Title of article
Evaluation of the micro-mechanical strength of resin bonded–dentin interfaces submitted to short-term degradation strategies
Author/Authors
Feitosa، نويسنده , , Victor P. and Sauro، نويسنده , , Salvatore and Watson، نويسنده , , Timothy F. and Correr، نويسنده , , Américo B. and Osorio، نويسنده , , Raquel and Toledano، نويسنده , , Manuel and Correr-Sobrinho، نويسنده , , Lourenço and Sinhoreti، نويسنده , , Mلrio Alexandre C.، نويسنده ,
Issue Information
ماهنامه با شماره پیاپی سال 2012
Pages
9
From page
112
To page
120
Abstract
The aim of this study was to evaluate the microtensile bond strength (μTBS) and confocal micropermeability of resin bonded–dentin specimens created using two representative two-step/self-etch adhesives submitted to short-term period degradation strategies such as simulated pulpal pressure, thermo- or mechanical-cycling challenges. Clearfil SE Bond (CSE) and Silorane adhesive (SIL) were bonded to flat deep dentin from seventy extracted human molars and light-cured for 10 s. Composite build-ups were constructed using with Filtek Z350 XT and Filtek P90 respectively. The specimens of each adhesive group were subjected to three different accelerated aging methods: (1) thermo-cycling challenge (5000 cycles); (2) mechanical-cycling load (200,000 cycles); (3) experiment and (4) conventional method for simulated pulpal pressure (20 cm H2O). Control resin-bonded specimens were stored in distilled water for 24 h. μTBS and confocal microscopy (CLSM) micropermeability evaluation were performed and the results were analyzed using Two-way ANOVA and Tukeyʹs tests (α=0.05). The CLSM evaluation revealed micro-cracks within the Silorane-bonded dentin subsequent to mechanical-cycling load, whereas, the simulated pulpal pressure induced evident micropermeability in both bonding agents. Mechanical loading provides discernible bonding degradation in a short-term period in resin–bonded dentin created using two-step/self-etch adhesives. However, simulated pulpal pressure may reduce the sealing ability of self-etch adhesives causing greater water uptake within the resin–dentin interface.
Keywords
Hydrostatic pulpal pressure , confocal microscopy , Mechanical loading , dental adhesives , Thermo-cycling
Journal title
Journal of the Mechanical Behavior of Biomedical Materials
Serial Year
2012
Journal title
Journal of the Mechanical Behavior of Biomedical Materials
Record number
1405563
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