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Abstract

It is unknown if epidermal stem cells are maintained during the commercial-scale manufacture of Apligraf, a bilayered living cellular construct (BLCC). To answer this question, we genetically marked replicating keratinocytes, derived from production-scale expansion of working cell banks, in two-dimensional culture with a beta-galactosidase-expressing retrovirus and monitored their fate after incorporation into BLCC and subsequent in vivo transplantation to a nude mouse. Histological analysis of BLCCs showed distinct beta-galactosidase-positive clusters similar to clonal proliferation units visible 8–32 weeks after grafting. Keratinocytes recovered from grafts at week 32 were expanded in vitro in two-dimensional culture, and clonal growth of recovered cells was then compared to the original pregraft population of keratinocytes by colony-forming efficiency (CFE) assays. The CFE of the cells regrown from the grafts was similar to pregraft CFEs (45% and 40%, respectively). Cells regrown from the grafts were then used to produce a second BLCC and generated a well-differentiated epithelium that was histologically similar to pregraft BLCC. These findings provide clear evidence that epidermal stem cells were sustained during the process of large-scale tissue fabrication and that the process of isolation and expansion of cells in BLCC construction retains viable stem cells.

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Epidermal Stem Cells Are Preserved During Commercial-Scale Manufacture of a Bilayered,Living Cellular Construct (Apligraf ® )

Abstract

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