CC BY-NC-ND 4.0 · Eur J Dent 2020; 14(01): 107-114
DOI: 10.1055/s-0040-1702254
Original Article

A Comparative Three-Dimensional Finite Element Study of Two Space Regainers in the Mixed Dentition Stage

Mohamed Ahmed Abdel Hakim
1   Ministry of Health and Population, El Minia, Egypt
,
Nagwa Mohamed Ali Khatab
2   Department of Paediatric and Community Dentistry, Faculty of Dentistry, Minia University, Minya, El Minia, Egypt
,
Kareem Maher Gaber Mohamed
3   Department of Orthodontic, Faculty of Dentistry, Minia University, Minya, El Minia, Egypt
,
Ahmad Abdel Hamid Elheeny
2   Department of Paediatric and Community Dentistry, Faculty of Dentistry, Minia University, Minya, El Minia, Egypt
› Author Affiliations
Funding None.

Abstract

Objectives This study aims to compare the stress distribution and displacement that resulted from the use of a Gerber space regainer and sagittal distalizer using three-dimensional finite element analysis.

Materials and Methods Three-dimensional simulated models of the appliances were developed using a software. The forces applied by the two appliances were 3N (tipping) and 15N (bodily), respectively. Displacement and von Mises stress on the compact and cancellous bone, periodontal ligament (PDL), crowns of the mandibular first, second permanent molars, and deciduous canines were calculated. Stress distribution and displacement values were measured via linear static analysis.

Results Gerber space regainer showed greater displacement than that produced by the sagittal distalizer at the first permanent molar. However, such displacement was less at the other tested points when compared with that delivered by sagittal distalizer. The stresses created by Gerber appliance were higher in the crown and PDL of the deciduous canine than the crown of the first permanent molar crown.

Conclusions Gerber appliance generates more distal force and less stress concentration on the crown of the mandibular first permanent molar than that created by the sagittal distalizer. On the other hand, stress concentrations produced by Gerber space regainer are found to be more on the crown and PDL of the deciduous canine. Therefore, it can be concluded that the use of Gerber appliance needs more anchorage.



Publication History

Article published online:
13 March 2020

© .

Thieme Medical and Scientific Publishers Private Ltd.
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  • References

  • 1 Klapper BJ, Strizak-Sherwin R. Esthetic anterior space maintenance. Pediatr Dent 1983; 5 (02) 121-123
  • 2 Barbería E, Lucavechi T, Cárdenas D, Maroto M. Free-end space maintainers: design, utilization and advantages. J Clin Pediatr Dent 2006; 31 (01) 5-8
  • 3 Setia V, Pandit IK, Srivastava N, Gugnani N, Sekhon HK. Space maintainers in dentistry: past to present. J Clin Diagn Res 2013; 7 (10) 2402-2405
  • 4 Law CS. Management of premature primary tooth loss in the child patient. J Calif Dent Assoc 2013; 41 (08) 612-618
  • 5 Rock WP. British Society of Paediatric Dentistry. UK National Clinical Guidelines in Paediatric Dentistry. Extraction of primary teeth – balance and compensation. Int J Paediatr Dent 2002; 12 (02) 151-153
  • 6 Magnússon TE. The effect of premature loss of deciduous teeth on the spacing of the permanent dentition. Eur J Orthod 1979; 1 (04) 243-249
  • 7 Chalakkal P, Thomas AM, Akkara F, Pavaskar R. New design space regainers: ‘lingual arch crossbow’ and ‘double banded space regainer’. J Indian Soc Pedod Prev Dent 2012; 30 (02) 161-165
  • 8 Vibhute PJ. Open-coil retraction spring. Case Rep Dent 2011; 2011: 435709
  • 9 von Fraunhofer JA, Bonds PW, Johnson BE. Force generation by orthodontic coil springs. Angle Orthod 1993; 63 (02) 145-148
  • 10 Singh G. Textbook of Orthodontics. New Delhi: JP Medical Ltd; 2015
  • 11 Knop L, Gandini LG Jr, Shintcovsk RL, Gandini MREAS. Scientific use of the finite element method in orthodontics. Dental Press J Orthod 2015; 20 (02) 119-125
  • 12 Singh JR, Kambalyal P, Jain M, Khandelwal P. Revolution in Orthodontics: finite element analysis. J Int Soc Prev Community Dent 2016; 6 (02) 110-114
  • 13 Kumar A, Ghafoor H, Khanam A. A comparison of three-dimensional stress distribution and displacement of naso-maxillary complex on application of forces using quad-helix and nickel titanium palatal expander 2 (NPE2): a FEM study. Prog Orthod 2016; 17 (01) 17
  • 14 Yu J, Park JH, Bayome M. et al. Treatment effects of mandibular total arch distalization using a ramal plate. Korean J Orthod 2016; 46 (04) 212-219
  • 15 Kim YB, Bayome M, Park JH. et al. Displacement of mandibular dentition during total arch distalization according to locations and types of TSADs: 3D finite element analysis. Orthod Craniofac Res 2019; 22 (01) 46-52
  • 16 Ebadian B, Mosharraf R, Khodaeian N. Effect of cantilever length on stress distribution around implants in mandibular overdentures supported by two and three implants. Eur J Dent 2016; 10 (03) 333-340
  • 17 Işeri H, Tekkaya AE, Oztan O, Bilgiç S. Biomechanical effects of rapid maxillary expansion on the craniofacial skeleton, studied by the finite element method. Eur J Orthod 1998; 20 (04) 347-356
  • 18 Jafari A, Shetty KS, Kumar M. Study of stress distribution and displacement of various craniofacial structures following application of transverse orthopedic forces–a three-dimensional FEM study. Angle Orthod 2003; 73 (01) 12-20
  • 19 Kamble RH, Lohkare S, Hararey PV, Mundada RD. Stress distribution pattern in a root of maxillary central incisor having various root morphologies: a finite element study. Angle Orthod 2012; 82 (05) 799-805
  • 20 Singh SV, Bhat M, Gupta S, Sharma D, Satija H, Sharma S. Stress distribution of endodontically treated teeth with titanium alloy post and carbon fiber post with different alveolar bone height: a three-dimensional finite element analysis. Eur J Dent 2015; 9 (03) 428-432
  • 21 Proffit WR, Fields Jr HW, Sarver DM. Contemporary Orthodontics Massachusetts. Elsevier Health Sciences; 2006
  • 22 Kang JM, Park JH, Bayome M. et al. A three-dimensional finite element analysis of molar distalization with a palatal plate, pendulum, and headgear according to molar eruption stage. Korean J Orthod 2016; 46 (05) 290-300
  • 23 Nalbantgil D, Tozlu M, Ozdemir F, Oztoprak MO, Arun T. FEM analysis of a new miniplate: stress distribution on the plate, screws and the bone. Eur J Dent 2012; 6 (01) 9-15
  • 24 Farnsworth D, Rossouw PE, Ceen RF, Buschang PH. Cortical bone thickness at common miniscrew implant placement sites. Am J Orthod Dentofacial Orthop 2011; 139 (04) 495-503
  • 25 Wichelhaus A, Geserick M, Ball J. A new nickel titanium rapid maxillary expansion screw. J Clin Orthod 2004; 38 (12) 677-680, quiz 671–672
  • 26 Yu HS, Baik HS, Sung SJ, Kim KD, Cho YS. Three-dimensional finite-element analysis of maxillary protraction with and without rapid palatal expansion. Eur J Orthod 2007; 29 (02) 118-125
  • 27 Nudehi S, Steffen J. Analysis of machine elements using SOLIDWORKS simulation 2018. USA, SDC Publications 2018
  • 28 Feizbakhsh M, Kadkhodaei M, Zandian D, Hosseinpour Z. Stress distribution in maxillary first molar periodontium using straight pull headgear with vertical and horizontal tubes: a finite element analysis. Dent Res J (Isfahan) 2017; 14 (02) 117-124
  • 29 Lee SC, Park JH, Bayome M, Kim KB, Araujo EA, Kook YA. Effect of bone-borne rapid maxillary expanders with and without surgical assistance on the craniofacial structures using finite element analysis. Am J Orthod Dentofacial Orthop 2014; 145 (05) 638-648
  • 30 Shetty P, Hegde AM, Rai K. Study of stress distribution and displacement of the maxillary complex following application of forces using jackscrew and nitanium palatal expander 2–a finite element study. J Clin Pediatr Dent 2009; 34 (01) 87-93
  • 31 Erverdi N, Koyutürk O, Küçükkeles N. Nickel-titanium coil springs and repelling magnets: a comparison of two different intra-oral molar distalization techniques. Br J Orthod 1997; 24 (01) 47-53
  • 32 Sung EH, Kim SJ, Chun YS, Park YC, Yu HS, Lee KJ. Distalization pattern of whole maxillary dentition according to force application points. Korean J Orthod 2015; 45 (01) 20-28
  • 33 Kang YG, Kim JY, Lee YJ, Chung KR, Park YG. Stability of mini-screws invading the dental roots and their impact on the paradental tissues in beagles. Angle Orthod 2009; 79 (02) 248-255
  • 34 Park M, Na Y, Park M, Ahn J. Biomechanical analysis of distalization of mandibular molars by placing a mini-plate: a finite element study. Korean J Orthod 2017; 47 (05) 289-297
  • 35 Fongsamootr T, Suttakul P. Effect of periodontal ligament on stress distribution and displacement of tooth and bone structure using finite element simulation. Eng J (NY) 2015; 19 (02) 99-108