Magneto-Controllable Capture and Release of Cancer Cells by Using a Micropillar Device Decorated with Graphite Oxide-Coated Magnetic Nanoparticles

Aiming to highly efficient capture and analysis of circulating tumor cells, a micropillar device decorated with graphite oxide‐coated magnetic nanoparticles is developed for magneto‐controllable capture and release of cancer cells. Graphite oxide‐coated, Fe3O4 magnetic nanoparticles (MNPs) are synthesized by solution mixing and functionalized with a specific antibody, following by the immobilization of such modified MNPs on our designed micropillar device. For the proof‐of‐concept study, a HCT116 colorectal cancer cell line is employed to exam the capture efficiency. Under magnetic field manipulation, the high density packing of antibody‐modified MNPs on the micropillars increases the local concentration of antibody, as well as the topographic interactions between cancer cells and micropillar surfaces. The flow rate and the micropillar geometry are optimized by studying their effects on capture efficiency. Then, a different number of HCT116 cells spiked in two kinds of cell suspension are investigated, yielding capture efficiency >70% in culture medium and >40% in blood sample, respectively. Moreover, the captured HCT116 cells are able to be released from the micropillars with a saturated efficiency of 92.9% upon the removal of applied magnetic field and it is found that 78% of the released cancer cells are viable, making them suitable for subsequent biological analysis. A micropillar device decorated with graphite oxide‐coated magnetic nanoparticles is fabricated for magneto‐controllable capture and release of cancer cells. Notably, the captured cancer cells are able to be released from the micropillars with high viability upon the removal of external magnetic field, which potentially facilitates subsequent analysis.