Anti-erosive profile of an experimental 5% SnCl₂ varnish containing different concentrations of NaF

Alencar, Cristiane de Melo; Ribeiro, Mara Eliane Soares; Zaniboni, Joissi Ferrari; Leandrin, Thais Piragine; Silva, Aryvelto Miranda; Campos, Edson Alves de

doi:10.1590/0103-6440202203969

Abstract

This in vitro study evaluated the anti-erosive effect of an experimental varnish containing 5% stannous chloride (SnCl₂) associated with different concentrations of NaF (NaF-free, 2.5% NaF, or 5.2% NaF) on bovine enamel and root dentin. One hundred samples were pre-eroded (0.3% citric acid, pH 2.6, 10 min) and randomized into five groups (n=10 for each substrate): Negative control - milli-Q water; NaF-free - Experimental varnish SnCl₂-free and NaF-free; 2.5 NaF - Experimental varnish 5% SnCl₂ associated with 2.5% NaF; 5.2 NaF: Experimental varnish 5% SnCl₂ associated with 5.2% NaF and positive control - Commercial varnish containing 5% NaF (Duraphat). After the varnishes were applied, the erosive and abrasive challenges were carried out for five days. Loss of tooth structure (TSL) was determined by optical profilometry, and the loss of calcium (ΔCa²⁺) using atomic absorption spectroscopy. Dentin analysis was also performed by SEM. A one-way ANOVA/Bonferroni test was performed to analyze the data (α=0.05). The experimental 2.5 NaF and 5.2 NaF groups showed greater effectiveness in preventing TSL when compared to the other groups (p <0.05), regardless of the substrate. In addition, these groups showed lower loss in Ca²⁺ content when compared to the other groups (p <0.05), for enamel and dentin. Dentin showed greater TSL and ΔCa²⁺ loss when compared to enamel in all treatments (p <0.05). The 5.2% and 2.5% NaF-containing experimental varnishes showed promising results in both, the prevention of TSL and the loss of Ca²⁺, regardless of the substrate studied.

Key Words:
Tooth Erosion; Root dentin; Enamel; Varnish; Sodium fluoride

Resumo

Este estudo in vitro avaliou o efeito anti-erosivo de um verniz experimental contendo 5% de cloreto estanoso (SnCl₂) associado a diferentes concentrações de NaF (sem NaF, 2,5% NaF ou 5,2% NaF) sobre esmalte e dentina radicular bovinos. Cem amostras foram pré-erodidas (ácido cítrico 0,3%, pH 2,6, 10 min) e randomizadas em cinco grupos (n=10 para cada substrato): Controle negativo - água milli-Q; Sem NaF - Verniz experimental sem SnCl₂ e sem NaF; 2,5 NaF - Verniz experimental 5% SnCl₂ associado a 2,5% NaF; 5,2 NaF: Verniz experimental 5% SnCl₂ associado a 5,2% NaF e controle positivo - Verniz comercial contendo 5% NaF (Duraphat). Após a aplicação dos vernizes, os desafios erosivos e abrasivos foram realizados por cinco dias. A perda de estrutura dentária (PED) foi determinada por perfilometria óptica e a perda de cálcio (ΔCa²⁺⁾ por espectroscopia de absorção atômica. A análise da dentina também foi realizada por MEV. Um teste ANOVA/Bonferroni de uma via foi realizado para analisar os dados (α=0,05). Os grupos experimentais 2,5 NaF e 5,2 NaF apresentaram maior eficácia na prevenção de PED quando comparados aos demais grupos (p<0,05), independentemente do substrato. Além disso, esses grupos apresentaram menor perda no teor de Ca²⁺ quando comparados aos demais grupos (p<0,05), para esmalte e dentina. A dentina apresentou maior PED e de ΔCa²⁺ quando comparada ao esmalte em todos os tratamentos (p<0,05). Os vernizes experimentais contendo NaF 5,2% e 2,5% apresentaram resultados promissores tanto na prevenção de PED quanto na perda de Ca²⁺, independente do substrato estudado.

Introduction

During the process of dental erosion, partial demineralization of the enamel and/or dentin surface occurs due to exposure to acidic substances. However, the loss of superficial dental tissue is the result of an association between acid and mechanical challenge simultaneously or alternately ¹1 Carvalho TS, Lussi A. Chapter 9: Acidic Beverages and Foods Associated with Dental Erosion and Erosive Tooth Wear. Monogr Oral Sci 2020; 28: 91-98.. Recently, there was an international consensus on the appropriate terminology to describe the loss of dental structure through erosion and mechanical abrasion: Erosive Tooth Wear ²2 Schlueter N, Amaechi BT, Bartlett D, Buzalaf MAR, Carvalho TS, Ganss C, et al. Terminology of Erosive Tooth Wear: Consensus Report of a Workshop Organized by the ORCA and the Cariology Research Group of the IADR. Caries Res 2020; 54: 2-6..

Frequent ingestion of acidic foods and drinks alters the structural integrity of enamel and dentin and the physical properties of these structures. This process causes the dental surface to soften along with partial loss of this altered structure. Clinically, the chemical-mechanical degradation process, enhanced by mechanical forces, accelerates erosive tooth wear ³3 Carvalho TS, Colon P, Ganss C, Huysmans MC, Lussi A, Schlueter N, et al. Consensus report of the European Federation of Conservative Dentistry: erosive tooth wear - diagnosis and management. Clin Oral Investig 2015; 19: 1557-1561.^,⁴4 Shellis RP, Ganss C, Ren Y, Zero DT, Lussi A. Methodology and models in erosion research: discussion and conclusions. Caries Res 2011; 45: 69-77.. When the acid can diffuse through the acquired enamel pellicle, the hydrogen ions (H⁺) present in the acidic substances damage the apatite crystals present in the enamel and this starts the process of acid erosion¹. If erosive tooth wear is continuous, it can reach the dentin and cause exposure of the dentinal tubules and dentin hypersensitivity ⁵5 Alencar CM, Leite KLF, Ortiz MIG, Magno MB, Rocha GM, Silva C, et al. Morphological and chemical effects of in-office and at-home desensitising agents containing sodium fluoride on eroded root dentin. Arch Oral Biol 2020; 110: 104619..

Therefore, several materials and protocols have been investigated to prevent or minimize erosive dental wear on enamel ⁶6 de Oliveira AF, de Oliveira Diniz LV, Forte FD, Sampaio FC, Ccahuana-Vásquez RA, Tochukwu Amaechi B. In situ effect of a CPP-ACP chewing gum on enamel erosion associated or not with abrasion. Clin Oral Investig2016; 21: 339-346. doi:10.1007/s00784-016-1796-1
https://doi.org/10.1007/s00784-016-1796-... ^,⁷7 da Silva VRM, Viana ÍEL, Lopes RM, Zezell DM, Scaramucci T, Aranha ACC. Effect of Er,Cr:YSGG laser associated with fluoride on the control of enamel erosion progression. Arch Oral Biol 2019; 99: 156-160. and dentin ⁵5 Alencar CM, Leite KLF, Ortiz MIG, Magno MB, Rocha GM, Silva C, et al. Morphological and chemical effects of in-office and at-home desensitising agents containing sodium fluoride on eroded root dentin. Arch Oral Biol 2020; 110: 104619.^,⁸8 Bezerra SJC, Trevisan LR, Viana IEL, Lopes RM, Pereira DL, Aranha ACC, et al. Er,Cr:YSGG laser associated with acidulated phosphate fluoride gel (1.23% F) for prevention and control of dentin erosion progression. Lasers Med Sci 2019; 34: 449-455.. A recent systematic review has shown that the use of stabilized stannous fluoride dentifrices can prevent the onset of tooth erosion ⁹9 Konradsson K, Lingström P, Emilson CG, Johannsen G, Ramberg P, Johannsen A. Stabilized stannous fluoride dentifrice in relation to dental caries, dental erosion and dentin hypersensitivity: A systematic review. Am J Dent 2020; 33: 95-105.. However, to date, no treatment has been considered the gold standard for this important issue, and the number of randomized clinical studies is very small.

Materials containing tin-like polyvalent metal ions (Sr²⁺) have previously shown some anti-erosive potential ¹⁰10 João-Souza SH, Bezerra SJC, de Freitas PM, de Lima NB, Aranha ACC, Hara AT, et al. In situ evaluation of fluoride-, stannous- and polyphosphate-containing solutions against enamel erosion. J Dent 2017; 63: 30-35.. Stannous chloride-based solutions and toothpastes (SnCl₂) have been tested previously showing promising results ¹¹11 Ganss C, Schlueter N, Hardt M, Schattenberg P, Klimek J. Effect of fluoride compounds on enamel erosion in vitro: a comparison of amine, sodium and stannous fluoride. Caries Res 2008; 42: 2-7.^,¹²12 Olivan SRG, Sfalcin RA, Fernandes KPS, Ferrari RAM, Horliana ACRT, Motta LJ, et al. Preventive effect of remineralizing materials on dental erosion lesions by speckle technique: An in vitro analysis. Photodiagnosis Photodyn Ther 2020; 29: 101655.. However, SnCl₂ shows severe solubility ¹³13 de Souza AP, Gerlach RF, Line SR. Inhibition of human gingival gelatinases (MMP-2 and MMP-9) by metal salts. Dent Mater 2000; 16: 103-108.. Stannous has a strong chemical affinity for mineralized dental tissues and promotes a protective effect due to the mechanical formation of a hypermineralized and acid-resistant surface layer ¹⁴14 Cvikl B, Lussi A, Carvalho TS, Moritz A, Gruber R. Stannous chloride and stannous fluoride are inhibitors of matrix metalloproteinases. J Dent 2018; 78: 51-58.. In addition, in eroded and exposed dentin, tin can be partially retained by the organic dentinal matrix ¹⁵15 Ganss C, Hardt M, Lussi A, Cocks AK, Klimek J, Schlueter N. Mechanism of action of tin-containing fluoride solutions as anti-erosive agents in dentine - an in vitro tin-uptake, tissue loss, and scanning electron microscopy study. Eur J Oral Sci 2010; 118: 376-384..

For this reason, this study aimed to evaluate in vitro the anti-erosive potential of an experimental varnish containing 5% SnCl₂ associated with different concentrations of sodium fluoride on the enamel and dentin subjected to acid challenges. According to the authors' best knowledge, SnCl₂ has not been studied in the varnish formulation until now. The null hypotheses tested were: H01 - There is no difference in erosive dental wear between the experimental and control varnishes; H02 - There is no difference in the loss of calcium ions between the experimental and control varnishes.

Material and Methods

Sample preparation

This study was approved by the animal ethics committee under the identifier ID CEUA - 8031261217. Enamel and dentin blocks were obtained from 140 healthy bovine incisors using a water-cooled double-sided diamond disc (Buehler, Lake Bluff, IL, USA). The blocks with surface of enamel and root dentin (4×4×2mm³) were cut using an Isomet cutting machine (Buehler, Lake Bluff, Illinois, United States) with a double-sided diamond disc (Extec, Enfield, Connecticut, United States). After that, the enamel blocks were polished using silicon carbide sandpapers #600, #1200, and #2400 (3M, Sumaré, São Paulo, Brazil) and dentin blocks using silicon carbide sandpaper #600 (3M, Sumaré, São Paulo, Brazil). After polishing, the samples were immersed in an ultrasonic bath (Euronda Spa, Montecchio Precalcino, Vicenza, Italy) with distilled water (Milli-Q, Merck Millipore Corporation, Darmstadt, Germany) for 5 min ⁵5 Alencar CM, Leite KLF, Ortiz MIG, Magno MB, Rocha GM, Silva C, et al. Morphological and chemical effects of in-office and at-home desensitising agents containing sodium fluoride on eroded root dentin. Arch Oral Biol 2020; 110: 104619.. Thereafter, the samples were stored in a humid environment (Milli-Q water) at 4 °C.

Selection of specimens

The 70 enamel and 70 dentin blocks were subjected to baseline surface microhardness (SMH. SMH was performed using Knoop microhardness (Surftest Mitsutoyo South American, São Paulo, Brazil) under a 50g load for 15 s ¹⁶16 Alexandria AK, Nassur C, Nóbrega CBC, Valença AMG, Rosalen PL, Maia LC. In situ effect of titanium tetrafluoride varnish on enamel demineralization. Braz Oral Res 2017; 31: e86. and 5 s ¹⁷17 Hosea Lalrin Muana, Noriko Hiraishi, Masatoshi Nakajima, Kalyan Kong, Junji Tagami. Effect of the Dentin Chelating Agents Phytic Acid and EDTA on Degree of Conversion, Microhardness, and Bond Strength of Chemical-curing Self-adhesive Cements. J Adhes Dent. 2019;21(4):299-306. doi: 10.3290/j.jad.a42997.
https://doi.org/10.3290/j.jad.a42997... , respectively. Five indentations were performed with a space of 100 µm from each other in the central area of the enamel surface. After the test, data normality assessment (Shapiro - Wilk test) was performed using SPSS software version 13.0 (SPSS, Tulsa, OK, USA). Twenty dentin blocks and 20 enamel blocks were excluded, as they presented outliers microhardness values and 50 enamel and 50 dentin samples were numbered and randomized into five groups (n=10 for each substrate) using Bioestat 5.3 software (Civil Society Mamirauá, Tefé, AM, Brazil); therefore, the mean baseline microhardness values were not statistically different between groups (analysis of variance [ANOVA]; α = 0.05).

Initial erosion

An initial erosive lesion was created by the application of citric acid at a concentration of 0.3%, pH 2.6, for 10 min. This protocol was performed on 10-well acrylic plates, and each sample was inserted into a specific well. After that, each sample was washed with distilled water for 10 s using a millimeter pick. Half of the samples' eroded surface was covered with unplasticized polyvinyl chloride (UPVC) tape to leave a 4×2 mm exposure window uncovered ⁵5 Alencar CM, Leite KLF, Ortiz MIG, Magno MB, Rocha GM, Silva C, et al. Morphological and chemical effects of in-office and at-home desensitising agents containing sodium fluoride on eroded root dentin. Arch Oral Biol 2020; 110: 104619..

Treatment with varnishes and erosive-abrasive challenge

After initial erosion and protection of half of the specimen's surface with UPVC tape, the varnishes were applied to the respective groups (n = 10 for each substrate): Negative control - milli-Q water; NaF-free - Experimental varnish SnCl₂-free and NaF-free; 2.5 NaF - Experimental varnish 5% SnCl₂ associated with 2.5% NaF; 5.2 NaF: Experimental varnish 5% SnCl₂ associated with 5.2% NaF and positive control - Commercial varnish containing 5% NaF (Duraphat, Colgate-Palmolive Company, Lörrach, Germany). The basic composition of the experimental varnishes incudes thickener polymer, rosin, synthetic resin, essence, and ethanol (Faculty of Pharmacy at USP Faculty of Pharmacy, São Paulo, SP, Brazil). The pH of all varnishes was measured using an indicator paper (± 0.5 units). The experimental materials showed color and consistency similar to Duraphat varnish.

The varnishes were applied in a thin layer using a disposable brush and the specimens were stored in artificial saliva for 6 h. Subsequently, the varnishes were removed with acetone solution (1:1) and cotton swabs, avoiding contact with the dentin surface ¹⁸18 Comar LP, Cardoso CDAB, Charone S, Grizzo LT, Buzalaf MAR, Magalhães AC. TiF4 and NaF varnishes as anti-erosive agents on enamel and dentin erosion progression in vitro. J Appl Oral Sci2015; 23: 14-8.. In the negative control group, the specimens were immersed in milli-Q water for 6 hours. After carrying out the treatments, the samples were subjected to acid cycling for five days. The specimens of each group were immersed in a 0.3% citric acid solution (pH = 2.6 for 10 min) and then immersed in artificial saliva (Concentration of components in 0.96 g/1000 mL - KCl; NaCl; MgCl₂; K₂HPO₄; CaCl₂; Carboxymethylcellulose; Sorbitol 70%; Nipagin; Nipazole and deionized water) for 60 minutes. The samples were brushed with a simulated brushing machine (MEV-2T Odeme, Joaçaba, SC, Brazil) twice daily, calibrated in 45 cycles of, 150 g for 15 s. The simulated brushing was performed 30 min after the 1st and 4th acidic challenges on each day of the cycle. The entire protocol was performed at an average temperature of 25 °C, and at the end of each day, the samples were stored in 100% humidity (Figure 1) ¹⁹19 Viana Í, Alania Y, Feitosa S, Borges AB, Braga RR, Scaramucci T. Bioactive Materials Subjected to Erosion/Abrasion and Their Influence on Dental Tissues. Oper Dent 2020; 45: E114-E123..

Figure 1
Specimen preparation, treatment and erosive-abrasive challenge. The four daily stages of the cycle were divided into: A - Erosion, abrasion and saliva immersion; B - Erosion and immersion in saliva; C - Erosion and immersion in saliva and D - Erosion, abrasion and immersion in saliva.

Loss of tooth structure

The 100% humidity of the specimens was maintained throughout the experiment. The surface topography of the samples was measured by non-contact 3D profilometry (Nanovea PS50 Optical, NANOVEA, Irvine, USA). The capture was carried out with a chromatic confocal sensor with an axial source of white light, a scanning speed of 2 m/s, and a refractive index of 10,000. An area of 1 mm × 1 mm was obtained from the center of each sample. The analysis determined the loss of tooth structure (TSL), defined as the difference in height (Δ height) between the untreated surface (baseline) and the treated surface. The values in µm were calculated using the Nanovea Professional 3D Software and this methodology was carried out according to Alexandria, et al. ²⁰20 Alexandria AK, Vieira TI, Pithon MM, da Silva Fidalgo TK, Fonseca-Gonçalves A, Valença AM, et al. In vitro enamel erosion and abrasion-inhibiting effect of different fluoride varnishes. Arch Oral Biol 2017; 77: 39-43..

Loss of calcium (Ca²⁺)

The loss of Ca²⁺ content in the samples was calculated by subtracting the percentage of Ca²⁺ in mg/L (%ΔCa²⁺) content between the side treated with the materials and the eroded side (_%ΔCa²⁺= _%Ca²⁺ - treated - _%Ca²⁺ - eroded). The dissolution of enamel and dentin was performed by chemical analysis on each side of the specimen. An Analyst 400 atomic absorption spectrometer (Perkin Elmer Analytical Instrument, Norwalk, CT, USA) was used with a wavelength of 422.7 nm and an air-acetylene flame was used to analyze the blind samples. 0.5% lanthanum was added to the etch samples (1:10, lanthanum: sample) to neutralize the negative effect of phosphorus on the calcium sensitivity of the spectrophotometer equipment ²¹21 Hjortsjö C, Jonski G, Young A, Saxegaard E. Effect of acidic fluoride treatments on early enamel erosion lesions--a comparison of calcium and profilometric analyses. Arch Oral Biol 2010; 55: 229-234..

Scanning electron microscopy

The images were obtained by scanning electron microscope (TESCAN, Mira3, quanta FEG-field emission gun, Czech Republic). The samples were mounted on aluminium supports (12 mm diameter) using carbon double-sided adhesive tape and metallized with gold for 1.5 h, which deposited on the sample a film with a mean thickness of 10 to 15 nm. The images were generated by detection of secondary electrons, using voltage acceleration of 3.0 kV, working distance of around 15 mm and 2,000× magnification. The resulting micrographs were qualitatively analysed.

Statistical analysis

SPSS software version 13.0 (SPSS, Tulsa, OK, USA) was used to perform the statistical analysis. The evaluation of the parametric distribution of data was performed using the Shapiro-Wilk test and homoscedasticity was also verified. Two-way ANOVA followed by the Bonferroni test was used. The significance level was set at α = 0.05.

Results

Loss of tooth structure

The results are shown in Table 1. The experimental groups 2.5 NaF and 5.2 NaF showed lower TSL when compared to the other groups (p <0.05), for enamel and dentin. There was no statistically significant difference between groups 2.5 NaF and 5.2 NaF (Enamel: p = 0.821; Dentin: p = 0.543). The negative control group showed significantly higher TSL when compared to the other groups for both substrates (p <0.05). When comparing substrates (enamel vs. dentin), dentin showed TSL significantly higher than enamel in all groups (p <0.05).

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Table 1
Mean and standard deviation (SD) of the enamel and dentin loss of tooth structure (TSL) values in µm

Loss of calcium (Ca²⁺)

The results of %ΔCa²⁺ are specified in Table 2. The experimental groups 2.5 NaF and 5.2 NaF showed lower loss in Ca²⁺ content when compared to the other groups (p <0.05), for enamel and dentin. There was a significant loss in Ca²⁺ content (mg/mL) in the negative control and NaF-free groups for the enamel when compared to the other groups (p <0.05). On the other hand, for dentin, the greatest loss of Ca²⁺ content occurred in the negative control group (p <0.05). When comparing substrates (enamel vs. dentin), enamel showed TSL significantly higher when compared to dentin in all groups (p <0.05).

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Table 2
Mean and standard deviation (SD) of the enamel and dentin loss of calcium (ΔCa²⁺) values in % (mg/mL)

Scanning electron microscopy

Scanning electron microscopy images are shown in Figure 2. Analysis of the samples after flattening with a #600-grit abrasive disc (Figure 2A) showed a total obliteration pattern of the dentin tubules due to the presence of the smear layer. Figure 2B illustrates the dentin surface covered by the experimental varnish containing 5.2% NaF, before being removed. After the erosion protocol with 0.3% citric acid (Figure 2C), the dentin surface revealed notable open dentinal tubules with a larger diameter.

The qualitative surface analysis showed that, among the groups studied, only 2.5 NaF (Figure 2F), 5.2 NaF (Figure 2G) and positive control (Figure 2H) showed partial obliteration of dentinal tubules.

Figure 2
A - Dentin with smear layer; B - Dentin after applying the varnish; C - Dentin after initial erosion; D - Negative control; E - NaF-free; F - 2.5 NaF; G - 5.2 NaF and H - positive control

Discussion

The current concern with ETW is growing³; therefore, several preventive treatments have been investigated. Among these therapies, toothpastes with and without NaF ⁵5 Alencar CM, Leite KLF, Ortiz MIG, Magno MB, Rocha GM, Silva C, et al. Morphological and chemical effects of in-office and at-home desensitising agents containing sodium fluoride on eroded root dentin. Arch Oral Biol 2020; 110: 104619.^,²¹21 Hjortsjö C, Jonski G, Young A, Saxegaard E. Effect of acidic fluoride treatments on early enamel erosion lesions--a comparison of calcium and profilometric analyses. Arch Oral Biol 2010; 55: 229-234.^,²²22 João-Souza SH, Sakae LO, Lussi A, Aranha ACC, Hara A, Baumann T, et al. Toothpaste factors related to dentine tubule occlusion and dentine protection against erosion and abrasion. Clin Oral Investig 2019; 24: 2051-2060., varnishes ¹⁶16 Alexandria AK, Nassur C, Nóbrega CBC, Valença AMG, Rosalen PL, Maia LC. In situ effect of titanium tetrafluoride varnish on enamel demineralization. Braz Oral Res 2017; 31: e86.^,²⁰20 Alexandria AK, Vieira TI, Pithon MM, da Silva Fidalgo TK, Fonseca-Gonçalves A, Valença AM, et al. In vitro enamel erosion and abrasion-inhibiting effect of different fluoride varnishes. Arch Oral Biol 2017; 77: 39-43., and bioactive materials ²⁴24 Poggio C, Gulino C, Mirando M, Colombo M, Pietrocola G. Protective effect of zinc-hydroxyapatite toothpastes on enamel erosion: An in vitro study. J Clin Exp Dent 2017; 9: e118-e122.^,²⁵25 Ganss C, Marten J, Hara AT, Schlueter N. Toothpastes and enamel erosion/abrasion - Impact of active ingredients and the particulate fraction. J Dent 2016; 54: 62-67. have shown promising results. However, the literature presents conflicting results and few randomized clinical studies on this issue. In the present in vitro research, the anti-erosive potential of two experimental varnishes was tested and showed positive results in preventing ETW in enamel and dentin. For this reason, hypothesis H01 was rejected.

Stannous (Sn²⁺) is a polyvalent metal ion that has a strong affinity for mineralized dental tissues. Sn²⁺ promotes a protective effect on dental tissue, acting on the formation of an acid-resistant surface layer ²⁶26 Yu H, Wegehaupt FJ, Zaruba M, Becker K, Roos M, Attin T, et al. Erosion-inhibiting potential of a stannous chloride-containing fluoride solution under acid flow conditions in vitro. Arch Oral Biol 2010; 55: 702-705.. A previous study showed that SnCl₂/NaF in solution form was able to prevent enamel and dentin erosion for 6 and 3.5 minutes, respectively ²⁶26 Yu H, Wegehaupt FJ, Zaruba M, Becker K, Roos M, Attin T, et al. Erosion-inhibiting potential of a stannous chloride-containing fluoride solution under acid flow conditions in vitro. Arch Oral Biol 2010; 55: 702-705.. The most pronounced protective effect at the beginning of the acid challenge may be related to the incorporation of stannous in the outermost enamel layer ²⁷27 Schlueter N, Hardt M, Lussi A, Engelmann F, Klimek J, Ganss C. Tin-containing fluoride solutions as anti-erosive agents in enamel: an in vitro tin-uptake, tissue-loss, and scanning electron micrograph study. Eur J Oral Sci2009; 117: 427-434.. An important study conducted by Babcock et al. ²⁸28 Babcock FD, King JC, Jordan TH. The reaction of stannous fluoride and hydroxyapatite. J Dent Res 1968; 57: 933-938. showed that the anti-erosive effect of the combination between Sn²⁺ and F^- occurs due to formation of less soluble precipitates on dental surface. Another study by Ganss, et al. ²⁹29 Ganss C, Lussi A, Sommer N, Klimek J, Schlueter N. Efficacy of fluoride compounds and stannous chloride as erosion inhibitors in dentine. Caries Res 2010; 44: 248-252. showed that the anti-erosive potential of NaF was better than SnCl₂, but less than its combination.

In the present study, experimental varnishes based on SnCl₂ associated with NaF showed promising results in decreasing TSL in enamel and dentin, regardless of NaF concentration. In this sense, it can be assumed that, in the present investigation, the combination of Sn²⁺ and F^- were incorporated into the structure of enamel and dentin, improving its acid resistance ³⁰30 João-Souza SH, Bezerra SJC, Borges AB, Aranha AC, Scaramucci T. Effect of sodium fluoride and stannous chloride associated with Nd:YAG laser irradiation on the progression of enamel erosion. Lasers Med Sci2015; 30: 2227-2232.. In addition, varnishes are materials that require less clinical applications compared to toothpastes and solutions because their effects last longer ⁵5 Alencar CM, Leite KLF, Ortiz MIG, Magno MB, Rocha GM, Silva C, et al. Morphological and chemical effects of in-office and at-home desensitising agents containing sodium fluoride on eroded root dentin. Arch Oral Biol 2020; 110: 104619.. A study by Sancakli, et al. ⁽³¹31 Sar Sancakli H, Austin RS, Al-Saqabi F, Moazzez R, Bartlett D. The influence of varnish and high fluoride on erosion and abrasion in a laboratory investigation. Aust Dent J2015; 60: 38-42. showed that topical fluoride varnish treatments have a superficial and sub-superficial effect, which plays a significant role in the prevention of TSL. There was no difference between the varnishes with a concentration of 2.5% and 5.2% NaF in the prevention of TSL during the erosive challenge in this study. It is possible that the effect of 5.2% NaF on TSL saturates the NaF concentration effectiveness threshold. Thus, the 2.5% concentration has already proved to be sufficiently efficient for an anti-erosion effect.

There are morphological and structural differences reported in the literature between dentin and enamel substrates ³²32 Laurance-Young P, Bozec L, Gracia L, Rees G, Lippert F, Lynch RJ, et al. A review of the structure of human and bovine dental hard tissues and their physicochemical behaviour in relation to erosive challenge and remineralization. J Dent 2011; 39: 266-272.. In the present study, we used the bovine buccal enamel and the root dentin of the cervical portion, which is predominantly involved in cervical lesions that are not carious by erosion ⁵5 Alencar CM, Leite KLF, Ortiz MIG, Magno MB, Rocha GM, Silva C, et al. Morphological and chemical effects of in-office and at-home desensitising agents containing sodium fluoride on eroded root dentin. Arch Oral Biol 2020; 110: 104619.^,³³33 Chiga S, Toro CV, Lepri TP, Turssi CP, Colucci V, Corona SA. Combined effect of fluoride varnish to Er:YAG or Nd:YAG laser on permeability of eroded root dentine. Arch Oral Biol 2016; 64: 24-27.. Bovine dentin and enamel demonstrate a structural biomorphology similar to the human substrate, including the quantity and density of dentinal tubules and a similar collagen matrix ³⁴34 Carmago MA, Marques MM, de Cara AA. Morphological analysis of human and bovine dentine by scanning electron microscope investigation. Arch Oral Biol2008; 53: 105-108.. It was previously concluded that the use of bovine teeth in vitro is acceptable, mainly for comparisons of effectiveness between materials ³⁵35 Yassen GH, Platt JA, Hara AT. Bovine teeth as substitute for human teeth in dental research: a review of literature. J Oral Sci 2011; 53: 273-282.; justifying the use of this substrate in this research.

In the present study, it was observed that dentin had a higher TSL than enamel. In contrast, the dentin structure showed lower loss of Ca²⁺ when compared to enamel. Thus, H02 was rejected. This can be explained by the differences between these substrates ³²32 Laurance-Young P, Bozec L, Gracia L, Rees G, Lippert F, Lynch RJ, et al. A review of the structure of human and bovine dental hard tissues and their physicochemical behaviour in relation to erosive challenge and remineralization. J Dent 2011; 39: 266-272., considering that the enamel has a higher inorganic content and consists of solid, interlaced, and rod-shaped structures. There is a large concentration of metal ions such as Na⁺, K⁺, and Mg²⁺ inside the enamel, while ions F^- and Cl^- are more prevalent on its surface ³²32 Laurance-Young P, Bozec L, Gracia L, Rees G, Lippert F, Lynch RJ, et al. A review of the structure of human and bovine dental hard tissues and their physicochemical behaviour in relation to erosive challenge and remineralization. J Dent 2011; 39: 266-272.^,³⁶36 Norén JG, Lodding A, Odelius H, Linde H. Secondary ion mass spectrometry of human deciduous enamel. Distribution of Na, K, Mg, Sr, F and Cl. Caries Res1983; 17: 496-502.. On the other hand, dentin is a less mineralized substrate, thus justifying the higher TSL compared to enamel ³⁷37 Carvalho TS, Lussi A. Age-related morphological, histological and functional changes in teeth. J Oral Rehabil2017; 44: 291-298.. Previous studies have shown a potential protective effect of solutions containing F^- and Sn²⁺ on TSL in the enamel ¹⁰10 João-Souza SH, Bezerra SJC, de Freitas PM, de Lima NB, Aranha ACC, Hara AT, et al. In situ evaluation of fluoride-, stannous- and polyphosphate-containing solutions against enamel erosion. J Dent 2017; 63: 30-35.^,³⁸38 Viana ÍEL, Lopes RM, Silva FRO, Lima NB, Aranha ACC, Feitosa S, et al. Novel fluoride and stannous -functionalized β-tricalcium phosphate nanoparticles for the management of dental erosion. J Dent2020; 92: 103263.^,³⁹39 Sakae LO, Bezerra SJC, João-Souza SH, Borges AB, Aoki IV, Aranha ACC, et al. An in vitro study on the influence of viscosity and frequency of application of fluoride/tin solutions on the progression of erosion of bovine enamel. Arch Oral Biol2018; 89: 26-30.. This was attributed to the formation of a layer of poorly soluble precipitates, with Sn₂OHPO₄, Sn₃F₃PO₄, and Ca(SnF₃)₂ on the enamel surface ²⁸28 Babcock FD, King JC, Jordan TH. The reaction of stannous fluoride and hydroxyapatite. J Dent Res 1968; 57: 933-938.. In addition, another study showed that Sn²⁺ can be incorporated into the enamel structure ³⁹39 Sakae LO, Bezerra SJC, João-Souza SH, Borges AB, Aoki IV, Aranha ACC, et al. An in vitro study on the influence of viscosity and frequency of application of fluoride/tin solutions on the progression of erosion of bovine enamel. Arch Oral Biol2018; 89: 26-30.^,⁴⁰40 Ganss C, Neutard L, von Hinckeldey J, Klimek J, Schlueter N. Efficacy of a tin/fluoride rinse: a randomized in situ trial on erosion. J Dent Res2010; 89: 1214-1218..

The experimental varnishes containing 2.5% and 5.2% NaF and the commercial varnish Duraphat promoted a greater pattern of dentinal tubule obliteration when compared to the negative control and NaF-free groups. Although the Duraphar varnish did not show promising results in TSL and Ca²⁺ loss, it was able to partially obliterate the dentin tubules. These results are possibly due to the remineralizing potential of NaF in these groups. The Duraphat varnish has a high concentration of sodium fluoride (22,600 ppm) and its effect is attributed to the formation of a CaF₂ layer on the surface, occluding the dentinal tubules.

The role of saliva is fundamental during the erosive challenge on dental tissues, as it acts in the formation of the acquired film. This film membrane is a semi-permeable structure that can decrease the contact of acids with the dental tissue ⁴¹41 Hara AT, Zero DT. The potential of saliva in protecting against dental erosion. Monogr Oral Sci2014; 25: 197-205.. The performance of the acquired film in the face of acid challenges must be considered in methodologies involving erosion and/or abrasion cycles. In the present study, we did not measure the thickness of the acquired film formed or the degree of its interference in the results. It is possible that this is a limitation of this study. However, it is important to consider that all groups were subjected to the same erosion/abrasion conditions.

Although in vitro studies aim to faithfully mimic the oral cavity in a controlled environment, there are variables that were not considered in this study: change in intraoral temperature, masticatory forces, and changes in salivary flow, etc. Further randomized controlled clinical studies with a low risk of bias should be conducted to evaluate promising alternatives for the prevention of TSL. However, testing of experimental materials must first be carried out in vitro and, if it shows promising results, it can be tested clinically in the future. The experimental varnishes tested in this research should be perfected in future in vitro research before they are suitable for clinical application.

Within the limitations of the present study, we can conclude that the 5.2% and 2.5% NaF-containing experimental varnishes showed promising results, both in the prevention of erosive tooth loss and loss of Ca²⁺, regardless of the substrate. In addition, dentin showed greater erosive tooth loss and less Ca²⁺ loss when compared to enamel in all treatments.

References

¹
Carvalho TS, Lussi A. Chapter 9: Acidic Beverages and Foods Associated with Dental Erosion and Erosive Tooth Wear. Monogr Oral Sci 2020; 28: 91-98.
²
Schlueter N, Amaechi BT, Bartlett D, Buzalaf MAR, Carvalho TS, Ganss C, et al. Terminology of Erosive Tooth Wear: Consensus Report of a Workshop Organized by the ORCA and the Cariology Research Group of the IADR. Caries Res 2020; 54: 2-6.
³
Carvalho TS, Colon P, Ganss C, Huysmans MC, Lussi A, Schlueter N, et al. Consensus report of the European Federation of Conservative Dentistry: erosive tooth wear - diagnosis and management. Clin Oral Investig 2015; 19: 1557-1561.
⁴
Shellis RP, Ganss C, Ren Y, Zero DT, Lussi A. Methodology and models in erosion research: discussion and conclusions. Caries Res 2011; 45: 69-77.
⁵
Alencar CM, Leite KLF, Ortiz MIG, Magno MB, Rocha GM, Silva C, et al. Morphological and chemical effects of in-office and at-home desensitising agents containing sodium fluoride on eroded root dentin. Arch Oral Biol 2020; 110: 104619.
⁶
de Oliveira AF, de Oliveira Diniz LV, Forte FD, Sampaio FC, Ccahuana-Vásquez RA, Tochukwu Amaechi B. In situ effect of a CPP-ACP chewing gum on enamel erosion associated or not with abrasion. Clin Oral Investig2016; 21: 339-346. doi:10.1007/s00784-016-1796-1
» https://doi.org/10.1007/s00784-016-1796-1
⁷
da Silva VRM, Viana ÍEL, Lopes RM, Zezell DM, Scaramucci T, Aranha ACC. Effect of Er,Cr:YSGG laser associated with fluoride on the control of enamel erosion progression. Arch Oral Biol 2019; 99: 156-160.
⁸
Bezerra SJC, Trevisan LR, Viana IEL, Lopes RM, Pereira DL, Aranha ACC, et al. Er,Cr:YSGG laser associated with acidulated phosphate fluoride gel (1.23% F) for prevention and control of dentin erosion progression. Lasers Med Sci 2019; 34: 449-455.
⁹
Konradsson K, Lingström P, Emilson CG, Johannsen G, Ramberg P, Johannsen A. Stabilized stannous fluoride dentifrice in relation to dental caries, dental erosion and dentin hypersensitivity: A systematic review. Am J Dent 2020; 33: 95-105.
¹⁰
João-Souza SH, Bezerra SJC, de Freitas PM, de Lima NB, Aranha ACC, Hara AT, et al. In situ evaluation of fluoride-, stannous- and polyphosphate-containing solutions against enamel erosion. J Dent 2017; 63: 30-35.
¹¹
Ganss C, Schlueter N, Hardt M, Schattenberg P, Klimek J. Effect of fluoride compounds on enamel erosion in vitro: a comparison of amine, sodium and stannous fluoride. Caries Res 2008; 42: 2-7.
¹²
Olivan SRG, Sfalcin RA, Fernandes KPS, Ferrari RAM, Horliana ACRT, Motta LJ, et al. Preventive effect of remineralizing materials on dental erosion lesions by speckle technique: An in vitro analysis. Photodiagnosis Photodyn Ther 2020; 29: 101655.
¹³
de Souza AP, Gerlach RF, Line SR. Inhibition of human gingival gelatinases (MMP-2 and MMP-9) by metal salts. Dent Mater 2000; 16: 103-108.
¹⁴
Cvikl B, Lussi A, Carvalho TS, Moritz A, Gruber R. Stannous chloride and stannous fluoride are inhibitors of matrix metalloproteinases. J Dent 2018; 78: 51-58.
¹⁵
Ganss C, Hardt M, Lussi A, Cocks AK, Klimek J, Schlueter N. Mechanism of action of tin-containing fluoride solutions as anti-erosive agents in dentine - an in vitro tin-uptake, tissue loss, and scanning electron microscopy study. Eur J Oral Sci 2010; 118: 376-384.
¹⁶
Alexandria AK, Nassur C, Nóbrega CBC, Valença AMG, Rosalen PL, Maia LC. In situ effect of titanium tetrafluoride varnish on enamel demineralization. Braz Oral Res 2017; 31: e86.
¹⁷
Hosea Lalrin Muana, Noriko Hiraishi, Masatoshi Nakajima, Kalyan Kong, Junji Tagami. Effect of the Dentin Chelating Agents Phytic Acid and EDTA on Degree of Conversion, Microhardness, and Bond Strength of Chemical-curing Self-adhesive Cements. J Adhes Dent. 2019;21(4):299-306. doi: 10.3290/j.jad.a42997.
» https://doi.org/10.3290/j.jad.a42997
¹⁸
Comar LP, Cardoso CDAB, Charone S, Grizzo LT, Buzalaf MAR, Magalhães AC. TiF4 and NaF varnishes as anti-erosive agents on enamel and dentin erosion progression in vitro. J Appl Oral Sci2015; 23: 14-8.
¹⁹
Viana Í, Alania Y, Feitosa S, Borges AB, Braga RR, Scaramucci T. Bioactive Materials Subjected to Erosion/Abrasion and Their Influence on Dental Tissues. Oper Dent 2020; 45: E114-E123.
²⁰
Alexandria AK, Vieira TI, Pithon MM, da Silva Fidalgo TK, Fonseca-Gonçalves A, Valença AM, et al. In vitro enamel erosion and abrasion-inhibiting effect of different fluoride varnishes. Arch Oral Biol 2017; 77: 39-43.
²¹
Hjortsjö C, Jonski G, Young A, Saxegaard E. Effect of acidic fluoride treatments on early enamel erosion lesions--a comparison of calcium and profilometric analyses. Arch Oral Biol 2010; 55: 229-234.
²²
João-Souza SH, Sakae LO, Lussi A, Aranha ACC, Hara A, Baumann T, et al. Toothpaste factors related to dentine tubule occlusion and dentine protection against erosion and abrasion. Clin Oral Investig 2019; 24: 2051-2060.
²³
Assunção CM, Lussi A, Rodrigues JA, Carvalho TS. Efficacy of toothpastes in the prevention of erosive tooth wear in permanent and deciduous teeth. Clin Oral Investig 2019; 23: 273-284.
²⁴
Poggio C, Gulino C, Mirando M, Colombo M, Pietrocola G. Protective effect of zinc-hydroxyapatite toothpastes on enamel erosion: An in vitro study. J Clin Exp Dent 2017; 9: e118-e122.
²⁵
Ganss C, Marten J, Hara AT, Schlueter N. Toothpastes and enamel erosion/abrasion - Impact of active ingredients and the particulate fraction. J Dent 2016; 54: 62-67.
²⁶
Yu H, Wegehaupt FJ, Zaruba M, Becker K, Roos M, Attin T, et al. Erosion-inhibiting potential of a stannous chloride-containing fluoride solution under acid flow conditions in vitro. Arch Oral Biol 2010; 55: 702-705.
²⁷
Schlueter N, Hardt M, Lussi A, Engelmann F, Klimek J, Ganss C. Tin-containing fluoride solutions as anti-erosive agents in enamel: an in vitro tin-uptake, tissue-loss, and scanning electron micrograph study. Eur J Oral Sci2009; 117: 427-434.
²⁸
Babcock FD, King JC, Jordan TH. The reaction of stannous fluoride and hydroxyapatite. J Dent Res 1968; 57: 933-938.
²⁹
Ganss C, Lussi A, Sommer N, Klimek J, Schlueter N. Efficacy of fluoride compounds and stannous chloride as erosion inhibitors in dentine. Caries Res 2010; 44: 248-252.
³⁰
João-Souza SH, Bezerra SJC, Borges AB, Aranha AC, Scaramucci T. Effect of sodium fluoride and stannous chloride associated with Nd:YAG laser irradiation on the progression of enamel erosion. Lasers Med Sci2015; 30: 2227-2232.
³¹
Sar Sancakli H, Austin RS, Al-Saqabi F, Moazzez R, Bartlett D. The influence of varnish and high fluoride on erosion and abrasion in a laboratory investigation. Aust Dent J2015; 60: 38-42.
³²
Laurance-Young P, Bozec L, Gracia L, Rees G, Lippert F, Lynch RJ, et al. A review of the structure of human and bovine dental hard tissues and their physicochemical behaviour in relation to erosive challenge and remineralization. J Dent 2011; 39: 266-272.
³³
Chiga S, Toro CV, Lepri TP, Turssi CP, Colucci V, Corona SA. Combined effect of fluoride varnish to Er:YAG or Nd:YAG laser on permeability of eroded root dentine. Arch Oral Biol 2016; 64: 24-27.
³⁴
Carmago MA, Marques MM, de Cara AA. Morphological analysis of human and bovine dentine by scanning electron microscope investigation. Arch Oral Biol2008; 53: 105-108.
³⁵
Yassen GH, Platt JA, Hara AT. Bovine teeth as substitute for human teeth in dental research: a review of literature. J Oral Sci 2011; 53: 273-282.
³⁶
Norén JG, Lodding A, Odelius H, Linde H. Secondary ion mass spectrometry of human deciduous enamel. Distribution of Na, K, Mg, Sr, F and Cl. Caries Res1983; 17: 496-502.
³⁷
Carvalho TS, Lussi A. Age-related morphological, histological and functional changes in teeth. J Oral Rehabil2017; 44: 291-298.
³⁸
Viana ÍEL, Lopes RM, Silva FRO, Lima NB, Aranha ACC, Feitosa S, et al. Novel fluoride and stannous -functionalized β-tricalcium phosphate nanoparticles for the management of dental erosion. J Dent2020; 92: 103263.
³⁹
Sakae LO, Bezerra SJC, João-Souza SH, Borges AB, Aoki IV, Aranha ACC, et al. An in vitro study on the influence of viscosity and frequency of application of fluoride/tin solutions on the progression of erosion of bovine enamel. Arch Oral Biol2018; 89: 26-30.
⁴⁰
Ganss C, Neutard L, von Hinckeldey J, Klimek J, Schlueter N. Efficacy of a tin/fluoride rinse: a randomized in situ trial on erosion. J Dent Res2010; 89: 1214-1218.
⁴¹
Hara AT, Zero DT. The potential of saliva in protecting against dental erosion. Monogr Oral Sci2014; 25: 197-205.

Publication Dates

Publication in this collection
07 Mar 2022
Date of issue
Jan-Feb 2022

History

Received
12 Sept 2020
Accepted
10 Mar 2021

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ¹
Carvalho TS, Lussi A. Chapter 9: Acidic Beverages and Foods Associated with Dental Erosion and Erosive Tooth Wear. Monogr Oral Sci 2020; 28: 91-98.

[2] ²
Schlueter N, Amaechi BT, Bartlett D, Buzalaf MAR, Carvalho TS, Ganss C, et al. Terminology of Erosive Tooth Wear: Consensus Report of a Workshop Organized by the ORCA and the Cariology Research Group of the IADR. Caries Res 2020; 54: 2-6.

[3] ³
Carvalho TS, Colon P, Ganss C, Huysmans MC, Lussi A, Schlueter N, et al. Consensus report of the European Federation of Conservative Dentistry: erosive tooth wear - diagnosis and management. Clin Oral Investig 2015; 19: 1557-1561.

[4] ⁴
Shellis RP, Ganss C, Ren Y, Zero DT, Lussi A. Methodology and models in erosion research: discussion and conclusions. Caries Res 2011; 45: 69-77.

[5] ⁵
Alencar CM, Leite KLF, Ortiz MIG, Magno MB, Rocha GM, Silva C, et al. Morphological and chemical effects of in-office and at-home desensitising agents containing sodium fluoride on eroded root dentin. Arch Oral Biol 2020; 110: 104619.

[6] ⁶
de Oliveira AF, de Oliveira Diniz LV, Forte FD, Sampaio FC, Ccahuana-Vásquez RA, Tochukwu Amaechi B. In situ effect of a CPP-ACP chewing gum on enamel erosion associated or not with abrasion. Clin Oral Investig2016; 21: 339-346. doi:10.1007/s00784-016-1796-1
» https://doi.org/10.1007/s00784-016-1796-1

[7] ⁷
da Silva VRM, Viana ÍEL, Lopes RM, Zezell DM, Scaramucci T, Aranha ACC. Effect of Er,Cr:YSGG laser associated with fluoride on the control of enamel erosion progression. Arch Oral Biol 2019; 99: 156-160.

[8] ⁸
Bezerra SJC, Trevisan LR, Viana IEL, Lopes RM, Pereira DL, Aranha ACC, et al. Er,Cr:YSGG laser associated with acidulated phosphate fluoride gel (1.23% F) for prevention and control of dentin erosion progression. Lasers Med Sci 2019; 34: 449-455.

[9] ⁹
Konradsson K, Lingström P, Emilson CG, Johannsen G, Ramberg P, Johannsen A. Stabilized stannous fluoride dentifrice in relation to dental caries, dental erosion and dentin hypersensitivity: A systematic review. Am J Dent 2020; 33: 95-105.

[10] ¹⁰
João-Souza SH, Bezerra SJC, de Freitas PM, de Lima NB, Aranha ACC, Hara AT, et al. In situ evaluation of fluoride-, stannous- and polyphosphate-containing solutions against enamel erosion. J Dent 2017; 63: 30-35.

[11] ¹¹
Ganss C, Schlueter N, Hardt M, Schattenberg P, Klimek J. Effect of fluoride compounds on enamel erosion in vitro: a comparison of amine, sodium and stannous fluoride. Caries Res 2008; 42: 2-7.

[12] ¹²
Olivan SRG, Sfalcin RA, Fernandes KPS, Ferrari RAM, Horliana ACRT, Motta LJ, et al. Preventive effect of remineralizing materials on dental erosion lesions by speckle technique: An in vitro analysis. Photodiagnosis Photodyn Ther 2020; 29: 101655.

[13] ¹³
de Souza AP, Gerlach RF, Line SR. Inhibition of human gingival gelatinases (MMP-2 and MMP-9) by metal salts. Dent Mater 2000; 16: 103-108.

[14] ¹⁴
Cvikl B, Lussi A, Carvalho TS, Moritz A, Gruber R. Stannous chloride and stannous fluoride are inhibitors of matrix metalloproteinases. J Dent 2018; 78: 51-58.

[15] ¹⁵
Ganss C, Hardt M, Lussi A, Cocks AK, Klimek J, Schlueter N. Mechanism of action of tin-containing fluoride solutions as anti-erosive agents in dentine - an in vitro tin-uptake, tissue loss, and scanning electron microscopy study. Eur J Oral Sci 2010; 118: 376-384.

[16] ¹⁶
Alexandria AK, Nassur C, Nóbrega CBC, Valença AMG, Rosalen PL, Maia LC. In situ effect of titanium tetrafluoride varnish on enamel demineralization. Braz Oral Res 2017; 31: e86.

[17] ¹⁷
Hosea Lalrin Muana, Noriko Hiraishi, Masatoshi Nakajima, Kalyan Kong, Junji Tagami. Effect of the Dentin Chelating Agents Phytic Acid and EDTA on Degree of Conversion, Microhardness, and Bond Strength of Chemical-curing Self-adhesive Cements. J Adhes Dent. 2019;21(4):299-306. doi: 10.3290/j.jad.a42997.
» https://doi.org/10.3290/j.jad.a42997

[18] ¹⁸
Comar LP, Cardoso CDAB, Charone S, Grizzo LT, Buzalaf MAR, Magalhães AC. TiF4 and NaF varnishes as anti-erosive agents on enamel and dentin erosion progression in vitro. J Appl Oral Sci2015; 23: 14-8.

[19] ¹⁹
Viana Í, Alania Y, Feitosa S, Borges AB, Braga RR, Scaramucci T. Bioactive Materials Subjected to Erosion/Abrasion and Their Influence on Dental Tissues. Oper Dent 2020; 45: E114-E123.

[20] ²⁰
Alexandria AK, Vieira TI, Pithon MM, da Silva Fidalgo TK, Fonseca-Gonçalves A, Valença AM, et al. In vitro enamel erosion and abrasion-inhibiting effect of different fluoride varnishes. Arch Oral Biol 2017; 77: 39-43.

[21] ²¹
Hjortsjö C, Jonski G, Young A, Saxegaard E. Effect of acidic fluoride treatments on early enamel erosion lesions--a comparison of calcium and profilometric analyses. Arch Oral Biol 2010; 55: 229-234.

[22] ²²
João-Souza SH, Sakae LO, Lussi A, Aranha ACC, Hara A, Baumann T, et al. Toothpaste factors related to dentine tubule occlusion and dentine protection against erosion and abrasion. Clin Oral Investig 2019; 24: 2051-2060.

[23] ²³
Assunção CM, Lussi A, Rodrigues JA, Carvalho TS. Efficacy of toothpastes in the prevention of erosive tooth wear in permanent and deciduous teeth. Clin Oral Investig 2019; 23: 273-284.

[24] ²⁴
Poggio C, Gulino C, Mirando M, Colombo M, Pietrocola G. Protective effect of zinc-hydroxyapatite toothpastes on enamel erosion: An in vitro study. J Clin Exp Dent 2017; 9: e118-e122.

[25] ²⁵
Ganss C, Marten J, Hara AT, Schlueter N. Toothpastes and enamel erosion/abrasion - Impact of active ingredients and the particulate fraction. J Dent 2016; 54: 62-67.

[26] ²⁶
Yu H, Wegehaupt FJ, Zaruba M, Becker K, Roos M, Attin T, et al. Erosion-inhibiting potential of a stannous chloride-containing fluoride solution under acid flow conditions in vitro. Arch Oral Biol 2010; 55: 702-705.

[27] ²⁷
Schlueter N, Hardt M, Lussi A, Engelmann F, Klimek J, Ganss C. Tin-containing fluoride solutions as anti-erosive agents in enamel: an in vitro tin-uptake, tissue-loss, and scanning electron micrograph study. Eur J Oral Sci2009; 117: 427-434.

[28] ²⁸
Babcock FD, King JC, Jordan TH. The reaction of stannous fluoride and hydroxyapatite. J Dent Res 1968; 57: 933-938.

[29] ²⁹
Ganss C, Lussi A, Sommer N, Klimek J, Schlueter N. Efficacy of fluoride compounds and stannous chloride as erosion inhibitors in dentine. Caries Res 2010; 44: 248-252.

[30] ³⁰
João-Souza SH, Bezerra SJC, Borges AB, Aranha AC, Scaramucci T. Effect of sodium fluoride and stannous chloride associated with Nd:YAG laser irradiation on the progression of enamel erosion. Lasers Med Sci2015; 30: 2227-2232.

[31] ³¹
Sar Sancakli H, Austin RS, Al-Saqabi F, Moazzez R, Bartlett D. The influence of varnish and high fluoride on erosion and abrasion in a laboratory investigation. Aust Dent J2015; 60: 38-42.

[32] ³²
Laurance-Young P, Bozec L, Gracia L, Rees G, Lippert F, Lynch RJ, et al. A review of the structure of human and bovine dental hard tissues and their physicochemical behaviour in relation to erosive challenge and remineralization. J Dent 2011; 39: 266-272.

[33] ³³
Chiga S, Toro CV, Lepri TP, Turssi CP, Colucci V, Corona SA. Combined effect of fluoride varnish to Er:YAG or Nd:YAG laser on permeability of eroded root dentine. Arch Oral Biol 2016; 64: 24-27.

[34] ³⁴
Carmago MA, Marques MM, de Cara AA. Morphological analysis of human and bovine dentine by scanning electron microscope investigation. Arch Oral Biol2008; 53: 105-108.

[35] ³⁵
Yassen GH, Platt JA, Hara AT. Bovine teeth as substitute for human teeth in dental research: a review of literature. J Oral Sci 2011; 53: 273-282.

[36] ³⁶
Norén JG, Lodding A, Odelius H, Linde H. Secondary ion mass spectrometry of human deciduous enamel. Distribution of Na, K, Mg, Sr, F and Cl. Caries Res1983; 17: 496-502.

[37] ³⁷
Carvalho TS, Lussi A. Age-related morphological, histological and functional changes in teeth. J Oral Rehabil2017; 44: 291-298.

[38] ³⁸
Viana ÍEL, Lopes RM, Silva FRO, Lima NB, Aranha ACC, Feitosa S, et al. Novel fluoride and stannous -functionalized β-tricalcium phosphate nanoparticles for the management of dental erosion. J Dent2020; 92: 103263.

[39] ³⁹
Sakae LO, Bezerra SJC, João-Souza SH, Borges AB, Aoki IV, Aranha ACC, et al. An in vitro study on the influence of viscosity and frequency of application of fluoride/tin solutions on the progression of erosion of bovine enamel. Arch Oral Biol2018; 89: 26-30.

[40] ⁴⁰
Ganss C, Neutard L, von Hinckeldey J, Klimek J, Schlueter N. Efficacy of a tin/fluoride rinse: a randomized in situ trial on erosion. J Dent Res2010; 89: 1214-1218.

[41] ⁴¹
Hara AT, Zero DT. The potential of saliva in protecting against dental erosion. Monogr Oral Sci2014; 25: 197-205.

Group	TSL (µm)
	Enamel	Dentin
	Mean (±SD)	Mean (±SD)
Negative control	-138.23 (±16.97)^Aa	-321.16 (±34.37)^Ab
NaF-free	-16.35 (±2.59)^Ba	-42.13 (±4.09)^Bb
2.5 NaF	-6.09 (±0.80)^Da	-16.25 (±3.32)^Db
5.2 NaF	-5.87 (±1.05)^Da	-14.98 (±2.88)^Db
Positive control	-10.86 (±1.22)^Ca	-21.41 (±4.76)^Cb

Group	_% ΔCa ²⁺ (mg/mL)
	Enamel	Dentin
	Mean (±SD)	Mean (±SD)
Negative control	-1.52 (±0.54)^Aa	-0.57 (±0.12)^Ab
NaF-free	-0.82 (±0.14)^Ba	-0.18 (±0.05)^Bb
2.5 NaF	-0.14 (±0.07)^Da	-0.06 (±0.03)^Cb
5.2 NaF	-0.11 (±0.04)^Da	-0.04 (±0.02)^Cb
Duraphat	-0.36 (±0.13)^Ca	-0.16 (±0.06)^Bb

Brasil

Brasil

Anti-erosive profile of an experimental 5% SnCl₂ varnish containing different concentrations of NaF

Abstract

Resumo

Introduction

Material and Methods

Sample preparation

Selection of specimens

Initial erosion

Treatment with varnishes and erosive-abrasive challenge

Loss of tooth structure

Loss of calcium (Ca²⁺)

Scanning electron microscopy

Statistical analysis

Results

Loss of tooth structure

Loss of calcium (Ca²⁺)

Scanning electron microscopy

Discussion

References

Publication Dates

History

Brasil

Brasil

Anti-erosive profile of an experimental 5% SnCl₂ varnish containing different concentrations of NaF

Abstract

Resumo

Introduction

Material and Methods

Sample preparation

Selection of specimens

Initial erosion

Treatment with varnishes and erosive-abrasive challenge

Loss of tooth structure

Loss of calcium (Ca2+)

Scanning electron microscopy

Statistical analysis

Results

Loss of tooth structure

Loss of calcium (Ca2+)

Scanning electron microscopy

Discussion

References

Publication Dates

History

Loss of calcium (Ca²⁺)

Loss of calcium (Ca²⁺)