Fatigue algorithm for dental implant

• Autorzy: Wierszycki M. , Kąkol W. , Łodygowski T.
• Języki publikacji: EN

Abstrakty

EN

Restorations with the application of implants are effective and commonly used in dental treatment. The computer simulation of implant fatigue life employing FEA is considered in the paper. For the simulation of implant structure behavior a 3D model including a spiral thread is applied, which allows for the full simulation of the kinematics of the implant, describing the multiaxial state of stress and, in consequence, the possibility of screw loosening. The cyclic scheme of the physiological occlusal loading and fatigue changes of dental material, bone loss phenomenon and changeability of boundary conditions are investigated. The valuable results for fatigue life which may be applied in modern prosthodontics are presented.

Słowa kluczowe

EN

fatigue; biomechanics; dental implant

PL

zmęczenie; biomechanika; implanty dentystyczne

• Wydawca: Wydawnictwo Politechniki Poznańskiej
• Czasopismo: Foundations of Civil and Environmental Engineering
• Rocznik: 2006
• Tom: No. 7
• Strony: 363--380
• Opis fizyczny: Bibliogr. 37 poz.

Twórcy

autor

Wierszycki M.

autor

Kąkol W.

autor

Łodygowski T.

• Institute of Structural Engineering, Poznań University of Technology, ul. Piotrowo 5, Poznań, Poland Tel.: (48 61) 665 21 03 fax: -.,

Bibliografia

• 1. ABAQUS Analysis User's Manuał, ABAQUS, Inc, Pawtucket, 2005.
• 2. ABAQUS Theory Manuał, ABAQUS, Inc. Pawtucket, 2005.
• 3. feSafe User's Manuał, Safe Technology Ltd, Sheffield, 2005.
• 4. Alkan I., Sertgoz A., Ekici B., Influence of occlusal forces on stress distribution in preloaded dental implant screws, The Journal of Prosthetic Dentistry, 91,4 (2004) 319-325.
• 5. Będziński R., Biomechanika inżynierska (in Polish), Oficyna Wydawnicza Politechniki Wrocławskiej, Wrocław, 1997.
• 6. Bishop N. W. M., Sherratt F., Finitc Element Based Fatigue Calculations, NAFEMS,Glasgow,2000.
• 7. Bozkaya D., Muftit S., Mechanics of the tapcr integrated scrcwed-in (TIS) abutments used in dental implants, Journal of Biomechanics, 38 (2005) 87-97.
• 8. Cehreli .M, Sahin .S, Akca K., Role of mechanical environment and implant design on bonę tissue differentiation: current knowledge and fulure contexts, Journal of Dentistry, 32 (2004) 123-132.
• 9. Draper J., Modern metal fatigue analysis, HKS, Inc. Pawtucket, 1999.
• 10. Eskitascioglu G., Usumez A., Sevimay M., Soykan M., Unsal E. The influence of occlusal loading location on stresses transferred to implant-supported prosthescs and supporting bonę: A three-dimensional fmite element study, The Journal of Prosthetic Dentistry, 91, 2 (2004) 144-150.
• 11. Genna F., Shakedown, sclf-stresses, and unilateral contact in a dental implant problem, Europcan Journal of Mechanics A/Solids, 23 (2004) 485-498.
• 12. Goodacre C. J., Bcrnal G.t Rungcharassacng K., Kań J. Y. K., Clinical complications with implants and implant prostheses, The Journal of Prosthetic Dentistry, 90, 2 (2003) 121-132.
• 13. Gratton D. G., Aąuilino S. A., Stanford C. M., Micromotion and dynamie fatigue propcrties of the dental implant-abutment intcrface, The Journal of Prosthetic Dentistry, 85,l (2001) 47-52.
• 14. Hecker D. M., Eckert S. E., Choi Y.-G., Cyclic loading of implant-supported prostheses: Comparison of gaps at the prosthetic-abutmcnt intcrface when cycled abutmcnts arę replaced with as-manufactured abutments, The Journal of Prosthetic Dentistry, 95, l (2006) 26-32.
• 15. Hędzelek W., Zagalak R., Łodygowski T., Wierszycki M., The effect of raarginal bonę loss and bonę density on the risk of łatę implant components failures, 27th Annual Conf. of the European Prosthodontic Association Gcneva, 2003.
• 16. Khraisat A., Stegaroiu R., Nomura S., Miyakawa O., Fatigue resistance of two implant/abutment joint designs, The Journal of Prosthetic Dentistry, 88 6(2002)604-610.
• 17. Kąkol W., Łodygowski T., Wierszycki M., Hędzelek W., Zagalak R., Numerical Analysis of the Behavior of Dental Implant, ABAQUS Users' Conference 2002, Newport RI, 2002.
• 18. Kąkol W., Łodygowski T., Wierszycki M., Estimate of tooth implant fatigue under cyclic loading, Conf. Computer Melhods in Mechanics, Gliwice, 2003.
• 19. Khraisat A., Hashimoto A., Nomura S., Miyakawa O., Effect of lateral cyclic loading on abutment cycrew loosening of an external hexagon implant system, The Journal of Prosthetic Denlistry, 91,4 (2004) 326-334.
• 20. Koa C-C., Swiftb J. Q., DeLonga R., Douglasa W. H., Kima Y., Anc K-N., Changd C-H., Huangd H-L., An intra-oral hydraulic system for controlled loadingof dental implanls, Journal of Biomcchanics, 35 (2002) 863-869.
• 21. Koca O. L., Eskitascioglu G., Usumez A., Threc-dimensional finite-elcment analysis of funetional stresses in diffcrent bonę locations produced by implants placed in the maxillary posterior region of the sinus floor, The Journal of Prosthetic Dentistry, 93, l (2005) 38-44.
• 22. Kocańda S., Zmęczeniowe pękanie metali (in Polish), Wydawnictwo Naukowo-Techniczne, Warszawa 1985.
• 23. Lang L. A., Kang B., Wang R. F., Lang B. R., Finite element analysis to determine implant preload, The Journal of Prosthetic Dentistry, 90, 6 (2003) 539-546.
• 24. Lee K.-S., Song J.-H., Estimalion methods for strain-Iife fatigue propertics from hardncss, International Journal of Fatigue, 28 (2006) 386^400.
• 25. Merz B. R., Hunenbart S., Belser U. C., Mechanics of the implant-abutment conncction: an 8-degree taper compared to a butt joint connection, The International Journal of Orał & Maxillofacial Implants, 15, 4 (2000) 519-526.
• 26. Park, J.-H., Song J.-H., Detailed cvaluation of methods for estimation of fatigue properties, International Journal of Fatigue, 17, 5 (1995) 365-373.
• 27. Roesslc M. L., Fatemi A., Strain-controlled fatigue propertics of steels and some simple approximations, International Journal of Fatigue, 22 (2000) 495-511.
• 28. Schutz W. A history of fatigue, Engineering Fracture Mechanics, 54, 2 (1996)263-300.
• 29. Sakaguchi R. L., Borgersen S. E., Nonlinear fmite element contact analysis of dental implant components, The International Journal of Orał & Maxillofacial Implants, 7, l (1993) 655-661.
• 30. Sevimay M., Turban F., Kilicxarslan M. A., Eskitascioglu G., Three-dimensional fmite element analysis of the effect of different bonę ąuality on stress distribution in an implant-supported crown, The Journal of Prosthetic Dentistry, 93, 3 (2005) 227-234.
• 31. Taylor, T, Prosthodontic problems and limitations associated with osscointegration, The Journal of Prosthetic Dentistry, 79, l (1998) 74-78.
• 32. Teoh S. H., Fatigue of biomatcrials: a review, Internationa! Journal of Fatigue, 22, (2000) 825-837.
• 33. Wang .K, The use of titanium for medical applications in the USA, Materials Science and Engineering, A213 (1996) 134-137.
• 34. Wierszycki M., Kąkol W., Łodygowski T., Numcrical complexity of selected biomechanical problems, Journal of Theoretical and Applied Mechanics (in press).
• 35. Wierszycki M., Kąkol W., Łodygowski T., The screw loosening and fatigue analyses of three dimensional dental implant model, ABAQUS Users1 Conference 2006, Boston MA, 2006.
• 36. Zagalak R. Ocena własności mechanicznych dwuczęściowych wszczepów stomatologicznych Osteoplant (in Polish), PhD Thesis, Fundacja Akademii Medycznej w Poznaniu, Poznań 2003.
• 37. Zienkiewicz O.C., Taylor R. L., The Finite Element Method, Elsevier, 2000.