A novel microfluidic co-culture system for investigation of bacterial cancer targeting†
Abstract
Although bacterial cancer targeting in animal models has been previously demonstrated and suggested as a possible therapeutic tool, a thorough understanding of the mechanisms responsible for cancer specificity would be required prior to clinical applications. To visualize bacterial preference for cancer cells over normal cells and to elucidate the cancer-targeting mechanism, a simple microfluidic platform has been developed for in vitro studies. This platform allows simultaneous cultures of multiple cell types in independent culture environments in isolated chambers, and creates a stable chemical gradient across a collagen-filled passage between each of these cell culture chambers and the central channel. The established chemical gradient induces chemotactic preferential migration of bacteria toward a particular cell type for quantitative analysis. As a demonstration, we tested differential bacterial behavior on a two-chamber device where we quantified bacterial preference based on the difference in fluorescence intensities of green fluorescence