Conclusions
DPSC-derived spheroids can mimic the developmental process of cell survival, cavitation and spontaneous multi-differentiation on matrigel under certain conditions. This work allows for functional studies to investigate organ regeneration with human DPSCs in vitro.
Results
DPSCs were able to form large-sized spheroids on matrigel in osteogenic medium. Inside the spheroids, cells in the centre showed positive stain to stem cell markers, alkaline phosphatase and STRO-1. Hypoxia and massive cell death were observed in the core of the spheroids. Cavities were formed when the spheroids were cultivated in the osteogenic medium for about 14 days. After 28 days of cultivation, the surviving cells around the cavity spontaneously differentiated into neuronal (28.8%), vascular (33.3%), osteogenic (46.7%) and cartilaginous (72.0%) tissues under the osteogenic medium only. In contrast, when DPSCs-formed cell sheets were folded into giant-sized lumps and cultivated under the same conditions, the folded cell sheets became an entire lumenal structure and failed to differentiate into neuronal, osteogenic and cartilaginous cells. Marker analysis showed that cavitation-related molecules BMP7 and FGF3 expressed on the wall of the cavity in the spheroids, suggesting that the cavitation was functional, whereas cavitation-related molecules were absent in the folded cell sheets. Conclusions: DPSC-derived spheroids can mimic the developmental process of cell survival, cavitation and spontaneous multi-differentiation on matrigel under certain conditions. This work allows for functional studies to investigate organ regeneration with human DPSCs in vitro.