Assessment of Surface Roughness and Compressive Strength of Resin-Based Composite Using Different Types of Bleaching Protocols

This study aims to assess surface roughness and compressive strength of resin-based composite using different types of bleaching protocols. Three different bleaching protocols were applied to determine their effect on composite resin's compressive strength and surface roughness. Eighty composite resin samples were prepared using metal molds; forty samples (2 mm in height and 8 mm in diameter) for surface roughness evaluation and the other forty samples (6 mm in height and 4 mm in diameter) for compressive strength. Every forty samples were divided into four groups. In group 1 (n = 10), samples were stored in deionized water at 37°C for two weeks as control, in group 2 (n =10), samples were subjected to home bleaching with 22% carbamide peroxide (CP), in group 3 (n = 10)  samples were subjected to home bleaching with 14% hydrogen peroxide (HP), and in group 4 (n =10)  samples were subjected to bleaching with 25% hydrogen peroxide (HP in-Office) in a dental clinic. After bleaching, surface roughness and compressive strength of groups 2, 3, and 4 were measured. After applying bleaching protocols, a similar increase in the enamel surface roughness of all samples was observed; however, this increase was not statistically significant compared to the control group. The CP-treated group had the highest surface roughness. All three bleaching protocols resulted in a decrease of compressive strength of the composite compared to the control group, and the minimum compressive strength belonged to the HP-treated group, followed by HP in-Office group and CP group, respectively. According to the results of this study, there was an increase in surface roughness using different types of bleaching protocols (22% CP and 14% HP) at-Home bleaching technique and (25%) in-Office HP bleaching with no significant difference between them, while all three bleaching protocols reduced the compressive strength of the composite with no significant difference.  

Keywords: bleaching protocol, hydrogen peroxide, carbamide peroxide.

BAHANNAN S. A. Effects of different bleaching agent concentrations on surface roughness and microhardness of esthetic restorative materials. The Saudi Journal for Dental Research, 2015, 6: 124-128.

BAHARI M, CHAHAROM M. E. E., DANESHPOOY M., GHOLIZADEH S., and PASHAYI H. Effect of bleaching protocols on surface roughness and biofilm formation on silorane-based composite resin. Dental Research Journal (Isfahan), 2019, 16(4): 264-270.

ATTIN T., PAQUÉ F., AJAM F., and LENNON A. M. Review of the current status of tooth whitening with the walking bleach technique. International Endodontic Journal, 2003, 36: 313-29.

DADOUN M. P. and BARTLETT D. W. Safety issues when using carbamide peroxide to bleach vital teeth – A review of the literature. European Journal of Prosthodontics and Restorative Dentistry, 2003, 11: 9-13.

PRABHAKAR A., SAHANA S., MAHANTESH T., and VISHWAS T. Effects of different concentrations of bleaching agent on the microhardness and shear bond strength of restorative materials. An in vitro study. Journal of Dentistry and Oral Hygiene, 2010, 2: 7-14.

LENHARD M. Assessing tooth color change after repeated bleaching in vitro with a 10 percent carbamide peroxide gel. Journal of the American Dental Association, 1996, 127: 1618-1624.

MCCASLIN A. J., HAYWOOD V.B., POTTER B. J., DICKINSON G. L., and RUSSELL C. M. Assessing dentin color changes from nightguard vital bleaching. Journal of the American Dental Association, 130: 1485-1490.

ZURYATI A., QIAN O. Q. AND DASMAWATI M. Effects of home bleaching on surface hardness and surface roughness of an experimental nanocomposite. Journal of Conservative Dentistry, 2013, 16(4): 356-361.

SABIR S. M. Evaluation of addition of dentin powder to unfilled resin as a fissure sealant. Ph.D. thesis, Hawler Medical University, College of Dentistry, Iraq. 2020.

ASAFARIAL S. Comparative Evaluation of Microleakage, Surface Roughness and Hardness of Three Glass Ionomer Cements – Zirconomer, Fuji IX Extra GC and Ketac Molar: An In Vitro Study. Dentistry Journal, 2017, 7(5): 1-5.

SALEEM S. S. Modification of microhybride composite resin by addition of zinc oxide and calcium carbonate nanofillers. Ph.D. thesis, Hawler Medical University, College of Dentistry, Iraq, 2013.

AL-QAHTANI K., AL BOUNNI R.S., AL OMARI M., and ASSERY M. Wear and Surface Roughness of Three different Composite Resins after Simulated Toothbrushing: An in vitro Study. International Journal of Oral Care and Research, 2017, 5(2): 1-6.

LOPES I. A. D., MONTEIRO P. J. V. C., MENDES J. J. B., GONÇALVES J. M. R., and CALDEIRA F. J. F. The effect of different finishing and polishing techniques on surface roughness and gloss of two nanocomposites. Saudi Dental Journal, 2018, 30(3): 197-207.

KANTOVITZ K. R., PASCON F. M., CORRER G. M., ALONSO R. C., RODRIGUES L. K., ALVES M. C., and PUPPIN-RONTANI R. M. Influence of environmental conditions on properties of ionomeric and resin sealant materials. Journal of Applied Oral Science, 2009, 17(4): 294-300.

ARATANI M., PEREIRA A. C., CORRER-SOBRINHO L., SINHORETI M. A. C, and CONSANI S. Compressive strength of resin-modified glass ionomer restorative material: effect of P/L ratio and storage time. Journal of Applied Oral Science, 2005, 13, 356-359.

WALSH R. M., WOODMANSEY K. E., GLICKMAN G. N., and HE J. Evaluation of compressive strength of hydraulic silicate-based root-end filling materials. Journal of Endodontics, 2014, 40: 969-972.

LINS F. C., FERREIRA R. C., SILVEIRA R. R., PEREIRA C. N., MOREIRA A. N., and MAGALHÃES C. S. Surface roughness, microhardness, and microleakage of a silorane-based Composite resin after immediate or delayed finishing/polishing. International Journal of Dentistry, 2016, 8346782: 1- 8.

BEKMEZOĞLU Z. E., GÜNGÖR O. E,. and KARAYILMAZ H. Comparison of Glass Carbomer, Giomer, Glass Ionomer and Resin Fissure Sealants on Permanent Molar Teeth. Journal of Dentistry Indonesia, 2019, 26(1): 5-9. DOI: 10.14693/jdi. v26i1.1234.

OBICI N., SINHORETI M. A. C., CORRR-SOBRINHO L. GOES MF DE, and CONSANI S. Evaluation of mechanical properties of Z250 composite resin light-cured by different methods. Journal of Applied Oral Science, 2005, 13(4): 393-398.

CILDIR S. K. SANDALLI N. Compressive Strength, Surface Roughness, Fluoride Release and Recharge of Four New Fluoride-releasing Fissure Sealants. Dental Materials Journal, 2007, 26 (3): 335- 341.

NAVIMIPOUR E. J., AJAMI A. A., OSKOEE S. S., KAHNAMOU M. A., BAHARI M., CHAHAROM M. E. E., and SHOJAEI S.M. Surface Roughness of Different Composite Resins after Application of 15% Carbamide Peroxide and Brushing with Toothpaste: An In-Vitro Study. Frontiers in Dentistry, 2019, 16(1): 55-61.

VISHWAKARMA P., KARALE R., SRIREKHA A., HEGDE J., SAVITHA B., and SRINIVASAN A. The Effect of Home Bleaching Agents on the Surface Roughness and Fracture Toughness of Composite Resin Materials. Dentistry, 2014, 4(7): 1-6.

COOLEY R. L. and BURGER K. M. Effect of carbamide peroxide on composite resins. Quintessence International, 1991, 22: 817-821.

BAILEY S. J. and SWIFT JR. E. J. Effects of home bleaching products on composite resins. Quintessence International, 1992, 23: 489-494.

MONAGHAN P., TROWBRIDGE T., and LAUTENSCHLAGER E. Composite resin color change after vital tooth bleaching. Journal of Prosthetic Dentistry, 1992, 67: 778-781.

SÖDERHOLM K. J., ZIGAN M., RAGAN M., FISCHLSCHWEIGER W., and BERGMAN M. Hydrolytic degradation of dental composites. Journal of Dental Research, 1984, 63: 1248-1254.

WATTANAPAYUNGKUL P., YAP A. U., CHOOI K. W., LEE M. F., SELAMAT R. S., and ZHOU R. D. The effect of home bleaching agents on the surface roughness of tooth-colored restoratives with time. Operative Dentistry, 2004, 29: 398-403.

BAHARI M., CHAHAROM M. E. E, DANESHPOOY M., GHOLIZADEH S., and PASHAYI H. Effect of bleaching protocols on surface roughness and biofilm formation on silorane-based composite resin. Dental Research Journal (Isfahan), 2019; 16(4): 264–270.