Numerical analysis of the foods nature effect on the mechanical behavior of dental implants

• Autorzy: Sifi M. , Serier B. , Merdji A. , Benaissa A , Mootanah R.
• Języki publikacji: EN

Abstrakty

EN

This study focuses on a three-dimensional numerical analysis by the finite element method, the mechanical behavior of the dental prosthesis implant composed of a single implant. The effect of the nature of food on the level and distribution of the Von Mises equivalent stress generated in the bone and the elements that constitute this prosthesis have been highlighted. It has been shown that this level is particularly important that the Crushed masticated foods are rigid. This work was carried out to answer questions whose purpose was to analyze the risk of overload in the mandibular region. Loads transfer mechanisms and the possible failure of osseointegrated implants, the shape of the implant, the geometrical and mechanical properties of the placement site and bone resorption of the crest. A proper estimation of these effects allows the correct design of the implant.

Słowa kluczowe

EN

implant; abutment; bone; constraints; distribution; modeling; prosthesis; effort

PL

implant; styk; kość; więzy; rozkład; modelowanie; proteza; wytężenie

• Wydawca: Wydawnictwo Politechniki Łódzkiej
• Czasopismo: Mechanics and Mechanical Engineering
• Rocznik: 2017
• Tom: Vol. 21, nr 4
• Strony: 1021--1032
• Opis fizyczny: Bibliogr. 24 poz., il. kolor., wykr.

Twórcy

autor

Sifi M.

• Laboratory of Physical Mechanics of Materials, Faculty of Engineering, Sidi Bel Abbes, 22000 Algeria

autor

Serier B.

• Laboratory of Physical Mechanics of Materials, Faculty of Engineering, Sidi Bel Abbes, 22000 Algeria

autor

Merdji A.

• Laboratory of Physical Mechanics of Materials, Faculty of Engineering, Sidi Bel Abbes, 22000 Algeria

autor

Benaissa A

• Faculty of Science and Technology, Mascara University, Algeria

autor

Mootanah R.

• Medical Engineering Research Group, Faculty of Science and Technology, Anglia Ruskin University, Bishop Hall Lane, Chelmsford, Essex, UK

Bibliografia

• [1] Branemark, P. I.: Osseointegrated implants in the treatment of the edentulous Jaw experience from a 10 year period, Scand. J. Plast. Reconstrs. Surg. 16, 130-132, 1977.
• [2] Obeid, A. S., Alkhodary, M. A., Omran, M. H., Abdelwahab, E. M.: The Basal Polymeric PEEK Dental Implant Restoring a Missing Molar: A Case Study Validated with Finite Element Analysis, Journal of Advanced Dental and Medical Sciences, 1, 2, 50-56, 2015.
• [3] Merdji, A., Bouiadjra, B., Achour, T., Serier, B., Ould B., Chikh, Z. O.: Feng Stress analysis in dental prosthesis, Computational Materials Science, 49, 126-133, 2010.
• [4] Vedovatto, E., Mazaro, J. V. Q., Filho, H. G., de Carvalho, P. S. P., de Mello, C. C., Lemos, C. A. A.: Biomechanical Analysis of Implant Assisted-Overdentures with Variations in the Attachments Systems, Materials Sciences and Applications, 6, 734-742, 2015.
• [5] Chrcanovic, B. R., Albrektsson, T., Wennerberg, A.: Tilted versus axially placed dental implants, Journal of Oral Rehabilitation, 41, 443-476, 2014.
• [6] Schwitalla, A. D., Abou-Emara, M., Spintig, T., Lackmann, J., Muller, W. D.: Finite element analysis of the biomechanical effects of PEEK dental implants on the peri-implant bone, Journal of Biomechanics, 48, 1-7, 2015.
• [7] Djebbar, N.: Stress distribution in dental implant with elastomeric stress barrier, Materials and Design, 32, 282-290, 2011.
• [8] Merdji, A., Mootanah, R., Bachir Bouiadjra, B., Benaissa, A., Aminallah, L., Ould Chikh, B., Mukdadi, S.: Stress analysis in single molar tooth. Materials Science and Engineering, C, 33, 691-698, 2013.
• [9] Achour, T., Merdji, A., Bachir Bouiadjra, B., Serier, B., Djebbar, N.: Stress distribution in dental implant with elastomeric stress barrier. Material and Design, 32, 282-290, 2011.
• [10] Saidin, S., Abdul Kadir, M. R., Sulaiman, E., Abu Kasim, N. H.: Effects of different implant- abutment connections on micromotion and stress distribution: Prediction of microgap formation, Journal of Dentistry, 40, 467-474, 2012.
• [11] Benaissa, A., Chikh, E. B. O., Meddah, H. M., Merdji, A., Bouiadjra, B. A. B.: Effects of overloading in mastication on the mechanical behavior of Dental Implants, Materials and Design, 47, 210-217, 2013.
• [12] Himmlova, L., Dostalova, T. and al.: Influence of implant length and diameter on stress distribution: A finite element analysis, The Journal of Prosthet Dent., 91, 1, 20-25, 2004.
• [13] Chen, K. K., Miyake, K., Terashita, M.: Cervical strains induced by occlusal loading, Journal of Dental Research, 478-478, 1999.
• [14] Shames, I. H., Dym, C. L.: Energy and finite element methods in structural mechanics, New York: McGraw-Hill, 1985.
• [15] Smukler, H.: Equilibration occlusale en denture naturelle, Paris: édition CdP, 16-19, 51, 81-82, 1993.
• [16] Boz-Kaya, D., Muftu, A.: Evaluation of load transfer characteristics of five different implants in compact bone at different load levels by finite. Journal of Prosthet Dent., 92, 6, 523-530, 2004.
• [17] Assunc, W., Gomes, E. A., Bara, V., Delben, J. A., Tabata, L. F., de Sousa, E. A.: Effect of superstructure materials and misfit on stress distribution in a single implant-supported prosthesis: a finite element analysis. J Craniofac Surg 21, 689-95, 2010.
• [18] Steigenga, J., Al-Shammari, K., Misch, C., Nociti, F.H., Jr., Wang, H. L.: Effects of implant thread geometry on percentage of osseointegration and resistance to reverse torque in the tibia of rabbits, J Periodontol, 75, 1233-1241, 2004.
• [19] Abu-Hammad, O. A., Harrison, A., Williams, D.: The effect of a hidroxyapatiterein forced polyethylene stress distributor in a dental implant on compressive stress levels in surrounding bone, Int J Oral Maxillofac Implants, 15, 4, 559-64, 2000.
• [20] Berkovitz, B. K. B.: Periodontal ligament: structural and clinical correlates. J Dent Res, 31, 46-54, 2004.
• [21] Nishida, E., Saito, M., Ishikawa, S., Sasaki, T., Noguchi, T., Shimizu, N., Teranaka, T.: Transcriptome analysis of extracellular matrix genes regulating periodontal ligament development, J. Dent. Res., 56, 2598-2605, 2006.
• [22] Asmussen, E., Peutzfeldt, A., Sahafi, A.: Finite element analysis of stresses in endo dontically treated, dowel-restored teeth, J. Prosthet Dent., 94, 321-329, 2005.
• [23] Bader, J. D., Shugars, D. A., Martin, J. A.: Risk indicators for posterior tooth fracture, Journal of the American Dental Association, 135, 7, 883-892, 2017.
• [24] Fill, T. S., Carey, J. P., Toogood, R. W., Major, P. W.: Experimentally Determined Mechanical Properties of Periodontal Ligament: Critical Review of Current Literature, Journal of Dental Biomechanics, doi:10.4061/2011/312980, 2011.