Shear bond strength of the ceramic veneer to additively manufactured titanium.
dental alloys
dental porcelain
dental prosthesis
titanium
Journal
Clinical and experimental dental research
ISSN: 2057-4347
Titre abrégé: Clin Exp Dent Res
Pays: United States
ID NLM: 101692332
Informations de publication
Date de publication:
03 Dec 2023
03 Dec 2023
Historique:
revised:
07
11
2023
received:
27
10
2023
accepted:
15
11
2023
medline:
4
12
2023
pubmed:
4
12
2023
entrez:
4
12
2023
Statut:
aheadofprint
Résumé
The objective of this in vitro study was to evaluate the shear bond strength between the ceramic veneer and additively manufactured titanium with different surface treatments, and to compare with milled titanium. Also, to characterize the surface and the presence of an α-case layer of additively manufactured and milled titanium. Sixty additively manufactured titanium grade 23, and 20 milled titanium grade 4 cylindrical specimens were divided into four groups based on surface treatments, air-particle abrasion and grinding. After ceramic veneering half of each group were thermocycled. The bond strength was analyzed using a shear bond strength test. The surfaces were analyzed using interferometry and scanning electron microscopy. The grinding procedure and air-particle abrading pressure had no significant effect on the shear bond strength (p = .264 and p = .344). Thermocycling showed a tendency towards an effect but not significant (p = .052). The group with the highest air-abrading pressure showed the highest surface roughness. No presence of an α-case layer was detected in any of the groups. Additively manufactured titanium grade 23 may be veneered with ceramics without prior grinding of the surfaces.
Types de publication
Journal Article
Langues
eng
Sous-ensembles de citation
IM
Subventions
Organisme : Dentsply Sirona
ID : I-IS-17-025
Organisme : Stiftelserna Wilhelm och Martina Lundgrens
ID : 2017-1616
Informations de copyright
© 2023 The Authors. Clinical and Experimental Dental Research published by John Wiley & Sons Ltd.
Références
Adachi, M., Mackert, Jr, J. R., Parry, E. E., & Fairhurst, C. W. (1990). Oxide adherence and porcelain bonding to titanium and Ti-6A1-4V alloy. Journal of Dental Research, 69(6), 1230-1235.
Al Hussaini, I., & Al Wazzan, K. A. (2005). Effect of surface treatment on bond strength of low-fusing porcelain to commercially pure titanium. The Journal of Prosthetic Dentistry, 94(4), 350-356.
Andersson, M., Carlsson, L., Persson, M., & Bergman, B. (1996). Accuracy of machine milling and spark erosion with a CAD/CAM system. The Journal of Prosthetic Dentistry, 76(2), 187-193.
Attanasio, A., Gelfi, M., Pola, A., Ceretti, E., & Giardini, C. (2013). Influence of material microstructures in micromilling of Ti6Al4V alloy. Materials, 6(9), 4268-4283.
Chan, K. S., Koike, M., Johnson, B. W., & Okabe, T. (2008). Modeling of alpha-case formation and its effects on the mechanical properties of titanium alloy castings. Metallurgical and materials transactions A, 39(1), 171-180.
Golebiowski, M., Wolowiec, E., & Klimek, L. (2015). Airborne-particle abrasion parameters on the quality of titanium-ceramic bonds. The Journal of Prosthetic Dentistry, 113(5), 453-459.
Guilin, Y., Nan, L., Yousheng, L., & Yining, W. (2007). The effects of different types of investments on the alpha-case layer of titanium castings. The Journal of Prosthetic Dentistry, 97(3), 157-164.
Hey, J., Beuer, F., Bensel, T., & Boeckler, A. F. (2014). Single crowns with CAD/CAM-fabricated copings from titanium: 6-year clinical results. The Journal of Prosthetic Dentistry, 112(2), 150-154.
Iseri, U., ÖZkurt, Z., & Kazazoglu, E. (2011). Shear bond strengths of veneering porcelain to cast, machined and laser-sintered titanium. Dental Materials Journal, 30(3), 274-280.
ISO. (2012). ISO Standard 9693-1. Dentistry-compatibility testing-Part 1: Metal-ceramic systems. International Organization for Standardization.
Kang, L., & Yang, C. (2019). A review on high-strength titanium alloys: Microstructure, strengthening, and properties. Advanced Engineering Materials, 21(8), 1801359.
Kasemo, B. (1983). Biocompatibility of titanium implants: Surface science aspects. The Journal of Prosthetic Dentistry, 49(6), 832-837.
Kasemo BL, J. (1985). Metal selection and surface characteristics. In P.-I. Z. G. A. Brånemark & T. Albrektsson (Eds.), Tissue-integrated prostheses (pp. 99-116). Quintessence Publishing Co., Inc.
Kaus, T., Pröbster, L., & Weber, H. (1996). Clinical follow-up study of ceramic veneered titanium restorations-Three-year results. The International Journal of Prosthodontics, 9(1), 9-15.
Lin, M. C., & Huang, H. H. (2014). Improvement in dental porcelain bonding to milled, noncast titanium surfaces by gold sputter coating. Journal of Prosthodontics, 23(7), 540-548.
Milleding, P., Haag, P., Neroth, B., & Renz, I. (1998). Two years of clinical experience with Procera titanium crowns. The International Journal of Prosthodontics, 11(3), 224-232.
Mohsen, C. A. (2012). Effect of surface roughness and thermal cycling on bond strength of C.P. titanium and Ti-6Al-4V alloy to ceramic. Journal of Prosthodontic Research, 56(3), 204-209.
Muiruri, A., Maringa, M., & du Preez, W. (2020). Crystallographic texture analysis of as-built and heat-treated Ti6Al4V (Eli) produced by direct metal laser sintering. Crystals, 10(8), 699.
Murr, L. E., Quinones, S. A., Gaytan, S. M., Lopez, M. I., Rodela, A., Martinez, E. Y., Hernandez, D. H., Martinez, E., Medina, F., & Wicker, R. B. (2009). Microstructure and mechanical behavior of Ti-6Al-4V produced by rapid-layer manufacturing, for biomedical applications. Journal of the Mechanical Behavior of Biomedical Materials, 2(1), 20-32.
Nilson, H., Bergman, B., Bessing, C., Lundqvist, P., & Andersson, M. (1994). Titanium copings veneered with Procera ceramics: A longitudinal clinical study. The International Journal of Prosthodontics, 7(2), 115-119.
Özcan, I., & Uysal, H. (2005). Effects of silicon coating on bond strength of two different titanium ceramic to titanium. Dental Materials, 21(8), 773-779.
Papia, E., Arnoldsson, P., Baudinova, A., Jimbo, R., & von Steyern, P. V. (2017). Cast, milled and EBM-manufactured titanium, differences in porcelain shear bond strength. Dental Materials Journal, 37(2), 214-221.
Park, S., Kim, Y., Lim, H., Oh, G., Kim, H., Ong, J. L., & Lee, K. (2009). Gold and titanium nitride coatings on cast and machined commercially pure titanium to improve titanium-porcelain adhesion. Surface and Coatings Technology, 203(20), 3243-3249.
Reyes, M. J., Oshida, Y., Andres, C. J., Barco, T., Hovijitra, S., & Brown, D. (2001). Titanium-porcelain system. Part III: Effects of surface modification on bond strengths. Bio-Medical Materials and Engineering, 11(2), 117-136.
Sendão, I. A., Alves, A. C., Galo, R., Toptan, F., Silva, F. S., & Ariza, E. (2015). The effect of thermal cycling on the shear bond strength of porcelain/Ti-6Al-4V interfaces. Journal of the Mechanical Behavior of Biomedical Materials, 44, 156-163.
Shen, C. (2013). Dental casting alloys and metal joining. In K. J. S. Anusavice & H. R. C. Rawls (Eds.), Phillips' science of dental materials 12 (pp. 376-377). Saunders.
Solomon, M. (1980). Surface roughness and porcelain bond. Quintessence of Dental Technology, 4(9), 65-70.
Svanborg, P., Eliasson, A., & Stenport, V. (2018). Additively manufactured titanium and Cobalt-Chromium implant frameworks: Fit and effect of ceramic veneering. The International Journal of Oral & Maxillofacial Implants, 33(3), 590-596.
Taira, M., Nomura, Y., Wakasa, K., Yamaki, M., & Matsui, A. (1990). Studies on fracture toughness of dental ceramics. Journal of Oral Rehabilitation, 17(6), 551-563.
Tholey, M. J., Waddell, J. N., & Swain, M. V. (2007). Influence of the bonder on the adhesion of porcelain to machined titanium as determined by the strain energy release rate. Dental Materials, 23(7), 822-828.
Tróia, M. G., Henriques, G. E. P., Nóbilo, M. A. A., & Mesquita, M. F. (2003). The effect of thermal cycling on the bond strength of low-fusing porcelain to commercially pure titanium and titanium-aluminium-vanadium alloy. Dental Materials, 19(8), 790-796.
Vásquez, V. Z. C., Özcan, M., & Kimpara, E. T. (2009). Evaluation of interface characterization and adhesion of glass ceramics to commercially pure titanium and gold alloy after thermal- and mechanical-loading. Dental Materials, 25(2), 221-231.
Wennerberg, A., & Albrektsson, T. (2000). Suggested guidelines for the topographic evaluation of implant surfaces. The International Journal of Oral & Maxillofacial Implants, 15(3), 331-344.
Wysocki, B., Maj, P., Krawczyńska, A., Rożniatowski, K., Zdunek, J., Kurzydłowski, K. J., & Święszkowski, W. (2017). Microstructure and mechanical properties investigation of CP titanium processed by selective laser melting (SLM). Journal of Materials Processing Technology, 241, 13-23.
Xiao, L., Song, W., Hu, M., & Li, P. (2019). Compressive properties and micro-structural characteristics of Ti-6Al-4V fabricated by electron beam melting and selective laser melting. Materials Science and Engineering: A, 764, 138204.
Zhao, C. Q., Wu, S. Q., Lu, Y. J., Gan, Y. L., Guo, S., Lin, J. J., Huang, T. T., & Lin, J. X. (2016). Evaluation to the effect of B2O3-La2O3-SrO-Na2O-Al2O3 bonding agent on Ti6Al4V-porcelain bonding. Journal of the Mechanical Behavior of Biomedical Materials, 63, 75-85.