Use of preheated resin as a cementitious material in indirect restoration: A literature review

Authors

DOI:

https://doi.org/10.33448/rsd-v10i7.16293

Keywords:

Thermoactivated resin; Temperature; Dental veneers.

Abstract

Due to the great aesthetic appeal over the years associated with minimally invasive techniques, contemporary dentistry bets on materials with excellent aesthetic and mechanical characteristics, so dentists seek to bet on the use of pre-heating of composite resins as a cementitious material for restorations indirect, since its optical and mechanical properties propose a better aesthetic and a better marginal adaptation compared to resin cements. The objective of this work is to review the literature about the optical and mechanical characteristics of the different materials used as cementing agents in indirect restorations, emphasizing long-term color stability, marginal adaptation, toxicity, degree of conversion of monomers and clinical practicality. For this purpose, an electronic search was performed in the Online Medical Literature Search and Analysis database (PubMed), using the following descriptors in English: thermoactivated resin, temperature and dental veneers, registered in the Mesh (Medical Subject Headings) combined between itself by the Boolean operator “AND”. After delimiting the search for 10 years, 50 articles were found. Of these, 13 studies were selected, based on the reading of titles and abstracts. In short, preheated resins have excellent mechanical and optical characteristics, however it is up to the dentist to choose which technique is most feasible in his clinical practice.

References

Alikhasi, M., Monzavi, A., Ebrahimi, H., Pirmoradian, M., Shamshiri, A., & Ghazanfari, R. (2019). Debonding Time and Dental Pulp Temperature With the Er, Cr: YSGG Laser for Debonding Feldespathic and Lithium Disilicate Veneers. J Lasers Med Sci, 10(3), 211-214.

Azer, S. S., Rosenstiel, S. F., Seghi, R. R., & Johnston, W. M. (2011). Effect of substrate shades on the color of ceramic laminate veneers. J Prosthet Dent, 106(3), 179-83.

Calheiros, F. C., Daronch, M., Rueggeberg, F. A., & Braga, R. R. (2014). Effect of temperature on composite polymerization stress and degree of conversion. Dent Mater, 30(6), 613-8.

Coelho, N. F., Barbon, F. J., Machado, R. G., Boscato, N., & Moraes, R. R. (2019). Response of composite resins to preheating and the resulting strengthening of luted feldspar ceramic. Dent Mater, 35(10),1430-1438.

Chaharom, M. E., Bahari, M., Safyari, L., Safarvand, H., Shafaei, H., Navimipour J. E., Oskoee A. P., Ajami, A. A., & Kahnamouei, A. M. (2020). Effect of preheating on the cytotoxicity of bulk-fill composite resins. J Dent Res Dent Clin Dent Prospects, 14(1), 19-25.

Deb, S., Di Silvio, L., Mackler, H. E., & Millar, B. J. (2011). Pre-warming of dental composites. Dent Mater, 27(4), 51-9.

Demirbuga, S., Ucar, F. I., Cayabatmaz, M., Zorba, Y. O., Cantekin, K., Topçuoğlu, H. S., & Kilinc, H. I. (2016). Microshear bond strength of preheated silorane- and methacrylate-based composite resins to dentin. Scanning, 38(1), 63-9.

El-Korashy, D. I. (2010). Post-gel shrinkage strain and degree of conversion of preheated resin composite cured using different regimens. Oper Dent, 35(2), 172-9.

Karacolak, G., Turkun, L.S., Boyacioglu, H., & Ferracane, J, L. (2018). Influence of increment thickness on radiant energy and microhardness of bulk-fill resin composites. Dent Mater J, 37(2), 206-213.

Knežević, A., Želježić, D., Kopjar, N., Duarte, S. J., & Tarle, Z. (2018). In Vitro Biocompatibility of Preheated Giomer and Microfilled-Hybrid Composite. Acta Stomatol Croat, 52(4), 286-297.

Lempel, E., Őri, Z., Szalma, J., Lovász, B.V., Kiss, A., Tóth, Á., & Kunsági-Máté, S. (2019). Effect of exposure time and pre-heating on the conversion degree of conventional, bulk-fill, fiber reinforced and polyacid-modified resin composites. Dent Mater, 35(2), 217-228.

Lima, M. O., Catelan, A., Marchi, G. M., Lima, D. A., Martins, L. R., & Aguiar, F. H. (2018). Influence of pre-heating and ceramic thickness on physical properties of luting agents. J Appl Biomater Funct Mater, 16(4), 252-259.

Lührs, A. K., De Munck, J., Geurtsen, W., & Meerbeek, B. V. (2014). Composite cements benefit from light-curing. Dent Mater, 30(3), 292-301.

Magne, P., Paranhos, M. P., Burnett, L. H. J., Magne, M., & Belser, U. C. (2011). Fatigue resistance and failure mode of novel-design anterior single-tooth implant restorations: influence of material selection for type III veneers bonded to zirconia abutments. Clin Oral Implants Res, 22(2), 195-200.

Mathias, C., Vitória, L. A., Gomes, R. S., Cavalcanti, A. N., & Mathias, P. (2017). Influence of Ceramic Laminate Veneer Thickness on Sorption and Solubility of Light-Cured Resin Ce-ment. Int J Dentistry Oral Sci, 4(2), 422-426.

Mohammadi, N., Jafari-Navimipour, E., Kimyai, S., Ajami, A. A, Bahari, M., Ansarin, M., & Ansarin, M. (2016). Efeito do pré-aquecimento nas propriedades mecânicas de compósitos à base de silorano e metacrilato. Journal of clinic and experimental dentistry, 8 (4), 373-378.

Oskoee, P. A., Azar, F. P., & Navimipour, E. J. (2017). The effect of repeated preheating of dimethacrylate and silorane-based composite resins on marginal gap of class V restorations. Journal of dental research, dental clinics, dental prospects, 11(1), 36-42.

Pereira, A. S., Shitsuka, Do. M., Parreira, F. J., & Shitsuka, R. (2018). Metodologia da Pesquisa Científica-Licenciatura em Computação. Santa Maria.

Rathke, A., Hokenmaier, G., Muche, R., & Haller, B. (2012). Effectiveness of the bond established between ceramic inlays and dentin using different luting protocols. Journal of Adhesive Dentistry, 14(2), 147-154.

Fróes-Salgado, N. R., Silva, L. M., Kawano, Y., Francci, C., Reis, A., & Loguercio, A. D. (2010). Composite pre-heating: effects on marginal adaptation, degree of conversion and mechanical properties. Dental materials, 26(9), 908-914.

Tauböck, T. T., Tarle, Z., Marovic, D., & Attin, T. (2015). Pre-heating of high-viscosity bulk-fill resin composites: effects on shrinkage force and monomer conversion. Journal of dentistry, 43(11), 1358-1364.

Tomaselli, L. D. O., Oliveira, D. C. R. S. D., Favarão, J., Silva, A. F. D., Pires-de-Souza, F. D. C. P., Geraldeli, S., & Sinhoreti, M. A. C. (2019). Influence of pre-heating regular resin composites and flowable composites on luting ceramic veneers with different thicknesses. Brazilian dental journal, 30(5), 459-466.

Yang, J., Silikas, N., & Watts, D. C. (2019). Pre-heating effects on extrusion force, stickiness and packability of resin-based composite. Dental Materials, 35(11), 1594-1602.

Published

12/06/2021

How to Cite

TEIXEIRA, J. P. S.; CAVALCANTE , S. K. da S. .; RONCOLATO, Álvaro T. L.; MENDES, T. A. D. .; PINTO, A. C. M. D. .; BRITO, R. de S. .; FONTES, N. M. .; SILVA, . R. A. D. A. da; ISAIAS , P. H. C. .; DINELLY, Érika M. P. . Use of preheated resin as a cementitious material in indirect restoration: A literature review. Research, Society and Development, [S. l.], v. 10, n. 7, p. e2810716293, 2021. DOI: 10.33448/rsd-v10i7.16293. Disponível em: https://rsdjournal.org/index.php/rsd/article/view/16293. Acesso em: 14 nov. 2024.

Issue

Section

Review Article