Effects of neural differentiation maturity status of human induced pluripotent stem cells prior to grafting in a subcortical ischemic stroke model.

Neural cell grafting is a promising therapy for stroke, but the optimal differentiation status of the cells prior to grafting is unclear. We grafted cells at different maturity stages (days 28, 42, or 56 of in vitro neural differentiation) into the brains of eight-week-old rats one week after subcortical ischemic stroke, and assessed motor and sensory behavioral recovery over one month. We did not find a difference between the grafted or control groups on behavioral recovery, or on brain tissue outcomes including infarct size, microgliosis, or astrocytosis. Further research is needed into mechanisms of benefit of neural cell grafting for stroke.

Effect of enzymatic and mechanical methods of dissociation on neural progenitor cells derived from induced pluripotent stem cells.

PURPOSE: To determine the most effective method of dissociating neural stem and progenitor cells into a single-cell suspension. MATERIALS/METHODS: Induced pluripotent stem cells were differentiated toward the neural fate for 4 weeks before clusters were subjected to enzymatic (Accutase, trypsin, TrypLE, dispase, or DNase I) or mechanical (trituration with pipettes of varying size) or combined dissociation. Images of cells were analyzed for cluster size using ImageJ. RESULTS: Cells treated with the enzymes Accutase, TrypLE, or trypsin/EDTA, these enzymes followed by trituration, or a combination one of these enzymes followed by incubation with another enzyme, including DNase I, were more likely to be dissociated into a single-cell suspension. CONCLUSIONS: Cells treated with enzymes or combinations of methods were more likely to be dissociated into a single-cell suspension.

Effect of different feeding schedules on the survival and neural differentiation of human embryonic and induced pluripotent stem cells.

Neural culture of human pluripotent stem cells is useful for neuroscience research, but the optimal feeding schedule for these in vitro systems is unclear. We evaluated the survival and neural differentiation profiles of human embryonic and induced pluripotent stem cells cultured with medium exchange schedules of five, six, or seven days weekly through two months of differentiation. No significant differences were seen in cell numbers or neural differentiation markers through this culture interval with either human pluripotent cell type. We conclude that there is unlikely to be an advantage of feeding more than five days weekly for this culture system.