A three-dimensional finite element study on the reaction of different force values generated from maxillary protraction appliance

Shanghai Journal of Stomatology ›› 2013, Vol. 22 ›› Issue (5): 498-503.

• Basic Scientific Study • Previous Articles Next Articles

A three-dimensional finite element study on the reaction of different force values generated from maxillary protraction appliance

LIU Wan-xin¹, WANG Xu-xia^1,2, ZHANG Wen-juan³, DONG Rui¹, CHEN Yun¹, ZHANG Jun^1,2

1.School of Stomatology, Shandong University. Jinan 250012; 2.Shandong Provincial Key Laboratory of Oral Biomedicine. Jinan 250012; 3.Deportment of Stomatology, Affiliated Hospital of Shandong University of Traditional Chinese Medicine. Jinan 250011, Shandong Province, China

Received:2013-04-15 Revised:2013-05-03 Online:2013-10-10 Published:2013-10-10
Supported by:
Supported by Natural Science Foundation of Shandong Province(ZR2011HM036), Medical Health and Technology Development Project(2011QZ023) of Shandong Province and Independent Innovation Project of Jinan College Institute(201202032).

Abstract

Abstract: PURPOSE: To analyse the stress distribution of temporomandibular joint(TMJ) and jaw and the displacement changes of each part from the reaction force generated from maxillary protraction appliance by establishing a craniomaxillofacial three-dimensional finite element model (3-D FEM). METHODS: A 3-D FEM of craniofacial structure including TMJ and jaw was established from a male healthy subject by using CT scan and Mimics, Magics, MSC and other data analysis softwares. It was based on the linear elastic materials which were continuous, homogeneous, and isotropic. Then the simulation model in craniofacial 3D structure model of maxillary protraction device was establish based on the reaction principle, and different forces from 3 N to 6 N with a 37° angle from the occlusal plane was loaded at the bottom of the lower jaw in order to measure and analyze changes of stress and displacement in TMJ and jaw with the finite element analysis software ANSYS10.0. RESULTS: At the same angle , the stress in articular fossa and the head and neck of condyle increased with the applied force. Maximum stress was located where the stress was loaded on the mandible and the rigid fixation of maxilla. Meanwhile, this model appeared slight variation of displacement which increased with loading force. The maxillary displacement from basis cranii and occlusal plane to the parietal decreased gradually. Moreover, the mandibular displacement from the front to the rear was gradually reduced, and clockwise rotation was appeared. CONCLUSIONS: The results indicate that maxillary protraction appliance has reaction force on TMJ and jaw. With increasing of loading forces, reaction forces and deformation increase. At the same time, chin deformation may occur and the mandible has clockwise rotation.

Key words: 3-D FEM, TMJ, Protraction, Reaction force

CLC Number:

R783.5

LIU Wan-xin, WANG Xu-xia, ZHANG Wen-juan, DONG Rui, CHEN Yun, ZHANG Jun,. A three-dimensional finite element study on the reaction of different force values generated from maxillary protraction appliance[J]. Shanghai Journal of Stomatology, 2013, 22(5): 498-503.

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A three-dimensional finite element study on the reaction of different force values generated from maxillary protraction appliance

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