Shear bond strength of ceramic brackets after different pre-treatments in
               porcelain surface

May, Naudy Brodbeck; Araújo, Élito; Vieira, Luiz Clovis Cardoso

doi:10.1590/1677-3225v14n1a07

Abstract

AIM:

To evaluate the bond strength of brackets bonded after different surface treatments on two dental ceramics.

METHODS:

One hundred and twenty discs 5 mm thick and 7 mm diameter of two ceramic types were made and randomly divided in 8 groups. Groups 1, 3, 5, and 7 used Eris ceramic and groups 2, 4, 6, and 8 used d.Sign ceramic. The ceramic surfaces were treated with 10% hydrofluoric acid G1 and G2, 10% hydrofluoric acid + silane G3 and G4, aluminum oxide blasting + 35% phosphoric acid + silane G5 and G6, CoJet blasting + 35% phosphoric acid + silane G7 and G8. Metallic brackets were cemented with Concise cement. Mechanical test was performed in a universal testing machine until failure.

RESULTS:

The average values MPa obtained G1 - 7.30; G2 - 6.12; G3 - 17.49; G4 - 19.54; G5 - 18.80; G6 - 21.93; G7 - 6.81 e G8 - 9.77 were submitted to ANOVA and Tukey test p<0.05. The fracture patterns were analyzed in stereoscopic microscope 25´X and representative samples of each group were analyzed in SEM.

CONCLUSIONS:

It was possible to conclude that use of silane after hydrofluoric acid increased the bond strength values.

adhesives; dental bonding; dental porcelain; orthodontic brackets; shear strength

Introduction

The advances in cosmetic dentistry and the increased aesthetic requirements have led to a growing demand for orthodontic treatments¹1. Komori A, Takemoto K, Shimoda T, Miyashita W, Scuzzo G. Precise direct lingual bonding with the KommonBase. J Clin Orthod. 2013; 47: 42-9.

2. Grewal Bach GK, Torrealba Y, Lagravère MO. Orthodontic bonding to porcelain: a systematic review. Angle Orthod. 2014; 84: 555-60.

3. Okuda W. Predictable replacement of failing porcelain restorations. Gen Dent. 2014; 62: 21-3. ^- ⁴4. Zhang ZC, Giordano R, Shen G, Chou LL, Qian YF. Shear bond strength of an experimental composite bracket. J Orofac Orthop. 2013; 74: 319-31. and orthodontists have sometimes to deal with patients that ceramic laminates or crowns from previous dental interventions³3. Okuda W. Predictable replacement of failing porcelain restorations. Gen Dent. 2014; 62: 21-3.

4. Zhang ZC, Giordano R, Shen G, Chou LL, Qian YF. Shear bond strength of an experimental composite bracket. J Orofac Orthop. 2013; 74: 319-31. ^- ⁵5. Gayake PV, Chitko SS, Sutrave N, Gaikwad PM. The direct way of indirect bonding-the combined effect. Int J Orthod Milwaukee. 2013; 24: 15-7.. It is known that the orthodontic treatment will be successful only if there is an adequate bond strength between the substrate tooth, ceramic, or ceromer and the orthodontic appliance bracket; notwithstanding, the bond strength between ceramic/brackets has proven to be unsatisfactory¹1. Komori A, Takemoto K, Shimoda T, Miyashita W, Scuzzo G. Precise direct lingual bonding with the KommonBase. J Clin Orthod. 2013; 47: 42-9. ^, ³3. Okuda W. Predictable replacement of failing porcelain restorations. Gen Dent. 2014; 62: 21-3.

4. Zhang ZC, Giordano R, Shen G, Chou LL, Qian YF. Shear bond strength of an experimental composite bracket. J Orofac Orthop. 2013; 74: 319-31.

5. Gayake PV, Chitko SS, Sutrave N, Gaikwad PM. The direct way of indirect bonding-the combined effect. Int J Orthod Milwaukee. 2013; 24: 15-7. ^- ⁶6. Lung CY, Liu D, Matinlinna JP. Silica coating of zirconia by silicon nitride hydrolysis on adhesion promotion of resin to zirconia. Mater Sci Eng C Mater Biol Appl. 2015; 46: 103-10..

Buonocore⁷7. Buonocore MG. A simple method of increasing the adhesion of acrylic filling materials to enamel surfaces. J Dent Res. 1955; 34: 849-53. 1955 reported that it was possible to bond the resin to the tooth based on a study about enamel. Ever since, several researches have been performed aiming to establish a clinical protocol for the bonding procedure using other substrates like dentin, metal, composite and ceramic⁸8. Trakyali G, Malkondu O, Kazazoðlu E, Arun T. Effects of different silanes and acid concentrations on bond strength of brackets to porcelain surfaces. Eur J Orthod. 2009; 31: 402-6. ^- ⁹9. Rathke A, Tymina Y, Haller B. Effect of different surface treatments on the composite-composite repair bond strength. Clin Oral Investig. 2009; 13: 317-23.. As regards ceramics, due to their different compositions, diverse methods have been developed for the treatment of their surfaces¹⁰10. Rao S, Chowdhary R. Comparison of fracture toughness of all-ceramic and metal-ceramic cement retained implant crowns: an in vitro study. J Indian Prosthodont Soc. 2014; 14: 408-14. ^- ¹¹11. Bieniaœ J, Surowska B, Stoch A, Matraszek H, Walczak M. The influence of SiO2 and SiO2-TiO2 intermediate coatings on bond strength of titanium and Ti6Al4V alloy to dental porcelain. Dent Mater. 2009; 25: 1128-35..

Different pretreatment methods have been proposed for substrates that will receive orthodontic brackets, as polishing with sandpapers²2. Grewal Bach GK, Torrealba Y, Lagravère MO. Orthodontic bonding to porcelain: a systematic review. Angle Orthod. 2014; 84: 555-60. ^, ¹²12. Valentini F, Moraes RR, Pereira-Cenci T, Boscato N. Influence of glass particle size of resin cements on bonding to glass ceramic: SEM and bond strength evaluation. Microsc Res Tech. 2014; 77: 363-7., creation of irregularities with diamond burs²2. Grewal Bach GK, Torrealba Y, Lagravère MO. Orthodontic bonding to porcelain: a systematic review. Angle Orthod. 2014; 84: 555-60. ^, ⁶6. Lung CY, Liu D, Matinlinna JP. Silica coating of zirconia by silicon nitride hydrolysis on adhesion promotion of resin to zirconia. Mater Sci Eng C Mater Biol Appl. 2015; 46: 103-10., laser¹³13. Geraldo-Martins VR, Lepri CP, Faraoni-Romano JJ, Palma-Dibb RG. The combined use of Er,Cr: YSGG laser and fluoride to prevent root dentin demineralization. J Appl Oral Sci. 2014; 22: 459-64., hydrofluoric acid etching³3. Okuda W. Predictable replacement of failing porcelain restorations. Gen Dent. 2014; 62: 21-3. ^, ⁵5. Gayake PV, Chitko SS, Sutrave N, Gaikwad PM. The direct way of indirect bonding-the combined effect. Int J Orthod Milwaukee. 2013; 24: 15-7. ^, ¹²12. Valentini F, Moraes RR, Pereira-Cenci T, Boscato N. Influence of glass particle size of resin cements on bonding to glass ceramic: SEM and bond strength evaluation. Microsc Res Tech. 2014; 77: 363-7., aluminum oxide blasting²2. Grewal Bach GK, Torrealba Y, Lagravère MO. Orthodontic bonding to porcelain: a systematic review. Angle Orthod. 2014; 84: 555-60. ^- ³3. Okuda W. Predictable replacement of failing porcelain restorations. Gen Dent. 2014; 62: 21-3. ^, ⁶6. Lung CY, Liu D, Matinlinna JP. Silica coating of zirconia by silicon nitride hydrolysis on adhesion promotion of resin to zirconia. Mater Sci Eng C Mater Biol Appl. 2015; 46: 103-10., phosphoric acid etching⁵5. Gayake PV, Chitko SS, Sutrave N, Gaikwad PM. The direct way of indirect bonding-the combined effect. Int J Orthod Milwaukee. 2013; 24: 15-7. ^, ¹³13. Geraldo-Martins VR, Lepri CP, Faraoni-Romano JJ, Palma-Dibb RG. The combined use of Er,Cr: YSGG laser and fluoride to prevent root dentin demineralization. J Appl Oral Sci. 2014; 22: 459-64., maleic acid etching¹³13. Geraldo-Martins VR, Lepri CP, Faraoni-Romano JJ, Palma-Dibb RG. The combined use of Er,Cr: YSGG laser and fluoride to prevent root dentin demineralization. J Appl Oral Sci. 2014; 22: 459-64., acidulated phosphate fluoride application²2. Grewal Bach GK, Torrealba Y, Lagravère MO. Orthodontic bonding to porcelain: a systematic review. Angle Orthod. 2014; 84: 555-60. ^, ¹²12. Valentini F, Moraes RR, Pereira-Cenci T, Boscato N. Influence of glass particle size of resin cements on bonding to glass ceramic: SEM and bond strength evaluation. Microsc Res Tech. 2014; 77: 363-7., silane agent application²2. Grewal Bach GK, Torrealba Y, Lagravère MO. Orthodontic bonding to porcelain: a systematic review. Angle Orthod. 2014; 84: 555-60. ^, ⁴4. Zhang ZC, Giordano R, Shen G, Chou LL, Qian YF. Shear bond strength of an experimental composite bracket. J Orofac Orthop. 2013; 74: 319-31. ^- ⁵5. Gayake PV, Chitko SS, Sutrave N, Gaikwad PM. The direct way of indirect bonding-the combined effect. Int J Orthod Milwaukee. 2013; 24: 15-7. ^, ¹²12. Valentini F, Moraes RR, Pereira-Cenci T, Boscato N. Influence of glass particle size of resin cements on bonding to glass ceramic: SEM and bond strength evaluation. Microsc Res Tech. 2014; 77: 363-7., and lastly, the combination of one of the above-mentioned treatments with or without silane application⁴4. Zhang ZC, Giordano R, Shen G, Chou LL, Qian YF. Shear bond strength of an experimental composite bracket. J Orofac Orthop. 2013; 74: 319-31.

5. Gayake PV, Chitko SS, Sutrave N, Gaikwad PM. The direct way of indirect bonding-the combined effect. Int J Orthod Milwaukee. 2013; 24: 15-7. ^- ⁶6. Lung CY, Liu D, Matinlinna JP. Silica coating of zirconia by silicon nitride hydrolysis on adhesion promotion of resin to zirconia. Mater Sci Eng C Mater Biol Appl. 2015; 46: 103-10.. However, failures have been normaly found when a bracket is cemented to a ceramic restoration¹1. Komori A, Takemoto K, Shimoda T, Miyashita W, Scuzzo G. Precise direct lingual bonding with the KommonBase. J Clin Orthod. 2013; 47: 42-9. ^, ³3. Okuda W. Predictable replacement of failing porcelain restorations. Gen Dent. 2014; 62: 21-3.

4. Zhang ZC, Giordano R, Shen G, Chou LL, Qian YF. Shear bond strength of an experimental composite bracket. J Orofac Orthop. 2013; 74: 319-31.

5. Gayake PV, Chitko SS, Sutrave N, Gaikwad PM. The direct way of indirect bonding-the combined effect. Int J Orthod Milwaukee. 2013; 24: 15-7. ^- ⁶6. Lung CY, Liu D, Matinlinna JP. Silica coating of zirconia by silicon nitride hydrolysis on adhesion promotion of resin to zirconia. Mater Sci Eng C Mater Biol Appl. 2015; 46: 103-10..

Considering the lack of conclusive studies regarding the most effective pretreatment technique for bonding orthodontic appliances to teeth with ceramic prosthesis, the aim of this study was to evaluate the bond strength of brackets bonded after different surface treatments on two dental ceramics. The null hypothesis is that there are no significant differences among pre-treatment with 10% hydrofluoric acid, 10% hydrofluoric acid with silane agent, aluminum oxide blasting with 35% phosphoric acid and silane and CoJet blasting with 35% phosphoric acid and silane.

Material and methods

For this study were made 60 discs for each ceramic Eris Ivoclar Vivadent, Schaan, Liechtenstein and d.Sign Ivoclar Vivadent using a plastic matrix 5 mm thick and 7 mm diameter. The specimens were embedded in PVC tubes Amanco, São Paulo, SP, Brazil, with 20 mm external diameter by 20 mm height. The PVC tubes were filled with polystyrene resin Central Fiberglass, Florianópolis, SC, Brazil, prepared according to manufacturer's recommendations. For easier identification of the groups, different pigmentations Clássico, São Paulo, SP, Brazil of polystyrene resin were used for each group. Then they were divided into 8 groups n=15 according to the surface treatment and type of ceramic Table 1.

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Table 1.
Groups according to the pre-treatment and the type of ceramic.

For G1 and G2, the surface treatment was 10% hydrofluoric acid for 20 s, rinse for 15 s and 10 s drying. For G3 and G4 the same procedures were performed plus the application of 3 layers of silane agent, dryed for 15s and photo-activated for 10 s. In G5 and G6, the aluminum oxide blasting was performed during 15 s, with pressure at 80 psi using a needle gauge to measure pressure at a 5 mm distance; 35% phosphoric acid etching for 30 s, rinsing during 15 s, drying for 10 s, application of 3 layers of silane agent, drying during 15 s and photo-activation during 10 s. At last, the specimens of G7 and G8, after the same previous procedures as in G5 and G6, were blasted by the CoJet system followed by application of 35% phosphoric acid for 30 s and 3 layers of silane agent.

Concise cement 3M ESPE, St Paul, MN, USA was prepared according to the manufacturer's instructions and inserted on the specimen's surface. Next, using tweezers Dental Morelli Ltda, Sorocaba, SP, Brazil, standard metallic brackets Dental Morelli for central incisors, with area of 6.08 mm²2. Grewal Bach GK, Torrealba Y, Lagravère MO. Orthodontic bonding to porcelain: a systematic review. Angle Orthod. 2014; 84: 555-60., were positioned at the center of ceramic blocks with manual pressure. The excess resin was removed using explorer catheter Duflex - SS White Group, Gloucester, UK.

The ceramic/bracket specimens were stored in an oven QUIMIS, model Q317B, Diadema, SP, Brazil at 37 °C immersed in distilled water for 24 h. After that, the specimens were subjected to 800 thermal cycles Ética Equip. Cient. S.A., series 96, no 0364, model 521-E, São Paulo, SP, Brazil, for 30 s at 5 °C and 30 s at 55 C, with 10 s dell-time between baths.

The shear strength test was performed in a universal testing machine Instron model 4444, Canton, MA, USA, at a cross-speed of 0.5 mm/min. The specimens were positioned in a metallic glove 20.5 mm diameter x 20 mm high. The test was performed using a chisel as load on the ceramic/bracket interface, trying to simulate the oral cavity environment, as well as the masticatory loads.

The fracture patterns produced after the shear test were observed with a stereomicroscope XLT30, Nova Optical Systems, Piracicaba, SP, Brazil at 25× magnification, and classified according to Vaz et al.¹⁴14. Vaz RR, Hipolito VD, D'Alpino PH. Bond strength and interfacial micromorphology of etch-and-rinse and self-adhesive resin cements to dentin. J Prosthodont. 2012; 21: 101-11. 2011 as: 1 adhesive fracture: cement/bracket; 2 adhesive fracture: ceramic/cement; 3 mixed fracture: cement/bracket; 4 mixed fracture: ceramic/bracket/cement. Representative specimens of each group were randomly selected to determine the fracture pattern in a scanning electron microscope Philips XL-30, Mahwah, NJ, USA set at 20 kV. SEM micrographs were obtained at 15× and 60× magnifocations.

The shear strength data were subjected to two-way ANOVA and Tukey's test for multiple comparisons p=0.05. Fracture pattern data were analyzed statistically by Kruskal-Wallis test p=0.05. Paiwise comparisons of groups were performed with Mann-Whitney U test p=0.05. The correlation between shear strength and fracture pattern was performed by Spearman's rank correlation.

Results

ANOVA showed that there were statistically significant differences among the ceramics p=0.01 and surface treatments p=0.0001, but it did not show interaction among them p=0.14. Means compared by the Tukey's test p<0.05 are described in Table 2. Faiure mode analysis is described in Table 3.

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Table 2.
Bond strength means and standard deviations.

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Table 3.
Distribution in percentiles of fracture standards after shear test.

Initially, the groups were compared relative to the fracture pattern scores by the Kruskal-Wallis test H=52.49; p<0.0001. In the Mann-Whitney U test, the groups were compared in a pairwise fashion Table 4. The Table 4 indicates significance values between the groups that did not present statistical difference related to ceramics.

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Table 4.
Comparisons of fracture patterns by Mann-Whitney U tes

The Spearman's rank correlation showed that the higher the bond strength value, the more severe the fracture pattern, including fracture of ceramic or bracket R=0.372; p<0.0001.

SEM micrographs Figures 1, 2, 3 and 4 illustrate representative fracture patterns found in each group.

Figure 1.
Fracture pattern in G1 and G2 after shear test Adhesive ceramic/cement.

Figure 2.
Fracture pattern in G3 and G4 after shear test Mixed cement/bracket.

Figure 3.
Fracture pattern in G5 and G6 after shear test Mixed cement/bracket/ ceramic

Figure 4.
Fracture pattern in G7 and G8 after shear test Adhesive cement/bracket

Discussion

Based on the results of this study, the null hypothesis that there are no significant differences among the different ceramics treatments was rejected. The use of 10% hydrofluoric acid alone produced lower bond strength values G1 - 7.30 MPa and G2 - 6.12 MPa. However, when it was combined with silane agent, the bond strength increased significantly G3 - 17.49 MPa and G4- 19.54 MPa, corroborating previous findings¹²12. Valentini F, Moraes RR, Pereira-Cenci T, Boscato N. Influence of glass particle size of resin cements on bonding to glass ceramic: SEM and bond strength evaluation. Microsc Res Tech. 2014; 77: 363-7. ^, ¹⁵15. Kim JH, Chae S, Lee Y, Han GJ, Cho BH. Comparison of shear test methods for evaluating the bond strength of resin cement to zirconia ceramic. Acta Odontol Scand. 2014; 72: 745-52.. The increase in bond strength could be due to silane capacity of increasing the energy on the substrate surface, optimizing resin penetration in the created micro-regions⁵5. Gayake PV, Chitko SS, Sutrave N, Gaikwad PM. The direct way of indirect bonding-the combined effect. Int J Orthod Milwaukee. 2013; 24: 15-7. ^, ¹²12. Valentini F, Moraes RR, Pereira-Cenci T, Boscato N. Influence of glass particle size of resin cements on bonding to glass ceramic: SEM and bond strength evaluation. Microsc Res Tech. 2014; 77: 363-7..

The groups treated with aluminum oxide blasting 50 ìm followed by phosphoric acid etching 35% + silane agent, obtained values of 18.80 MPa G5 and 21.93 MPa G6, and did not differ significantly from groups treated with hydrofluoric acid + silane agent G3 and G4. These findings agree with those of recent studies²2. Grewal Bach GK, Torrealba Y, Lagravère MO. Orthodontic bonding to porcelain: a systematic review. Angle Orthod. 2014; 84: 555-60. ^- ³3. Okuda W. Predictable replacement of failing porcelain restorations. Gen Dent. 2014; 62: 21-3. ^, ⁶6. Lung CY, Liu D, Matinlinna JP. Silica coating of zirconia by silicon nitride hydrolysis on adhesion promotion of resin to zirconia. Mater Sci Eng C Mater Biol Appl. 2015; 46: 103-10. ^, ¹⁶16. Brunharo IH, Fernandes DJ, de Miranda MS, Artese F. Influence of surface treatment on shear bond strength of orthodontic brackets. Dental Press J Orthod. 2013; 18: 54-62. ^- ¹⁷17. Denry I, Kelly JR. Emerging Ceramic-based Materials for Dentistry. J Dent Res. 2014; 93: 1235-42.. A possible explanation could be the fact the impact produced by this treatment raises temperature locally, causing an incorporation of particles up to 15 ìm from ceramic structure¹⁸18. Kosyfaki P, Swain MV. Adhesion determination of dental porcelain to zirconia using the Schwickerath test: strength vs. fracture energy approach. Acta Biomater. 2014; 10: 4861-9., which increases surface roughness and makes it more retentive¹⁸18. Kosyfaki P, Swain MV. Adhesion determination of dental porcelain to zirconia using the Schwickerath test: strength vs. fracture energy approach. Acta Biomater. 2014; 10: 4861-9. ^- ¹⁹19. Bunek SS, Swift EJ Jr. Contemporary ceramics and cements. J Esthet Restor Dent. 2014; 26: 297-301. and receptive to the chemical bond with silane agent²⁰20. Wady AF, Paleari AG, Queiroz TP, Margonar R. Repair technique for fractured implant-supported metal-ceramic restorations: a clinical report. J Oral Implantol. 2014; 40: 589-92..

G7 6.81 MPa and G8 9.77 MPa bond strength means were significantly lower than those of G3-G6, and similar to those of G1 and G2. It is possible that the micro-retentions generated by CoJet system, whose particles are 30 ìm in size, could be lower than those created by the aluminum oxide blasting 50 ìm particles. These findings agree with Girish et al.²¹21. Girish PV, Dinesh U, Bhat CS, Shetty PC. Comparison of shear bond strength of metal brackets bonded to porcelain surface using different surface conditioning methods: an in vitro study. J Contemp Dent Pract. 2012; 13: 487-93. 2012, who reported that blasting with larger particles 110 ìm produced higher bond strength values than those found with CoJet. Ozcan²²22. Ozcan M. Surface conditioning protocol for multiple substrates in repair of cervical recessions adjacent to ceramic. J Adhes Dent. 2014; 16: 394. 2014, who evaluated the CoJet in ceramic, metal-ceramics, metal-mechanics and metallic substrates, achieved the best results with metallic substrates. According to Wady et al.²⁰20. Wady AF, Paleari AG, Queiroz TP, Margonar R. Repair technique for fractured implant-supported metal-ceramic restorations: a clinical report. J Oral Implantol. 2014; 40: 589-92. 2014, the efficiency of CoJet depends on the mechanical properties of the ceramic, working better in leucite-based ceramics than is feldspathic ones.

On the other hand, Passos et al.²³23. Passos SP, Kimpara ET, Bottino MA, Júnior GC, Rizkalla AS. Bond strength of different resin cement and ceramic shades bonded to dentin. J Adhes Dent. 2013; 15: 461-6. 2013 reported bond strength of 13.2 MPa after 37% phosphoric acid etching of enamel for 60 s. Zhang et al.⁴4. Zhang ZC, Giordano R, Shen G, Chou LL, Qian YF. Shear bond strength of an experimental composite bracket. J Orofac Orthop. 2013; 74: 319-31. 2013 disagree with this values theretofore considered adequate clinically by Silveira et al.²⁴24. Silveira GS, Bittencourt LP, Mucha JN. Scoring of ceramic bracket bases for easier debonding. J Clin Orthod. 2014; 48: 441-2. 2014. Based on the results of bracket bond to ceramic, there is a common sense to use Vijayakumar²⁵25. Vijayakumar RK, Jagadeep R, Ahamed F, Kanna A, Suresh K. How and why of orthodontic bond failures: An in vivo study. J Pharm Bioallied Sci. 2014; 6: 85-9. 2014 findings as a reference to indicate the best pretreatment to be performed or at least the one that produces the closest to values obtained in enamel. This author suggested that the appropriate bond strength values to enamel bracket be 6-8 MPa. Therefore, in the present study, all treatments produced adequate values G1 - 7.30; G2 - 6.12; G3 - 17.49; G4 - 19.54; G5 - 18.80; G6 - 21.93; G7 - 6.81 and G8 - 9.77 MPa.

According to the classification used in this study for analysis of fracture patterns, it is possible to observe that G1 and G2 presented exclusively 100% adhesive failures on ceramic/cement interface. This suggests that the bond strength between cement and ceramic was weak G1 - 7.30 MPa and G2 - 6.12 MPa, according to findings by Okuda³3. Okuda W. Predictable replacement of failing porcelain restorations. Gen Dent. 2014; 62: 21-3. 2014. Statistically similar, G7 6.81 MPa and G8 9.77MPa, also presented prevalence of adhesive failures; however, they occurred in the cement/bracket interface 93.33% and 100%, respectively, which denotes more effectiveness in the treatment of the surface. In G3 and G5, the treatment was hydrofluoric acid application and silane agent. It was observed that the bond performance was different between the ceramics: it was predominantly adhesive in ceramic/cement 60% interface in d.Sign and mixed in cement/bracket 53.33% interface in Eris. G5 and G6 were also statistically similar 18.80 and 21.93 MPa, respectively, with prevalence of mixed fails cement/bracket/ceramic, G7 60% and G8 66.66%.

Comparing the bond strength values and fracture patterns obtained in this study, it may be observed that despite the significant correlation R=0.372; p<0.0001, a tendency could be identified that the higher bond strength, the higher the fracture scores; in other words, higher quantity of fractures on the ceramic. This led the authors to believe that the higher retention created by the pre-treatment, more severe can be the structural damage, according to the findings by Grewal Bach²2. Grewal Bach GK, Torrealba Y, Lagravère MO. Orthodontic bonding to porcelain: a systematic review. Angle Orthod. 2014; 84: 555-60. 2014, Gavake et al.⁵5. Gayake PV, Chitko SS, Sutrave N, Gaikwad PM. The direct way of indirect bonding-the combined effect. Int J Orthod Milwaukee. 2013; 24: 15-7. 2013, Lung et al.⁶6. Lung CY, Liu D, Matinlinna JP. Silica coating of zirconia by silicon nitride hydrolysis on adhesion promotion of resin to zirconia. Mater Sci Eng C Mater Biol Appl. 2015; 46: 103-10. 2015, Kumar et al.²⁶26. Kumar M, Maheshwari A, Lall R, Navit P, Singh R, Navit S. Comparative evaluation of shear bond strength of recycled brackets using different methods: an in vitro study. J Int Oral Health. 2014; 6: 5-11. 2014 and Okuda³3. Okuda W. Predictable replacement of failing porcelain restorations. Gen Dent. 2014; 62: 21-3. 2014.

Further research should be done including thermal and mechanical cycling treatment as well the ideal strength to avoid the bracket displacement damage to the ceramic structure. Based on data obtained in this study, it is possible to conclude that: 1 despite the different types of surface pretreatments, the tested ceramics performed similarly in therms of bond strength; 2 the use of silane after hydrofluoric acid etching was responsible for the increase of bond strength values; 3 pretreatment of ceramic substrate by 10% hydrofluoric acid etching during 20 s followed by silane application, as well as aluminum oxide 50 ìm blasting for 15 s, followed by 35% phosphoric acid etching and silane application provided significantly higher bond strength values to metallic brackets; 4 the CoJet system did not result in significantly higher values than those observed for aluminum oxide blasting, becoming similar to the groups treated with hydrofluoric acid without silane application; 5 aluminum oxide blasting followed by phosphoric acid etching and silane presented results similar to the treatment with hydrofluoric acid and silane.

References

¹
Komori A, Takemoto K, Shimoda T, Miyashita W, Scuzzo G. Precise direct lingual bonding with the KommonBase. J Clin Orthod. 2013; 47: 42-9.
²
Grewal Bach GK, Torrealba Y, Lagravère MO. Orthodontic bonding to porcelain: a systematic review. Angle Orthod. 2014; 84: 555-60.
³
Okuda W. Predictable replacement of failing porcelain restorations. Gen Dent. 2014; 62: 21-3.
⁴
Zhang ZC, Giordano R, Shen G, Chou LL, Qian YF. Shear bond strength of an experimental composite bracket. J Orofac Orthop. 2013; 74: 319-31.
⁵
Gayake PV, Chitko SS, Sutrave N, Gaikwad PM. The direct way of indirect bonding-the combined effect. Int J Orthod Milwaukee. 2013; 24: 15-7.
⁶
Lung CY, Liu D, Matinlinna JP. Silica coating of zirconia by silicon nitride hydrolysis on adhesion promotion of resin to zirconia. Mater Sci Eng C Mater Biol Appl. 2015; 46: 103-10.
⁷
Buonocore MG. A simple method of increasing the adhesion of acrylic filling materials to enamel surfaces. J Dent Res. 1955; 34: 849-53.
⁸
Trakyali G, Malkondu O, Kazazoðlu E, Arun T. Effects of different silanes and acid concentrations on bond strength of brackets to porcelain surfaces. Eur J Orthod. 2009; 31: 402-6.
⁹
Rathke A, Tymina Y, Haller B. Effect of different surface treatments on the composite-composite repair bond strength. Clin Oral Investig. 2009; 13: 317-23.
¹⁰
Rao S, Chowdhary R. Comparison of fracture toughness of all-ceramic and metal-ceramic cement retained implant crowns: an in vitro study. J Indian Prosthodont Soc. 2014; 14: 408-14.
¹¹
Bieniaœ J, Surowska B, Stoch A, Matraszek H, Walczak M. The influence of SiO2 and SiO2-TiO2 intermediate coatings on bond strength of titanium and Ti6Al4V alloy to dental porcelain. Dent Mater. 2009; 25: 1128-35.
¹²
Valentini F, Moraes RR, Pereira-Cenci T, Boscato N. Influence of glass particle size of resin cements on bonding to glass ceramic: SEM and bond strength evaluation. Microsc Res Tech. 2014; 77: 363-7.
¹³
Geraldo-Martins VR, Lepri CP, Faraoni-Romano JJ, Palma-Dibb RG. The combined use of Er,Cr: YSGG laser and fluoride to prevent root dentin demineralization. J Appl Oral Sci. 2014; 22: 459-64.
¹⁴
Vaz RR, Hipolito VD, D'Alpino PH. Bond strength and interfacial micromorphology of etch-and-rinse and self-adhesive resin cements to dentin. J Prosthodont. 2012; 21: 101-11.
¹⁵
Kim JH, Chae S, Lee Y, Han GJ, Cho BH. Comparison of shear test methods for evaluating the bond strength of resin cement to zirconia ceramic. Acta Odontol Scand. 2014; 72: 745-52.
¹⁶
Brunharo IH, Fernandes DJ, de Miranda MS, Artese F. Influence of surface treatment on shear bond strength of orthodontic brackets. Dental Press J Orthod. 2013; 18: 54-62.
¹⁷
Denry I, Kelly JR. Emerging Ceramic-based Materials for Dentistry. J Dent Res. 2014; 93: 1235-42.
¹⁸
Kosyfaki P, Swain MV. Adhesion determination of dental porcelain to zirconia using the Schwickerath test: strength vs. fracture energy approach. Acta Biomater. 2014; 10: 4861-9.
¹⁹
Bunek SS, Swift EJ Jr. Contemporary ceramics and cements. J Esthet Restor Dent. 2014; 26: 297-301.
²⁰
Wady AF, Paleari AG, Queiroz TP, Margonar R. Repair technique for fractured implant-supported metal-ceramic restorations: a clinical report. J Oral Implantol. 2014; 40: 589-92.
²¹
Girish PV, Dinesh U, Bhat CS, Shetty PC. Comparison of shear bond strength of metal brackets bonded to porcelain surface using different surface conditioning methods: an in vitro study. J Contemp Dent Pract. 2012; 13: 487-93.
²²
Ozcan M. Surface conditioning protocol for multiple substrates in repair of cervical recessions adjacent to ceramic. J Adhes Dent. 2014; 16: 394.
²³
Passos SP, Kimpara ET, Bottino MA, Júnior GC, Rizkalla AS. Bond strength of different resin cement and ceramic shades bonded to dentin. J Adhes Dent. 2013; 15: 461-6.
²⁴
Silveira GS, Bittencourt LP, Mucha JN. Scoring of ceramic bracket bases for easier debonding. J Clin Orthod. 2014; 48: 441-2.
²⁵
Vijayakumar RK, Jagadeep R, Ahamed F, Kanna A, Suresh K. How and why of orthodontic bond failures: An in vivo study. J Pharm Bioallied Sci. 2014; 6: 85-9.
²⁶
Kumar M, Maheshwari A, Lall R, Navit P, Singh R, Navit S. Comparative evaluation of shear bond strength of recycled brackets using different methods: an in vitro study. J Int Oral Health. 2014; 6: 5-11.

Publication Dates

Publication in this collection
Jan-Mar 2015

History

Received
22 Jan 2015
Accepted
04 Mar 2015

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

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Wady AF, Paleari AG, Queiroz TP, Margonar R. Repair technique for fractured implant-supported metal-ceramic restorations: a clinical report. J Oral Implantol. 2014; 40: 589-92.

[21] ²¹
Girish PV, Dinesh U, Bhat CS, Shetty PC. Comparison of shear bond strength of metal brackets bonded to porcelain surface using different surface conditioning methods: an in vitro study. J Contemp Dent Pract. 2012; 13: 487-93.

[22] ²²
Ozcan M. Surface conditioning protocol for multiple substrates in repair of cervical recessions adjacent to ceramic. J Adhes Dent. 2014; 16: 394.

[23] ²³
Passos SP, Kimpara ET, Bottino MA, Júnior GC, Rizkalla AS. Bond strength of different resin cement and ceramic shades bonded to dentin. J Adhes Dent. 2013; 15: 461-6.

[24] ²⁴
Silveira GS, Bittencourt LP, Mucha JN. Scoring of ceramic bracket bases for easier debonding. J Clin Orthod. 2014; 48: 441-2.

[25] ²⁵
Vijayakumar RK, Jagadeep R, Ahamed F, Kanna A, Suresh K. How and why of orthodontic bond failures: An in vivo study. J Pharm Bioallied Sci. 2014; 6: 85-9.

[26] ²⁶
Kumar M, Maheshwari A, Lall R, Navit P, Singh R, Navit S. Comparative evaluation of shear bond strength of recycled brackets using different methods: an in vitro study. J Int Oral Health. 2014; 6: 5-11.

Groups	Mean (MPa)	Standard deviation
G1	7.30^a	3.5043
G2	6.12^a	3.1490
G3	17.49^b	3.9677
G4	19.54^b	4.3325
G5	18.80^b	4.9050
G6	21.93^b	4.6884
G7	6.81^a	2.4816
G8	9.77^a	4.5717

Comparisons among the groups	U	p*
G1XG2	112.500	1
G3XG4	96.000	0.460419
G5XG6	104.500	0.695646
G7XG8	105.000	0.317310

Brasil

Brasil

Shear bond strength of ceramic brackets after different pre-treatments in porcelain surface

Abstract

AIM:

METHODS:

RESULTS:

CONCLUSIONS:

Introduction

Material and methods

Results

Discussion

References

Publication Dates

History

Surface treatment	Eris Ceramic	d.Sign Ceramic
10% hydrofluoric acid	G1	G2
10% hydrofluoric acid + silane agent	G3	G4
Aluminum oxide blasting + 35% phosphoric acid + silane agent	G5	G6
CoJet blasting + 35% phosphoric acid + silane agent	G7	G8

Groups	Fracture standard (%)
Groups	Adhesive (cement/bracket)	Adhesive (ceramic/cement)	Mixed (cement/bracket)	Mixed (cement/bracket/ ceramic)
G1	0	100	0	0
G2	0	100	0	0
G3	46.66	0	53.33	0
G4	0	60	40	0
G5	33.33	0	6.66	60
G6	26.66	0	6.66	66.66
G7	93.33	0	6.66	0
G8	100	0	0	0