivity and specificity. Conclusions: Molecular analysis of CTCs is a challenge since CTCs are very rare in the blood and there are technical limitations in isolating CTCs with sufficient purity for NGS analysis. In this study, we developed the process for NGS analysis on very small number of high-purity CTCs using CytoGen's Smart Biopsy™ System. Taken together with the results from our ongoing clinical trials, this process could provide information for the diagnosis and appropriate treatment of breast cancer and NSCLC patients.