Tooth movement out of the bony wall using augmented corticotomy with nonautogenous graft materials for bone regeneration
Kye-Bok Lee, Dong-Yeol Lee, Hyo-Won Ahn, Seong-Hun Kim, Eun-Cheol Kim, Igor Roitman, Kye-Bok Lee, Dong-Yeol Lee, Hyo-Won Ahn, Seong-Hun Kim, Eun-Cheol Kim, Igor Roitman
Abstract
This prospective randomized split-mouth study was performed to compare the effects of augmented corticotomy with those of different nonautogenous bone graft materials combined with orthodontic tooth movement in dogs. Decortication was performed on the buccal bone surface of 6 male beagle dogs that were randomly assigned to receive grafts of deproteinized bovine bone mineral, irradiated cortical bone, or synthetic bone. Immediate orthodontic force was applied to the second and third premolars for buccal tipping for 6 weeks. The pocket depth and width of keratinized tissue (WKT) were measured. Histologic and histomorphometric analyses were performed. The probing depth, WKT, and ratio of the area of new bone to that of total bone on the buccal side were not significantly different between groups. All groups had considerable new bone formation on the pressure side. New bone formation on the buccal side and buccal plate formation in the coronal direction along the root surfaces were induced by the bone-derived and PDL-derived mesenchymal matrix, respectively. The angular change between groups was significantly different (P < 0.001). Augmented corticotomy using nonautogenous graft materials facilitated tooth movement without fenestrations and accelerated new bone formation on the pressure side.
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References
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