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Osseodensification-induced bone healing in mouse calvaria under static condition

BACKGROUND: Recently osseodensification has been introduced as a novel approach to management of the recipient site. The concept had been described in 2013 by Huwais which has revolutionized the way we approach an osteotomy site as we may obtain densification of the bone rather than its complete removal.
AIM: We hypothesize that proper manipulation of the recipient site will induce cellular activities to accelerate new bone formation. We compared bone formation in a critical defect created by the osseodensification method or regular osteotomy under ex-vivo static calvarial culture.
MATERIALS AND METHODS: Under sterile conditions, calvaria from 7-9-day-old neonatal CD-1 mice (n = 15) were dissected and trimmed. Densahâ„¢ burs were used to create 2.0 mm diameter defects. Clockwise rotation of the bur produced "Conventional Osteotomy," whereas counter-clockwise rotation created "Osseodensification." Five randomly selected calvaria halves for control and test groups were used to evaluate morphological changes, at 7, 14, and 28 days utilizing the Image J software. Statistical analyses were performed using SPSS software.
RESULTS: Defect closure was significantly greater in the osseodensification group compared to the conventional group at post-operative day7 (p = 0.028), day 14 (p = 0.046) and day 28 (p=0.015). The original defects in both groups were not significantly different.
CONCLUSION: Results showed that osseodensification lead to faster wound healing. Clinical studies have shown that osseodensification leads to better bone density around implants. These outcomes suggest that the compressed edge of a bone defect can accelerate the healing cascade by increasing cellular activity.

Identiferoai:union.ndltd.org:bu.edu/oai:open.bu.edu:2144/41343
Date29 July 2020
CreatorsAhmad, Bushra A M A
ContributorsOhira, Taisuke
Source SetsBoston University
Languageen_US
Detected LanguageEnglish
TypeThesis/Dissertation

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