OBJECTIVE: To determine the effects of vitamin C and insulin on osteoblasts harvested from neonatal mouse calvaria. To determine the effects of experimental media (vitamin C and insulin and a combination) on the ex-vivo live bone organ culture model and explore the capacity of addition of osteoblasts to allow for bone formation within a critical defect. To use the chick chorioallantoic membrane (CAM) model to explore bone formation within critical bone defect.
METHODS: Osteoblasts were harvested from neonatal mice were tested using four types of experimental media: control DMEM, media prepared with 150 μg/ml vitamin C, 10 nM media, or a combination of both vitamin C, insulin, and a combination of vitamin C and insulin media. Cell were cultured for 18 days at 37°C. Neutral red was done to identify cellular activity and silver nitrate to detect calcium deposits. Two types of scaffolds were inserted into the defect: collagen membrane scaffold and NuOss (xenograft) with collagen scaffold. After 30 days the samples were collected for histological analysis. Neonatal mouse calvaria were harvested and a 2mm critical defect made on each calvaria. Each calvaria received a scaffold of collagen or NuOss with or without osteoblasts with one of three experimental media within the CAM model. After 7 days, the amnion membrane of the egg was dropped and a window was made. The calvaria with the scaffold samples were placed on the amnion membrane. The eggs were incubated for 10 days then the experiment was terminated. Calvaria were collected and processed for histological evaluation.
RESULTS: Neutral red and silver nitrate of 2D in-vitro cells revealed calcium deposits in culture well using vitamin C media, cell cultured with insulin media showed calcium deposits and cell morphological change, and cell cultured with a combination of vitamin C and insulin media showed the most calcium deposits and morphological changed. Ex-Vivo samples with collagen scaffold had bone thickening but not enough nutrients for bone regeneration, despite the addition of cells. The collagen scaffold is a more suitable material than xenograft due to particle size. The CAM model showed new bone formation and new vessels were most abundant in areas closest to lining cells in collagen samples. Samples with additional osteoblasts added showed greater results. NuOss scaffold samples did not show the same bone formation or vessel growth.
CONCLUSIONS: The results indicate and confirm the basic principles of tissue engineering. In order to have bone regeneration more cells allow for better results. The quality of the scaffold is important and should have stability as well as enough space for cellular migration and recruitment for new blood vessel to support regeneration of bone to its original state.
| Identifer | oai:union.ndltd.org:bu.edu/oai:open.bu.edu:2144/42218 |
| Date | 02 March 2021 |
| Creators | Sawyer, Hillary |
| Contributors | Dibart, Serge |
| Source Sets | Boston University |
| Language | en_US |
| Detected Language | English |
| Type | Thesis/Dissertation |
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