Deformations at the craniofacial complex depending on the HYRAX device design
Vol 32 No 291 (1) (2015), Articles
Vol 32 No 291 (1) (2015)

Deformations at the craniofacial complex depending on the HYRAX device design

Articles
https://doi.org/10.7862/rm.2015.1
Published April 10, 2015
Sergei Bosiakov
Belarusian State University, 4 Nezavisimosti Avenue, 220030 Minsk, Belarus
https://orcid.org/0000-0003-4524-9304
Anastasiya Vinakurava
Rzeszow University of Technology
Andrei Dosta
Belarusian State Medical University
PDF

Keywords

czaszka nienaruszona
rozszczep podniebienia
aparat HYRAX
stan naprężeniowo-odkształceniowy

How to Cite

Bosiakov, S., Vinakurava, A., & Dosta, A. (2015). Deformations at the craniofacial complex depending on the HYRAX device design. Advances in Mechanical and Materials Engineering, 32(291 (1), 5-15. https://doi.org/10.7862/rm.2015.1
ACM ACS APA ABNT Chicago Harvard IEEE MLA Turabian Vancouver

Download Citation

Endnote/Zotero/Mendeley (RIS) BibTeX

Abstract

Finite element analysis of the stress-strain state of a human skull after the expansion of the maxilla with using different designs orthodontic appliance HYRAX was carried out. Finite element model of craniofacial complex and supporting teeth are obtained on the basis of tomographic data. An orthodontic appliance differs by the localization of the screw relative to the palate. The design with location of the rods and screw of device in the same horizontal plane as well as the design with the location of the screw at the 8 mm closer to the palate relative to the horizontal localization are considered. Deformations at the intact skull and a skull with a cleft palate were derived. The regions of the largest deformations of the skull bone structures are defined for different orthodontic device designs. Effect of the orthodontic device design on displacements of the supporting teeth is analyzed. The results can be used to design devices HYRAX for the orthodontic correction and treatment of the cross-bite patients.

https://doi.org/10.7862/rm.2015.1
PDF

References

Boryor A., Geigera M., Hohmann A., Wunderlich A., Sander C., Sander F.M., Sander F.G.: Stress distribution and displacement analysis during an intermaxillary disjunction. A three-dimensional FEM study of a human skull, J. Biomechanics, 41 (2008), 376-382.

Braun S., Bottrel J.A., Lee K.G., Lunazzi J.J., Legan H.L.: The biomechanics of maxillary sutural expansion, American J. Orthodontics Dentofacial Orthopedics, 118 (2000), 257-261.

Chaconas S.J., Caputo A.A.: Observation of orthopedic force distribution produced by maxillary orthodontic appliances, American J. Orthodontics Dentofacial Orthopedics, 82 (1982), 492-501.

Chung C.H., Font B.: Skeletal and dental changes in the sagittal, vertical, and transverse dimensions after rapid palatal expansion, American J. Orthodontics Dentofacial Orthopedics, 126 (2004), 569-575.

Gautam P., Zhao L., Patel P.: Biomechanical response of the maxillofacial skeleton to transpalatal orthopedic force in a unilateral palatal cleft, Angle Orthodontist, 81 (2011), 503-509.

Ghoneima A., Abdel-Fattah E., Hartsfield J., El-Bedwehi A., Kamel A., Kulaf K.: Effects of rapid maxillary expansion on the cranial and circummaxillary sutures, American J. Orthodontics Dentofacial Orthopedics, 140 (2011), 510-519.

Han U.A., Kim Yo., Park J.U.: Three-dimensional finite element analysis of stress distribution and displacement of the maxilla following surgically assisted rapid maxillary expansion, J. Cranio-Maxillofacial Surgery, 37 (2009), 145-154.

Holberg C., Holberg N., Schwenzer K., Wichelhaus A., Rudzki-Janson I.: Biomechanical analysis of maxillary expansion in CLP patients, Angle Orthodontist, 77 (2007), 280-287.

Isaacson R.J., Ingram A.H.: Forces produced by rapid maxillary expansion. Part II. Forces present during treatment, Angle Orthodontist, 34 (1964), 261-270.

Isaacson R.J., Wood J.L., Ingram A.H.: Forces produced by rapid maxillary expansion. Part I. Design of the force measuring system, Angle Orthodontist, 34 (1964), 256-260.

Iseri H., Tekkaya A.E., Öztan Ö., Bilgiç S.: Biomechanical effects of rapid maxillary expansion on the craniofacial skeleton, studied by the finite element method, European J. Orthodontics, 20 (1998), 347-356.

Jafari A., Shetty K.S., Kumar M.: Study of stress distribution and displacement of various craniofacial structures following application of transverse orthopedic forcesa three-dimensional FEM study, Angle Orthodontist, 73 (2003), 12-20.

Kragt G., Duterloo H.S., Ten Bosch J.J.: The initial reaction of a macerated human skull caused by orthodontic cervical traction determined by laser metrology, American J. Orthodontics Dentofacial Orthopedics, 81 (1982), 49-56.

Landes C.A., Laudermann K., Petruchin O., Mack M.G., Kopp S., Ludwig B., Sader R.A., Seitz O.: Comparison of bipartite versus tripartite osteotomy for maxillary transversal expansion using 3-dimensional preoperative and postexpansion computed tomography data, J. Oral Maxillofacial Surgery, 67 (2009), 2287-2301.

Lee H., Ting K., Nelson M., Sun N., Sung S.J.: Maxillary expansion in customized finite element method models, American J. Orthodontics Dentofacial Orthopedics, 136 (2009), 367-374.

Ludwig B., Baumgaertel S., Zorkun B., Bonitz L., Glasl B., Wilmes B., Lisson J.: Application of a new viscoelastic finite element method model and analysis of miniscrew-supported hybrid hyrax treatment, American J. Orthodontics Dentofacial Orthopedics, 143 (2013), 426-435.

Majourau A., Nanda R.: Biomechanical basis of vertical dimension control during rapid palatal expansion therapy, American J. Orthodontics Dentofacial Orthopedics, 106 (1994), 322-328. Memikoglu T.U.T., Iseri H.: Effects of a bonded rapid maxillary expansion appliance during orthodontic treatment, Angle Orthodontist, 69 (1999), 251-256.

Pan X., Qian Y., Yu J., Wang D., Tang Y., Shen G.: Biomechanical effects of rapid palatal expansion on the craniofacial skeleton with cleft palate: a three-dimensional FE analysis, Cleft Palate-Craniofacial J., 44 (2007), 149-154.

Provatidis C., Georgiopoulos B., Kotinas A., McDonald J. P.: On the FEM modeling of craniofacial changes during rapid maxillary expansion, Medical Engng. Physics, 29 (2007), 566-579.

Sander C., Hüffmeier S., Sander F. M., Sander F. G.: Initial results regarding force exertion during rapid maxillary expansion in children, J. Orofacial Orthopedics, 67 (2006), 19-26.

Susami T., Kuroda T., Amagasa T.: Orthodontic treatment of a cleft palate patient with surgically assisted rapid maxillary expansion, Cleft Palate-Craniofacial J., 33 (1996), 445-449.

Tanne K., Sakuda M.: Biomechanical and clinical changes of the craniofacial complex from orthopedic maxillary protraction, Angle Orthodontist, 61 (1991), 145-152.

Timms D.J.: A study of basal movement with rapid maxillary expansion, American J. Orthodontics Dentofacial Orthopedics, 77 (1980), 500-507.

Wang D., Cheng L., Wang C., Qian Y., Pan X.: Biomechanical analysis of rapid maxillary expansion in the UCLP patient, Medical Engineering and Physics, 31 (2009), 409-417.

Weissheimer A., Macedo de Menezes L., Mezomo M., Dias D.M., Santayana de Lima E.M., Rizzatto S.M.D.: Immediate effects of rapid maxillary expansion with Haas-type and hyrax-type expanders: A randomized clinical trial, American J. Orthodontic Dentofacial Orthopedics, 140 (2011), 366-376.

Wood S.A., Strait D.S., Dumont E.R., Ross C.F., Grosse I.R.: The effects of modeling simplifications on craniofacial finite element models: The alveoli (tooth sockets) and periodontal ligaments, Journal of Biomechanics, 44 (2011), 1831-1838.

Zimring J.F., Isaacson R.J.: Forces produced by rapid maxillary expansion. Part III. Forces present during retention, Angle Orthodontist, 35 (1965), 178-186.