Cancer stem cells (CSCs) are sub-populations of tumor cells with the properties of self-renewal, clonal tumor initiation ability, drug-resistance, and for tumor initiation. Hence, targeting CSCs has been suggested as the key for development of new treatment strategy to cure cancer. CSCs reside in the microenvironment, which are majorly supported via the cancer-associated fibroblasts (CAF), as the feeder cells. The feeder cells could enrich the CSCs population and promote the stemness-associated gene expression in the CSC populations. The co-culture system is helpful to establish a model for CSC-targeting drug screening. However, the sources of CAFs and the heterogeneity of such stromal cells might affect the CSC and the drug-screening efficacy and reproducibility. Here, we wanted to setup a feeder-free culture system for CSC. Base on the CSCs/CAFs co-culture system, we have identified the CSCs-dependent micro-environmental factors, which may enrich and maintain their “stemness” through identifying the cytokine profiling in the co-culture condition medium. Then, we tried to find the suitable combination of CSCs-dependent cytokines for establishing a feeder free culture system of lung CSCs. Base on the transcriptomic analysis and protein cytokine array, several candidate cytokines were performed to examine the individual and combinatory effects on maintaining the CSCs characteristics. ry to find the suitable combination of different cytokines for establishing a feeder free culture system of lung CSCs. Here, we found IGF-1 combined with IL-6 could significantly increase the tumorous sphere numbers and promote Nanog gene expression. Such combination could also improve the CSCs 3-D culture in the HA-chitosan Plates. Above all, our results show the promising to maintain CSCs in the feeder-free culture system by using IGF-1 and IL-6 combination. This model could be helpful for establish the drug screening system for targeting on CSCs.