A novel etching technique for surface treatment of zirconia ceramics to improve adhesion of resin-based luting cements

Eystein Ivar Ruyter, Nalini Vajeeston, Torbjørn Knarvang, Ketil Kvam, Eystein Ivar Ruyter, Nalini Vajeeston, Torbjørn Knarvang, Ketil Kvam

Abstract

Objectives: Bonding of zirconia crowns and bridges to abutments is important, not only bonding of the thin resin layer to the abutment, but also bonding to the zirconia ceramic is crucial. Both mechanical and chemical adhesion are desired. Mechanical retention of dental porcelain achieved by etching with moderately concentrated hydrofluoric acid is not possible with zirconia ceramics. The purpose of this study was to show that etching is possible with relative low melting fluoride compounds such as ammonium hydrogen difluoride and potassium hydrogen difluoride. Materials and methods: Before melting, the fluorides can be introduced as powders or as aqueous slurries to the contact surfaces of the zirconia. After melting, the yttria-stabilized zirconia surface revealed a surface similar to an HF-etched dental feldspathic porcelain surface. Shear bond testing (n = 10) was performed with zirconia attached to zirconia with the Duo-Link composite luting cement (Bisco) after treatment of the etched zirconia surfaces with Bis-Silane (Bisco) and the Porcelain Bonding Resin (Bisco). Results: Values for adhesive strength (mean ± standard deviation) after melt etching of the surfaces with initially dry powders were for K[FHF], (31.2 ± 7.5) MPa and for NH4[FHF] (31.0 ± 11.8) MPa. When initially aqueous slurries were applied, the values were for K[FHF] (42.7 ± 12.7) MPa and for NH4[FHF] (40.3 ± 10.0) MPa. Conclusion: Good adhesion to zirconia can be achieved by a procedure including etching with selected melted fluoride compounds.

Keywords: Difluoride melt etching; FTIR spectroscopy; SEM; XRD analysis.

Figures

Figure 1.
Figure 1.
Schematic view of etching process. Diffusion of active etching agents in the melt and to the solid zirconia surface with simultaneous diffusion of etching products, fluorozirconates, from the zirconia surface and into the melt.
Figure 2.
Figure 2.
Schematic illustration of combination of materials (zirconia bonded to zirconia ceramic).
Figure 3.
Figure 3.
SEM images of the zirconia disc specimens (reference) after different surface treatments (a) Sandblasted; (b) K[FHF] powder, etched; (c) K[FHF] slurry, etched; (d) NH4[FHF] powder etched; (e) NH4[FHF] slurry etched.
Figure 4.
Figure 4.
SEM images of the zirconia disc specimens after shear bond measurements (a) EKPS (b) EKPU and (c) EKSU.
Figure 5.
Figure 5.
SEM images of the fracture surfaces of zirconia disc and rod specimens after shear bond testing measurements. Light areas are thin layers and darker areas are thicker layers of bonding resin cement. (a) SBS zirconia disc, contact area at the upper part; (b) SBS zirconia rod, contact area at the upper part; (c) EASS zirconia disc, contact area; (d) EASS zirconia rod, contact area.
Figure 6.
Figure 6.
Rietveld fit to XRD data for Y-TZP specimens after different surface treatments. (a) Polished; (b) Sandblasted; (c) K[FHF] slurry etched; (d) NH4[FHF] slurry etched. Upper plots showing observed and calculated intensities, lower plot shows the difference for the samples. *Monoclinic peak.
Figure 7.
Figure 7.
FT-IR spectra of (a) etched surface product and (b) K2[ZrF6] in the region 510–460 cm−1. The figures on the absorption peaks represent wavenumbers and peak areas.
Figure 8.
Figure 8.
FT-IR spectra for (a) etched surface product and (b) K2[ZrF6] in the region 500–200 cm−1.

References

    1. Papia E, Larsson C, du Toit M, et al. . Bonding between oxide ceramics and adhesive cement systems: a systematic review. J Biomed Mater Res Part B Appl Biomater. 2014;102:395–413.
    1. Chen L, Suh BI.. Bonding of resin materials to all-ceramics: a review. Curr Res Dent. 2012;3:7–17.
    1. Wegner SM, Gerdes W, Kern M.. Effect of different artificial aging conditions on ceramic-composite bond strength. Int J Prosthodont. 2002;15:267–272.
    1. Yang B, Barloi A, Kern M.. Influence of air-abrasion on zirconia ceramic bonding using an adhesive composite resin. Dent Mater. 2010;26:44–50.
    1. Denry IL. Recent advances in ceramics for dentistry. Crit Rev Oral Biol Med. 1996;7:134–143.
    1. Derand T, Molin M, Kvam K.. Bond strength of composite luting cement to zirconia ceramic surfaces. Dent Mater. 2005;21:1158–1162.
    1. Sriamporn T, Thamrongananskul N, Busabok C, et al. . Dental zirconia can be etched by hydrofluoric acid. Dent Mater J. 2014;33:79–85.
    1. Aboushelib MN, Kleverlaan CJ, Feilzer AJ.. Selective infiltration-etching technique for a strong and durable bond of resin cements to zirconia-based materials. J Prosthet Dent. 2007;98:379–388.
    1. Aboushelib MN, Matinlinna JP, Salameh Z, et al. . Innovations in bonding to zirconia-based materials: Part I. Dent Mater. 2008;24:1268–1272.
    1. Aboushelib MN, Mirmohamadi H, Matinlinna JP, et al. . Innovations in bonding to zirconia-based materials. Part II: focusing on chemical interactions. Dent Mater. 2009;25:989–993.
    1. Aboushelib MN, Feilzer AJ, Kleverlaan CJ.. Bonding to zirconia using a new surface treatment. J Prosthodont. 2010;19:340–346.
    1. Grigore A, Spallek S, Petschelt A, et al. . Microstructure of veneered zirconia after surface treatments: a TEM study. Dent Mater. 2013;29:1098–1107.
    1. Wang H, Aboushelib MN, Feilzer AJ.. Strength influencing variables on CAD/CAM zirconia frameworks. Dent Mater. 2008;24:633–638.
    1. Aboushelib MN, Wang H.. Influence of crystal structure on debonding failure of zirconia veneered restorations. Dent Mater. 2013;29:e97–e102.
    1. Aboushelib MN. Low energy surface activation of zirconia based restorations. Eur J Prosthodont Restor Dent. 2016;24:3–9.
    1. Kern M, Wegner SM.. Bonding to zirconia ceramic: adhesion methods and their durability. Dent Mater. 1998;14:64–71.
    1. Piascik JR, Swift EJ, Braswell K, et al. . Surface fluorination of zirconia: adhesive bond strength comparison to commercial primers. Dent Mater. 2012;28:604–608.
    1. Piascik JR, Wolter SD, Stoner BR.. Development of a novel surface modification for improved bonding to zirconia. Dent Mater. 2011;27:e99–105.
    1. Cotton FA, Wilkinson G, Murillo CA, Bochmann M, The elements of the second and third transition series Advanced inorganic chemistry. New York: John Wiley and Sons; 1999. p. 878–885.
    1. CRC Handbook of chemistry and physics, 88th ed. Boca Raton, FL: CRC press: 2007.
    1. Ibers JA. Refinement of Peterson and Levy neutron diffraction data on KHF2. J Chem Phys. 1964;40:402–404.
    1. Rietveld HM. A profile refinement method for nuclear and magnetic structures. J Appl Crystallogr. 1969;2:65–71.
    1. Young RA, The Rietveld method. Oxford: Oxford University Press & International Union of Crystallography; 1993.
    1. Coelho AA, TOPAS User Manual: Bruker AXS GmbH; Karlsruhe, Germany; 2003.
    1. Balzar D, Voigt function model in diffraction-line broadening analysis In: Microstructure analysis from diffraction. Oxford: Oxford University Press; 1999.
    1. Dentistry-Polymer-Based Crown and Bridge Materials, ISO 10477:2004; International Organization for Standardization (ISO) 2004.
    1. Srinivasan R, De Angelis RJ, Ice G, et al. . Identification of tetragonal and cubic structures of zirconia using synchrotron x-radiation source. J Mater Res. 1991;6:1287–1292.
    1. Ruyter IE. The chemistry of adhesive agents. Oper Dent. 1992;32–43.
    1. Mack H, Silane oligomers: a class of their own In: Mittal K, editor. Silanes and other coupling agents. 3. 1 ed. Utrecht: Boston; 2004. p. 11–20.
    1. Su N, Yue L, Liao Y, et al. . The effect of various sandblasting conditions on surface changes of dental zirconia and shear bond strength between zirconia core and indirect composite resin. J Adv Prosthodont. 2015;7:214–223.
    1. Oliveira-Ogliari A, Vasconcelos CS, Bruschi RC, et al. . Thermal silicatization: a new approach for bonding to zirconia ceramics. Int J Adhes Adhes. 2014;48:164–167.
    1. Kosmač T, Oblak Č, Marion L.. The effects of dental grinding and sandblasting on ageing and fatigue behavior of dental zirconia (Y-TZP) ceramics. J Eur Ceram Soc. 2008;28:1085–1090.
    1. Tiller HJ, Magnus B, Gobel R, et al. . Der sandstrstrahlprozess und seine einwirkung auf den oberflächenzustand von dentallegierungen (I) [sand-blasting process and its use in surface conditioning of dental alloys (I)]. Quintessenz. 1985;36:1927–1934.
    1. Lohbauer U, Zipperle M, Rischka K, et al. . Hydroxylation of dental zirconia surfaces: characterization and bonding potential. J Biomed Mater Res Part B Appl Biomater. 2008;87:461–467.
    1. Kirkpatrick JJ, Enion DS, Burd DA.. Hydrofluoric acid burns: a review. Burns. 1995;21:483–493.
    1. Forrest IW, Lane AP.. Single-crystal polarized infrared and Raman-spectra and normal-coordinate analysis of some group 4 complex hexafluorometalates. Inorg Chem. 1976;15:265–269.
    1. Toth LM, Bates JB.. Vibrational spectra of crystalline Li2ZrF6 and Cs2ZrF6 . Spestrochim Acta. 1974;30A:1095–1104.
    1. Lane AP, Sharp DWA.. Infrared and raman spectra of some group IV complex hexafluorometallates. J Chem Soc A. 1969;2942–2945.
    1. Hoppe R, Mehlhorn B.. Crystal structure of K2ZrF6 . Z Anorg Allg Chem. 1976;425:200–208.
    1. Voit EI, Didenko NA, Galkin KN.. Vibrational spectra of zirconium fluoride complexes with different structures of anionic sublattice. Opt Spectrosc. 2015;118:114–124.
    1. Agulyanskii AI, Zalkind OA, Masloboev VA.. Influence of temperature on IR spectra of fluoride complexes of group IV and V elements. Zhurnal Prikladnoi Spektroskopii 1981;39:960–964.

Source: PubMed

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