The roughness of the bone matrix surface affects osteoblastic differentiation. However, the effect of the roughness of the matrix surface on osteoclastic bone resorption remains to be studied. We examined the latter effect using disaggregated osteoclasts from neonatal rats. The resorption pit number and the total pit area on the rough surface were not different from those on smooth surfaces after 1 day, but they were 2 or more times higher after 3 days. The number of osteoclasts was not different on bone slices with either smooth or rough surfaces at 3 days. The alkaline phosphatase (ALP)-positive osteoblasts were relatively rare in both types of slices at first, then the number and the diameter of the enzyme-positive cells and the clusters preferentially increased on the rough bone slices. When hydroxyurea was added to the culture in order to suppress the proliferation and the subsequent differentiation of osteoblastic cells on rough surfaces, the increase in resorption on the rough surfaces was effaced; however, this agent had little affect on resorption of the smooth surfaces. The addition of ALP-positive cells to disaggregated osteoclasts increased bone resorption on the smooth surface. The results suggest that osteoblast development and subsequently bone resorption by osteoclasts is enhanced by the roughness of matrix surfaces.
The development of the potential of osteoblasts to support bone resorption by osteoclasts in response to roughness on bone slices was examined in the co-incubation cell system of immature osteoclasts and osteoblastic cells. The immature osteoclasts, which need alkaline phosphatase (ALP)-positive osteoblastic cells for bone resorption, were generated in mouse spleen cultures with 1, 25-dihydroxyvitamin D(3) and prostaglandin E(2). ALP-negative osteoblastic cells from mouse calvaria were incubated on rough surfaced bone slices for 3 days. The number of ALP-positive cells increased greatly on the rough surface, but little on the smooth surface. When immature osteoclasts were added and incubated for 1 more day, the resorption pit number and the total pit areas on the smooth surface were not much different from those before incubation but were approximately four times higher on the rough surface.
The roughness of the bone matrix surface affects osteoblastic differentiation. However, the effect of the roughness of the matrix surface on osteoclastic bone resorption remains to be studied. We examined the latter effect using disaggregated osteoclasts from neonatal rats. The resorption pit number and the total pit area on the rough surface were not different from those on smooth surfaces after 1 day, but they were 2 or more times higher after 3 days. The number of osteoclasts was not different on bone slices with either smooth or rough surfaces at 3 days. The alkaline phosphatase (ALP)-positive osteoblasts were relatively rare in both types of slices at first, then the number and the diameter of the enzyme-positive cells and the clusters preferentially increased on the rough bone slices. When hydroxyurea was added to the culture in order to suppress the proliferation and the subsequent differentiation of osteoblastic cells on rough surfaces, the increase in resorption on the rough surfaces was effaced; however, this agent had little affect on resorption of the smooth surfaces. The addition of ALP-positive cells to disaggregated osteoclasts increased bone resorption on the smooth surface. The results suggest that osteoblast development and subsequently bone resorption by osteoclasts is enhanced by the roughness of matrix surfaces.
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