Stress Distribution in Roots Restored with Different Types of Post Systems with Composite Resin

Stress Distribution in Roots Restored with Different Types of Post Systems with Composite Resin

Although composite resin core is used with various types of prefabricated posts, it remains unclear which kind of material is most suitable for the post. The aim of this study was to evaluate the influence of prefabricated posts on the stress distribution within the root by finite element analysis....

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Veröffentlicht in:Dental Materials Journal 2008, Vol.27(4), pp.605-611
Hauptverfasser: OKADA, Daizo, MIURA, Hiroyuki, SUZUKI, Chikako, KOMADA, Wataru, SHIN, Chiharu, YAMAMOTO, Masahiro, MASUOKA, David
Format: Artikel
Sprache:eng
Schlagworte:
Adult
Bite Force
Composite Resins - chemistry
Dental Stress Analysis
Dentistry
Finite Element Analysis
Glass
Humans
Male
Nonlinear finite element analysis
Post and Core Technique - adverse effects
Post and Core Technique - instrumentation
Stainless Steel
Titanium
Tooth Fractures - etiology
Tooth Fractures - prevention & control
Tooth Root - anatomy & histology
Tooth Root - physiology
Tooth, Nonvital - pathology
Von Mises stress
Young's modulus
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Zusammenfassung:Although composite resin core is used with various types of prefabricated posts, it remains unclear which kind of material is most suitable for the post. The aim of this study was to evaluate the influence of prefabricated posts on the stress distribution within the root by finite element analysis. Posts and cores were built up with composite resin and four types of prefabricated posts: two types of glass fiber posts (GFP1, GFP2) with low and high Young's moduli, a titanium post (TIP), and a stainless steel post (SSP). In all models, stress distribution during function was calculated. There were differences in stress concentration at the root around the end of posts. The magnitudes of stress for GFP1, GFP2, TIP, and STP were 8.7, 9.3, 11.7, and 13.9 MPa respectively. Given the results obtained, GFP1 was the most suitable material for post fabrication since this model showed a lower stress value. It would therefore mean a lower possibility of root fracture.
ISSN:0287-4547
1881-1361
DOI:10.4012/dmj.27.605