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Abstract

Composite restorations degrade during wear, but it is unknown how wear affects the composite surface and influences composite-to-composite bonding in minimally invasive repair. Here, it is hypothesized that in vitro exposure of composites to oral biofilm yields clinically relevant degradation of composite surfaces, and its influence on composite-to-composite bonding is determined. Biofilms on composite surfaces in vitro increased their roughness and decreased filler particle exposure, except for a microhybrid composite, similar to effects of clinical wear in palatal appliances. Failure shear stresses after intermediate-adhesive-resin application were significantly lower after aging by in vitro exposure to biofilms, while silica-coating maintained the same failure stress levels as in non-aged composites. Failure modes were predominantly cohesive after silica-coating, while intermediate-adhesive-resin application yielded more adhesive failure. It is concluded that in vitro exposure to oral biofilm is a clinically relevant aging condition, and that silica-coating is to be preferred for the repair of aged composites.

Keywords

biofilm composite repair intermediate adhesive resin microhybrid composite nanofilled composite nanohybrid composite silica-coating

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References

Akova

Ozkomur

Uysal

(2006). Effect of food-simulating liquids on the mechanical properties of provisional restorative materials. J Dent 22:1130-1134.

Asmussen

(1984). Softening of BISGMA-based polymers by ethanol and by organic acids of plaque. Scand J Dent Res 92:257-261.

Beyth

Bahir

Matalon

Domb

Weiss

(2008). Streptococcus mutans biofilm changes surface-topography of resin composites. Dent Mater 24:732-736.

Bouschlicher

Reinhardt

Vargas

(1997). Surface treatment techniques for resin composite repair. Am J Dent 10:279-283.

Brendeke

Özcan

(2007). Effect of physicochemical aging conditions on the composite-composite repair bond strength. J Adhes Dent 9:399-406.

Busscher

Rinastiti

Siswomihardjo

Van der Mei

(2010). Biofilm formation on dental restorative and implant materials. J Dent Res 89:657-665.

Carlen

Nikdel

Wennerberg

Holmberg

Olsson

(2001). Surface characteristics and in vitro biofilm formation on glass ionomer and composite resin. Biomaterials 22:481-487.

Chiba

Hosoda

Fusayama

(1989). The addition of an adhesive composite resin to the same material: bond strength and clinical techniques. J Prosthet Dent 61:669-675.

Fúcio

Carvalho

Sobrinho

Sinhoreti

Puppin-Rontani

(2008). The influence of 30-day-old Streptococcus mutans biofilm on the surface of esthetic restorative materials — An in vitro study. J Dent 36:833-839.

10.

Gmür

Guggenheim

(1983). Antigenic heterogeneity of Bacteroides intermedius as recognized by monoclonal antibodies. Infect Immun 42:459-470.

11.

Göpferich

(1996). Mechanisms of polymer degradation and erosion. Biomaterials 17:103-114.

12.

Guggenheim

Gmür

Giertsen

Thurnheer

(2004). Application of the Zürich biofilm model to problems of cariology. Caries Res 38:212-222.

13.

Ikeda

Matin

Nikaido

Foxton

Tagami

(2007). Effect of surface characteristics on adherence of S. mutans biofilms to indirect resin composites. Dent Mater J 26:915-923.

14.

Lee

Huang

Lin

Shih

(1998). Leached components from dental composites in oral simulating fluids and the resultant composite strengths. J Oral Rehabil 25:575-588.

15.

Lucena-Martín

González-López

Navajas-Rodríguez de Mondelo

(2001). The effect of various surface treatments and bonding agents on the repaired strength of heat-treated composites. J Prosthet Dent 86:481-488.

16.

McCabe

Carrick

(1986). A statistical approach to the mechanical testing of dental materials. Dent Mater 2:139-142.

17.

Øilo

(1992). Biodegradation of dental composites/glass-ionomer cements. Adv Dent Res 6:50-54.

18.

Özcan

Barbosa

Melo

Galhano

Bottino

(2007). Effect of surface conditioning methods on the microtensile bond strength of resin composite to composite after aging conditions. Dent Mater 23:1276-1282.

19.

Rinastiti

Özcan

Siswomihardjo

Busscher

(2010a). Immediate repair bond strengths of microhybrid, nanohybrid and nanofilled composites after different surface treatments. J Dent 38:29-38.

20.

Rinastiti

Özcan

Siswomihardjo

Busscher

(2010b). Effects of surface conditioning on repair bond strengths of non-aged and aged microhybrid, nanohybrid and nanofilled composites. Clin Oral Investig [Epub ahead of print, May 25, 2010] (in press). doi:10.1007/s00784-010-0426-6

21.

Robin

Scherrer

Wiskott

de Rijk

Belser

(2002). Weibull parameters of composite resin bond strengths to porcelain and noble alloy using the Rocatec system. Dent Mater 18:389-395.

22.

Rodrigues

Jr Ferracane

Della Bona

(2009). Influence of surface treatments on the bond strength of repaired resin composite restorative materials. Dent Mater 25:442-451.

23.

Shahdad

Kennedy

(1998). Bond strength of repaired anterior composite resins: an in vitro study. J Dent 26:685-694.

24.

Söderholm

(1981). Degradation of glass filler in experimental composites. J Dent Res 60:1867-1875.

25.

Swift

Jr LeValley

Boyer

(1992). Evaluation of new methods for composite repair. Dent Mater 8:362-365.

26.

Yap

Lye

(1999). Effects of aging on repair bond strengths of a polyacid-modified composite resin. Oper Dent 24:371-376.

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Effect of Biofilm on the Repair Bond Strengths of Composites

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