DOI: 10.3290/j.jad.a11223, PubMed ID (PMID): 16830661Pages 151-160, Language: EnglishArmstrong, Steve R. / Jessop, Julie L. P. / Vargas, Marcos A. / Zou, Yuan / Qian, Fang / Campbell, Joshua A. / Pashley, David H.Purpose: The purpose of this work was to determine microtensile dentin bond strengths (µTBS) of dentin-resin composite bonds after three-month storage in artificial saliva containing either collagenase (COL) or cholesterol esterase (EST). The null hypothesis tested is that the resin-dentin bond strength is equivalent for each storage medium at the tested storage times.
Materials and Methods: Resin composite was bonded to occlusal dentin, and µTBS specimens were formed and stored in the artificial saliva, COL, EST, or synthetic oil. After 24 h and 12-week storage, µTBS was determined and failure modes were characterized by SEM. The interfacial ultrastructure was evaluated by transmission electron microscopy as unstained and stained sections (phosphotungstic acid/uranyl acetate). Statistical analysis was performed by ANOVA and Weibull survival analyses at the 0.05 level of statistical significance.
Results: There were significantly weaker bond strengths after 12 weeks for all experimental storage media (p 0.001). Artificial saliva containing EST lowered bond strengths to a significantly greater extent than did COL after 12 weeks of storage, while no difference between these groups could be discerned after 24 h. Therefore, the null hypothesis of this experiment is rejected.
Conclusion: Exogenous enzymatic challenge to resin-dentin bonds decreased bond durability only with EST. However, when further challenges to ideal infiltration of the comonomers into the hybrid layer were carried out using inadequate removal of solvent, additional alterations in hybrid layer ultrastructure were discerned by TEM that may represent different potential degradative processes. The contribution of endogenous enzymatic challenges to the primary degradative process, ie, hydrolysis, is unknown and deserves continued attention.
Keywords: enzymes, hydrolysis, degradation, dental adhesives, dentin