Effect of vital bleaching on surface roughness and microhardness of nanofilled and nanohybrid composite resins

Anindita Chakraborty; Tina Purayil; Kishore Ginjupalli; Kalyana-Chakravarthy Pentapati; Neetha Shenoy

doi:10.12688/f1000research.130071.1

. 2023 Feb 2;12:129. [Version 1] doi: 10.12688/f1000research.130071.1

Effect of vital bleaching on surface roughness and microhardness of nanofilled and nanohybrid composite resins

Anindita Chakraborty ¹, Tina Purayil ^1,^a, Kishore Ginjupalli ², Kalyana-Chakravarthy Pentapati ³, Neetha Shenoy ¹

PMCID: PMC10311121 PMID: 37396049

Abstract

Background: To compare the surface roughness and microhardness of Ceram.x® SphereTEC™ one and Filtek Z350 XT after in-office vital bleaching with Pola office.

Methods: A total of 20 samples of 10 mm diameter and 2 mm height of Ceram.x® SphereTEC™ one and Filtek Z350 XT were prepared. The samples were subjected to two bleaching sessions with 35% hydrogen peroxide (Pola office) with a seven-day interval between each session. Surface roughness and microhardness of the prepared samples prior to and after the bleaching regimen were measured using a profilometer and Vickers hardness tester, respectively.

Results: A significant reduction (p <0.001) in the surface hardness of Filtek Z350 XT from 26.67 ± 2.10 to 17.83 ± 1.36 Vickers hardness number (VHN) was observed after the bleaching whereas no significant reduction in surface hardness was observed with Ceram.x® SphereTEC™ one. However, in-office bleaching of these materials did not significantly alter their surface roughness.

Conclusions: The effect of in-office bleaching on the surface hardness of resin composites seem to vary due to variations in the composition of dental composites such as filler loading. Among the composites tested, in office bleaching of Ceram.x® SphereTEC™ did not result in significant changes in its surface hardness and roughness.

Keywords: restorative resin, microhardness, surface roughness, in-office bleaching

Introduction

Bleaching removes intrinsic and extrinsic stains from the dental tissues. ¹ ^, ² Although the procedure is complex the vast majority work by oxidation, a chemical process that converts organic materials into carbon dioxide and water. The outcome depends on the concentration and the ability of the bleaching agent to reach the chromophore molecules coupled with duration and frequency of contact.

Dental bleaching can be either in-office (under clinical supervision) or at-home bleaching. Bleaching is effective in improving esthetics, but there has been a growing concern in the recent past on the effect of bleaching materials and techniques on existing restorative materials in the oral cavity. With ever-increasing demand for esthetics, there has been an increase in the use of direct esthetic restorative materials, especially dental composites. A dental composite restorative material mainly consists of a polymerizable resin matrix, reinforcing fillers, and a coupling agent that bonds resin with the fillers. The vast majority of dental composites are commercially available for clinical use mainly differ in terms of the resin matrix materials and the fillers used. The clinical performance of these materials significantly vary depending on the type, size, distribution, and concentration of fillers used in the composites.

Ceram.x ^® SphereTEC™ one (Dentsply, Konstanz, Germany) is a light-curable nanoceramic, radiopaque restorative material with a granulated filler technology (SphereTEC™). It consists of a blend of pre-polymerized fillers of a size equivalent to 15 μm, non-agglomerated glass of 0.6 μm, and Ytterbium fluoride of 0.6 μm. It has distinctive handling characteristics, natural-looking gloss, and effortless polishing. Its resin matrix consists of a reformed version of the polysiloxane comprising matrix from the original Ceram.x ^® mono+/duo+. It is combined with a well-established polyurethane methacrylate, bis-EMA, and TEGDMA to increase its mechanical strength.

Filtek™ Z350 XT (3M, ESPE, St. Paul, USA) universal nanocomposite restorative is a light-activated composite designed for use in anterior and posterior restorations. The nanofillers consist of 20 nm silica and 4–11 nm zirconia, both in combination of non-agglomerated/non-aggregated and aggregated forms. The presence of nanofillers in agglomerated or clustered forms with a broad distribution in the size of the clusters permits higher filler loading as well as superior polishing ability and thus the esthetic characteristics. Both Ceram.x ^® SphereTEC™ one and Filtek™ Z350 XT contain fillers in the nanometer range; however, their particle size and distribution is different.

Many studies have reported the action of bleaching agents on restorative materials. ³ ^– ⁷ The observed changes after bleaching of composite resin materials are alterations in smoothness, hardness and reduction in bond strength. ⁸ ^, ⁹ Such observed changes could be due to the differences in the concentration and type of bleaching agent used. In addition, compositional changes in composites in terms of the resin matrix, filler content, size, and distribution may also affect their susceptibility to bleaching. ¹⁰ Hence, it is essential to investigate the effect of bleaching on the properties of composites, especially those with newer fillers. The use of hybrid composites as universal composites for anterior and posterior restoration is common during the regular dental practice. In this regard, the present study aimed to compare the surface roughness and microhardness of nanofilled and nanohybrid composite restorative materials subjected to in-office bleaching.

Methods

A customized split mold was used to fabricate twenty disc-shaped specimens of 10 mm diameter and 2 mm height of Ceram.x ^® SphereTEC™ one (Dentsply, Sirona) and Filtek Z350 XT (3M ESPE, St. Paul, USA). Table 1 summarizes information regarding the composition and manufacturers’ details of composite resin materials.

Table 1. Composite resin materials used in the study.

Type of composite	Composition		Manufacturer
Type of composite	Inorganic matrix	Fillers	Manufacturer
Ceram.X SphereTec One	Poly-urethane-methacrylate Bis-EMA TEGDMA	• Spherical, prepolymerized SphereTEC™ fillers (d3,50 ≈ 15 μm) • Non-agglomerated barium glass (d3,50 ≈ 0.6 μm) and ytterbium fluoride (d3,50 ≈ 0.6 μm)	Dentsply, UK
Filtek Z 350XT	Bis-GMA UDMA TEGDMA Bis-EMA PEGDMA	• Non-aggregated 20 nm silica, 4–11 nm zirconia • Aggregated zirconia/silica clusters	3M ESPE, United States

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After the composite material was packed into the mold, mylar strip was used both on top and bottom surfaces to obtain a smooth surface on the composite. Subsequently, the composite material was cured for 20 seconds on both sides using a visible light curing unit (3M ESPE Elipar, St Paul, USA).

The prepared discs were subjected to in-office bleaching using 35% hydrogen peroxide (Pola office, SDI Limited, Australia) as per the manufacturer’s instructions. The procedure involved applying a bleaching agent two times with one-week interval between the applications. The bleaching protocol involved the application of a bleaching agent three times onto the surfaces of each disc for 15 mins. The discs were rinsed with distilled water for one minute between each application. After the bleaching process, all the discs were stored in distilled water.

The surface hardness of the discs before and after the bleaching was measured using the Vickers hardness testing machine (MMT X7, Matsuzawa Company, Japan). The specimens were mounted on a platform of the device, and a load of 200 g was applied for 30 seconds. The load was removed after dwell time, and the length of the diagonal of the indentation was measured. Three measurements of each sample were carried out and an average length of the indentation was used for the computation of hardness. The surface hardness was calculated by dividing the load by the area of the indention and was reported as Vickers hardness number (VHN).

Surface roughness of the specimens pre- and post-bleaching was measured using a surface profilometer (Surtronics 3+, Taylor Hobson, UK). The samples were placed on a flat stable surface. The stylus of the profilometer was passed over the surface of the specimen perpendicularly to a distance of 0.8 mm. The experiment was carried out in triplicate on each disc, and average surface roughness, as Ra, was recorded in microns.

Statistical analysis

All the analyses were done using SPSS version 20 (RRID:SCR_019096). A p-value of < 0.05 was considered statistically significant. Normality was tested using the Kolmogorov Smirnov test. Comparison of mean surface roughness and microhardness before and after the bleaching was done using the Paired t-test. ANCOVA was used to evaluate the significant differences in the surface roughness and microhardness between the materials after adjusting the baseline values. Data for this study can be accessed at Mendeley Data. ¹¹

Results

There was no significant difference in mean microhardness before and after bleaching (p = 0.954) in Ceram.x ^® SphereTEC™ one. However, Filtek Z350 XT showed a significant reduction in the surface hardness after bleaching (p < 0.001). There were no significant differences in the mean surface roughness before and after bleaching in both the composite resin materials (p = 0.153 and 0.199), respectively ( Table 2).

Table 2. Comparison of microhardness and surface roughness between the composite resin materials before and after bleaching.

	Before	After	P-value
	Mean ± SD	Mean ± SD	P-value
Microhardness (VHN)
Ceram.x ^® SphereTEC™ one	37.59 ± 4.28	37.5 ± 4.34	0.954
Filtek Z350 XT	27.67 ± 2.1	17.83 ± 1.36	<0.001 ^*
Surface roughness (μm)
Ceram.x ^® SphereTEC™ one	2.66 ± 0.26	2.11 ± 0.92	0.153
Filtek Z 350XT	2.62 ± 0.2	2.52 ± 0.24	0.199

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Denotes statistically significant (p < 0.05), paired t test.

ANCOVA evaluated the difference in microhardness and surface roughness between Ceram.x ^® SphereTEC™ one and Filtek Z350 XT after bleaching while adjusting for before bleaching values. The adjusted mean (estimated marginal mean) microhardness after bleaching for Ceram.x ^® SphereTEC™ one (35.79 ± 1.45) was significantly higher than Filtek Z350 XT (19.538 ± 1.45) (p < 0.001). However, no significant difference in the adjusted mean (estimated marginal mean) surface roughness after bleaching was seen between Ceram.x ^® SphereTEC™ one (2.13 ± 0.2) and Filtek Z350 XT (2.5 ± 0.2) (p = 0.21).

Discussion

The main objective of the present study was to assess the effect of in-office bleaching on two nanohybrid composites with variations in filler size and loading. As the bleaching process generally affects the surface characteristics of dental composites, both surface roughness and microhardness of Ceram.x ^® SphereTEC™ one and Filtek Z350 XT were measured prior to and after bleaching using Pola office. The bleaching agent consisted of hydrogen peroxide/sodium perborate/carbamide peroxide that generally oxidizes the chromophores and improves the shade of the discolored tooth. Exposure of these bleaching materials can also potentially affect the existing restorative materials due to their strong oxidizing ability.

Some of the previous investigations have reported an increase in microhardness of composites after bleaching treatment with carbamide peroxide. ¹² In contrast, other research studies have indicated a reduction in surface hardness. ¹³ Our study did not show any significant changes in the microhardness and surface roughness concerning nanohybrid composite [Ceram.x ^® SphereTEC™ one] which was in accordance with previous reports. ¹⁴ ^, ¹⁵ There was a significant reduction in microhardness of Filtek Z350 XT, whereas the surface roughness remained unaffected. These observations were in agreement with previous research. ¹⁶ An increase in the surface roughness of restorative materials will facilitate the plaque accumulation on the surface thus affecting the esthetics. ¹⁷ Similarly, a decrease in the surface hardness makes the material more vulnerable to wear during masticatory force application. ¹⁸

Hydrogen peroxide tends to cause oxidation, thereby facilitating the generation of free radicals. ¹⁹ The unreacted double bonds in the polymer resin are prone to oxidative cleavage by peroxides. The by-products of this reaction may bring about a reduction in microhardness. Moreover, the free radicals generated by the peroxides are capable of causing hydrolytic degradation of composite resin at the resin-filler interface, thereby paving the way for filler-matrix debonding, leading to microscopic cracks and thus increasing surface roughness. ²⁰

Ceram.x ^® SphereTEC™ has a high proportion of filler particles with advanced granulated filler technology. The nanohybrid composition with advanced filler technology ensures a higher filler loading and hence superior flexural strength, compressive strength, and low water sorption. Higher filler loading and reduced resin matrix content reduces the chance of resin matrix oxidation by hydrogen peroxide, making them resilient to acidic bleaching agents. On the other hand, resin composite Filtek Z350 is a nanoparticulated composite compounded by BisGMA, UDMA, BisEMA, and minor proportions of TEGDMA. The overall inorganic filler loading in these composites is about 72% by weight, which is less than Ceram.x ^® SphereTEC™ composites with an inorganic filler loading of 77–79% by weight. A low filler loading with a large resin matrix volume makes these composites more prone to oxidation or degradation by bleaching agents, hence a significant reduction in microhardness after bleaching. ²¹

Free radicals induced by peroxides may impact the resin–filler interface and cause a filler–matrix debonding. ²² The microhardness of the composites is highly influenced by the amount and type of the inorganic fillers. ²³ Hence, a reduction in the surface microhardness for Filtek Z350 XT may be due to the inorganic filler loss on the surface. Ceram.x ^® SphereTEC™ one has pre-polymerized filler particles of non-agglomerated barium glass and ytterbium fluoride and a resin matrix with highly dispersed methacrylic polysiloxane nanoparticles that are chemically similar to glass or ceramics. Such filler composition is more resistant to abrasion and inorganic filler loss at the surface. Hence no significant changes in microhardness and surface roughness were observed.

Conclusions

The results of the present study indicate that the effect of in-office bleaching on dental composites vary significantly depending on the type of dental composite. Variations in the composition such as filler size and loading may alter their resistance to bleaching. Hence, the effect of the bleaching agent on the existing composite resin restorations must be considered at the time of selection of the bleaching agent and the regimen for clinical use.

Funding Statement

The author(s) declared that no grants were involved in supporting this work.

[version 1; peer review: 2 approved with reservations]

Data availability

Underlying data

Mendeley Data: Underlying data for ‘Effect of vital bleaching on surface roughness and microhardness of nanofilled and nanohybrid composite resins’, https://www.doi.org/10.17632/5fjyt8z6vc.1. ¹¹

Data are available under the terms of the Creative Commons Attribution 4.0 International license (CC-BY 4.0).

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F1000Res. 2023 Apr 17. doi: 10.5256/f1000research.142799.r168376

Reviewer response for version 1

Osiro Olivia Millicent Awino ¹

The article is coherent and addresses a relevant topic. The study design and methodology are suitable to answer the research question.

In the introduction, although a clear description of the relevance of the study is provided together with a description of the composite materials, very little information is covered on bleaching materials and techniques and how these can specifically affect the material properties. For example, where this is attempted in the first two paragraphs, the information is scanty and supported by only two citations. Likewise, in the final paragraph, a general statement is made on the effect of the bleaching agents and suspected attributes regarding the material composition but no specific explanation and corresponding examples which would be helpful in justifying the need for this study. A clear distinction should be made between the nanofilled and the nanohybrid composite.

In the methods, the manufacture of Ceram.X SphereTec One in Table 1 is different from that stated in the introduction.

The description of the specimens is also lacking important detail - how many specimens were prepared for each composite material? This should also be clarified in the abstract. What was the total sample size and was this calculated based on a determined statistical power?

What material was the split mould made of? Where was the mylar strip sourced from?

How much bleaching agent was applied on the discs? Was it the same quantity for all discs at all times? Were the discs dry at the initial bleaching application, before they were stored in distilled water?

For the hardness test, the length of indentation was measured but the calculation was derived from the area of indentation. This description should be clarified.

The description of the surface roughness measurement is also unclear, specifically, '...passed over the surface of the specimen perpendicularly to a distance of 0.8mm...'

In the results, it would be useful to also report the t-values in Table 2 and F or relevant test values for ANCOVA, as well as the 95% CI.

Table 2 shows paired t-test results within the same material, that is, before and after for the same material (within) not between the two materials.

A statement on the significant difference on microhardness between the two materials should also be captured in the abstract.

In the discussion, reference is made to a study on two nanohybrid composites in the first paragraph - this should be clarified as the title talks of a nanofilled and a nanohybrid.

The description of the bleaching agent in the discussion is different from that presented in the methodology - can this have any influence on the outcome observed?

Although clear arguments are presented in the discussion, some paragraphs lack supporting citations e.g only one in paragraph 4.

Were there any limitations in this study? Are the conclusions generalizable? Can the observations be accurately and undoubtedly attributed to the type of composite as implied in the conclusion? Do the authors believe that this study was able to show the effect of the bleaching agent on the composite due to the filler type and load?

Throughout the MS, some minor grammatical errors should also be addressed to improve clarity e.g In the title and objective, is the use of 'vital' correct considering that this was an in vitro study?; In the abstract conclusion, '...seems to vary due to variations...'; In the introduction, the second statement in the first paragraph, '..the majority of bleaching agents...' could improve clarity; in the second paragraph, third statement, '...ever-increasing demand...there has been an increase....'

Is the work clearly and accurately presented and does it cite the current literature?

Partly

If applicable, is the statistical analysis and its interpretation appropriate?

Yes

Are all the source data underlying the results available to ensure full reproducibility?

Yes

Is the study design appropriate and is the work technically sound?

Yes

Are the conclusions drawn adequately supported by the results?

Partly

Are sufficient details of methods and analysis provided to allow replication by others?

Partly

Reviewer Expertise:

Dental Biomaterials Science

I confirm that I have read this submission and believe that I have an appropriate level of expertise to confirm that it is of an acceptable scientific standard, however I have significant reservations, as outlined above.

F1000Res. 2023 May 16.

Tina Purayil ¹

Reviewer 2

Query 1

In the introduction, Although a clear description of the relevance of the study is provided together with a description of the composite materials, very little information is covered on bleaching materials and techniques and how these can specifically affect the material properties. For example, where this is attempted in the first two paragraphs, the information is scanty and supported by only two citations. Likewise, in the final paragraph, a general statement is made on the effect of the bleaching agents and suspected attributes regarding the material composition but no specific explanation and corresponding examples which would be helpful in justifying the need for this study. A clear distinction should be made between the nanofilled and the nanohybrid composite.

Response 1

The introduction has been revised.

Although a clear description of the relevance of the study is provided together with a description of the composite materials, very little information is covered on bleaching materials and techniques and how these can specifically affect the material properties-

The most commonly used bleaching agents are hydrogen peroxide and carbamide peroxide. These bleaching agents can be applied at-home and in-office and are considered to be effective and relatively safe when supervised by a dentist.

Many studies have reported the action of bleaching agents on restorative materials. The observed changes after bleaching of composite resin materials are alterations in smoothness, hardness and reduction in bond strength.

A clear distinction should be made between the nanofilled and the nanohybrid composite.

Filtek™ Z350 XT (3M, ESPE, St. Paul, USA) is a universal nanocomposite consisting of nanometer-sized filler particles in the composite matrix.

Ceram.x ^® SphereTEC™ one (Dentsply, Konstanz, Germany) is a light-curable nanohybrid composite consisting of nanometer and micrometer-sized fillers with a granulated filler technology (SphereTEC™).

Query 2

In the methods, the manufacture of Ceram.X SphereTec One in Table 1 is different from that stated in the introduction.

Response 2

Manufacturer details of Ceram X Sphertec One in Table 1 has been changed to Dentsply, Konstanz, Germany

Query 3

The description of the specimens is also lacking important detail - how many specimens were prepared for each composite material? This should also be clarified in the abstract.

Response 3

20 samples each of (10 mm diameter and 2 mm height) Ceram.x® SphereTEC™ one and Filtek Z350 XT were prepared. It has been revised both in abstract and also in the main text.

Query 4

What was the total sample size and was this calculated based on a determined statistical power?

Response 4

Total sample size is 40.

Sample size was estimated based on the microhardness values reported by Sharafeddin and Jamalipour which yielded an effect size of 1.42. With a power of 80% and 95% confidence interval, the sample size was estimated to be nine per group

Query 5

What material was the split mould made of? Where was the mylar strip sourced from?

Response 5

Split mould was made of stainless steel.

Manufacturing detail of mylar strip is (SS White Co, Philadelphia, PA, USA) and its been added to the main text

Query 6

Response 6

The prepared discs were subjected to 0.1 ml of 35% hydrogen peroxide (Pola office, SDI Limited, Australia)

Same quantities were used for all the discs.

Yes, the discs were dry at the initial bleaching application.

Query 7

For the hardness test, the length of indentation was measured but the calculation was derived from the area of indentation. This description should be clarified.

Response 7

Using the length of the diagonal of the indentation, area of the indentation [square-shaped indentation] was measured as follows: area of indentation = ½ x length of the diagonal ²

Query 8

The description of the surface roughness measurement is also unclear, specifically, '...passed over the surface of the specimen perpendicularly to a distance of 0.8mm...'

Response 8

The word perpendicular was used in the context that the stylus was moving over the surface We have removed the word “perpendicularly” from the text. Surface roughness of the specimens pre- and post-bleaching was measured using a surface profilometer (Surtronics 3+, Taylor Hobson, UK). The samples were placed on a flat stable surface. The stylus of the profilometer was passed over the surface of the specimen to a distance of 0.8 mm. The experiment was carried out in triplicate on each disc,and average surface roughness, as Ra, was recorded in microns

Query 9

In the results, it would be useful to also report the t-values in Table 2 and F or relevant test values for ANCOVA, as well as the 95% CI.

Response 9

t-values ,F values and 95% CI have been added to the table 2 and text.

Query 10

Table 2 shows paired t-test results within the same material, that is, before and after for the same material (within) not between the two materials.

Response 10

It has been included in the Table 2

Query 11

A statement on the significant difference on microhardness between the two materials should also be captured in the abstract.

Response 11

This statement is added to the abstract: The adjusted mean (estimated marginal mean) microhardness after bleaching for Ceram.x ^® SphereTEC™ one (35.79 ± 1.45) was significantly higher than Filtek Z350 XT (19.54 ± 1.45) (p < 0.001).

Query 12

In the discussion, reference is made to a study on two nanohybrid composites in the first paragraph - this should be clarified as the title talks of a nanofilled and a nanohybrid.

Response 12

It has been revised in the first paragraph of the discussion: The main objective of the present study was to assess the effect of in-office bleaching on nanohybrid and nanofilled composites

Query 13

The description of the bleaching agent in the discussion is different from that presented in the methodology - can this have any influence on the outcome observed?

Response 13

The active ingredient of majority of bleaching agents is hydrogen peroxide and generally oxidizes the chromophores and improves the shade of the discolored tooth. It has been revised in the second paragraph of the discussion

Query 14

Although clear arguments are presented in the discussion, some paragraphs lack supporting citations e.g only one in paragraph 4.

Response 14

Supporting study has been included in paragraph 4 : Preethy NA, Jeevanandan G, Govindaraju L, Subramanian EMG. Comparison of Shear Bond Strength of Three Commercially Available Esthetic Restorative Composite Materials: An In Vitro Study. Int J Clin Pediatr Dent. 2020 Nov 1;13(6):635–9.

Query 15

Were there any limitations in this study?

Response 15

The results of the present study indicate that compositional variations influence the susceptibility of dental composites to bleaching. However, the present study selected only two types of dental composites. Additional studies on large number of composites and their types (microfilled, nanofilled, hybrid composites etc) may provide more insights on the effect of bleaching on composites restorative materials.

Query 16

Are the conclusions generalizable? Can the observations be accurately and undoubtedly attributed to the type of composite as implied in the conclusion? Do the authors believe that this study was able to show the effect of the bleaching agent on the composite due to the filler type and load?

Response 16

From the results of the present study, we conclude that the variations in formulation of dental composites can influence their susceptibility to bleaching. In that sense, variations in filler size and loading would also alter the ratio between resin matrix to filler. Hence, the findings of the present study can be generalized to the extent that variations in composition changes their susceptibility to bleaching

Query 17

Response 17

In the title and objective, is the use of 'vital' correct considering that this was an in vitro study?:Title has been rephrased to “Effect of in-office bleaching agent on the surface roughness and microhardness of nanofilled and nanohybrid composite resins”

In the abstract conclusion, '...seems to vary due to variations..: Abstract has been revised to -In office-bleaching with 35% hydrogen peroxide can reduce the microhardness of nanofilled composite. However, the surface roughness was not influenced by the bleaching procedure in both nanohybrid and nanofilled composite resin materials.

In introduction-the majority of bleaching agents: Second statement in the first paragraph has been revised to :This procedure involves diffusion of bleaching agent which alters the structure of chromophore molecules present in enamel and dentin , thereby promoting tooth whitening ever-increasing demand...there has been an increase -third statement in the second paragraph has been revised to With greater demand for esthetics, there has been an increase in the use of direct esthetic restorative materials, especially dental composites

F1000Res. 2023 Feb 20. doi: 10.5256/f1000research.142799.r162247

Reviewer response for version 1

Rama Krishna Alla ¹

This manuscript compared the surface roughness and microhardness of Ceram.x® SphereTEC™ one and Filtek Z350 XT after in-office vital bleaching with Pola office. A total of 20 composite discs with 10 x 2 mm were fabricated with Ceram.x® SphereTEC™ one and Filtek Z350 XT. The samples were subjected to two bleaching sessions with 35% hydrogen peroxide (Pola office) with a seven-day interval between each session. Surface roughness and microhardness of the prepared samples prior to and after the bleaching procedures were measured using a profilometer and Vickers hardness tester, respectively. This study reported a significant reduction (p <0.001) in the surface hardness of Filtek Z350 XT after the bleaching and no significant decrease in surface hardness with Ceram.x® SphereTEC™ one. However, in-office bleaching of these materials did not report a significant change in their surface roughness.

The detailed report is as follows.

This manuscript was well-written and adhered to the standards.

The introduction was adequate and described the objectives of the study clearly. In the second paragraph, a few references should have been cited to substantiate the information presented.
The methodology was clearly described. The methodology can include information about the curing lamp specifications and the radiation/wavelength employed.
Results described well based on the statistical analysis performed.
The discussion is adequate and consistent with the results. The reasons for varying the surface hardness and roughness were discussed. The outcomes of the current study were compared with those of other comparable investigations. The limitations and the future scope of this study could have been emphasized.
The conclusions were appropriate based on the results.
The references were appropriate and mentioned the most recent studies.

The data presented in the current study is useful to the scientific community and clinicians. This study reported a significant decrease in the surface hardness of the composites with the bleaching procedures. This decrease in hardness was dependent on the filler loading to resin ratio. Therefore, the data presented in this study is handy to clinicians for selecting an appropriate composite for their patient's needs.

Is the work clearly and accurately presented and does it cite the current literature?

Yes

If applicable, is the statistical analysis and its interpretation appropriate?

Yes

Are all the source data underlying the results available to ensure full reproducibility?

Yes

Is the study design appropriate and is the work technically sound?

Yes

Are the conclusions drawn adequately supported by the results?

Yes

Are sufficient details of methods and analysis provided to allow replication by others?

Yes

Reviewer Expertise:

Dental Materials, Nanoparticles in dentistry, fibre-reinforced composites.

F1000Res. 2023 May 16.

Tina Purayil ¹

Query 1

The introduction was adequate and described the objectives of the study clearly. In the second paragraph, a few references should have been cited to substantiate the information presented.

Response 1

References has been added to the second paragraph.

Abouassi T, Wolkewitz M, Hahn P. Effect of carbamide peroxide and hydrogen peroxide on enamel surface: an in vitro study. Clin Oral Investig. 2011;15(5):673–80.
De Geus JL, Wambier LM, Kossatz S, Loguercio AD, Reis A. At-home vs In-office Bleaching: A Systematic Review and Meta-analysis. Oper Dent. 2016 Jul 1;41(4):341–56.

Query 2

The methodology was clearly described. The methodology can include information about the curing lamp specifications and the radiation/wavelength employed.

Response 2

The composite material was cured for 20 seconds on both sides using a visible light curing unit (3M ESPE Elipar, St Paul,MN, USA ) having a light intensity of 1200 wM/cm ².

Query 3

The limitations and the future scope of this study could have been emphasized.

Response 3

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Data Availability Statement

Underlying data

Mendeley Data: Underlying data for ‘Effect of vital bleaching on surface roughness and microhardness of nanofilled and nanohybrid composite resins’, https://www.doi.org/10.17632/5fjyt8z6vc.1. ¹¹

Data are available under the terms of the Creative Commons Attribution 4.0 International license (CC-BY 4.0).

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PERMALINK

Effect of vital bleaching on surface roughness and microhardness of nanofilled and nanohybrid composite resins

Anindita Chakraborty

Tina Purayil

Kishore Ginjupalli

Kalyana-Chakravarthy Pentapati

Neetha Shenoy

Roles

Abstract

Introduction

Methods

Table 1. Composite resin materials used in the study.

Statistical analysis

Results

Table 2. Comparison of microhardness and surface roughness between the composite resin materials before and after bleaching.

Discussion

Conclusions

Funding Statement

Data availability

Underlying data

References

Reviewer response for version 1

Osiro Olivia Millicent Awino

Roles

Tina Purayil

Reviewer response for version 1

Rama Krishna Alla

Roles

Tina Purayil

Associated Data

Data Availability Statement

Underlying data

ACTIONS

PERMALINK

RESOURCES

Cite

Add to Collections

PERMALINK

Effect of vital bleaching on surface roughness and microhardness of nanofilled and nanohybrid composite resins

Anindita Chakraborty

Tina Purayil

Kishore Ginjupalli

Kalyana-Chakravarthy Pentapati

Neetha Shenoy

Roles

Abstract

Introduction

Methods

Table 1. Composite resin materials used in the study.

Statistical analysis

Results

Table 2. Comparison of microhardness and surface roughness between the composite resin materials before and after bleaching.

Discussion

Conclusions

Funding Statement

Data availability

Underlying data

References

Reviewer response for version 1

Osiro Olivia Millicent Awino

Roles

Tina Purayil

Reviewer response for version 1

Rama Krishna Alla

Roles

Tina Purayil

Associated Data

Data Availability Statement

Underlying data

ACTIONS

PERMALINK

RESOURCES

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