Extruded upper first molar intrusion: Comparison between unilateral and bilateral miniscrew anchorage

Sugii, Mari Miura; Barreto, Bruno de Castro Ferreira; Francisco Vieira-Júnior, Waldemir; Simone, Katia Regina Izola; Bacchi, Ataís; Caldas, Ricardo Armini

doi:10.1590/2177-6709.23.1.063-070.oar

ABSTRACT

Objective:

The aim of his study was to evaluate the stress on tooth and alveolar bone caused by orthodontic intrusion forces in a supraerupted upper molar, by using a three-dimensional Finite Element Method (FEM).

Methods:

A superior maxillary segment was modeled in the software SolidWorks 2010 (SolidWorks Corporation, Waltham, MA, USA) containing: cortical and cancellous bone, supraerupted first molar, periodontal tissue and orthodontic components. A finite element model has simulated intrusion forces of 4N onto a tooth, directed to different mini-screw locations. Three different intrusion mechanics vectors were simulated: anchoring on a buccal mini-implant; anchoring on a palatal mini-implant and the association of both anchorage systems. All analyses were performed considering the minimum principal stress and total deformation. Qualitative analyses exhibited stress distribution by color maps. Quantitative analysis was performed with a specific software for reading and solving numerical equations (ANSYS Workbench 14, Ansys, Canonsburg, Pennsylvania, USA).

Results:

Intrusion forces applied from both sides (buccal and palatal) resulted in a more homogeneous stress distribution; no high peak of stress was detected and it has allowed a vertical resultant movement. Buccal or palatal single-sided forces resulted in concentrated stress zones with higher values and tooth tipping to respective force side.

Conclusion:

Unilateral forces promoted higher stress in root apex and higher dental tipping. The bilateral forces promoted better distribution without evidence of dental tipping. Bilateral intrusion technique suggested lower probability of root apex resorption.

Keywords:
Finite element analysis; Anchorage technique; Orthodontic

RESUMO

Objetivos:

o presente estudo teve como objetivo avaliar, por meio da Análise de Elementos Finitos, as tensões geradas por forças ortodônticas intrusivas em um molar superior e no osso alveolar circundante.

Métodos:

um segmento maxilar foi modelado no software SolidWorks 2010 (SolidWorks Corporation, Waltham, MA, EUA), contendo: osso cortical e medular, primeiro molar extruído, tecido periodontal e acessórios ortodônticos. Um modelo de elementos finitos simulou forças intrusivas de 4 N no elemento dentário, aplicadas a partir de mini-implantes em localizações distintas. Três diferentes vetores para mecânica de intrusão foram simulados: ancoragem em mini-implante vestibular, ancoragem em mini-implante palatino ou a associação de ambas. Todas as análises foram realizadas em termos de tensão mínima principal e deformação total. A análise qualitativa foi feita por meio do mapeamento da distribuição das tensões em gradiente de cores. A análise quantitativa foi feita em software específico para leitura e resolução de equações numéricas (ANSYS Workbench 14, Ansys, Canonsburg, Pennsylvania, EUA).

Resultados:

as forças intrusivas aplicadas simultaneamente nos dois lados (vestibular e palatino) resultaram em uma distribuição mais homogênea das tensões geradas, sem zonas de acúmulo de tensão e com uma resultante vertical para a movimentação intrusiva. As forças aplicadas somente em um lado, vestibular ou palatino, resultaram em zonas de concentração de tensão, com maiores valores, e na inclinação do elemento dentário para o lado em que a força foi aplicada.

Conclusão:

as forças unilaterais promoveram maior tensão no ápice radicular e maiores inclinações do elemento dentário. Já as forças bilaterais promoveram melhor distribuição das tensões e não resultaram em inclinação do elemento dentário. Assim, as forças intrusivas ancoradas bilateralmente apresentam menor probabilidade de reabsorção do ápice radicular.

Palavras-chave:
Ortodontia; Movimentação dentária; Intrusão dentária

INTRODUCTION

Oral rehabilitation is a complex topic that frequently involves various specialists. This process may be hindered by the presence of malocclusions. Among malocclusions, dental supraeruption is one of the most complex conditions to be reversed.¹1 Heravi F, Bayani S, Madani AS, Radvar M, Anbiaee N. Intrusion of supra-erupted molars using miniscrews: clinical success and root resorption. Am J Orthod Dentofacial Orthop. 2011 Apr;139(4 Suppl):S170-5.

Supraeruption is derived from the lacking of antagonistic teeth and the absence of occlusal contact.¹1 Heravi F, Bayani S, Madani AS, Radvar M, Anbiaee N. Intrusion of supra-erupted molars using miniscrews: clinical success and root resorption. Am J Orthod Dentofacial Orthop. 2011 Apr;139(4 Suppl):S170-5. Some different techniques have been described in the literature such as loops,²2 Küçükkeles N, Acar A, Demirkaya AA, Evrenol B, Enacar A. Cephalometric evaluation of open bite treatment with NiTi arch wires and anterior elastics. Am J Orthod Dentofacial Orthop. 1999 Nov;116(5):555-62. transpalatal arch, extraoral devices³3 Kumar ND, Krishna BRG, Shamnur N, Mithun K. Modified transpalatal arch for molar intrusion. J Int Oral Health. 2012 Nov-Dec;6(6):88-9. and lately, the use of mini-screws.¹1 Heravi F, Bayani S, Madani AS, Radvar M, Anbiaee N. Intrusion of supra-erupted molars using miniscrews: clinical success and root resorption. Am J Orthod Dentofacial Orthop. 2011 Apr;139(4 Suppl):S170-5. Another possibility to remove the occlusal interference is total crown preparation; however, when there is a substantial amount of tooth structure to be worn, previous endodontic treatment is necessary.¹1 Heravi F, Bayani S, Madani AS, Radvar M, Anbiaee N. Intrusion of supra-erupted molars using miniscrews: clinical success and root resorption. Am J Orthod Dentofacial Orthop. 2011 Apr;139(4 Suppl):S170-5.^,⁴4 Park YC, Lee SY, Kim DH, Jee SH. Intrusion of posterior teeth using mini-screw implants. Am J Orthod Dentofacial Orthop. 2003 June;123(6):690-4.

The less invasive approach to restore occlusal plane is the orthodontic intrusion. In order to achieve better results with the intrusive forces, with low-risk of root resorption, steady anchorage associated with intermittent and light forces are required.⁵5 Phillips JR. Apical root resorption under orthodontic therapy. Angle Orthod. 1955 Jan;25:1-22.

6 DeShields RW. A study of root resorption in treated Class II, Division I malocclusions. Angle Orthod. 1969 Oct;39(4):231-45.

7 Goldin B. Labial root torque: effect on the maxilla and incisor root apex. Am J Orthod Dentofacial Orthop. 1989 Mar;95(3):208-19.^-⁸8 Wickwire NA, Mc Neil MH, Norton LA, Duell RC. The effects of tooth movement upon endodontically treated teeth. Angle Orthod. 1974 July;44(3):235-42. Yet, it is important to consider some aspects such as: amount of alveolar bone surrounding the supraerupted tooth; conditions of adjacent teeth; periodontal health; and the required amount of intrusion, reported as determinant for choosing the intrusion method.⁴4 Park YC, Lee SY, Kim DH, Jee SH. Intrusion of posterior teeth using mini-screw implants. Am J Orthod Dentofacial Orthop. 2003 June;123(6):690-4.

Root resorption is an irreversible side effect of orthodontic treatment.⁹9 Rudolph DJ, Willes PMG, Sameshima GT. A finite element model of apical force distribution from orthodontic tooth movement. Angle Orthod. 2001 Apr;71(2):127-31. Among the orthodontic movements tipping, torque, bodily movement into the lingual cortical plate of the maxilla,¹⁰10 Brezniak N, Wasserstein A. Root resorption after orthodontic treatment: Part 2. Literature review. Am J Orthod Dentofacial Orthop. 1993 Feb;103(2):138-46. palatal expansion and specially intrusion, display greater risk of root resorption.¹⁰10 Brezniak N, Wasserstein A. Root resorption after orthodontic treatment: Part 2. Literature review. Am J Orthod Dentofacial Orthop. 1993 Feb;103(2):138-46.

11 Carrillo R, Rossouw PE, Franco PF, Opperman LA, Buschang PH. Intrusion of multiradicular teeth and related root resorption with mini-screw implant anchorage: a radiographic evaluation. Am J Orthod Dentofacial Orthop. 2007 Nov;132(5):647-55.^-¹²12 Brezniak N, Wasserstein A. Orthodontically induced inflammatory root resorption. Part I: the basic science aspects. Angle Orthod. 2002 Apr;72(2):175-9. Maxillary teeth are the most affected by external root resorption⁵5 Phillips JR. Apical root resorption under orthodontic therapy. Angle Orthod. 1955 Jan;25:1-22.^,¹³13 Ketcham AH. A progress report of an investigation of apical root resorption of vital permanent teeth. Int J Orthod Oral Surg Radiogr. 1929 Apr;15(4):310-28.^,¹⁴14 Massler M, Malone AJ. Root resorption in human permanent teeth. Am J Orthod. 1954 Aug;40(8):619-33. and molars have the second highest incidence, after incisors.¹⁵15 Sharpe W, Reed B, Subtelny JD, Polson A. Orthodontic relapse, apical root resorption, and crestal alveolar bone levels. Am J Orthod Dentofacial Orthop. 1987 Mar;91(3):252-8. So, the intrusion of the posterior segment must be planned and performed with prudence.

Conventional intrusion techniques for posterior teeth usually rely on multiple tooth anchorage. Based on reciprocal force mechanics, dental anchorage may result in undesirable movements and extrusion of other teeth rather than the aspired intrusion.¹1 Heravi F, Bayani S, Madani AS, Radvar M, Anbiaee N. Intrusion of supra-erupted molars using miniscrews: clinical success and root resorption. Am J Orthod Dentofacial Orthop. 2011 Apr;139(4 Suppl):S170-5. Another approach for achieving intrusion is hight-pull headgear,¹⁶16 Kim YH. Anterior openbite and its treatment with multiloop edgewise archwire. Angle Orthod. 1987 Oct;57(4):290-321. which effectiveness is highly dependent on patient compliance.

Skeletal anchorage with mini-screws does not depend on multiple teeth involvement and have proven to be a minimally invasive and money-saving alternative.¹⁷17 Wilmes B, Drescher D. Impact of bone quality, implant type, and implantation site preparation on insertion torques of mini-implants used for orthodontic anchorage. Int J Oral Maxillofac Surg. 2011 July;40(7):697-703. Moreover, this type of anchorage avoid undesirable tooth movements and does not dependent on patient cooperation, allowing better control of the applied force.¹¹11 Carrillo R, Rossouw PE, Franco PF, Opperman LA, Buschang PH. Intrusion of multiradicular teeth and related root resorption with mini-screw implant anchorage: a radiographic evaluation. Am J Orthod Dentofacial Orthop. 2007 Nov;132(5):647-55. Mini-screws are inserted in bone structure, and can resist to orthodontic displacement forces, preserving a static anchorage with no signs of marginal bone loss.¹⁸18 Cornelis MA, Scheffler NR, De Clerck HJ, Tulloch JF, Behets CN. Systematic review of the experimental use of temporary skeletal anchorage devices in orthodontics. Am J Orthod Dentofacial Orthop. 2007 Apr;131(4 Suppl):S52-8.

In-vivo studies are not able to show the biomechanics inside the bone tissue, thus finite element analysis (FEA) has become a suitable method to investigate stresses under orthodontic forces.¹⁹19 Çifter M, Saraç M. Maxillary posterior intrusion mechanics with mini-implant anchorage evaluated with the finite element method. Am J Orthod Dentofacial Orthop. 2011 Nov;140(5):e233-41.

In orthodontics field, FEA has been successfully applied to assess stress distribution upon different amounts and directions of force.⁹9 Rudolph DJ, Willes PMG, Sameshima GT. A finite element model of apical force distribution from orthodontic tooth movement. Angle Orthod. 2001 Apr;71(2):127-31. Results from FEA have shown great agreement with in-vivo results, therefore it may be considered a relevant and noninvasive method to virtually investigate stresses distribution during orthodontic force application.²⁰20 Bourauel C, Freudenreich D, Vollmer D, Kobe D, Drescher D, Jäger A. Simulation of orthodontic tooth movements a comparison of numerical models. J Orofac Orthop. 1999;60(2):136-51.

Thus, the purpose of this study was to determine, by using finite element analysis, the stress distribution and displacement effects of three types of mini-screw anchorage for a first upper molar intrusion: buccal, palatal or buccal-palatal.

MATERIAL AND METHODS

Model construction

The model was designed based on a clinical situation of supraerupted maxillary first molar needing for orthodontic intrusion, with the help of design software SolidWorks 2010 (SolidWorks Corporation, Waltham, MA, USA).

Maxillary models were constructed on the basis of cone beam computer tomography cross-sectional images from a posterior edentulous human maxilla. The maxillary segment was built considering a difference between cortical and cancellous bone.

The geometric model of the tooth was constructed based on computed micro-tomography from an online database (Department of Oral Anatomy, School of Dentistry of Aichi-Gakuin University Available from: http://www.agu.ac.jp/english/index.html). The tooth model was created with distinction between enamel and dentin. Periodontal ligament was modeled considering a 0.3-mm thickness.²¹21 Toms SR, Dakin GJ, Lemons JE, Eberhardt AW. Quasi-linear viscoelastic behavior of the human periodontal ligament. J Biomech. 2002 Oct;35(10):1411-5.^,²²22 Andreaus U, Colloca M, Iacoviello D. Coupling image processing and stress analysis for damage identification in a human premolar tooth. Comput Methods Programs Biomed. 2011 Aug;103(2):61-73.

The Edgewise buccal tube and the orthodontic button (Morelli, Sorocaba, SP, Brazil) were modeled based on measurements with optical microscope at 40x magnification (VMM-100-BT; Walter UHL, Asslar, Germany) attached to a measurement device (QC 220-HH Quadra-Check 200; Metronics Inc., Bedford, USA). Full template is represented in Figure 1.

Figure 1
Complete template of the geometric model.

Finite element analysis

After the modeling phase, the assembly was imported into the software ANSYS Workbench v. 14 (Ansys, Canonsburg, Pennsylvania, USA), for processing. Mechanical properties were used as described in Table 1. All materials were considered linearly elastic, homogeneous and isotropic. Mesh discretization was defined with tetrahedral 10-node elements. Model stability was performed using element quality analysis and the mesh was refined in regions of interest using specific tools from the software. All contacts were settled to Bonded. Thinned regions of the maxilla were considered as fixed constraints (zero degrees of freedom).

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Table 1
Material properties.

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Table 2
Highest compressive stress values (MPa).

Orthodontic intrusion forces were applied using three different techniques: 1) from the orthodontic double tube region to the buccal mini-implant; 2) from the palatal button to the palatal mini-implant and 3) combination of both forces simultaneously. A 4N force¹1 Heravi F, Bayani S, Madani AS, Radvar M, Anbiaee N. Intrusion of supra-erupted molars using miniscrews: clinical success and root resorption. Am J Orthod Dentofacial Orthop. 2011 Apr;139(4 Suppl):S170-5. component (in total) was applied directed to the orthodontic mini screw site: unilateral directed to buccal mini-screw (4N) - located between first and second upper molar in buccal side; unilateral directed to palatal mini-screw (4N) - located between first and second pre molar in palatal side; and bilateral force, a combination of both directions (2N each) (Fig 2).

Figure 2
Orthodontic forces directed to mini-screw site: A) palatal force; B) buccal force.

RESULTS

Results were analyzed in minimum principal stress (dentin and bone) and total deformation (periodontal ligament). Minimum principal stress was used to obtain better compressive stress analysis (negative values), and total deformation was used to predict the resultant movement of the intrusive forces.

Figure 3 shows the minimum principal stress in alveolar bone. Bilateral forces presented good stress distribution between cortical and cancellous bone and lowest compressive values, equally distributed (similar values) for all three periapical regions. Buccal force generated a compressive region at buccal furcation and both buccal roots. Palatal force generated compressive region near mesial furcation and periapical region of palatal root.

Figure 3
Minimum principal stress at alveolar bone. Negative values means compressive region. Occlusal view of dental alveolus, tooth was hidden for better visualization.

The periodontal ligament (Fig 4) presented similar behavior as previous results,¹⁹19 Çifter M, Saraç M. Maxillary posterior intrusion mechanics with mini-implant anchorage evaluated with the finite element method. Am J Orthod Dentofacial Orthop. 2011 Nov;140(5):e233-41.^,³⁰30 Jeon PD, Turley PK, Moon HB, Ting K. Analysis of stress in the periodontium of the maxillary first molar with a three-dimensional finite element model. Am J Orthod Dentofacial Orthop. 1999 Mar;115(3):267-74. with well distributed compressive stresses when bilateral forces were used. Single-sided forces presented highest compressive values, especially near cancellous bone and periapical region of the same side force was applied. Higher values were found in dentin (Fig 5) near cortical bone at the same side of force application, without high compressive values in periapical region.

Figure 4
Minimum principal stress at periodontal ligament. Negative values represent compressive regions.

Figure 5
Minimum principal stress at dentin. Negative values represent compressive regions.

Figure 6 show that bilateral forces resulted in predominance of vertical vectors (intrusive resultants), single forces presented oblique vectors, with vertical resultants and lateral resultants. Also, higher values of deformation were found for unilateral forces, compared to bilateral force.

Figure 6
Tooth movement: arrows indicate movement direction and magnitude.

DISCUSSION

Dental intrusion is considered one of the most challenging movements in orthodontics. Posterior teeth intrusion is even more complex due to its roots anatomy and lack of anchorage. In order to prevent undesirable movements and root resorption, the degree and direction of force must be controlled.²³23 Kravitz ND, Kusnoto B, Tsay TP, Hohlt WF. The use of temporary anchorage devices for molar intrusion. J Am Dent Assoc. 2007 Jan;138(1):56-64.

The present study evaluated by finite element analysis the stress distribution in a maxillary first molar and alveolar bone after simulation of an intrusion force. Forces magnitudes were chosen accordingly to a systematic literature review about skeletal anchorage.¹⁸18 Cornelis MA, Scheffler NR, De Clerck HJ, Tulloch JF, Behets CN. Systematic review of the experimental use of temporary skeletal anchorage devices in orthodontics. Am J Orthod Dentofacial Orthop. 2007 Apr;131(4 Suppl):S52-8.

Minimum principal stresses increased on the alveolar bone, periodontal ligament and dentin, near dentin-enamel junction (DEJ), on the side in which the intrusive force was applied (Figs 3, 4 and 5). This observation suggests a possible dental inclination directed to the side to which the force was applied, as presented in dislodgement analysis (Fig 6). Furthermore, it can be inferred that intruding molars can enhance risk of gingival retraction near DEJ, since bone is prone to reabsorb during constant compressive forces at adjacent periodontal tissue. Çifter and Saraç¹⁹19 Çifter M, Saraç M. Maxillary posterior intrusion mechanics with mini-implant anchorage evaluated with the finite element method. Am J Orthod Dentofacial Orthop. 2011 Nov;140(5):e233-41. found buccal tipping in molars when an intrusive force was applied; also, an uniform stress distribution when forces were applied from buccal and palatal sites concomitantly, these results are in agreement with the present findings.

Palatal intrusive force caused higher compressive stresses near mesial furcation of palatal root and around root apex on alveolar bone, near DEJ of periodontal ligament and on cervical dentin. Compressive stresses originated from tipping movement, as in unilateral palatal force, are known to cause more severe root resorption than bodily movements.²⁴24 Ajmera S, Shivanand Venkatesh, Ganeshkar SV. Volumetric evaluation of root resorption during orthodontic treatment. J Clin Orthod. 2014 Feb;48(2):113-9. This is due to the distribution of stresses per area unit, which is more concentrated in smaller apex area than in cervical region. It is also important to emphasize that the more tipping vectors are present on intrusion mechanics, the less periodontal ligament can soften stresses.²⁵25 Consolaro A. Force distribution is more important than its intensity! Dental Press J Orthod. 2014 Jan-Feb;19(1):5-7.

Single buccal force has caused higher compressive stresses on vestibular furcation and on alveolar bone around vestibular roots apex, on cervical region of periodontal ligament and on the cervical third of the roots dentin. When considering forces applied to buccal side, their resulting stresses are distributed in two roots instead of only one, as in the case of the palatal root. Also, is already known that unilateral forces promote tipping movement and stress concentration around buccal cervical regions.²⁶26 Chan E, Darendeliler MA. Physical properties of root cementum: Part 7. Extent of root resorption under areas of compression and tension. Am J Orthod Dentofacial Orthop. 2006 Apr;129(4):504-10. However, this is not a major concern considering the larger area and the slight deflection of the bone crest.²⁵25 Consolaro A. Force distribution is more important than its intensity! Dental Press J Orthod. 2014 Jan-Feb;19(1):5-7.

In addition, bilateral forces showed better stress distribution in alveolar bone and the roots. This type of movement makes the force perpendicular to dental alveolus, resulting in stresses efficiently softened and distributed along periodontal ligament. Also promoted a more efficient intrusion movement, with higher vertical resultant vector than the other techniques.

Resorption as a side effect of orthodontic intrusion has been reported for years. Some studies showed that intruding incisors lead to stress accumulation at root apex.²⁷27 Beck BW, Harris EF. Apical root resorption in orthodontically treated subjects: analysis of edgewise and light wire mechanics. Am J Orthod Dentofacial Orthop. 1994 Apr;105(4):350-61.^,²⁸28 Costopoulos G, Nanda R. An evaluation of root resorption incident to orthodontic intrusion. Am J Orthod Dentofacial Orthop. 1996 May;109(5):543-8. There are different degrees of severity: 1) Resorption of outer cemental layers, which can be fully regenerated; 2) Besides the outer cemental layers there is dentin resorption, usually repaired with cementum material; and 3) circunferencial apical root resorption, on this stage root shortening is evident.¹²12 Brezniak N, Wasserstein A. Orthodontically induced inflammatory root resorption. Part I: the basic science aspects. Angle Orthod. 2002 Apr;72(2):175-9.

When intrusion forces are applied, the periodontal ligament is damaged, creating a sterile necrotic tissue (hyalinization tissue) and consequently causing macrophage-like cell activation and also differentiation of osteoclasts not fully expressed, into fully developed ones. The sterile necrotic tissue is then slowly removed by these cells, starting at the region of blood supply to the periodontal ligament. As the root surface is very close to this area, the outer layers of cementoblasts and cementoids can be damaged too. Resorption process goes until the necrotic tissue is no longer present, creating bone lacunae and decreasing the pressure exerted through force application.¹²12 Brezniak N, Wasserstein A. Orthodontically induced inflammatory root resorption. Part I: the basic science aspects. Angle Orthod. 2002 Apr;72(2):175-9.^,²⁵25 Consolaro A. Force distribution is more important than its intensity! Dental Press J Orthod. 2014 Jan-Feb;19(1):5-7.^,²⁹29 von Böhl M, Kuijpers-Jagtman AM. Hyalinization during orthodontic tooth movement: a systematic review on tissue reactions. Eur J Orthod. 2009 Feb;31(1):30-6. Therefore, the heavier applied force, the longer the resorption process takes place, enabling more root damage. Techniques which lead to a lower stress induction in periodontal ligament associated to tooth correct movement is desirable, possibly promoting a lower dentin resorption.

Despite this fact, this FEA study revealed stress accumulation in tooth furcation rather than in root apex, suggesting that molars are less likely to apical root resorption when compared to single-rooted teeth during intrusion forces. Jeon et al,³⁰30 Jeon PD, Turley PK, Moon HB, Ting K. Analysis of stress in the periodontium of the maxillary first molar with a three-dimensional finite element model. Am J Orthod Dentofacial Orthop. 1999 Mar;115(3):267-74. also using FEA have found that molar intrusion displayed stress zone at furcation and along root length. According to these authors, the rationale consists on the different number of roots and consequently on the difference in total root area between single and multi-radicular teeth. Stresses are better spread along three roots rather than in only one.

As in any other hypothetic simulation, there are some limitations inherent to Finite Element Analysis. There are individual variations, especially because of differences in teeth anatomy and dimensions, between patients. Also, stress distribution and interaction between hard and soft tissue are complex.⁹9 Rudolph DJ, Willes PMG, Sameshima GT. A finite element model of apical force distribution from orthodontic tooth movement. Angle Orthod. 2001 Apr;71(2):127-31. Therefore, creation of an exact mathematic model for each individual case is unlikely.¹⁹19 Çifter M, Saraç M. Maxillary posterior intrusion mechanics with mini-implant anchorage evaluated with the finite element method. Am J Orthod Dentofacial Orthop. 2011 Nov;140(5):e233-41. Still, even with these disadvantages, this study showed great convergence with other FEA investigations, in vitro research and clinical findings cited on the literature.

CONCLUSION

This FEA simulation could provide the following conclusions: Unilateral force unleashed higher stress in root apex and higher evidence for dental tipping directed to mini-implant site; the bilateral force promoted a more homogeneous stress distribution without evidence of dental tipping. Bilateral intrusion technique suggested a vertical movement of intrusion and lower probability of root apex resorption.

REFERENCES

¹
Heravi F, Bayani S, Madani AS, Radvar M, Anbiaee N. Intrusion of supra-erupted molars using miniscrews: clinical success and root resorption. Am J Orthod Dentofacial Orthop. 2011 Apr;139(4 Suppl):S170-5.
²
Küçükkeles N, Acar A, Demirkaya AA, Evrenol B, Enacar A. Cephalometric evaluation of open bite treatment with NiTi arch wires and anterior elastics. Am J Orthod Dentofacial Orthop. 1999 Nov;116(5):555-62.
³
Kumar ND, Krishna BRG, Shamnur N, Mithun K. Modified transpalatal arch for molar intrusion. J Int Oral Health. 2012 Nov-Dec;6(6):88-9.
⁴
Park YC, Lee SY, Kim DH, Jee SH. Intrusion of posterior teeth using mini-screw implants. Am J Orthod Dentofacial Orthop. 2003 June;123(6):690-4.
⁵
Phillips JR. Apical root resorption under orthodontic therapy. Angle Orthod. 1955 Jan;25:1-22.
⁶
DeShields RW. A study of root resorption in treated Class II, Division I malocclusions. Angle Orthod. 1969 Oct;39(4):231-45.
⁷
Goldin B. Labial root torque: effect on the maxilla and incisor root apex. Am J Orthod Dentofacial Orthop. 1989 Mar;95(3):208-19.
⁸
Wickwire NA, Mc Neil MH, Norton LA, Duell RC. The effects of tooth movement upon endodontically treated teeth. Angle Orthod. 1974 July;44(3):235-42.
⁹
Rudolph DJ, Willes PMG, Sameshima GT. A finite element model of apical force distribution from orthodontic tooth movement. Angle Orthod. 2001 Apr;71(2):127-31.
¹⁰
Brezniak N, Wasserstein A. Root resorption after orthodontic treatment: Part 2. Literature review. Am J Orthod Dentofacial Orthop. 1993 Feb;103(2):138-46.
¹¹
Carrillo R, Rossouw PE, Franco PF, Opperman LA, Buschang PH. Intrusion of multiradicular teeth and related root resorption with mini-screw implant anchorage: a radiographic evaluation. Am J Orthod Dentofacial Orthop. 2007 Nov;132(5):647-55.
¹²
Brezniak N, Wasserstein A. Orthodontically induced inflammatory root resorption. Part I: the basic science aspects. Angle Orthod. 2002 Apr;72(2):175-9.
¹³
Ketcham AH. A progress report of an investigation of apical root resorption of vital permanent teeth. Int J Orthod Oral Surg Radiogr. 1929 Apr;15(4):310-28.
¹⁴
Massler M, Malone AJ. Root resorption in human permanent teeth. Am J Orthod. 1954 Aug;40(8):619-33.
¹⁵
Sharpe W, Reed B, Subtelny JD, Polson A. Orthodontic relapse, apical root resorption, and crestal alveolar bone levels. Am J Orthod Dentofacial Orthop. 1987 Mar;91(3):252-8.
¹⁶
Kim YH. Anterior openbite and its treatment with multiloop edgewise archwire. Angle Orthod. 1987 Oct;57(4):290-321.
¹⁷
Wilmes B, Drescher D. Impact of bone quality, implant type, and implantation site preparation on insertion torques of mini-implants used for orthodontic anchorage. Int J Oral Maxillofac Surg. 2011 July;40(7):697-703.
¹⁸
Cornelis MA, Scheffler NR, De Clerck HJ, Tulloch JF, Behets CN. Systematic review of the experimental use of temporary skeletal anchorage devices in orthodontics. Am J Orthod Dentofacial Orthop. 2007 Apr;131(4 Suppl):S52-8.
¹⁹
Çifter M, Saraç M. Maxillary posterior intrusion mechanics with mini-implant anchorage evaluated with the finite element method. Am J Orthod Dentofacial Orthop. 2011 Nov;140(5):e233-41.
²⁰
Bourauel C, Freudenreich D, Vollmer D, Kobe D, Drescher D, Jäger A. Simulation of orthodontic tooth movements a comparison of numerical models. J Orofac Orthop. 1999;60(2):136-51.
²¹
Toms SR, Dakin GJ, Lemons JE, Eberhardt AW. Quasi-linear viscoelastic behavior of the human periodontal ligament. J Biomech. 2002 Oct;35(10):1411-5.
²²
Andreaus U, Colloca M, Iacoviello D. Coupling image processing and stress analysis for damage identification in a human premolar tooth. Comput Methods Programs Biomed. 2011 Aug;103(2):61-73.
²³
Kravitz ND, Kusnoto B, Tsay TP, Hohlt WF. The use of temporary anchorage devices for molar intrusion. J Am Dent Assoc. 2007 Jan;138(1):56-64.
²⁴
Ajmera S, Shivanand Venkatesh, Ganeshkar SV. Volumetric evaluation of root resorption during orthodontic treatment. J Clin Orthod. 2014 Feb;48(2):113-9.
²⁵
Consolaro A. Force distribution is more important than its intensity! Dental Press J Orthod. 2014 Jan-Feb;19(1):5-7.
²⁶
Chan E, Darendeliler MA. Physical properties of root cementum: Part 7. Extent of root resorption under areas of compression and tension. Am J Orthod Dentofacial Orthop. 2006 Apr;129(4):504-10.
²⁷
Beck BW, Harris EF. Apical root resorption in orthodontically treated subjects: analysis of edgewise and light wire mechanics. Am J Orthod Dentofacial Orthop. 1994 Apr;105(4):350-61.
²⁸
Costopoulos G, Nanda R. An evaluation of root resorption incident to orthodontic intrusion. Am J Orthod Dentofacial Orthop. 1996 May;109(5):543-8.
²⁹
von Böhl M, Kuijpers-Jagtman AM. Hyalinization during orthodontic tooth movement: a systematic review on tissue reactions. Eur J Orthod. 2009 Feb;31(1):30-6.
³⁰
Jeon PD, Turley PK, Moon HB, Ting K. Analysis of stress in the periodontium of the maxillary first molar with a three-dimensional finite element model. Am J Orthod Dentofacial Orthop. 1999 Mar;115(3):267-74.

»
The authors report no commercial, proprietary or financial interest in the products or companies described in this article.

Publication Dates

Publication in this collection
Jan 2018

History

Received
23 Mar 2017
Accepted
01 Oct 2017

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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Material	Young’s modulus (Gpa)	Poisson’s ratio
Cortical bone	13.7	0.30
Cancellous bone	1.37	0.26
Periodontal tissue	0.05	0.49
Enamel	80	0.25
Dentin	24.4	0.43
Orthodontic components (stainless steel)	193	0.30
Composite resin	22	0.27

	Force
	Buccal and Palatal	Buccal	Palatal
Alveolar bone	0.105	0.374	0.24
Periodontal tissue	0.043	0.16	0.121
Dentin	0.401	0.657	1.07

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