摘要
Traditional two-dimensional(2D)cell cultures lack the extracellular matrix(ECM)-like structure or dynamic fluidic microenvironment for cells to maintain in vivo functionality.Three-dimensional(3D)tissue scaffolds,on the other hand,could provide the ECM-like microenvironment for cells to reformulate into tissue or organoids that are highly useful for in vitro drug screening.In this study,a high-throughput two-chamber 3D microscale tissue model platform is developed.Porous scaffolds are selectively foamed on a commercially available compact disk using laser.Perfusion of cell culture medium is achieved with centrifugal force-driven diffusion by disk rotation.Experimental studies were conducted on the fabrication process under various gas saturation and laser power conditions.Cell cultures were performed with two types of human cell lines:M059K and C3A-sub28.It is shown that the structure of microscale porous scaffolds can be controlled with laser foaming parameters and that coating with polydopamine these scaffolds are inducive for cell attachment and aggregation,forming a 3D network.With many such two-chamber models fabricated on a single CD and perfusion driven by the centrifugal force from rotation,the proposed platform provides a simple solution to the high-cost and lengthy drug development process with a high-throughput and physiologically more relevant tissue model system.
基金
supported by the US National Science Foundation under Grant No.CMMI-1131710.