Stem-cell biology for the applications of regenerative medicine is gathering great interests because of their self-renewal property and ability to differentiate into many types of cells. Since differentiation of stem cells is sensitive to environmental factors, stem cells for clinical use are encountering a vast challenge. The microfluidic chip system fabricated by micro electro mechanical systems (MEMS) technology is able to provide microenvironments which can mimic in vivo surroundings and to be well-controlled. Besides, these devices are characterized as a smaller size, less sample/reagent consumption, reduced risk of contamination, and real-time optical analysis. In this study, a new microfluidic chip system is developed which can culture and differentiate PDMCs in in vivo-like microenvironments. Experimental results indicate that the microfluidic chip system can achieve a well biocompatibility, and the cells can be cultured under perfusion in the chips over 10 days. We also used IBMX to induce the differentiation of PDMCs into neuron within temporary fluid flow stimuli under the various rate at 0.083, 2 and 30 μL/min, respectively. The results illustrate that the fluid flow could promote cells differentiation earlier at higher flow rates.