Color Stability of CAD/CAM Interim Material for Long-Term Fixed Dental Prostheses vs. Conventional Materials after Immersion in Different Staining Solutions

Abstract

The color stability of interim computer-aided design and computer-assisted manufacturing (CAD/CAM) materials has not been exhaustively investigated. The aim of this study was to compare the translucency (TP) and contrast ratio (CR) of CAD/CAM blocks and conventional interim materials, as well as the effects of varnish application and tooth-brushing on color stability after immersion in different staining solutions. Four hundred and eighty specimens were fabricated with four different interim materials (n = 120) and were divided into three experimental, and one control group (n = 30). The color measurements were taken at the initial time (T0), 24 h (T1), 7 days (T2), and 30 days (T3) after immersion in different solutions. CIEDE2000 (ΔE₀₀) values were analyzed with ANOVA and Fischer’s LSD test with a 95% confidence interval. The relationship between TP and CR was analyzed with a Pearson correlation. All interim materials showed a significant difference (p < 0.05) in color change after 30 days. Results showed that polyethyl methacrylate resins (PEMA) had the highest stability over time. The TP and CR were statistically significant (p < 0.05). It was observed that brushing improved the color stability but the ΔE₀₀ were the highest when the varnish alone or varnish and brushing were used, except in the bis-acryl group, in which varnish and brushing decreased the color stainability.

1. Introduction

Interim materials should have appropriate mechanical, biological and aesthetic properties until the cementation of the definitive restoration [1,2,3,4]. Powder and liquid methacrylate resins and paste–paste composite resin-based materials have been used in recent years to manufacture interim restorations [5,6]. These materials can be polymerized by different reactions (chemical, light or dual reactions) that are activated by one or several initiators (benzoyl peroxide activated by a tertiary amine or camphorquinone) [1,5]. A number of interim resins are used in clinical practice; the most widely used are polymethyl methacrylate resins (PMMA), polyethyl methacrylate resins (PEMA), and resins based on multifunctional methacrylic acid esters (bis-acryl) [4,6].

One of the drawbacks of interim materials when exposed to the oral environment is their propensity to change color. The degree of color change is affected by exogenous and endogenous factors. Exogenous factors include patient habits, such as diet, tooth brushing or staining solutions, namely coffee, red wine, and black tea, among others. Endogenous factors include the initiator systems, polymerization, matrix composition, particle size, hardness, water sorption, hydrolysis, oxidation of the unreacted carbon double bonds [6,7,8,9,10,11,12,13,14], and surface roughness [15]. In order to overcome some of the problems related to the amount of powder and liquid or paste–paste mixed, manufacturers have recently introduced blocks for interim restorations to computer-aided design and computer-assisted manufacturing (CAD/CAM) [16]. These blocks are mainly based on polymethyl methacrylates (PMMAs), which are industrially polymerized at high pressure and temperature, a process that significantly increases fracture load compared with conventional interim materials [17,18,19].

Considering the increase in surface roughness and the decrease in material brightness with tooth brushing, which affect the aesthetic quality of the restoration [20,21,22], some studies have proposed the use of sealant agents or varnish to cover the interim restoration surfaces to fill the irregularities in order to reduce porosity, increase wear resistance, and reduce the color stainability of the material [23,24,25,26,27,28]. However, a recent study suggested that a resin sealant may provide adequate protection for surfaces in the short term, but repeated applications are necessary for surfaces requiring protection over the longer term [29].

Research findings have pointed to qualitative and quantitative approaches to evaluate color differences. Qualitative methods are based on a subjective comparison of the specimen with a shade guide, while quantitative evaluations use a spectrophotometer to prevent bias due to human perception limits [1,7,11,30]. Several dental studies of color have applied the parameters of the Commission Internationale de l‘Eclairage Color System (CIE). According to the CIELAB system, color relates to the proportions of the three basic colors: red, blue and green [1,31]. A spectrophotometer expresses measurements in terms of three coordinate values (L*, a*, b*). The L* coordinate represents the brightness; the a* value represents red or green chroma; and the b* value represents the yellow or blue chroma [1]. The CIELAB formula has been the classical parameter for color measurements. However, in order to analyze color stability with better adjustment, acceptability, and human perceptibility, some authors have recommended using the CIEDE2000 (ΔE₀₀) instead of the CIELAB (ΔEab) color-difference formula [32,33,34] The CIEDE2000 formula was published by CIE in 2001; it reinforces the conceptual developments of the Munsell system by using concepts of lightness, chroma, and hue, with an interaction between chroma and hue, providing much better fits for the experimental data characterized by small color differences [34,35,36,37].

In addition, other researchers have reported color parameters to evaluate translucency and opacity, such as the translucency parameter (TP) and contrast ratio (CR), both of which are based on CIE colorimetry. Translucency is known as the state between complete transparency and complete opacity, which occurs when a light beam passes through the material and part of the light is transmitted and reflected through the object. If the material is completely opaque TP = 0, and the light passes completely through the object, translucency will be greater [38,39,40,41,42,43,44]. A contrast ratio (CR) is defined as the ratio of the luminance of the brightest color (white) to that of the darkest color (black), resulting in the capacity of the material itself to hide a background [11,40]. This parameter depends upon the thickness of the material and the reflectance of the background [42,43,44]. Little research has been published comparing the color stability of CAD/CAM interim blocks with conventional interim materials. Furthermore, to our knowledge, no studies have evaluated the effect of brushing and varnish protection over these materials when they are immersed in staining solutions. The aim of this study was to compare the translucency and contrast ratio between CAD/CAM blocks and conventional interim materials, as well as the effect of varnish application and tooth-brushing on color stability after immersion in different staining solutions. Therefore, the two null hypotheses of the study were that: 1. No difference would be found in color stability between CAD/CAM blocks and conventional interim materials after being immersed in different staining solutions for four weeks; and 2. Varnishing and brushing do not influence the color stability of the material.

2. Materials and Methods

Three interim materials for the direct technique and one material for the CAD/CAM technique were used to fabricate four hundred and eighty specimens in accordance with the manufacturer’s recommendations, and these were divided into three experimental groups (brush (n = 30); varnish (n = 30); and brush–varnish (n = 30)) and one control group (without brush and varnish (n = 30)) (

Table 1. Provisional materials used in the study.

Dental Materials (n) *	Product Name (Manufacturer)	Composition **	Groups			Batch Numbers
			Code	Brushing	Varnish (Easy Glaze)
Bis-acryl (n = 120)	Structur 3 (VOCO GmbH)	Urethane dimethacrylate (UDMA), bisphenol A-glycidyl methacrylate (Bis-GMA), benzoyl peroxide.	S3	NO	NO	1212333
			S3B	YES	NO
			S3V	NO	YES
			S3BV	YES	YES
Polyethyl methacrylate (n = 120)	Trim (Bosworth)	P: ethyl methacrylate pre-polymers, benzoyl peroxide, pigments, TiO2. L: isobutyl methacrylate, di-butyl phthlate, dimethyl-p-toluidine.	T	NO	NO	P: 1206–284 L: 1206–286
			TB	YES	NO
			TV	NO	YES
			TBV	YES	YES
Polymethyl methacrylate (n = 120)	DuraLay Crown &- Bridge (Reliance)	P: benzoyl peroxide, dialkyl phthalate, residual monomers, titanium dioxide, mineral pigment, disazo pigment. L: methyl methacrylate.	DL	NO	NO	P: 092611 L: 091411
			DLB	YES	NO
			DLV	NO	YES
			DLBV	YES	YES
Polymethyl methacrylate blocks for CAD/CAM (n = 120)	Telio CAD (Ivoclar Vivadent)	Polymethyl methacrylate (PMMA)	TC	NO	NO	R29681
			TCB	YES	NO
			TCV	NO	YES
			TCBV	YES	YES

P, powder; L, liquid. * 120 specimens per material were subdivided into groups of 30 specimens (n = 30). ** Information provided by the manufacturers’ safety data sheets. CAD/CAM: computer-aided design and computer-assisted manufacturing.

). The sample size was determined by using sample size and power calculator software (GRANMO; Institut Municipal d´Investigació Mèdica, Barcelona, Spain). Figure 1 shows a diagram of the study design.

A stainless steel mold was used to make the interim material specimens for the direct technique. The mold was held between two glass slides, which were gently pressed together to eliminate excess material. Each direct technique specimen had a diameter of 10 ± 0.1 mm and a height of 2 ± 0.05 mm, and blocks of polymethyl methacrylate (Telio CAD; Ivoclar Vivadent, Schaan, Liechtenstein) were cut into 2 mm slices with a ½ inch (12.7 mm) diamond specimen with the Isomet 1000 Precision Saw (Buehler, Esslingen am Neckar, Germany).

Once the specimens had been made, they were polished on the edges only with grit sandpaper (P.320; Hitech Europe MP Series, Corsico, Italy) at 50 rpm. Then, the specimens were calibrated by using a digital calibrator to verify the size to 2 ± 0.05 mm thickness in order to achieve standardization. Finally, a small mark was made on the surface of the specimen to identify the same side for the color measurements. Varnish (Easy Glaze; VOCO GmbH, Cuxhaven, Germany) was applied over the surface of half of the specimens following the manufacturer’s instructions.

Afterwards, five specimens per experimental group and staining solution were placed into 24-well cell culture plates, immersed in distilled water for rehydration and then left in a stove (Memmert) at 37 °C for 24 h. The specimens were then dried with gauze and the baseline color was measured (T0) with the spectrophotometer (SpectroShade; Micro-Dental Spectrophotometer MHT;Arbizzano di Negar, Italy). The pH of the solution was measured during each solution replacement to verify its quality, and the specimens were then immersed in 2 mL staining solutions (

Table 2. Staining solutions used in the study.

Scheme (n) *	Manufacturer	pH ** (SD)	Abbreviation
Distilled water (n = 20)	SOSMI S.A, Spain	6.73 (0.62)	DW
Orange juice (n = 20)	Pascual, Spain	3.77 (0.19)	OJ
Black tea (n = 20)	Classics English Breakfast Tea, Twining, England	5.03 (0.25)	BT
Coffee (n = 20)	Nescafé Classic, Nestlé, Spain	4.83 (0.11)	CF
Red wine (n = 20)	Don Simon, Spain	3.50 (0.10)	RW
Coca-Cola (n = 20)	Coca-Cola, The Coca-Cola Company, Spain	2.57 (0.15)	CC

* (n = 20) specimens per material in each solution. ** pH is a mean of values obtained during each solution replacement. SD: standard deviation.

). Before each measurement, the spectrophotometer was calibrated according to the manufacturer’s instructions, by using the calibration supply and during measurements of each specimen. The color was measured in a black room without windows using black and white backgrounds to minimize the influence of external light on the borders of each specimen.

2.1. Color Evaluation

Color measurements were measured with the same procedure before staining (T0) and after immersion in staining solutions after 24 h (T1), 7 days (T2), and 30 days (T3). Twice a week, the staining solution was replaced, and half of the whole specimen was brushed for 10 s with an electric toothbrush (Oral-B Professional Care Triumph 5000) impregnated with Colgate toothpaste (Colgate-Palmolive); each solution had its own brush head. Silicone holders were used to fix the specimens and the toothbrush in the same horizontal positions. The brush operated at 8800 oscillations–rotations per minute and 40,000 pulsations per minute [26].

The same protocol of changing the staining solutions twice a week was followed for the duration of this study.

Each specimen with a black background was analyzed by using the SpectroShade program. The image was opened and a contour of 300 μm was established with the metric tool; this same tool was used to locate the center of the specimen. The analysis was undertaken following the same steps; in this way, the procedure was standardized for each specimen and each measurement was made in the same center spot.

Calculation for the CIEDE2000 (ΔE₀₀) color difference was performed according to Equation (1) [35,36,45]:

$$∆E_{00 }={\left[{(\frac{\Delta L^{\prime }}{K_L{S}_L})}^2+{(\frac{\Delta C^{\prime }}{K_C{S}_C})}^2+ {(\frac{\Delta H^{\prime }}{K_H{S}_H})}^2+ R_{T }\left(\frac{\Delta C^{\prime }}{K_C{S}_C}\right)\left( \frac{\Delta H^{\prime }}{K_H{S}_H}\right)\right]}^{1/2}$$

(1)

For this analysis, the CIEDE2000 color-differences formula in Microsoft Excel (Excel 14.5.7, Mac, Microsoft Corporation, Redmond, DC, USA) was used, as proposed by Sharma et al. [35].

To determine the acceptability and perceptibility thresholds of color change, we used the parameters described by Ghinea et al. in 2010. The color change was clinically acceptable when ΔE₀₀ = 2.23 and considered perceptible when ΔE₀₀ = 1.25 [34].

2.2. Translucency Parameter (TP)

TP values were determined by calculating the color differences against black and white backgrounds for the same specimen, according to the Equation (2) [38,41,44]:

TP = [(ΔL_B* − ΔL_W*)² + (Δa_B* − Δa_W*)² + (Δb_B* − Δb_W*)²]^1/2

(2)

where the subscripts B and W refer to the color coordinate values obtained against black and white backgrounds, respectively.

2.3. Contrast Ratio (CR)

The CR values were calculated from the spectral reflectance (Y) of the specimens with a black (Y_B) and white (Y_w) background as follows in the equation 3 [39,44]:

CR = Y_B/Y_w

(3)

The specimens with CR = 0.0 and CR = 1.0 were considered transparent and totally opaque materials, respectively [39].

2.4. Statistical Analysis

Two-way ANOVA was performed to determine the color change (ΔE₀₀) between materials and treatments, and the Fisher’s post hoc test was used for multiple comparisons between groups. Pearson’s correlation test was used to analyze the relationship between TP and CR values. A confidence level of 95% was used in all tests. Statistical analysis was performed with a statistical software program (StatGraphics Centurion XV, StatPoint Technologies, Inc.; Warrenton, VA, USA).

3. Results

3.1. Color Change Evaluation

The two-way repeated measures ANOVA showed a significant difference (p < 0.05) in the color changes (ΔE₀₀) of all tested materials after being immersed in different staining solutions for 30 days. Regarding the stability of the materials tested, ΔE₀₀ (T3) values showed that PEMA had the highest stability over time, followed by PMMA, PMMA blocks for CAD/CAM, and finally bis-acryl, which obtained the greatest color change (

Table 3. Mean of the color changes (ΔE₀₀) for each material immersed in different staining solutions according to the time (Equation (1)).

Material	ΔΕ00
	ΔΕ00 (T1) (SD)	ΔΕ00 (T2) (SD)	ΔΕ00 (T3) (SD)
Bis-acryl (Structur 3)	1.82 c (1.42)	2.88 c (2.30)	5.52 c (4.89)
PEMA (Trim)	1.08 a (0.87)	2.11 a (1.34)	3.08 a (1.64)
PMMA (DuraLay)	1.32 b (1.06)	2.55 b (1.80)	3.39 a (1.85)
PMMA blocks for CAD/CAM (Telio CAD)	1.53 c (1.07)	2.40 a,b (1.80)	3.83 b (3.51)

Values with the same uppercase letter do not differ significantly (p > 0.05). T1: 24 h; T2: 7 days; T3: 30 days. SD: standard deviation. The mean values correspond to 30 specimens per material immersed into six staining solutions with black background.

).

Regarding the color stability of the groups,

Table 4. Mean of color stability (ΔE₀₀) for each group immersed in different staining solutions according to the time (Equation (1)).

Material	Groups	Mean ΔE00
		ΔΕ00 T1 (SD)	ΔΕ00 T2 (SD)	ΔΕ00 T3 (SD)
Bis-acryl	S3	1.83 e,f (1.33)	4.09 i (2.93)	7.41 i (6.15)
	S3B	1.67 d,e (1.31)	2.70 f,g (1.58)	5.14 h (3.33)
	S3BV	1.52 c,d (1.01)	1.77 a,b (1.24)	4.42 e,f (4.48)
	S3V	2.24 g (1.85)	2.93 g,h (2.48)	5.11 g,h (4.87)
Polyethyl methacrylate	T	1.12 a,b (0.68)	2.23 c,d,e (0.98)	3.30 b,c (1.08)
	TB	0.86 a (0.39)	1,74 a (1.08)	2,54 a (1.01)
	TBV	1.35 b,c (1.16)	2.33 d,e,f (1.13)	3.18 b,c (1.83)
	TV	0.99 a,b (1.01)	2.13 b,c,d,e (1.94)	3.31 b,c (2.24)
Polymethyl methacrylate	D	1.13 a,b (0.65)	2.00 a,b,c,d (0.56)	2.88 a,b (1.02)
	DB	1.06 a (0.56)	1.89 a,b,c (0.55)	2.51 a (0.77)
	DBV	1.57 c,d,e (1.35)	3.03 g,h (1.63)	3.94 d,e (1.91)
	DV	1.50 c,d (1.35)	3.29 h (2.90)	4.22 d,e,f (2.58)
Polymethyl methacrylate blocks for CAD/CAM	TC	0.91 a (0.62)	2.45 e,f (2.25)	3.86 d (3.71)
	TCB	1.03 a (0.70)	1.72 a (1.15)	3.20 b,c (3.27)
	TCBV	1.99 f,g (1.16)	2.32 d,e,f (1.63)	3.70 c,d (3.29)
	TCV	2.18 g (1.10)	3.11 h (1.80)	4.59 f,g (3.78)

Values with the same lower case superscript letters within column denote groups whose color does not differ significantly for each staining solution (p > 0.05) (a = low staining and i = high staining). The method used to discriminate among the means is Fisher’s least significant difference (LSD). T1: 24 h; T2: 7 days; T3: 30 days. SD: standard deviation. Letter B in the groups denote brushing process and groups with letter V indicate varnish application. The mean values correspond to five specimens per group immersed in six staining solutions with black background.

shows the ΔE₀₀ black background mean values of each group after 24 h (T1), 7 days (T2), and 30 days (T3). Furthermore, Figure 2 and Figure 3 show the ΔE₀₀ black background mean values of each group and staining solution after four weeks (T3). For the PEMA material, the TB group obtained the highest stability after T3 with statistical significance respect to T, TBV, and TV (p < 0.05). In the PMMA material, DB had less color changes compared with D, DBV and DV (p < 0.05). The PMMA blocks for CAD/CAM showed the highest color stability in the TCB group, with statistical significance (p < 0.05), followed by TC, TCBV and TCV. Finally, bis-acryl material obtained the greatest color stability in the S3BV group (p < 0.05) followed by S3B and S3V without significant difference, and the S3 group with the least color stability.

For the different groups evaluated, the highest staining potential values were observed in the red wine solution followed by coffee, black tea, orange juice, Coca-Cola, and distilled water (p < 0.05) (Figure 2).

When each group was analyzed with a clinical perceptibility threshold (PT) and clinical acceptability threshold (AT), the results showed that in the first day (T1) TB, TC, TV, TCB, DB, T, and D groups were in the PT (ΔE₀₀ = 0.91–1.13), while the other groups maintained AT within a range of ΔE₀₀ = 1.83–2.23.

In T2 (7 days), all the groups were above PT. However, TCB, TB, S3BV, DB, D, and TV groups maintained AT with a range of ΔE₀₀ = 1.72–2.13. Finally, in T3 (30 days), all the groups were out of the threshold.

3.2. Translucency Parameter and Contrast Ratio

The mean translucency values measured by TP and CR were statistically significant (p < 0.05). These methods showed a strong correlation (r² = 0.96), as seen in

Table 5. Mean of initial (T0) translucency parameter (TP) and contrast ratio (CR) by material.

Material	TP (SD)	CR (SD)
Bis-acryl	15.45 d (0.78)	1.40 d (0.02)
PEMA	11.70 b (1.39)	1.34 b (0.05)
PMMA	7.14 a (0.57)	1.22 a (0.03)
PMMA blocks for CAD/CAM	13.37 c (0.63)	1.38 c (0.03)

Different letters show statistical differences of mean values within the parameter (column) (p < 0.05); Fisher’s least significant difference. SD: standard deviation.

.

4. Discussion

The first null hypothesis of the study was partly accepted because the CAD/CAM blocks had a color-difference from some conventional materials (PEMA and bis-acryl) after immersion in staining solutions for four weeks. The second null hypothesis was accepted but should be analyzed separately regarding varnish and brushing.

In this study, four materials were used (PEMA, PMMA, PMMA blocks for CAD/CAM, and bis-acryl); each material was divided into four groups, which were exposed to different surface treatments and immersed in six staining solutions. The color values were analyzed by using CIEDE2000 but to our knowledge, no studies exist comparing the color stability of PMMA blocks for CAD/CAM with conventional interim materials with and without varnish and brushing.

To analyze the color stability in the present study, we accounted for perceptibility (PT) and acceptability (AT) thresholds 50:50% published in 2010, which uses TSK Fuzzy Approximation in preference to an S-shaped curve due to the slightly higher accuracy of the former. The perceptibility threshold was ΔE₀₀ = 1.25 (r² = 0.89) and the acceptability threshold was 2.23 (r² = 0.89) [34]. In the present study, it was found that all materials values in the first day (T1) were within the parameters of acceptability, however, the bis-acryl material was slightly higher (p < 0.05). From seven days (T2) the mean value showed that all materials were above the acceptability threshold (ΔE₀₀ > 2.23), except the PEMA which obtained ΔE₀₀ = 2.11 (p < 0.05). Ertaş et al. [12] suggest that 24 h of immersion simulates about one month of consumption. Therefore, the values of the present study in T1, T2, and T3 should be equivalent to 1, 7, and 30 months, respectively, in vivo.

Staining is a common problem for all restorative materials after long-term use [46]. Changes in the optical properties have been attributed to the oxidation of the polymer matrix or oxidation of unreacted double bonds in the residual monomers [7]. The results of the present study are in agreement with the others showing high color stability for PEMA materials after 30 days of immersion [13] and the least color stability in bis-acryl materials after immersion in coffee solution [7]. Furthermore, the present findings accord with those of studies where more color stability was obtained in PMMA than in bis-acryl materials [4,47].

The color stability of organic molecules is related to their capacity to absorb light into energy levels involving molecular orbitals, which are generally based on covalent chemical bonding in a conjugated system of alternating single and double bonds, which may have attached to it electron donor and acceptor groups [48]. Exogenous and endogenous factors decompose the original molecular structure and organization, disturbing the color stability of the material.

In common with other studies, red wine caused the most staining in all experimental groups, followed by coffee, black tea, orange juice, Coca-Cola, and distilled water [12]. In spite of Coca-Cola having the lowest pH, which might modify the material surface, in the present study it did not have a stainability as high as other solutions such as black tea, coffee, and orange juice [12]. According to Um et al. [14], solutions such as tea and coffee contain yellow colorants, which have different polarities (higher polarity for tea and lower polarity for coffee). The materials immersed in coffee solutions pigmented more than tea because the lower polarity of the solution promotes a high penetration of pigments into the organic phase due to adsorption and absorption processes, whereas solutions with high polarity such as tea do not penetrate easily into the materials, and therefore the pigments can be removed by tooth brushing.

These results are at odds with the suggestions of Dede et al. [23] and Doray et al. [24] who found better results applying the surface varnish because it improved the staining resistances of the interim materials. Similarly to the works of some authors, the present study found that when varnish was applied, the values of color stability exceeded the clinical acceptability parameter (ΔE₀₀ > 2.23) [49,50], probably because, as explained by some authors, surface varnish tends to separate and degrade with tooth brushing [26,27].

Regarding the effect of tooth brushing on the color stability of materials, the present study found better color stability with interim materials such as other authors who brushed their specimens, because some absorbed colorants or surface staining can be removed by tooth brushing [45,51].

Although the Telio CAD is a PMMA block without filler content, and it is possible to create abrasions during brushing, resulting in increased roughness [52], the results described in the present study regarding color stability are favorable.

Finally, to evaluate the translucency parameter (TP) and contrast ratio (CR), in the literature there are no data with optimal or acceptable TP values for dental materials. However, Paravina et al. [38] suggest dividing the TP range into low translucency (TP = 2.0–3.7), medium translucency (TP = 3.8–5.4), and high translucency (TP > 5.5). The results of the present study showed a high TP in all materials evaluated (range TP = 7.14–15.45), with significant differences of translucency (p < 0.05). Considering the TP and CR of interim materials, we agree with the consensus in the literature on when an aesthetic interim restoration is necessary; to hide the background, the restoration should be made with a greater thickness [42,43]. As in previous studies, TP and CR were strongly correlated; when TP decreases CR increases (r² = 0.96) [39,43].

The effect of absorption influence and roughness parameters on color stability should be evaluated in future studies.

5. Conclusions

Within the limitations of this in vitro study, the following conclusions were drawn:

PEMA had the highest stability over time, followed by PMMA, PMMA blocks for CAD/CAM, and finally bis-acryl, which obtained the greatest color change.

From seven days of immersion, the mean value showed that PMMA, PMMA blocks for CAD/CAM, and finally bis-acryl materials were above the clinical acceptability threshold.

The lower staining values were presented in groups with brushing when compared with the other groups (p < 0.05).

The varnish does not reduce the color stainability of materials with different compositions, such as PEMA, PMMA, and PMMA blocks for CAD/CAM. It was more favorable in bis-acryl material.

TP and CR showed a strong correlation for all the interim materials evaluated.