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Purpose: Many clinicians use dentures with metallic core due to fears of insufficient strength of ceramic bridges. The aim of work was finite element strength analysis of fullcontour ceramic implant supported denture in lateral region. Design/methodology/approach: Finite element analysis (Solidworks) of occlusal load transfer in all-ceramic implant supported denture for missing second premolar, first molar and second molar teeth was made. Bridgework from zirconia was supported on two implants 4x12 mm (diameter x length) placed in bone with good quality and quantity. Model was loaded with lateral maximal occlusal force of 800 N. Findings: In the bridgework in the connector with premolar tooth Huber-Mises stress reached 375 MPa. Stress in implants was about 1000 MPa and small plastic deformation zones can occur close to the implant edge under pressure of abutment. Stress in abutment screw reached about 800 MPa in the first thread root and up to 400 MPa in the shank. Stress in bone tissues around implant neck and slightly lower of the beginning of the thread exceeded 140 MPa. Research limitations/implications: Linear isotropic behavior of materials and tied contact between components were assumed in the model. Practical implications: Detrimental effect of maximal occlusal force on the osseointegration between implant and bone showed that patients must be warned against loading of the denture over normal mastication. Stress in the abutment screw reached dangerous value and specific design to prevent fatigue failure is required. Originality/value: An impact of torsion and oblique bending are rarely considered in investigations. This result is relevant for the design of bridgeworks and graded materials for ceramic restoration.
Słowa kluczowe
Wydawca
Rocznik
Tom
Strony
61--68
Opis fizyczny
Bibliogr. 18 poz.
Twórcy
autor
- Institute of Engineering Materials and Biomaterials, Silesian University of Technology, ul. Konarskiego 18A, 4 4 -1 0 0 Gliwice, Poland
autor
- Institute of Engineering Materials and Biomaterials, Silesian University of Technology, ul. Konarskiego 18A, 4 4 -1 0 0 Gliwice, Poland
autor
- Medical College of Silesian Province, Department of Dental Technicians, ul. 3 Maja 63, 4 1 -8 0 0 Zabrze, Poland
Bibliografia
- [1] R.S. Akulwar, A. Kodgi, Non-Rigid connector for managing pier abutment in FPD: A Case Report, Journal of Clinical and Diagnostic Research 8/7 (2014) ZD12-ZD13.
- [2] T. Miyazaki, T. Nakamura, H. Matsumura, S. Ban, T. Kobayashi, Current status of zirconia restoration, Journal of Prosthodontic Research 57/4 (2013) 236-261.
- [3] E. Camposilvan, F.G. Marro, A. Mestra, M. Anglada, Enhanced reliability of yttria-stabilized zirconia for dental applications, Acta Biomaterialia 17 (2015) 36-46.
- [4] J.I. Cawood, R.A. Howell, A classification of the edentulous jaws, International Journal of Oral and Maxillofacial Surgery 17/4 (1988) 232-236.
- [5] J.R. Kelly, Ceramics in restorative and prosthetic dentistry, Annual Review of Materials Research 27 (1997)443-468.
- [6 ] A. Shenoy, N. Shenoy, Dental ceramics: An update, Journal of Conservative Dentistry 13/4 (2010) 195-203.
- [7] J. Żmudzki, W. Walke, W. Chladek, Stresses present in bone surrounding dental implants in FEM model experiments, Journal of Achievements in Materials and Manufacturing Engineering 27/1 (2008) 71-74.
- [8 ] G.J. Fleming, M. Dickens, L.J. Thomas J.J. Harris, The in vitro failure of all-ceramic crowns and the connector area of fixed partial dentures using bilayered ceramic specimens: the influence of core to dentin thickness ratio, Dental Materials 22/8 (2006) 771-777.
- [9] S. Oruc, O. Eraslan, H.A. Tukay, A. Atay, Stress analysis of effects of nonrigid connectors on fixed partial dentures with pier abutments, Journal of Prosthetic Dentistry 99/3 (2008) 185-192. doi: 10.1016/S0022-3913(08)60042-6.
- [10] M.P. Dittmer, P. Kohorst, L. Borchers, M. Stiesch, Influence of the supporting structure on stress distribution in all-ceramic FPDs, The International Journal of Prosthodontics 23/1 (2010) 63-68.
- [11] Y. Takuma, S. Nomoto, T. Sato, N. Sugihara, Effect of framework design on fracture resistance in zirconia 4-unit all-ceramic fixed partial dentures, The Bulletin of Tokyo Dental College 54/3 (2013) 149-156.
- [12] K. Möllers, W Pätzold, D. Parkot, A. Kirsten, J.F. Gtith, D. Edelhoff, H. Fischer, Influence of connector design and material composition and veneering on the stress distribution of all-ceramic fixed dental prostheses: a finite element study, Dental Materials 27/8 (2011) 171-175
- [13] M. Tsumita, Y. Kokubo, P. Vult von Steyern, S. Fukushima, Effect of framework shape on the fracture strength of implant-supported all-ceramic fixed partial dentures in the molar region, Journal of Prosthodontics 17/4 (2008) 274-285.
- [14] S.M. Rezaei, H. Heidarifar, F.F. Arezodar, A. Azary, S. Mokhtarykhoee, Influence of connector width on the stress distribution of posterior bridges under loading, Journal of Dentistry (Tehran, Iran) 8/2 (2011)67-74.
- [15] A.B. Motta, L.C. Pereira, A.R. da Cunha, F.P. Duda, The influence of the loading mode on the stress distribution on the connector region of metal-ceramic and all-ceramic fixed partial denture, Artificial Organs 32/4 (2008) 283-291.
- [16] Ł. Reimann, J. Żmudzki, L.A. Dobrzański, Strength analysis of a three-unit dental bridge framework with the Finite Element Method, Acta of Bioengineering and Biomechanics 17/1 (2015)51-59.
- [17] G. Sannino, A. Pozzi, R. Schiavetti, A. Barlattani, Stress distribution on a three-unit implantsupported zirconia framework. A 3D finite element analysis and fatigue test, Oral & Implantology 5/1 (2012) 11-20.
- [18] Y. Zhang, J.W. Kim, Graded structures for damage resistant and aesthetic all-ceramic restorations, Dental Materials 25/6 (2009) 781-790.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-10fcdb30-a775-422d-8b59-9341a935a82c