Effect of Over-the-Counter Whitening Dentifrices on the Color Stability and Microhardness of Composite Resins

Abstract

Objective: To evaluate the color stability and microhardness of resin-based bioactive composites after brushing with over-the-counter whitening toothpastes. Methods: A conventional resin (Luna 2) and two bioactive resins (Stela Mix and Activa Presto) were tested. Four toothpastes were used: Colgate Fresh Gel (control), Colgate Max White, Yotuel, and Crest 3D White. Forty disks of each material were prepared and divided into four subgroups. The disks were brushed to simulate three months of daily brushing. Microhardness and color changes were measured before and after brushing. Color variation was calculated using the ΔE_ab, ΔE₀₀, and ΔWI_D indexes. Wilcoxon and two-way ANOVA tests were performed (p < 0.05). Results: In the Luna 2 and Stela groups, the b* parameter decreased significantly with all toothpastes (p < 0.05), while lightness and a* remained stable with no significant differences (p > 0.05). Stela Mix and Activa Presto exhibited color changes within the “moderately unacceptable” range according to ΔE₀₀ (>1.8 and ≤3.6). Based on the ΔWI_D index, Luna 2 showed the highest variation when treated with Colgate Max (2.14 ± 1.33) and the lowest in the control group (1.08 ± 0.56A), remaining within acceptable margins with all treatments. The microhardness values before/after treatment remained for Luna 2 between 77.44 and 76.97; for Stela Mix between 76.24 and 74.13; and for Activa presto between 74.5 and 71.33. Differences were not significant for any of the pastes within each composite (p > 0.05). Conclusions: The evaluated bioactive resins exhibited color changes within the moderately unacceptable range. Colgate Max White induced the most significant color changes. Microhardness was not affected by treatment with whitening toothpastes.

1. Introduction

In recent years, there has been a notable increase in the popularity of tooth whitening among patients, as it is considered a conservative, safe, effective, and minimally invasive method [1]. It is common for teenagers to decide to use whitening toothpastes to lighten the color of their teeth. Today, tooth whitening methods range from professionally applied in-office whitening (PIO) and professionally prescribed home whitening (PPH) to nonprescription over-the-counter (OTC) whitening [2]. OTC products are becoming more popular due to their lower cost, availability, easy access, and simple application [3,4]. The desire for a whiter, brighter smile has led to the widespread use of OTC products for teeth whitening, with whitening toothpastes being the most popular and convenient method [5]. Advertising on TV channels and internet platforms has further increased their appeal to consumers.

Currently available OTC whitening toothpastes use different active ingredients to remove surface stains and enhance tooth lightness. The main components of these toothpastes include abrasives such as hydrated silica, calcium carbonate, or magnesium carbonate, as well as chemical agents such as hydrogen peroxide, carbamide peroxide, activated charcoal, blue covarine, or a combination of these. These ingredients produce a whitening effect through mechanical abrasion, chemical bleaching, or optical modification [6,7].

Some OTC toothpaste formulations contain hydrogen peroxide (HP), the active agent commonly used in professional in-office dental bleaching procedures. HP has demonstrated whitening effectiveness by penetrating the tooth structure and breaking down chromophores, leading to the oxidation of organic staining compounds [8]. Incorporating this potent agent into daily-use toothpaste formulations may offer a more convenient and accessible alternative for achieving professional-grade teeth whitening compared to other OTC products or in-office procedures [9].

Research assessing low concentrations of at-home bleaching gels with carbamide peroxide (CP) or (HP) indicates that these agents do not produce significant alterations in the surfaces of composite resins and other restorative materials [10,11,12]. However, other studies have reported bleaching-induced increases in the surface roughness of composite resins [13]. Abrasive particles, which are essential for stain removal, can also contribute to enamel abrasion and increase the roughness or microhardness of composite resin restorations, especially when their size, hardness, and concentration are not carefully controlled [9]. Additionally, acids such as citric or phosphoric acid are often included in toothpaste formulations to enhance stain removal and stabilize other components. However, these acids can lower the pH of the dentifrice, creating an acidic environment that promotes tooth wear and compromises the integrity of dental restorations [14].

Dental restorations, including composites and ceramics, play a crucial role in achieving esthetic and functional outcomes in contemporary restorative dentistry [15]. In recent years, the popularity of bioactive materials has increased due to their ability to align with the shift toward biologically integrated, patient-centered care. Bioactive resin composites represent an advancement designed to release and recharge fluoride, calcium, and phosphate ions, actively promoting tooth remineralization and reducing the risk of caries recurrence around restorations [16].

Although ion release from bioactive materials provides important therapeutic benefits, it may also affect the mechanical and esthetic properties of the material, potentially compromising its durability and longevity [17]. Compared to conventional resin composites, bioactive materials may exhibit different behavior due to variations in their composition and surface characteristics, affecting roughness, gloss, and color [18]. The stability of recently introduced bioactive materials when exposed to staining from beverages is currently under investigation [19,20]. Furthermore, as patients increasingly seek tooth whitening for esthetic purposes using OTC products, it is essential to understand how these whitening toothpastes affect bioactive restorative materials.

The present study aims to evaluate the color stability and microhardness of different resin-based bioactive materials after brushing with various OTC whitening toothpastes.

The null hypothesis is that there will be no differences in (1) color change or (2) microhardness between the investigated restorative materials and the different dentifrices.

2. Materials and Methods

For this in vitro study, three composite resins were used, all of which are characterized by being BPA-free. The composition of these materials is shown in

Table 1. Composition of the resin composites and toothpastes.

Product	Manufacturer	Composition
Stela Mix Composite Resin	SDI. Victoria, Australia	Urethane dimethacrylate (44%), glycerol dimethacrylate, 10-MDP filler (55%), fluoroaluminosilicate ionomer glass, ytterbium trifluoride opacifier, silicon dioxide, calcium aluminate, initiators, stabilizers, pigments. (Filler 61.0 wt.%.)
Luna 2 Composite Resin (A2)	SDI. Victoria, Australia	Urethane dimethacrylates (44%), tritylene glycol dimethacrylate, tricyclododecanedimethanol dimethacrylate fillers (56%), strontium glass, silicon dioxide, ytterbium trifluoride, initiators, stabilizers, pigments (Filler 77.0 wt.%.)
ActivaTM Presto Composite Resin (A2)	Pulpdent Corporation, Watertown, MA, USA	UDMA, Bis-2MP 35%. Methacrylate-functionalized calcium phosphate (MCP), silanated barium, strontium alumino-silicate glasses and silica. (Filler 56.0 wt.%.)
Colgate Max White One Phosphoric Acid Potassium Hydroxide Tooth Paste (Erosive Action)	Colgate-Palmolive Company, New York, NY, USA	Aqua, hydrated silica, sorbitol, PEG-12, pentasodium triphosphate, tetrapotassium pyrophosphate, aroma, sodium lauryl sulfate, cellulose gum, potassium hydroxide, phosphoric acid, cocamidopropyl betaine, sodium fluoride, sodium saccharin, xanthan gum, limonene, CI 74160.
Yotuel microbiome one premium whitening dentifrice Tooth Paste CP TiO2 optical effect	Bio Cosmetic Laboratories, S.L, Madrid, Spain	Glycerin, xylitol, water, potassium citrate, betaine, silica, dicalcium phosphate, sodium monofluorophosphate, flavor, titanium dioxide (TiO2), cocamidopropyl betaine, hydroxyethyl acrylate/sodium acryloyldimethyl tatouate copolymer, olea europea oil, sodium benzoate, carbomer, carbamide peroxide, potassium sorbate, sucralose, stevia rebaudiana leaf extract, cinnamon.
Crest 3D White Brilliance Whitening two-step Tooth Paste HP TiO2 optical effect	Procter & Gamble, Cincinnati, OH, USA	Stannous fluoride 0.454%, glycerin, hydrated silica, water, zinc lactate, sodium lauryl sulfate, trisodium phosphate, flavor, sodium gluconate, sodium saccharin, xanthan gum, cellulose gum, sodium didroxide, mica, titanium dioxide (TiO2), hydrogen peroxide, carbomer, disodium pyrophosphate, sucralose, sodium hydroxide.
Colgate Fresh Gel Tooth Paste (Control)	Colgate-Palmolive Company, New York, NY, USA	Sorbitol, water, hydrated silica, PEG-12, sodium lauryl sulfate, PEG-12, flavor, cellulose gum, sodium fluoride, sodium saccharine, CI42090.

. Three commercially available whitening toothpastes and one conventional toothpaste without whitening agents were selected. Their composition is specified in Table 1.

2.1. Sample Size Calculation

For a 95% significance level, an 80% statistical power, an effect size of 0.8, and a standard deviation of the difference in means of 2, a sample size of 8.28 elements per group was calculated and rounded up to 10.

2.2. Sample Preparation

A total of 120 composite resin samples were prepared, each with a diameter of 7 mm and a thickness of 2 mm. A disk former (Sampler, Smile Line, Brandenburg, Germany) was used. The composite was placed into the disk former with the help of a spatula. Once positioned, an acetate strip was placed over the surface, followed by a 200 g glass slab for 30 s. Each disk was polymerized using an LED curing light (RADII-CAL, SDI, Victoria, Australia) for 20 s on each side, except for Stela, which is a self-curing composite; therefore, it was allowed to set for 4 min according to the manufacturer’s instructions. After 24 h of polymerization, the samples were polished using multi-grit aluminum oxide disks (medium, fine, and super fine) (Sof-Lex Pop-On, 3M Oral Care, St Paul, MN, USA) in three different grit sizes.

The samples were stored in distilled water at room temperature until use, in separate containers for each resin. Within each material group, the samples were randomly divided into four subgroups (n = 10) according to the toothpaste to be used, as schematized in Figure 1.

2.3. Brushing with Whitening Toothpastes

To simulate the effect of brushing over three months, each disk was brushed for 90 s per day for 10 days [2]. Brushing was performed using an electric toothbrush with a built-in pressure sensor (Oral-B Pro3 3000, Procter & Gamble, Cincinnati, OH, USA). The toothpaste was diluted in water at a 1:3 ratio (by weight) for each brushing cycle [21]. To prevent cross-contamination between different toothpastes, a separate toothbrush head was used for each paste. Brushing time was timed, and after each cycle, the samples were rinsed with water and stored again in distilled water.

A support system was designed to hold the electric toothbrush in place, allowing it to function without manual assistance. The design was based on the brushing simulation device developed by Dudas C. et al., 2017 [22]. A sketch was created using SketchUp software (Trimble Inc., Westminster, CO, USA). To fabricate the system efficiently, a box was modified by creating two concavities in the upper part to hold the toothbrush handle. A rigid, waterproof base was constructed. A platform was placed to hold the resin disks at an appropriate distance for the toothbrush head to reach them. Additionally, silicone putty was added inside the box to adjust the toothbrush height (Express XT Putty Soft, -3M ESPE, St. Paul, MN, USA). Figure 2 illustrates a schematic representation of the fabricated instrument.

2.4. Color Measurement

The color of each sample was evaluated at the beginning and end of the experiment using the VITA Easyshade V spectrophotometer (VITA, Bad Säckingen, Germany). The spectrophotometer was calibrated before measuring the color of each subgroup of samples. Color measurements were taken in a completely dark environment. The samples were placed on a neutral gray background (9a9a98 HSL color space), and the spectrophotometer tip was positioned perpendicularly at the center of each sample. The lightness (L), red–green distance (a*), and yellow–blue distance (b*) parameters were recorded in an Excel table (Microsoft, Redmond, WA, USA). Based on these parameters, the following indexes were calculated: ΔE_ab, ΔE₀₀, and WI_D.

For color difference calculations, the CIE L_ab* total color difference (ΔE_ab) was determined using the following formula:

ΔE_ab = [(L_after − L_before)² + (a_after − a_before)² + (b_after − b_before*)²]^1/2

The visual acceptability and perceptibility thresholds described by Paravina et al. were also used to interpret the results. A value of ΔE₀₀ ≤ 0.8 is considered clinically imperceptible; >0.8 and ≤ 1.8 is perceptible, but clinically acceptable; >1.8 and ≤3.6 is moderately unacceptable; >3.6 and ≤5.4 is clearly unacceptable; and >5.4 is extremely unacceptable [23].

ΔE₀₀ = {[ΔL/(KLSL)]² + [ΔC/(KCSC)]²+ [Δh/(KhSh)]² + ΔR}^1/2

The WI_D index is highly correlated with the visual perception registration. The 50:50 perceptibility (WPT) and acceptability (WAT) thresholds were established at 0.72 and 2.62 WI_D units, respectively [24]. It is calculated from the parameters L, a*, and b* according to the following formula:

WI_D = 0.511L* − 2.324a* − 1.100b*

2.5. Microhardness Evaluation

Microhardness was evaluated before and after treatment using a microhardness tester (HMV-2000, Shimadzu, MD, USA) with a Knoop-type penetrator and a static load of 25 g for 10 s. The specimens were positioned perpendicularly to the identifier, and the Knoop microhardness values were calculated using CAMS-WIN software (New Age Industries, Southampton, PA, USA). Three indentations were made in the central region of each specimen, with a distance of 100 μm between them.

2.6. Statistical Analisis

The data collected from the color measurements and microhardness evaluation were analyzed using the SPSS statistical software package, version 29.0.10 for Windows (IBM, New York, NY, USA). The distribution of the studied variables was determined using the Shapiro–Wilk test. Since not all variables followed a normal distribution, changes in L, a*, and b* parameters, as well as variations in microhardness for each material before and after each treatment, were compared using the Wilcoxon test.

Changes in the color indexes ΔEab, ΔE00, and WI_D, as well as microhardness, based on the material and the whitening treatment applied, were compared using two-way ANOVA, followed by the Games–Howell post hoc test. A significance level of p < 0.05 was used in all cases.

3. Results

3.1. Color Changes

The variations in the CIELab parameters for each material before and after treatment with the toothpaste were compared using the Wilcoxon test. For the Luna 2 composite, the lightness and the “a” component did not show significant changes with any of the pastes used. As for the “b” component, it was significantly reduced in all treatment groups, indicating a shift towards blue, ranging from 2.18 points in the group treated with Colgate Max to 1.33 with the control paste (

Table 2. Comparison of color parameters in the CIELab space before and after treatment.

Colgate Fresh Gel (Control)
A	L	p	a	p	b	p
Luna 2/before	88.80 ± 1.57	0.13	−2.50 ± 0.65	0.06	15.50 ± 3.97	<0.001
Luna 2/after	89.12 ± 1.37		−2.22 ± 0.69		14.07 ± 3.52
Colgate Max White
Luna 2/before	89.53 ± 1.73	0.30	−2.21 ± 0.55	0.12	14.68 ± 3.36	<0.001
Luna/after	89.12 ± 1.71		−1.98 ± 0.78		12.10 ± 3.21
Yotuel
Luna 2/before	89.86 ± 048	1	−1.99 ± 0.43	0.44	15.22 ± 1.54	<0.001
Luna 2/after	89.75 ± 1.01		−1.88 ± 0.49		13.73 ± 1.50
Crest 3D White
Luna 2/before	89.46 ± 0.55	0.47	−1.78 ± 0.32	0.72	15.16 ± 2.04	<0.001
Luna 2/after	89.33 ± 1.25		−1.81 ± 0.59		13.61 ± 2.47
Colgate Fresh Gel (Control)
B	L	p	a	p	b	p
Stela/before	84.25 ± 3.27	0.09	1.71 ± 0.43	0.17	19.57 ± 2.80	0.01
Stela/after	85.96 ± 1.84		1.26 ± 0.33		17.02 ± 1.56
Colgate Max White
Stela/before	82.70 ± 1.69	0.41	1.33 ± 0.17	0.12	19.84 ± 1.38	<0.001
Stela/after	83.63 ± 2.08		1.59 ± 0.41		15.20 ± 2.09
Yotuel
Stela/before	83.37 ± 1.93	0.22	0.91 ± 2.57	<0.001	19.15	<0.001
Stela/after	84.03 ± 2.21		1.42 ± 0.25		16.32
Crest 3D White
Stela/before	84.27 ± 1.99	0.45	1.37 ± 0.31	0.93	18.05 ± 1.11	0.07
Stela/after	82.78 ± 2.81		1.51 ± 0.29		15.81 ± 1.34
Colgate Fresh Gel (Control)
C	L	p	a	p	b	p
Activa Presto/before	84.80 ± 1.13	0.65	1.80 ± 0.14	1	26.65 ± 0.21	0.08
Activa Presto/after	84.05 ± 0.49		1.80 ± 0.14		25.75 ± 0.63
Colgate Max White
Activa Presto/before	86.05 ± 1.90	0.12	2.80 ± 0.28	0.89	29.05 ± 1.48	0.03
Activa Presto/after	87.25 ± 0.77		2.89 ± 0.14		24.90 ± 2.26
Yotuel
Activa Presto/before	85.90 ± 0.14	0.04	1.70 ± 0.56	0.65	30.60 ± 1.97	0.04
Activa Presto/after	89.15 ± 0.49		1.45 ± 0.07		26.15 ± 0.63
Crest 3D White
Activa Presto/before	84.70 ± 2.82	0.03	1.35 ± 0.63	0.31	25.40 ± 4.10	0.65
Activa Presto/after	88.50 ± 1.41		1.50 ± 0.42		24.20 ± 2.12

A).

In the Stela resin disks, lightness also did not vary significantly with any of the pastes used, although a slight increase was observed except in the group brushed with Crest 3D White, where a decrease of 1.49 points was found. The a* parameter shifted to green by 0.51 points after brushing with Yotuel paste (p < 0.001). Samples brushed with Colgate Max White and Crest 3D White also showed a non-significant shift to green of 0.26 and 0.14 points, respectively, while after brushing with the control paste, a non-significant decrease of 0.45 points was observed. A significant decrease in the b* component was recorded in all groups, around three points (shift to blue) (Table 2B).

In the Activa Presto composite group, lightness significantly increased in the subgroups treated with Yotuel and Crest 3D White, in all groups except in the control paste group. The a* component shifted to green with Colgate Max White and Crest 3D White, although non-significantly, and to red by 0.25 points with Yotuel paste. The b* parameter showed a shift to blue, ranging from 4.15 points in the Colgate Max White group to 0.9 points for the control paste, being significant for the subgroups treated with Colgate Max White and Yotuel (Table 2C).

In

Table 3. Variations in ΔE_ab, ΔE₀₀, and ΔWI_D based on the composite and toothpaste.

	Colgate Fresh Gel (Control)	Colgate Max White	Yotuel	Crest White
	ΔEab
	mean ± SD	mean ± SD	mean ± SD	mean ± SD
Luna 2	1.59 ± 0.52 aA	2.86 ± 1.27 aA	1.89 ± 0.66 A	2.08 ± 2.11 A
Stela	4.28 ± 1.73 A	5.46 ± 1.43 a,b,A	3.38 ± 1.32 a,A	3.75 ± 1.80 b
Activa Presto	4.12 ± 0.69	4.37 ± 1.04	5.72 ± 1.69 A	4.08 ± 1.02 A
	ΔE00
Luna 2	0.97 ± 028 a,A	1.84 ± 0.77 a,b,A	1.23 ± 0.40 b,A	1.42 ± 1.28
Stela	2.58 ± 1.05 A	3.30 ± 1.07 a,b,A	2.11 ± 0.74 a,A	2.40 ± 1.17 b
Activa Presto	2.05 ± 0.43	2.11 ± 0.62	2.96 ± 0.45 A	3.57 ± 0.90
	ΔWID
Luna 2	1.08 ± 0.56 A,B	2.14 ± 1.33 A	1.32 ± 1.21	1.61 ± 1.78
Stela	4.72 ± 3.08 a,b,A	4.97 ± 1.61 c,d,A	2.26 ± 1.57 a,c	1.37 ± 1.86 b,d
Activa Presto	3.90 ± 0.29 B	5.17 ± 2.41 A	3.13 ± 3.70	2.44 ± 1.94

Values with the same superscripts (uppercase or lowercase) within the same column or row, respectively, for each index are significantly different (two-way ANOVA test, significance threshold of p < 0.05).

, the changes in the color indexes calculated based on the material and toothpaste used are summarized, analyzed using a two-way ANOVA test. The Luna 2 resin showed the least color change compared to the other two resins for all indexes, with significant differences after treatment with the control paste, Colgate Max White, and Yotuel for the Δab and ΔE₀₀ indexes (p < 0.05).

The composite resins treated with Colgate Max White experienced the greatest color change, with the Δab and ΔE₀₀ indexes significantly higher compared to the control paste (p < 0.05).

For all resins, regardless of the toothpaste used, ΔE₀₀ was found to be within the clinically acceptable range (>0.8 and ≤3.6). Regarding ΔWI_D, Stela and Activa Presto showed values above the acceptable limit (>2.62) after being treated with the control paste, and with Colgate Max White, as well as Activa Presto treated with Yotuel.

3.2. Microhardness Changes

The variations in microhardness are shown in Figure 3. It can be observed that the mean microhardness values before treatment were higher for the Luna composite (77.47 ± 3.73), followed by Stela (76.24 ± 3.23) and Activa Presto (74.50 ± 2.59), although there were no significant differences between the three materials (p > 0.05). Comparing the values for each material before treatment and after brushing with the different pastes under study, no significant differences were found (p > 0.05).

4. Discussion

The results of this study provide information on the effects of different composite resins and whitening toothpastes on color change and surface hardness, contributing to the understanding of their clinical performance in esthetic dental restorations. As the results demonstrate, color change was influenced by the type of restorative material and toothpaste used, leading to the rejection of the first null hypothesis.

Recently, new nanohybrid composites that claim to release fluoride, calcium, and phosphate ions have been introduced to the market. These materials are referred to as bioactive. Bioactive resin composites represent a transformative approach, particularly in their enhanced capacity to inhibit caries adjacent to the restoration compared to traditional resin composites [14]. While the ion release from bioactive materials provides significant therapeutic benefits, it may also affect the material’s mechanical and esthetic properties, potentially compromising the material’s overall durability and longevity [17]. Activa Presto and Stela would fall into this group of materials with the capacity to release ions, as they contain fluoroaluminosilicate glass and other ion-active fillers [17,25].

Three materials were selected for this study: one conventional nanohybrid composite (Luna 2), which served as a control, and two bioactive composites, Activa Presto and Stela.

Luna 2 is a conventional nanohybrid composite, with long-chain cross-linking monomers intended to reduce intermonomer distance within a polymer compared to shorter cross-linking monomers [26]. The manufacturers claim that the filler formula is designed for excellent polishing results, wear resistance, and longevity.

Activa Presto is a stackable, low-flow composite that supports remineralization through its methacrylate-functionalized calcium phosphate (MCP) molecule and fluoride [17].

Stela is a bulk-fill, self-curing composite that comes in a single color and two formats: capsules and an automix syringe. In the present study, the automix presentation was used. Since it does not require light for polymerization, in experimental studies, it has demonstrated greater bonding performance and fewer gaps at the interfaces compared to other light-curing composites [25]. The polymerization of Stela is initiated when it contacts the primer, accelerating the reaction at the tooth/primer–resin interface. This system uses a novel primer, free from tertiary amines, and includes glycerol-dimethacrylate (GDMA), which may enhance polymerization, mechanical properties, and adhesion to dentin, and reduce water uptake and solubility [27]. ST Automix is formulated with various fillers, including strontium fluoroaluminosilicate, ytterbium trifluoride, and calcium aluminate [25]. However, this novel automixed composite material (ST) has rarely been studied.

Four different toothpastes were used: one conventional non-whitening toothpaste and three whitening toothpastes. The whitening toothpastes were selected based on their active ingredients, either erosive and abrasive agents alone (Colgate Max White) or a combination of abrasives and CP or HP (Yotuel and Crest 3D White). To simulate the effect of three months of use, each disk was brushed for 90 s per day for 10 consecutive days. Assuming that there are 28 teeth in the mouth, the maximum contact time of a tooth was determined as 10 s, based on the recommended 2 min of brushing twice a day [28].

Changes in lightness (L), red–green distance (a*), and yellow–blue distance (b*) were determined for each material and toothpaste used to establish which parameters showed the greatest variation. It was found that the parameter b* (yellow–blue distance) had the greatest influence on the color change of the different materials. It should be noted that neither lightness nor the a* component showed significant differences for almost any material, regardless of the dentifrice used, although small variations were found in most cases. Only for Activa Presto with the dentifrices containing CP and HP (Yotuel and Crest 3D White) was a significant increase in lightness found. A yellow-to-blue tooth color shift (decrease in the b* value) is one of the important factors influencing the perception of teeth as being whiter [29].

Yotuel and Crest 3D White also incorporate titanium dioxide (TiO₂) in their compositions. The catalytic action of TiO₂ has strong oxidative power and chemical stability, and is influenced by reactions with its surface molecules. This process can be influenced by several factors, such as catalyst concentration, particle size and shape, pH, and substrate surface [30]. Due to this catalytic action, some studies have found that its incorporation into bleaching agents with low concentrations of HP can promote a greater release of free radicals and, consequently, a more effective bleaching effect, which can be enhanced if subjected to light [31]. TiO₂ is incorporated to provide opalescence in natural teeth in restorative materials [32]. Brushing with toothpastes containing TiO₂ may contribute to increasing the opacity of restorative materials and modifying their color, as has been shown in other studies [33]. In the present study, significant changes in lightness were only found with Yotuel and Crest 3D White when applied to Activa Presto, which could be due to an increase in the opacity of the material because of the composition of the dentifrices.

Colgate Max White was the toothpaste that produced the most significant changes compared to the control for all the evaluated composites in the ΔE_ab, ΔE_{00, and} ΔWI_D indexes. This paste contains abrasive and erosive agents in its composition.

The response to color change was found to be influenced by the type of resin and by the dentifrice tested, so the first null hypothesis was rejected.

Achieving acceptable esthetics in dentistry requires accurately matching and reproducing the color appearance of dental materials, teeth, and other oral tissues. Visual assessment remains the most commonly used method for evaluating color. Therefore, a thorough understanding of perceptual thresholds within the dental color space is essential for interpreting color differences in both clinical practice and dental research. The perceptibility and acceptability thresholds defined by ΔE₀₀ and ΔWI_D function as quality control tools to support the assessment of clinical performance in dentistry [34]. To ensure the accuracy of the results according to human visual perception, ΔE₀₀ and WI_D indexes were calculated. The results indicate that using the ΔE₀₀ index, Stela and Activa Presto changed color in the “moderately unacceptable” range (AT > 1.8 units). Using the WI_D index, Stela and Activa Presto showed unacceptable values for the WI_D index with the control paste, Colgate Max White, and Activa Presto also with Yotuel (AT > 2.62 units). This may indicate that the WI_D index is more sensitive in assessing changes in tooth color and more comprehensively evaluates the color alteration process and its acceptability [35].

The amount of organic components is a factor that can influence the more pronounced color changes in bioactive composites [17,28]. The conventional resin Luna 2 is composed of 23% organic phase by weight; Stela has 39%; and Activa Presto has 46%. In the present study, Luna 2 was the only material that maintained the color change in the acceptable range. Its chemical characteristics and higher amount of filler by wt% could justify this finding.

Tooth whitening is one of the fastest growing areas in cosmetic and restorative dentistry [36]. Whitening toothpastes are a widely used alternative by patients to lighten the color of their teeth in pursuit of a better esthetic appearance. This can contribute to an improved sense of well-being and even enhance self-esteem [37]. However, as shown in the results of the present study, bioactive restorative materials may be affected by whitening toothpastes, potentially requiring the replacement or repair of restorations, especially in areas with esthetic importance.

As described in the literature, pastes containing peroxides can cause degradation of the organic component of resins due to oxidative free radicals (ROS), which would increase the roughness and reduce the microhardness of the resins [38,39,40]. However, in the present study, no changes in microhardness were found for any of the materials tested or with any of the pastes used for brushing. Therefore, the second null hypothesis was accepted. This may be due to the fact that the paste remains in contact with the composite for a very short time, which reduces this adverse effect. Some studies indicate that the degradation capacity of composite resins is more related to the exposure time to bleaching agents than to the concentration [41,42]. Three months of treatment were simulated in the present study, which may limit the results obtained with respect to microhardness. Also the simulated exposure time for each sample (90 s for each cycle) could influence the result.

Studies have shown that microhardness values of a composite can be affected by several factors, such as organic and inorganic composition, filler content (wt%), distribution on the surface, degree of C=C conversion in methacrylate groups, and cross-linking density [43,44,45]. As demonstrated in the study by Binhasan et al., different responses were found for nanohybrid composite materials when treated with whitening pastes. They found that materials with zirconium particles in their composition were more stable with respect to hardness after brushing with whitening dentifrices [46]. In the present study, the initial microhardness obtained for Luna 2 was similar to that found in the literature [47] and higher than that of the other two materials. However, the values for Stela and Activa Presto were higher than those found in the literature [46]. It should be noted that the amount of load by weight of the materials studied before treatment follows the same trend as the microhardness, i.e., higher for Luna2, followed by Stela Mix and Activa Presto.

5. Conclusions

After analysis of the data from the present study, and within the limitations of this current study, the following conclusions can be made: Hypothesis 1: the b* component was the most reduced. All composites changed color after brushing with whitening pastes in ranges between “moderately acceptable” and “moderately unacceptable.” Colgate Max White produced the greatest changes, with Luna2 being the composite with the least color variation. Hypothesis 2: no changes in microhardness were found in any material or with any of the dentifrices evaluated.

From a clinical point of view, it must be taken into account that bioactive resins undergo color changes over time due to brushing, particularly when using toothpastes containing erosive and abrasive agents. This should be considered in clinical practice, and patients should be informed of the need to replace restorations over time, especially when these resins are placed in esthetically sensitive areas.