Torque movement of the upper anterior teeth using a clear aligner in cases of extraction: a finite element study

Cheng, Yuxun; Gao, Jie; Fang, Shishu; Wang, Wei; Ma, Yanning; Jin, Zuolin

doi:10.1186/s40510-022-00421-8

Cited by 29 publications

(34 citation statements)

References 23 publications

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“…From the perspectives of biomechanics, Hahn et al considered that controlling the torque of an upper central incisor requires the creation of effective couples: a tipping force was required, evoked by reversible deformation of the appliance near the gingival margin and the resulting force in the opposite direction produced by movement of the tooth against the inner opposite surface of the appliance near the incisor edge [ 33 ]. However, the force couple generated at the cervical and incisal regions of the aligners is not large enough to generate an adequate counter moment due to limitations imposed by material properties [ 17 , 34 ]. This situation could eventually be improved by selective modifications to aligners by means of mechanical reinforcement of the cervical area [ 34 ], such as the power ridge of the Invisalign system.…”

Section: Discussionmentioning

confidence: 99%

“…In essence, the presence of a power ridge in the tooth neck produced a counter moment because it generated an angle between the inner face of the aligner and the tooth surface; this led to further deformation of the aligner. From mechanical knowledge, this angle was determined by the height of the power ridge and reflected the magnitude of torque control [ 17 ]. This indicated that the 0.75 mm-thick aligner generated less torque loss and required less torque compensation, that is, the thicker aligner magnified the effect of the selective modification.…”

Section: Discussionmentioning

confidence: 99%

“…Clear aligner and composite attachments: We assumed a linear elastic isotropic and homogeneous behavior. Mechanical properties were inferred from previous studies [ 15 – 17 , 24 , 25 ].…”

Section: Methodsmentioning

confidence: 99%

“…In another study, Liu constructed a FEM for maxillary dentition and demonstrated that appropriate overtreatment, by placing attachments on the canines, should be designed to ensure the bodily retraction of anterior teeth in cases of extraction [ 16 ]. Our previous work showed that the required torque control for upper anterior teeth with oversize axial inclination was weaker than that for upper anterior teeth with normal axial inclination [ 17 ]. Although many studies have analyzed the biomechanics of aligner-attachments and torque control of anterior teeth, the thickness of aligner has not been investigated in full detail, even though this factor is closely associated with other important features such as the forces and moments they generate and the displacement tendency of teeth [ 18 , 19 ].…”

Section: Introductionmentioning

confidence: 99%

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The three-dimensional displacement tendency of teeth depending on incisor torque compensation with clear aligners of different thicknesses in cases of extraction: a finite element study

et al. 2022

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Background Despite the popularity of clear aligner treatment, the effect of the thickness of these aligners has not been fully investigated. The objective of this study was to assess the effects of incisor torque compensation with different thicknesses of clear aligner on the three-dimensional displacement tendency of teeth in cases of extraction. Methods Three-dimensional finite element models of the maxillary dentition with extracted first premolars, maxilla, periodontal ligaments, attachments, and aligners were constructed and subject to Finite Element Analysis (FEA). Two groups of models were created: (1) with 0.75 mm-thick aligners and (2) with 0.5 mm-thick aligners. A loading method was developed to simulate the action of clear aligners for the en masse retraction of the incisors. Power ridges of different heights were applied to both groups to mimic torque control, and the power ridges favoring the translation of the central incisors were selected. Then, we used ANSYS software to analyze the initial displacement of teeth and the principle stress on the PDL. Results Distal tipping, lingual tipping and extrusion of the incisors, distal tipping and extrusion of the canines, and mesial tipping and intrusion of the posterior teeth were all generated by clear aligner therapy. With the 0.5 mm-thick aligner, a power ridge of 0.7 mm could cause bodily retraction of the central incisors. With the 0.75 mm-thick aligner, a power ridge of 0.25 mm could cause translation of the central incisors. Aligner torque compensation created by the power ridges generated palatal root torque and intrusion of the incisors, intrusion of the canines, mesial tipping and the intrusion of the second premolar; these effects were more significant with a 0.75 mm-thick aligner. After torque compensation, the stress placed on the periodontal ligament of the incisors was distributed more evenly with the 0.75 mm-thick aligner. Conclusions The torque compensation caused by power ridges can achieve incisor intrusion and palatal root torque. Appropriate torque compensation with thicker aligners should be designed to ensure bodily retraction of anterior teeth and minimize root resorption, although more attention should be paid to the anchorage control of posterior teeth in cases of extraction.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

“…Clear aligner and composite attachments: We assumed a linear elastic isotropic and homogeneous behavior. Mechanical properties were inferred from previous studies [ 15 – 17 , 24 , 25 ].…”

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The three-dimensional displacement tendency of teeth depending on incisor torque compensation with clear aligners of different thicknesses in cases of extraction: a finite element study

et al. 2022

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“…we employed SOLID187, a 3D 10-node tetrahedral structural solid. The material properties were extracted from previous research works [ 14 , 16 – 18 ] (Table 1 ). A linear viscoelastic model was employed for biomechanical modelling of the disc, which was implemented using a generalized Maxwell model via an optimized Prony series [ 15 ].…”

Section: Methodsmentioning

confidence: 99%

Effects of upper-molar distalization using clear aligners in combination with Class II elastics: a three-dimensional finite element analysis

et al. 2022

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Introduction The effects of upper-molar distalization using clear aligners in combination with Class II elastics for anchorage reinforcement have not been fully investigated yet. The objective of this study is to analyze the movement and stress of the whole dentition and further explore guidelines for the selection of traction methods. Methods Three-dimensional (3D) finite element models are established to simulate the sequential molar distalization process, including the initial distalization of the 2nd molar (Set I) and the initial distalization of the 1st molar (Set II). Each group set features three models: a control model without Class II elastics (model A), Class II elastics attached to the tooth by buttons (model B), and Class II elastics attached to the aligner by precision cutting (model C). The 3D displacements, proclination angles, periodontal ligament (PDL) hydrostatic stress and alveolar bone von Mises stress in the anterior area are recorded. Results In all of the models, the maxillary anterior teeth are labial and mesial proclined, whereas the distal moving molars exhibit distal buccal inclination with an extrusion tendency. With the combination of Class II elastics, the anchorage was effectively reinforced; model C demonstrates superior anchorage reinforcement with lower stress distribution in comparison with model B. The upper canines in model B present an extrusion tendency. Meanwhile, the mandibular dentition in models B and C experience undesired movement tendencies with little discrepancy from each other. Conclusions Class II elastics are generally effective for anchorage reinforcement as the upper-molar distalization is performed with clear aligners. Class II elastics attached to an aligner by precision cutting is a superior alternative for maxillary anchorage control in cases that the proclination of upper incisors and extrusion of upper canines are unwanted.

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Actual contribution ratio of maxillary and mandibular molars for total molar relationship correction during maxillary molar sequential distalization using clear aligners with Class II elastics: A finite element analysis

Liu,

Wang,

Gao

et al. 2023

American Journal of Orthodontics and Dentofacial Orthopedics

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Torque movement of the upper anterior teeth using a clear aligner in cases of extraction: a finite element study

Cited by 29 publications

References 23 publications

The three-dimensional displacement tendency of teeth depending on incisor torque compensation with clear aligners of different thicknesses in cases of extraction: a finite element study

The three-dimensional displacement tendency of teeth depending on incisor torque compensation with clear aligners of different thicknesses in cases of extraction: a finite element study

Effects of upper-molar distalization using clear aligners in combination with Class II elastics: a three-dimensional finite element analysis

Actual contribution ratio of maxillary and mandibular molars for total molar relationship correction during maxillary molar sequential distalization using clear aligners with Class II elastics: A finite element analysis

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