Browsing by Author "Adams, Heather"
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Item Development of a laboratory model to assess the removal of biofilm from interproximal spaces by powered tooth brushing(2002-11) Adams, Heather; Winston, Matthew T.; Heersink, Joanna; Buckingham-Meyer, Kelli; Costerton, J. William; Stoodley, PaulPurpose: To develop an interproximal laboratory model to compare the potential effectiveness of powered brushing to remove biofilm plaque from interproximal spaces beyond the reach of bristles. Materials and Methods: Streptococcus mutans biofilms were first grown onglass microscope slides in a drip-flow reactor. The slides were removed and positioned in the interproximal model. Each slide was exposed to 15 seconds powered brushing with either the Sonicare® Elite or the Braun Oral-B 3D Excel. The thickness of the biofilm was measured with confocal microscopy at various distances from the bristle tips. Results: The Sonicare® Elite reduced the thickness of biofilm by 57% at a distance of 0-5 mm from the bristle tips, 46% at 5-10 mm and 43% at 10-15 mm, relative to biofilm in areas unexposed to brushing. All reductions in thickness were statistically significant (P< 0.01). The Braun Oral-B 3D reduced the biofilm thickness by 16%, 13%, and 19% at the same distances respectively, but the thickness reductions were not statistically significant from those in the unexposed areas (P> 0.1).Item Rheology of biofilms(2003) Winston, Matthew T.; Rupp, Cory J.; Vinogradov, A. M.; Towler, Brett William; Adams, Heather; Stoodley, PaulThe paper describes an experimental study concerning the mechanical properties of bacterial biofilms formed from the early dental plaque colonizer Streptoccocus mutans and pond water biofilms. Experiments reported in this paper demonstrate that both types of biofilms exhibit mechanical behavior similar to that of rheological fluids. The time-dependent properties of both biofilms have been modeled using the principles of viscoelasticity theory. The Burger model has been found to accurately represent the response of both biofilms for the duration of the experiments. On this basis, the creep compliances of both biofilms have been characterized, and the respective relaxation functions have been determined analytically.