An experimental design to study adipocyte stem cells for reconstruction of calvarial defects.

Autogenous osteogenic differentiated rat adipose stromal cells (ASCs) were used to repopulate cadaveric processed bone in a critical calvarial defect model to improve bone healing as compared with the standard treatment of cadaveric bone implantation alone. Forty-two skeletally mature Sprague-Dawley rats were randomized to 5 groups including bone graft only, bone/osteogenic differentiated ASCs, fibrin glue/osteogenic differentiated ASCs, and bone/fibrin glue/osteogenic differentiated ASCs; 2 animal calvarias were left empty. Adipose stromal cells were isolated from the inguinal fat pad of rats and differentiated into osteogenic cells, verified using von Kossa and alkaline phosphatase staining, and osteocalcin immunohistochemistry. These cells were added to sterilized, 8-mm cadaveric bone graft disks and placed back into calvarial defect for 6 weeks. The rat calvarias then underwent bone density analysis and histology. Intact cells were observed in the bone graft of the bone/osteogenic differentiated ASC group only. Islands of bone were seen in the bone-graft-only group, the bone/osteogenic differentiated ASC group, and the bone/fibrin/osteogenic differentiated ASC group. The bone-graft-only group and bone/osteogenic differentiated ASC group were similar in bone mineral density (1397 +/- 184.5 vs 1365 +/- 160.4). The bone/fibrin/osteogenic differentiated ASC group density was less than the bone and bone/osteogenic differentiated ASC groups at 835.2 +/- 319.5 (P < 0.001). Allograft bone scaffolds with autogenous osteogenic differentiated ASCs showed cellularity within the bone grafts and had larger bone islands. The presence of osteogenic differentiated ASCs did not increase overall bone density compared with bone graft only.

In vitro osteogenic differentiation of adipose stem cells after lentiviral transduction with green fluorescent protein.

BACKGROUND: Adipose-derived stem cells (ASCs) have the potential to differentiate into osteogenic cells that can be seeded into scaffolds for tissue engineering for use in craniofacial bone defects. Green fluorescent protein (GFP) has been widely used as a lineage marker for mammalian cells. The use of fluorescent proteins enables cells to be tracked during manipulation such as osteogenic differentiation within three-dimensional scaffolds. The purpose of this study was to examine whether ASCs introduced with GFP-encoding lentivirus vector exhibit adequate GFP fluorescence and whether the expression of GFP interfered with osteogenic differentiation of ASCs in both monolayer and three-dimensional scaffolds in vitro. METHODS: Primary ASCs were harvested from the inguinal fat pad of Sprague Dawley rats. Isolated ASCs were cultured and infected with a lentiviral vector encoding GFP and plated into both monolayers and three-dimensional scaffolds in vitro. The cells were then placed in osteogenic medium. Osteogenic differentiation of the GFP-ASCs was assessed using alizarin red S, alkaline phosphate staining, and immunohistochemistry staining of osteocalcin with quantification of alizarin red S and osteocalcin staining. RESULTS: The efficacy of infection of ASCs with a lentiviral vector encoding GFP was high. Cell-cultured GFP-ASCs remained fluorescent over the 8 weeks of the study period. The GFP-ASCs were successfully induced into osteogenic cells both in monolayers and three-dimensional scaffolds. Whereas the quanitification of alizarin red S revealed no difference between osteoinduced ASCs with or without GFP, the quantification of osteocalcin revealed increased staining in the GFP group. CONCLUSIONS: Transduction of isolated ASCs using a lentiviral vector encoding GFP is an effective method for tracing osteoinduced ASCs in vitro. Quantification data showed no decrease in staining of the osteoinduced ASCs.