Influence of the adhesive bonding protocol on the inflammatory cellular response and gelatinolytic activity in human teeth

Manuella Uilmann Silva da Costa  Soares; Laís Maciel  Costa; Leorik Pereira da  Silva; Isabelle Lins Macêdo de Oliveira; Márcia Maria Fonseca da  Silveira; Ana Paula Veras Sobral

doi:10.33448/rsd-v10i9.18552

Autores/as

Manuella Uilmann Silva da Costa Soares Universidade Federal de Campina Grande https://orcid.org/0000-0002-8167-5426
Laís Maciel Costa Universidade de Pernambuco https://orcid.org/0000-0003-3880-1914
Leorik Pereira da Silva Universidade Federal de Campina Grande https://orcid.org/0000-0003-1890-8415
Isabelle Lins Macêdo de Oliveira Universidade de Pernambuco https://orcid.org/0000-0003-1660-3482
Márcia Maria Fonseca da Silveira Universidade de Pernambuco https://orcid.org/0000-0002-2611-5661
Ana Paula Veras Sobral Universidade de Pernambuco https://orcid.org/0000-0002-0801-9385

DOI:

https://doi.org/10.33448/rsd-v10i9.18552

Palabras clave:

Dentina; Metaloproteinasa 9 de la Matriz; Recubrimientos Dentinarios.

Resumen

El objetivo de este trabajo fue evaluar la biocompatibilidad y expresión de la metaloproteinasa -9 de dos agentes adhesivos de dentina en dientes humanos, utilizando diferentes métodos de pretratamiento de dentina y diferentes intervalos de tiempo. Se prepararon cavidades profundas de clase I en la superficie oclusal de 18 molares sanos. Las restauraciones se realizaron con XP Bond ™ (Dentsply) y Futurabond® DC (VOCO). Después de 30, 90 o 120 días, los dientes fueron extraídos y procesados para evaluación histológica e inmunohistoquímica. En el grupo XP Bond, se observó un infiltrado inflamatorio moderado e inmunorreactividad de metaloproteinasa -9 en todos los intervalos de almacenamiento. En el grupo Futurabond DC se encontró un leve infiltrado inflamatorio en los primeros intervalos. Después de 120 días, el infiltrado inflamatorio era leve o ausente, mientras que la morfología del tejido permanecía normal. La inmunorreactividad de la metaloproteinasa -9 se consideró moderada, a excepción de dos muestras después de 120 días, que no demostraron inmunorreactividad. Por lo tanto, los adhesivos de grabado y enjuague exhibieron una respuesta pulpar más intensa que los agentes de autograbado. Al realizar restauraciones adhesivas en cavidades medias y profundas en dientes humanos, se debe considerar el uso de una estrategia adhesiva de autograbado en vista de la menor inducción de actividad inflamatoria y proteolítica. Se deben realizar más estudios de los eventos moleculares, teniendo en cuenta las posibles reacciones inflamatorias de la pulpa que pueden contribuir al éxito de los procedimientos de restauración.

Citas

Accorsi-Mendonça, T., Silva, E. J. N. L., Marcaccini, A. M., Gerlach, R. F., Duarte, K. M. R., Pardo, A. P. S., ... & Zaia, A. A. (2013). Evaluation of gelatinases, tissue inhibitor of matrix metalloproteinase-2, and myeloperoxidase protein in healthy and inflamed human dental pulp tissue. Journal of endodontics, 39(7), 879-882.

Alves, G. C., & Sobral, A. P. V. (2015). Evaluation of biocompatibility of an etch-and-rinse adhesive system based in tertiary butanol applied in deep cavity. The open dentistry journal, 9, 168.

Arrais, C. A. G., & Giannini, M. (2002). Morphology and thickness of the diffusion of resin through demineralized or unconditioned dentinal matrix. Pesquisa Odontológica Brasileira, 16(2), 115-120.

Bagis, B., Atilla, P., Cakar, N., & Hasanreisoglu, U. (2007). Immunohistochemical evaluation of endothelial cell adhesion molecules in human dental pulp: effects of tooth preparation and adhesive application. Archives of oral biology, 52(8), 705-711.

Ballal, V., Rao, S., Bagheri, A., Bhat, V., Attin, T., & Zehnder, M. (2017). MMP-9 in dentinal fluid correlates with caries lesion depth. Caries research, 51(5), 460-465.

Bianchi, L., Ribeiro, A. P. D., de Oliveira Carrilho, M. R., Pashley, D. H., de Souza Costa, C. A., & Hebling, J. (2013). Transdentinal cytotoxicity of experimental adhesive systems of different hydrophilicity applied to ethanol-saturated dentin. Dental Materials, 29(9), 980-990.

Boelen, G. J., Boute, L., d’Hoop, J., EzEldeen, M., Lambrichts, I., & Opdenakker, G. (2019). Matrix metalloproteinases and inhibitors in dentistry. Clinical oral investigations, 23(7), 2823-2835.

Büyükgüral, B., & Cehreli, Z. C. (2008). Effect of different adhesive protocols vs calcium hydroxide on primary tooth pulp with different remaining dentin thicknesses: 24-month results. Clinical Oral Investigations, 12(1), 91-96.

Costa, L. M., Rizuto, A. V., Mendonça, L. S. de, Carvalho, M. V., Silveira, M. M. F., Sobral, A. P. V. (2021). Immunoxpression of MMPs -9, -13 and TIMP-3 after Using Etch-and-rinse Adhesive. Research, Society and Development, 10(9), e14010917315.

da Silva, J. M., Rodrigues, J. R., Camargo, C. H., Fernandes, V. V. B., Hiller, K. A., Schweikl, H., & Schmalz, G. (2014). Effectiveness and biological compatibility of different generations of dentin adhesives. Clinical Oral Investigations, 18(2), 607-613.

De Munck, J., Van den Steen, P. E., Mine, A., Van Landuyt, K. L., Poitevin, A., Opdenakker, G., & Van Meerbeek, B. (2009). Inhibition of enzymatic degradation of adhesive-dentin interfaces. Journal of dental research, 88(12), 1101-1106.

de Souza Costa, C. A., Hebling, J., & Randall, R. C. (2006). Human pulp response to resin cements used to bond inlay restorations. Dental Materials, 22(10), 954-962.

de Souza Costa, C. A., Hebling, J., Scheffel, D. L., Soares, D. G., Basso, F. G., & Ribeiro, A. P. D. (2014). Methods to evaluate and strategies to improve the biocompatibility of dental materials and operative techniques. Dental Materials, 30(7), 769-784.

Elias, S. T., Santos, A. F. D., Garcia, F. C., Pereira, P. N., Hilgert, L. A., Fonseca-Bazzo, Y. M., ... & Ribeiro, A. P. D. (2015). Cytotoxicity of universal, self-etching and etch-and-rinse adhesive systems according to the polymerization time. Brazilian dental journal, 26, 160-168.

Ferracane, J. L., Cooper, P. R., & Smith, A. J. (2010). Can interaction of materials with the dentin-pulp complex contribute to dentin regeneration?. Odontology, 98(1), 2-14.

Gusman, H., Santana, R. B., & Zehnder, M. (2002). Matrix metalloproteinase levels and gelatinolytic activity in clinically healthy and inflamed human dental pulps. European journal of oral sciences, 110(5), 353-357.

Hashimoto, M., Ito, S., Tay, F. R., Svizero, N. R., Sano, H., Kaga, M., & Pashley, D. H. (2004). Fluid movement across the resin-dentin interface during and after bonding. Journal of Dental Research, 83(11), 843-848.

Hebling, J., Giro, E. M. A., & de Souza Costa, C. A. (1999). Biocompatibility of an adhesive system applied to exposed human dental pulp. Journal of Endodontics, 25(10), 676-682.

Hebling, J., Pashley, D. H., Tjäderhane, L., & Tay, F. R. (2005). Chlorhexidine arrests subclinical degradation of dentin hybrid layers in vivo. Journal of dental research, 84(8), 741-746.

Hebling, J., Ribeiro, A. P. D., & Costa, C. A. S. (2010). Relationship between dental materials and the dentin-pulp complex. Rev Odontol Bras Central, 18(48), 1-9.

Huang, F. M., & Chang, Y. C. (2002). Cytotoxicity of resin-based restorative materials on human pulp cell cultures. Oral Surgery, Oral Medicine, Oral Pathology, Oral Radiology, and Endodontology, 94(3), 361-365.

Kostoryz, E. L., Eick, J. D., Glaros, A. G., Judy, B. M., Welshons, W. V., Burmaster, S., & Yourtee, D. M. (2003). Biocompatibility of hydroxylated metabolites of BISGMA and BFDGE. Journal of dental research, 82(5), 367-371.

Leonardi, D. P., Giovanini, A. F., Almeida, S., Schramm, C. A., & Baratto-Filho, F. (2011). Pulp and periapical pathologies. RSBO (Online), 8(4), 47-61.

Lovász, B. V., Lempel, E., Szalma, J., Sétáló, G., Vecsernyés, M., & Berta, G. (2021). Influence of TEGDMA monomer on MMP-2, MMP-8, and MMP-9 production and collagenase activity in pulp cells. Clinical Oral Investigations, 25(4), 2269-2279.

Machado, N. P., Moysés, M. R., Pereira, A. A. C., Pereira, L. J., Ribeiro, J. C. R., & Dias, S. C. (2016). Study of dentinal adhesives compatibility using histological analysis. Brazilian Journal of Oral Sciences, 1289-1294.

Murray, P. E., Windsor, L. J., Smyth, T. W., Hafez, A. A., & Cox, C. F. (2002). Analysis of pulpal reactions to restorative procedures, materials, pulp capping, and future therapies. Critical Reviews in Oral Biology & Medicine, 13(6), 509-520.

Nowicka, A., Parafiniuk, M., Lipski, M., Lichota, D., & Buczkowska-Radlinska, J. (2012). Pulpo-dentin complex response after direct capping with self-etch adhesive systems. Folia Histochemica et Cytobiologica, 50(4), 565-573.

O'Boskey Jr, F. J., & Panagakos, F. S. (1998). Cytokines stimulate matrix metalloproteinase production by human pulp cells during long-term culture. Journal of endodontics, 24(1), 7-10.

Ozer, F., & Blatz, M. B. (2013). Self-etch and etch-and-rinse adhesive systems in clinical dentistry. Compendium of continuing education in dentistry (Jamesburg, NJ: 1995), 34(1), 12-4.

Pashley, D. H., Tay, F. R., Yiu, C. K. Y., Hashimoto, M., Breschi, L., Carvalho, R., & Ito, S. (2004). Collagen degradation by host-derived enzymes during aging. Journal of dental research, 83(3), 216-221.

Perdigao, J. (2007). New developments in dental adhesion. Dental Clinics of North America, 51(2), 333-357.

Sabatini, C., & Pashley, D. H. (2014). Mechanisms regulating the degradation of dentin matrices by endogenous dentin proteases and their role in dental adhesion. A review. American journal of dentistry, 27(4), 203.

Shafiei, F., Tavangar, M. S., Razmkhah, M., Attar, A., & Alavi, A. A. (2014). Cytotoxic effect of silorane and methacrylate based composites on the human dental pulp stem cells and fibroblasts. Medicina oral, patologia oral y cirugia bucal, 19(4), e350.

Shimada, Y., Ichinose, S., Sadr, A., Burrow, M. F., & Tagami, J. (2009). Localization of matrix metalloproteinases (MMPs‐2, 8, 9 and 20) in normal and carious dentine. Australian dental journal, 54(4), 347-354.

Strobel, S., & Hellwig, E. (2015). The effects of matrix-metallo-proteinases and chlorhexidine on the adhesive bond. Swiss dental journal, 125(2), 134-145.

Sulkala, M., Larmas, M., Sorsa, T., Salo, T., & Tjäderhane, L. (2002). The localization of matrix metalloproteinase-20 (MMP-20, enamelysin) in mature human teeth. Journal of dental research, 81(9), 603-607.

Suyama, Y., De Munck, J., Cardoso, M. V., Yamada, T., & Van Meerbeek, B. (2013). Bond durability of self-adhesive composite cements to dentine. Journal of dentistry, 41(10), 908-917.

Tran-Hung, L., Laurent, P., Camps, J., & About, I. (2008). Quantification of angiogenic growth factors released by human dental cells after injury. Archives of oral biology, 53(1), 9-13.

Van Strijp, A. J. P., Jansen, D. C., DeGroot, J., Ten Cate, J. M., & Everts, V. (2003). Host-derived proteinases and degradation of dentine collagen in situ. Caries Research, 37(1), 58-65.

Influencia del protocolo de unión adhesiva en la respuesta celular inflamatoria y la actividad gelatinolítica en dientes humanos

Autores/as

DOI:

Palabras clave:

Resumen

Citas

Descargas

Publicado

Cómo citar

Número

Sección

Licencia

JOURNAL METRICS

Idioma

Enviar un artículo