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Objective: � Over the past decade, the clinical placement of dental composites for posterior restorations has dramatically increased as amalgam use has declined.� Dental composites have evolved both chemically and physically; however, they still have some drawbacks, including polymerization shrinkage, potential failure at resin-dentin interfaces leading to secondary caries, and relatively high coefficient of thermal expansion.� Recently, attention has shifted towards deleterious effects of dental biofilms on the potential accelerated degradation of resin-based composites
Methods: Composite discs were formed in Teflon molds and light-activated according to the manufacturers' recommended procedures. Cured specimens were then wet-polished with 3 mm diamond paste to replicate clinical polishing procedures.� Specimens were then exposed to Streptococcus mutans (biofilm-forming strain of this organism (UA159-BS480)) and bacterial adhesion was quantified using confocal scanning laser microscopy (CLSM) after period of 1, 4, 7, 11, 13, and 15 days.� Additionally, stylus profilometry, AFM, and SEM were used to analysis composite degradation.
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�Results: CLSM
revealed that surfaces exhibited an increase in biofilm thickness (from 2-4 �m
at 1 day to 5-30 �m at 13 days) and the onset of concavities indicating foci of
microbial attack and potential sites of material degradation.� Surface
roughness analysis showed that all composite surfaces increased in Ra
indicating biofilm-driven degradation.
Keywords: Adhesion, Biofilm, Composites, Dental materials and Surfaces