Failure analysis of a new post-and-core restoration system using the finite element method
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Julian Boldt
Abstract
Human teeth with substantial coronal defects are subject to reconstruction by means of post-and-core restorations. Typically, such a restoration comprises a slightly cylindrical post onto which an abutment of varying shape, depending on the designated restoration, is attached. As clinical results are not satisfactory to date, a new post-and-core design which makes use of positive locking (rather than relying on chemical bonding agents for retention in the residual root) was proposed. Using proprietary burs, an inversely conical hole is machined into the root, into which the prefabricated post-and-core restoration is inserted. This part can be spread at the bottom to match the cavity's undercut form, resulting in a positive lock which can only be separated by destruction of root, restoration or both. Another key feature of this system is a ring/groove geometry which is able to absorb the wedging forces created by said spreading and the stress of loading of the restoration which arises from mascatory forces. To assess the properties, especially in terms of the stress imposed on the remaining tooth at highest possible loading, both finite element simulations and in vitro failure tests were performed and the findings compared. The results suggest that the parameters of the finite element simulations are in good agreement with reality. As calculated and measured force levels immediately before failure of the restoration are high, the introduced new geometry has significant advantages over the classical restoration.
©2008 by Walter de Gruyter Berlin New York
Articles in the same Issue
- Guest editorial
- Biomechanics and biomaterials in oral rehabilitation and dental treatment
- Mini review
- Bone quality, quantity and metabolism in terms of dental implantation
- Research articles
- Finite element representation of bone substitute remodelling in the jaw bone
- The biomaterial influences the ossification after sinus floor elevation using tissue-engineered bone grafts
- O-phospho-l-serine: a modulator of bone healing in calcium-phosphate cements
- A new design for post and core restorations implementing positive locking
- Mechanical loading of orthodontic miniscrews – significance and problems: an experimental study
- Effect of load angulation and crown shape on forces acting on post and core restored teeth: an in vitro study
- Failure analysis of a new post-and-core restoration system using the finite element method
- The influence of the root cross-section on the stress distribution in teeth restored with a positive-locking post and core design: a finite element study
- Reproducibility of electronic tooth colour measurements
Articles in the same Issue
- Guest editorial
- Biomechanics and biomaterials in oral rehabilitation and dental treatment
- Mini review
- Bone quality, quantity and metabolism in terms of dental implantation
- Research articles
- Finite element representation of bone substitute remodelling in the jaw bone
- The biomaterial influences the ossification after sinus floor elevation using tissue-engineered bone grafts
- O-phospho-l-serine: a modulator of bone healing in calcium-phosphate cements
- A new design for post and core restorations implementing positive locking
- Mechanical loading of orthodontic miniscrews – significance and problems: an experimental study
- Effect of load angulation and crown shape on forces acting on post and core restored teeth: an in vitro study
- Failure analysis of a new post-and-core restoration system using the finite element method
- The influence of the root cross-section on the stress distribution in teeth restored with a positive-locking post and core design: a finite element study
- Reproducibility of electronic tooth colour measurements
