Geometric design of sleeve and abutment for subperiosteal implants using finite element analysis

  • Klaudia Kulcsár Győr
  • János Kónya
Keywords: implant, subperiosteal implant, finite element analysis, sleeve, abutment

Abstract

Nowadays, we experience a rapid development is the field of implantology. Dental implant insertion became a routine procedure during which, mostly screw-type implants are used. Achievements in modern implantology result in such tooth replacements which are perfectly identical to natural teeth both aesthetically and functionally. Thus, chewing ability can be completely restored. The most important advantage of these procedures is that they prevent further bone resorption in neighbouring tissues. The use of custom-made implants becomes even more widespread in modern implantology. Thanks to the patient-specific design, various dental replacements are made that fulfil different needs and expectations of each patient. The creation of these custom design implants is carried out with additive manufacturing technology. This additive technology provides an opportunity for patients who have insufficient bone tissue for the insertion of conical implants. This study presents denture-supporting abutments of different geometric designs. The abutment is directly connected to the sleeve, which is fixed to the subperiosteal implant with micro-welding technology. In geometric design, the distribution of axial forces resultant from the denture is of vital importance as stress levels should be decreased. Examinations were carried out with finite element analysis, which is a widely-used method in engineering practice. By the end of this study, optimal geometric design is determined by comparing the result of each design. The chosen geometry is then implemented into practice and used for the implantation procedure. The material of choice for the subperiosteal implant is Grade 23 titanium alloy, and it is created with an additive manufacturing process. The material of the sleeve and abutment is Grade 5 titanium alloy, and these parts are manufactured with a subtractive process.

References

1] Vajdovics, I. (2008). Dentális implantológia – gyakorló fogorvosok részére. Budapest: Semmelweis Kiadó
[2] Forrai, J. (2016). Pierre Fauchard paradigma váltása a fogászatban, esettanulmány. Művelődés-, Tudományos- és Orvostörténeti Folyóirat, 6(10)
[3] Nagy, P. (2018. december). Implantátumok – Ötlettől a termékig. Forrás: http://att.bme.hu/oktatás/BMEGEPTAGA0/letoltes
[4] Reham, O. B., Swain M. V. (2015). A Critical Review of Dental Implant Materials with an Emphasis on Titanium versus Zirconia. Materials Journal, 8(3), 932-958.
[5] Dallas R Trinkle Research Group. (2018). Titanium. University of Illinois, Department of Materials Science and Engineering. Forrás: http://dtrinkle.matse.illinois.edu/dokuwiki/doku.php?id=research:ti
[6] Bhola, R., Bhola, S. M., Mishra, B., Olson, D. L. (2011). Corrosion on Titanium Dental Implants/Prostheses (Requirements). Trends n Biomat. and Artif. 25(1), 34-46.
[7] Bozkaya, D., Müftü S.. (2003). Mechanics of the tapered interference fit in dental implants. Journal of Biomechanics, 26(11), 1649-1658.
[8] Ekici, B. (2002). Numerical analysis of a dental implant system in three-dimension. Advances in engineering Software, 33(2), 109-113.
[9] Tamás, P., Bojtos, A., Décsei-Paróczi, A., Fekete, R. T. (2014). Végeselem módszerek. Budapest, BME MOGI http://www.mogi.bme.hu/TAMOP/vegeselem_modszerek/book.html
[10] Guo-Hao, L., Hsun-liang, C., Hom-Lay, W. (2013). The significance of keratinized mucosa on implant health: a systematic rewiev. J Periodontol 84(12), 1755-1767.
Published
2019-06-12
Section
Materials Science and Technology (Anyagtudomány és Technológia)