Physical properties of root cementum : Part 18. The extent of root resorption after the application of light and heavy controlled rotational orthodontic forces for 4 weeks : a microcomputed tomography study | Macquarie University ResearchOnline

Home

Physical properties of root cementum : Part 18. The extent of root resorption after the application of light and heavy controlled rotational orthodontic forces for 4 weeks : a microcomputed tomography study

Please use this identifier to cite or link to this item: http://hdl.handle.net/1959.14/145172

20 Visitors

23 Hits

0 Downloads

Title: Physical properties of root cementum : Part 18. The extent of root resorption after the application of light and heavy controlled rotational orthodontic forces for 4 weeks : a microcomputed tomography study
Related: American journal of orthodontics and dentofacial orthopedics, Vol. 139, No. 5, (2011), p.e495-e503
DOI: 10.1016/j.ajodo.2010.01.036
Publisher: Mosby
Date: 2011
Author/Creator: Wu, Andy T. J
Author/Creator: Turk, Tamer
Author/Creator: Colak, Canan
Author/Creator: Elekdağ-Türk, Selma
Author/Creator: Jones, Allan S
Author/Creator: Petocz, Peter
Author/Creator: Darendeliler, M. Ali
Description: Introduction: The aim of this prospective randomized clinical trial was to quantitatively measure and compare the locations, dimensions, and volume of root resorption craters in human premolars after the application of controlled light and heavy rotational orthodontic forces over a 28-day (4-week) period. Methods: Fifteen patients requiring bilateral extraction of maxillary first premolars as part of their orthodontic treatment were recruited for this study. Each patient received a heavy (225 g) rotational force on 1 premolar and a light (25 g) rotational force on the contralateral premolar. Orthodontic rotational forces were applied over 28 days with buccal and palatal cantilever springs; 0.016-inch beta-titanium molybdenum alloys were used to apply the light force and 0.018-inch stainless steel was used for the heavy force. After the 28-day experimental period, the upper first premolars were extracted under stringent protocols to prevent root surface damage. The samples were then scanned using a microcomputed tomography (micro-CT) scan x-ray system (SkyScan 1072, Skyscan, Aartselaar, Belgium), and analyzed using convex hull algorithm (CHULL2D; University of Sydney, Sydney, Australia) software to obtain direct volumetric measurements. Results: The mean volume of resorption craters was 0.42 in the light force group and 0.51 in the heavy force group (P = 0.013). When separated at the root level, the difference in volume of root resorption craters between the 2 groups was significantly different only at the midlevel (P = 0.001). Root resorption craters were consistently detected at the boundaries between the buccal and distal surfaces and the mesial and lingual surfaces. The result supports our hypothesis that positive areas develop significantly more root resorption craters at all 3 levels, as compared with minimal areas (paired t test <0.001). Conclusions: Heavy rotational forces caused more root resorption than light rotational forces and compression areas (buccal-distal and lingual-mesial surfaces in this study) showed significantly higher root resorption than other areas at all levels of the root.
Description: 9 page(s)
Resource Type: journal article
Organisation: Macquarie University. Dept. of Statistics

Identifier: http://hdl.handle.net/1959.14/145172
Identifier: ISSN:0889-5406
Identifier: mq_res-ext-2-s2.0-79955608566
Language: eng
Reviewed

Macquarie University ResearchOnline

Search

Browse

Highlights

Resources