Submitted: 22 May 2007
Accepted: 25 Feb 2013
ePublished: 25 Feb 2013
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J Iran Dent Assoc. 2004;16(4): 35-43.
  Abstract View: 18

Research

Stress analysis of all-ceramic three-unit dental bridges ‌using finite element method

Mohammad jafar Biria*, Farzam Farahmand, Gholam reza Eslami Amirabadi
*Corresponding Author: Email:

Abstract

Stress analysis of all-ceramic three-unit dental bridges ‌using finite element method

M.F. Biria *- Dr. F. Farahmand** - Dr. Gh. Eslami Amirabadi***

*- M.S in Biomechanics Engineering Faculty of Mechanics. Sharif Industrial University.

** - Associate professor of Mecanical Engineering Dept. Sharif Industrial University.

*** - Assistant professor of Orthodontics Dept. Faculty of Dentistry Shahed University of Medical Sciences.

Background and aim: Mechanical fracture is a common cause for the failure of three-unit dental bridges, particularly the all-ceramic ones. The goal of the present study was to evaluate the effects of convergent angles of the abutments on the peak and distribution of mechanical stresses wihtin the prosthesis and at the restoration abutment interface of a three-unit all-ceramic bridge using finite element method.

Materials and Methods: The cloud points of three-D geometrical data of the second premolar and first and second molar teeth were obtaind using ATOS Scanner system and utilized for the reconstruction of a surface model of the three-unit bridge in CATIA software. Data were than transferred to I-DEAS software for mesh generation and finite element analysis. Two EF models were developed with convergent angles corresponding to the up and low defined range including 171900 and 168700 tetraherdal solid four-node elements, respectively. The models were subjected to two different prosthesis materials and three different load cases.

Results: The maximum tensile stresses occured on the gingival surface of the second premolar retainer and at the tooth /restoration interface on the marginal distal surface of the second molar abutment. The peak tensile stress was relatively lower for the model with the higher convergent angle but the difference was not significant. Changing the prosthesis material from IE2 to Dicor desreased the stresses within the prosthesis.

Conclusion: Higher safety factor was found for IE2 due to its higher mechanical strenght. Moreover, it was proved that load condition played an important role on the mechanical stress observed.

Key Words: Prosthesis - Three unit bridge - Finite Element Method - Convergence angles. ‌

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