Abstract

Microimplants are widely used to provide absolute anchorage in cases with bimaxillary dentoalveolar protrusion especially in those that require simultaneous retraction and intrusion of anterior teeth. The position of the microimplant significantly affects the build up of stress in the alveolar bone as well as the incisor inclinations, and is therefore a critical factor in treatment plannning. Keeping this in mind, this finite element method(FEM) study was taken up to identify the most suitable combination of implant placement sites for cases in which en-masse anterior retraction is done along with intrusion. The geometric model was constructed from a CBCT scan of the maxilla of an adult patient with full permanent dentition.The images were saved as DICOM files and were later exported to the 3D image processing software (Mimics,version 17). The center of resistance for the 6 anterior teeth was 9 mm superiorly and 13.5 mm posteriorly from the midpoint of crown tip of central incisors. The working archwires were assumed to be 0.019 / 0.025-in stainless steel. The three mini-implant placement sites compared were – S1- Midline micro implant between the maxillary central incisors with two placed posteriorly between maxillary 2nd premolar 1st molar roots. S2 – Micro implant placed between the lateral incisor and canine along with posterior mini implants as above. S3- Micro implant placed high up between the maxillary second premolar and first molar roots. The amount of tooth displacement after finite element analysis was compared with central and lateral incisor and canine axis graphs. For the system S1, intrusive components were seen on the archwire mainly in the anterior region with maximum displacement between central incisors and gradually decreasing away from point of force application. In S2, the intrusive component of force was more evenly distributed. In S3, pattern of intrusive component was similar to S2 but the maximum displacement was slightly lower. Greatest value of minimal principal stress was seen on cervical and apical third of central incisors as well as apical third of lateral incisors in S1; and cervical third of lateral incisors and apical and cervical third of canines in S2. Maximum retraction of anterior teeth was seen in S3. In all of the three systems of force application, tooth inclinations were maintained. Maxillary anterior teeth showed more tendency towards retraction in the case where two micro implants were placed posteriorly high up above the roots of maxillary premolars and molars such that the force is directed diagonally having both horizontal and vertical components, and hence eliminating the need for anterior implants. Greater intrusion tendency was seen when implants were placed between the roots of maxillary central incisors.

Highlights

  • Microimplants are widely used to provide absolute anchorage in cases with bimaxillary dentoalveolar protrusion especially in those that require simultaneous retraction and intrusion of anterior teeth

  • S2 – Micro implant placed between the lateral incisor and canine along with posterior mini implants as above

  • It is characterized by proclination of maxillary and mandibular anterior teeth with resultant projection of the lips as well as convexity of the profile.It is conventionally treated by therapeutic extraction of the first premolars,trailed by complete anterior tooth retraction to acquire the desired dental and soft tissue profile changes[1].Anchorage requirement is critical in such cases and a successful treatment outcome is often dependent on effective anchorage control strategies.[2]

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Summary

Materials and Methods

It was a 3D finite element analysis study for which prior ethical clearance was obtained from the Institutional Ethics committee, Manipal College of Dental Sciences,Mangalore. In order to make the connected nodes between the brackets and archwires deform together, translational degrees of freedom of the arch wire in the two flexural directions were coupled; and in the axial direction of the arch wire, translational degrees of freedom remained unconstrained This allowed free axial rotation movement of the arch wire, while the friction between the arch wire and brackets along the axial direction was ignored[4].To simulate the constraints of the model, the boundary conditions of alveolar bone was defined to prevent it from free bodily motion. Results along the alveolar bone of maxillary incisors on application of intrusive and retraction forces using micro implants, using ANSYS workbench. In the second scenario S2 with the micro implant placed between the lateral incisor and canine, the intrusive force was more evenly distributed(Figure 7).In the third scenario S3,pattern of intrusive component of force in the archwire was similar to S2, but the maximum displacement was lesser than in S2(Figure 8)

Discussion
Conclusion
Conclusions drawn from this study are
23. Orthodontic treatment of Class II malocclusion

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