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Original Research

Open Access

Envisioning Post-treatment Occlusions after Space Closure Using Temporary Skeletal Anchorage Devices

  • Un-Bong Baik1
  • Junji Sugawara2
  • Youn-Sic Chun3
  • Suchita Mandair4
  • Jae Hyun Park4,5,*,

1Private practice, Seoul, Korea

2Private practice, Sendai, Japan

3Department of Orthodontics, Ewha Womans University, Mokdong Hospital, Seoul, Korea

4Postgraduate Orthodontic Program, Arizona School of Dentistry & Oral Health, A.T. Still University, Mesa, AZ

5International scholar, Graduate School of Dentistry, Kyung Hee University, Seoul, Korea

DOI: 10.17796/1053-4625-43.2.11 Vol.43,Issue 2,March 2019 pp.131-136

Published: 01 March 2019

*Corresponding Author(s): Jae Hyun Park E-mail: JPark@atsu.edu

Abstract

Missing posterior teeth and posterior tooth extractions are commonly seen and needed within orthodontic practices. With the invention of temporary skeletal anchorage devices (TSADs), clinicians can now effectively close posterior tooth spaces. Various molar occlusions are discussed to help clinicians envision post-treatment occlusions after posterior teeth space closure using TSADs.


Keywords

Molar protraction; Temporary skeletal anchorage devices (TSADs); Occlusion; Space closure

Cite and Share

Un-Bong Baik,Junji Sugawara,Youn-Sic Chun,Suchita Mandair,Jae Hyun Park. Envisioning Post-treatment Occlusions after Space Closure Using Temporary Skeletal Anchorage Devices. Journal of Clinical Pediatric Dentistry. 2019. 43(2);131-136.

References

1. Baik UB, Kim MR, Yoon KH, Kook YA, Park JH. Orthodontic uprighting of a horizontally impacted third molar and protraction of mandibular second and third molars into the missing first molar space for a patient with posterior crossbites. Am J Orthod Dentofacial Orthop, 151: 572-582, 2017.

2. Baik UB, Kook YA, Bayome M, Park JU, Park JH. Vertical eruption patterns of impacted mandibular third molars after the mesialization of second molars using miniscrews. Angle Orthod, 86: 565-570, 2016.

3. Baik UB, Chun YS, Jung MH, Sugawara J. Protraction of mandibular second and third molars into missing first molar spaces for a patient with an anterior open bite and anterior spacing. Am J Orthod Dentofacial Orthop, 141: 783-795, 2012.

4. Baik UB. Molar Protraction: Orthodontic substitution of missing posterior teeth. In: Kim KB, editor. Temporary Skeletal Anchorage Devices. Heidelberg: Springer, 119-160, 2014.

5. Khalaf K, Miskelly J, Voge E, Macfarlane TV. Prevalence of hypodontia and associated factors: a systematic review and meta-analysis. J Orthod, 41: 299-316, 2014.

6. McCaul LK, Jenkins WM, Kay EJ. The reasons for the extraction of various tooth types in Scotland: a 15-year follow up. J Dent, 29: 401-407, 2001.

7. Sayegh A, Hilow H, Bedi R. Pattern of tooth loss in recipients of free dental treatment at the University Hospital of Amman, Jordan. J Oral Rehabil, 31: 124-130, 2004.

8. Casko JS, Vaden JL, Kokich VG, Damone J, James RD, Cangialosi TJ, et al. Objective grading system for dental casts and panoramic radiographs. American Board of Orthodontics. Am J Orthod Dentofacial Orthop, 114:

589- 599, 1998.

9. Patel S, Mansuri S, Shaikh F, Shah T. Impacted mandibular third molars: a retrospective study of 1198 cases to assess indications for surgical removal, and correlation with age, sex and type of impaction-a single institutional experience. J Maxillofac Oral Surg, 16: 79-84, 2017.

10. 10. McArdle LW, Patel N, Jones J, McDonald F. The mesially impacted mandibular third molar: the incidence and consequences of distal cervical caries in the mandibular second molar. Surgeon, 16: 67-673, 2018.

11. Silva HO, Pinto ASB, Pinto MESC, de Siqueira Rego MR, Gois JF, de Araujo TLC, Mendes JDP. Dental caries on distal surface of mandibular second molar. Braz Dent Sci, 18: 51-59, 2015.

12. Sarikov R, Juodzbalys G. Inferior alveolar nerve injury after mandibular third molar extraction: a literature review. J Oral Maxillofac Res, 5: e1, 2014.

13. Nguyen E, Grubor D, Chandu A. Risk factors for permanent injury of inferior alveolar and lingual nerves during third molar surgery. J Oral Maxillofac Surg, 72: 2394-2401, 2014.

14. Orton-Gibbs S, Crow V, Orton HS. Eruption of third permanent molars after the extraction of second permanent molars. Part 1: Assessment of third molar position and size. Am J Orthod Dentofacial Orthop, 119:

226- 238, 2001.

15. Proffit WR, Fields HW, Sarver DM. Contemporary Orthodontics. St. Louis, MO 2013.

16. Hattab FN, Abu Alhaija ESJ. Radiographic evaluation of mandibular third molar eruption space. Oral Surg Oral Med Oral Pathol Oral Radiol Endod, 88: 285-291, 1999.

17. Türköz C, Ulusoy C. Effect of premolar extraction on mandibular third molar impaction in young adults. Angle Orthod, 83: 572-577, 2013.

18. Orton-Gibbs S, Orton S, Orton H. Eruption of third permanent molars after the extraction of second permanent molars. Part 2: Functional occlusion and periodontal status. Am J Orthod Dentofacial Orthop, 119: 239-244, 2001.

19. Reitan K. Tissue rearrangement during retention of orthodontically rotated teeth. Angle Orthod, 29: 105-113, 1959.

20. Reitan K. Clinical and histologic observations on tooth movement during and after orthodontic treatment. Am J Orthod 53:721-745, 1967.

21. Reitan K. Principles of retention and avoidance of posttreatment relapse. Am J Orthod, 55: 776-790, 1969.

22. Sicher H. Oral Anatomy. 4th ed. St. Louis: C.V. Mosby; 1965.

23. Durbin DS, Sadowsky C. Changes in tooth contacts following orthodontic treatment. Am J Orthod Dentofacial Orthop, 90: 375-382, 1986.

24. Park JH, Tai K, Kanao A, Takagi M. Space closure in the maxillary posterior area through the maxillary sinus. Am J Orthod Dentofacial Orthop, 145: 95-102, 2014.

25. Oh H, Herchold K, Hannon S, Heetland K, Ashraf G, Nguyen V, et al. Orthodontic tooth movement through the maxillary sinus in an adult with multiple missing teeth. Am J Orthod Dentofacial Orthop, 146: 493-505, 2014.

26. Maeda Y, Kuroda S, Ganzorig K, Wazen R, Nanci A, Tanaka E. Histomorphometric analysis of overloading on palatal tooth movement into the maxillary sinus. Am J Orthod Dentofacial Orthop, 148: 423-430, 2015.

27. Nagaraj K, Upadhyay M, Yadav S. Titanium screw anchorage for protraction of mandibular second molars into first molar extraction sites. Am J Orthod Dentofacial Orthop, 134: 583-591, 2008.

28. Stepovich ML. A clinical study on closing edentulous spaces in the mandible. Angle Orthod, 49: 227-233, 1979.

29. Kravitz ND, Jolley T. Mandibular molar protraction with temporary anchorage devices. J Clin Orthod, 42: 351-355, 2008.

30. Chhibber A, Upadhyay M. Anchorage reinforcement with a fixed functional appliance during protraction of the mandibular second molars into the first molar extraction sites. Am J Orthod Dentofacial Orthop, 148: 165-173, 2015.

31. Chhibber A, Upadhyay M. En-masse protraction of mandibular posterior teeth into missing mandibular lateral incisor spaces using fixed functional appliance. Am J Orthod Dentofacial Orthop, 150: 864-875, 2016.

32. Hom BM, Turley PK. The effects of space closure of the mandibular first molar area in adults. Am J Orthod, 85: 457-469, 1984.

33. Carvalho RS, Nelson D, Kelderman H, Wise R. Guided bone regeneration to repair an osseous defect. Am J Orthod Dentofacial Orthop, 123: 455-467, 2003.

34. Long H, Pyakurel U, Wang Y, Liao L, Zhou Y, Lai W. Interventions for accelerating orthodontic tooth movement. Angle Orthod, 83: 164-171, 2013.

35. Yi J, Xiao J, Li H, Li Y, Li X, Zhao Z. Effectiveness of adjunctive interventions for accelerating orthodontic tooth movement: a systematic review of systematic reviews. J Oral Rehabil, 44: 636-654, 2017.

36. Cheung T, Park J, Lee D, Kim C, Olson J, Javadi S, Lawson G, Mccabe J, Moon W, Ting K, Hong C. Ability of mini-implant facilitated micro-osteoperforations to accelerate tooth movement in rats. Am J Orthod Dentofacial Orthop, 150: 958-967, 2016. Downloaded from http://meridian.allenpress.com/jcpd/article-pdf/43/2/131/1752490/1053-4625-43_2_11.pdf by Bharati Vidyapeeth Dental College & Hospital


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