TY - JOUR
T1 - Force system generated by an adjustable molar root movement mechanism
AU - Viecilli, Rodrigo F.
AU - Chen, Jie
AU - Katona, Thomas R.
AU - Roberts, W. Eugene
N1 - Tooth movement simulation is important for planning the optimal force system and appliance design to correct a specific malocclusion. Experimental ver...
PY - 2009/2
Y1 - 2009/2
N2 - Introduction: Tooth movement simulation is important for planning the optimal force system and appliance design to correct a specific malocclusion. Experimental verification of a 3-dimensional force system is described for a unique molar root movement strategy that can be adapted to many clinical scenarios. Methods: The force system was measured for molar root movement springs that had adjustable alpha (anterior) and beta (posterior) moments. A 3-dimensional transducer assessed moments and forces in 3 planes during deactivation and simulated molar rotation. Two experimental situations were compared by using 10 springs in each group: spring reactivation was performed to compensate for changes in the force system caused by molar movement, or there was no reactivation. Results: Without reactivation, the force system becomes unfavorable after approximately 5° of molar movement (rotation). With reactivations, a favorable force system through 20° of molar movement is maintained. Conclusions: Present root-movement appliances require periodic adjustment to achieve optimal tooth movement. Additional studies are needed to design orthodontic appliances for delivering optimal force systems for the entire range of tooth movement. © 2009 American Association of Orthodontists.
AB - Introduction: Tooth movement simulation is important for planning the optimal force system and appliance design to correct a specific malocclusion. Experimental verification of a 3-dimensional force system is described for a unique molar root movement strategy that can be adapted to many clinical scenarios. Methods: The force system was measured for molar root movement springs that had adjustable alpha (anterior) and beta (posterior) moments. A 3-dimensional transducer assessed moments and forces in 3 planes during deactivation and simulated molar rotation. Two experimental situations were compared by using 10 springs in each group: spring reactivation was performed to compensate for changes in the force system caused by molar movement, or there was no reactivation. Results: Without reactivation, the force system becomes unfavorable after approximately 5° of molar movement (rotation). With reactivations, a favorable force system through 20° of molar movement is maintained. Conclusions: Present root-movement appliances require periodic adjustment to achieve optimal tooth movement. Additional studies are needed to design orthodontic appliances for delivering optimal force systems for the entire range of tooth movement. © 2009 American Association of Orthodontists.
KW - Orthodontic Wires
KW - Transducers
KW - Molar/pathology
KW - Humans
KW - Stress, Mechanical
KW - Rotation
KW - Orthodontic Appliance Design
KW - Orthodontic Brackets
KW - Patient Care Planning
KW - Tooth Root/pathology
KW - Models, Biological
KW - Tooth Movement Techniques/instrumentation
KW - Imaging, Three-Dimensional/instrumentation
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UR - https://www.mendeley.com/catalogue/995dd594-e44a-32cc-84af-a7d80208fe67/
U2 - 10.1016/j.ajodo.2007.02.058
DO - 10.1016/j.ajodo.2007.02.058
M3 - Article
C2 - 19201322
SN - 0889-5406
VL - 135
SP - 165
EP - 173
JO - American Journal of Orthodontics and Dentofacial Orthopedics
JF - American Journal of Orthodontics and Dentofacial Orthopedics
IS - 2
ER -