Difference in shape of bone formed by isolated calvarial and scapular osteoblasts transplanted under various conditions.

To study the influence of transplantation conditions on early stages of osteogenesis, isolated calvarial or scapular osteoblasts were injected into the leg or dorsal muscles (free transplants) or implanted after seeding on fragments of devitalized parietal bones (supported transplants) into dorsal muscles. The cross-sections of bone islands formed by calvarial osteoblasts in the different types of transplants were then compared according to their maximal breadth and length. Moreover, the same dimensions of pieces of bone formed by scapular osteoblasts in supported transplants were compared with those of bones formed in free transplants into leg muscles. Finally, comparison of the dimensions of cross-sections of supported transplants of calvarial and scapular osteoblasts was done. Calvarial osteoblasts in dorsal muscles produced a slightly higher percentage of wider and longer islands than those in leg muscles. In supported transplants of calvarial osteoblasts the percentage of narrow bone islands (breadth less than 100 microns) was considerably higher than in free transplants. Similarly, the percentage of narrow cross-sections in bones formed by scapular osteoblasts was higher in supported than in free transplants. In supported transplants of calvarial osteoblasts the percentage of narrow islands was higher than in similar transplants of scapular bone cells. It is suggested that the differences in shape of pieces of bone formed in supported and free transplants reflect the difference in mechanical conditions to which the bone cells were subjected. Furthermore, in supported transplants devitalized parietal bones could form a barrier for diffusion of nutrients.(ABSTRACT TRUNCATED AT 250 WORDS)

The morphologic and biochemical effects of tensile force application to the interparietal suture of the Sprague-Dawley rat.

The purpose of this study was to correlate the histologic and biochemical responses of the interparietal suture to a range of tensile forces. Stainless steel spring implants, calibrated to generate expansive forces from 50 to 250 g, were placed across the interparietal suture in 85 female Sprague-Dawley rats. After experimental periods from 2 hours to 14 days, the interparietal sutures were evaluated by radiography, histology, and biochemistry. An in vivo/in vitro system was used for the biochemical analysis; total protein, proline incorporated, percent collagen, and alkaline phosphatase activity were measured. The radiographs and histology showed that in vivo suture expansion was achievable with 50 to 70 g of force, but the heavier forces showed greater sutural opening, more cellular proliferation, and more bone formation. This increased biologic response by the heavier forces was substantiated by an increase in sutural protein and alkaline phosphatase activity but not in percent collagen. It was concluded that changes in the total protein content of the suture were not primarily caused by proliferation of osteogenic cells and fibroblasts but due to an influx of transudate. In contrast, the increase in incorporation of 3H-proline and alkaline phosphatase activity correlated with the observance of bone formation. This study indicated a positive correlation between the magnitude of tensile forces and osteogenic response.