iPSCs are potential cell types that can be used for regenerative medicine. Suspension culture is the main approach to produce a sufficient amount of required cells to realize the application of hiPSCs for the transplantation of the large organ. The dialysis culture system holds the potential to reduce the cost by utilizing endogenous growth factors and recycle the remaining exogenous growth factors at the same time. However, the current large scale dialysis culture system was not optimized for expanding the high-density culture. Several problems such as the requirement of the large volume and technical complexity make the optimization of this system remain challenging. Also, the interference of mechanical stress in the dynamic suspension culture may reduce cellular viability, pluripotency, and differentiation capacity. Here, we describe the simple miniaturized dialysis platform to evaluate the feasibility of high-density hiPSCs culture by combining the utilization of endogenous growth factors supported by a continuous exchange of nutrition and toxic metabolic product in a low mechanical stress culture environment in a viscoelastic medium.
Keywords: Growth factors; High-density; Human induced pluripotent stem cells (hiPSCs); Pluripotency; Simple dialysis culture.
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