<i>In vitro</i> and <i>in situ</i> caries-preventive effect of a new combined fluoride and calcium experimental nanocomposite solution.

Leite, Karla Lorene de França; Martins, Mariana Leonel; Dias, Millene de Oliveira; Tavares, Fernanda Oliveira Miranda; Justino, Isabella Barbosa dos Santos; Cabral, Lúcio Mendes; Neves, Aline de Almeida; Cavalcanti, Yuri Wanderley; Maia, Lucianne Cople

doi:10.1590/0103-6440202305460

Abstract

To assess the in vitro and in situ effect of experimental combined fluoride and calcium nanocomposite solutions on dental caries prevention. Nanocompound mesoporous silica (MS) with calcium (Ca) and sodium fluoride (NaF) - (MSCaNaF); MS with NaF (MSNaF), NaF solution (positive control), and deionized water (negative control - CG) were studied. The specimens (n=130) were submitted in vitro to a multispecies biofilm in the presence of 2% sucrose. After 24 h and 48 h, the culture medium pH, the percent of surface mineral loss (%SML), and lesion depth (ΔZ) were analyzed. In the in situ study, 10 volunteers participated in four phases of 7-days each. The products were applied on the specimens (n=240) before 20% sucrose solution drips. The polysaccharides (SEPS and IEPS), %SML and roughness (Sa) were evaluated. There was an in vitro decrease in pH values in 24h and 48h, compared to baseline. The MSCaNaF and MSNaF groups obtained lower values of %SML and ΔZ (p < 0.05) than CG and NaF after 24h and were similar to NaF after 48h (p<0.05). In situ results showed similar SEPS and IEPS among all groups after 48h. An after 7-days, the nanocomposites had similar values (p>0.05), while NaF was similar to CG (p>0.05). After 48h, the MSCaNaF and MSNaF reduced the %SML (p<0.05). After 7-days, both experimental nanocomposites were similar to NaF (p>0.05). Regarding Sa, MSCaNaF was better than NaF for both periods (p<0.05). The nanocomposites controlled the in vitro and in situ enamel demineralization, mainly in the initial periods.

Key Words:
Nanotechnology; Fluorides; Calcium; Dental Biofilm

Introduction

Dental caries lesions are the result of an imbalance of de-remineralization processes occurring in the oral cavity. As a simple and low-cost treatment, professionally applied high-concentration (1.23 or 2%) topical fluoride is approved for dental caries prevention, remineralizing early enamel caries (white spot lesions) or to arrest dentine caries ¹1. Gao SS, Zhang S, Mei ML, Lo EC, Chu CH. Caries remineralisation and arresting effect in children by professionally applied fluoride treatment - a systematic review. BMC Oral Health. 2016Feb 1;16:12. Doi: 10.1186/s12903-016-0171-6.
https://doi.org/10.1186/s12903-016-0171-... . In fact, fluoride-based agents have been known as a standard for caries prevention and thus, dental research is exploring other possible combinations of fluoridated compounds including calcium complexes ²2. Bijle MNA, Yiu CKY, Ekambaram M. Calcium-Based Caries Preventive Agents: A Meta-evaluation of Systematic Reviews and Meta-analysis. J Evid Based Dent Pract. 2018Sep;18(3):203-217.e4. Doi: 10.1016/j.jebdp.2017.09.003.
https://doi.org/10.1016/j.jebdp.2017.09.... .

In high caries-risk patients, regular visits to the dentist are necessary to keep oral health, and many previous studies have investigated the effect of various materials in dental caries prevention ²2. Bijle MNA, Yiu CKY, Ekambaram M. Calcium-Based Caries Preventive Agents: A Meta-evaluation of Systematic Reviews and Meta-analysis. J Evid Based Dent Pract. 2018Sep;18(3):203-217.e4. Doi: 10.1016/j.jebdp.2017.09.003.
https://doi.org/10.1016/j.jebdp.2017.09.... ^,³3. Singh A, Purohit BM. Caries Preventive Effects of High-fluoride vs Standard-fluoride Toothpastes - A Systematic Review and Meta-analysis. Oral Health Prev Dent. 2018, 16(4):307-314.. In this regard, nanoparticulated products, with prolonged action, may keep a more effective residual effect than conventional products ⁴4. Wang Y, Zhao Q, Han N, Bai L, Li J, Liu J, Che E, Hu L, Zhang Q, Jiang T, Wang S. Mesoporous silica nanoparticles in drug delivery and biomedical applications. Nanomedicine. 2015Feb;11(2):313-27.^,⁵5. Kavoosi F, Modaresi F, Sanaei M, Rezaei Z. Medical and dental applications of nanomedicines. APMIS. 2018, Oct;126(10):795-803..

Mesoporous materials with high specific surface, high pore volume and unique pore size have been recently studied as biomaterials, such as carriers for controlled bioactive delivery ⁶6. Kuang Y, Zhai J, Xiao Q, Zhao S, Li C. Polysaccharide/mesoporous silica nanoparticle-based drug delivery systems: A review. Int J Biol Macromol. 2021Oct 25:S0141-8130(21)02299-6. Doi: 10.1016/j.ijbiomac.2021.10.142.
https://doi.org/10.1016/j.ijbiomac.2021.... ^,⁷7. Ashour MM, Mabrouk M, Soliman IE, Beherei HH, Tohamy KM. Mesoporous silica nanoparticles prepared by different methods for biomedical applications: Comparative study. IET Nanobiotechnol. 2021May;15(3):291-300. Doi: 10.1049/nbt2.12023.
https://doi.org/10.1049/nbt2.12023.... . The search for new dental applications of mesoporous silica nanoparticles (MS), in the scope of the delivering active compounds, has been the focus of nanotechnology and bone tissue engineering, mainly aimed at the development of biocompatible and multifunctional nanocarriers. Previous in vitro studies show that calcium MS was as effective as TiF₄and NaF to reduce erosive tooth loss ⁸8. Canto FMT, Alexandria AK, Vieira TI, Justino IBS, Cabral LM, Silva RF, Maia LC. Comparative effect of calcium mesoporous silica versus calcium and/or fluoride products against dental erosion Braz. Dent. J. 2020aMar; 31(2): 164-170. Doi: 10.1590/0103-6440202002557.
https://doi.org/10.1590/0103-64402020025... ^,⁹9. Canto FMT, Alexandria AK, Justino IBS, Rocha GM, Cabral LM, Silva RF, Pithon MM, Maia LC. The use of a new calcium mesoporous silica nanoparticle versus calcium and/or fluoride products in reducing the progression of dental erosion. J. Appl. Oral Sci. 2020bJan; 28. Doi: 10.1590/1678-7757-2020-0131.
https://doi.org/10.1590/1678-7757-2020-0... ^,¹⁰10. Justino IBS, Alexandria AK, Canto FMT, Leite KLF, Vieira TI, Cabral LM, Silva RF, Maia LC. Comparative effect of calcium mesoporous silica versus calcium and/or fluoride products on the reduction of erosive tooth wear and abrasive enamel lesion. Pesqui. Bras. Odontopediatria Clín. Integr. 2020; 20. Doi: 10.1590/pboci.2020.146.
https://doi.org/10.1590/pboci.2020.146.... while others showed that these solutions were able to reduce enamel demineralization around orthodontic brackets ¹¹’1. Leite KLF, Vieira TI, Alexandria AK, Silva RFD, Silva ASS, Lopes RT, Fonseca-Gonçalves A, Neves AA, Cabral LM, Pithon MM, Cavalcanti YW, Maia LC. In vitro effect of experimental nanocomposites solutions on the prevention of dental caries around orthodontic brackets. Braz Dent J. 2021Jul-Aug;32(4):62-73. Doi: 10.1590/0103-6440202104331.
https://doi.org/10.1590/0103-64402021043... . However, no study has yet compared the effect of mesoporous silica nanoparticles with added fluoride in reducing demineralization and enhancing remineralization under in situ cariogenic challenge. Therefore, this in vitro and in situ study was designed to identify the caries preventive effect of new sodium fluoride nanoparticle solution, with and without added calcium, in dental enamel submitted to cariogenic challenge.

Materials and Methods

Preparation of the Experimental Nanocomposites

Mesoporous silica (MS) based nanocomposites were obtained by a nanoprecipitation technique, varying the molar ratio of water/tetraethoxysilane (TEOS), NH3/TEOS and the amount of cetyltrimethylammonium bromide. All characterization analyses are described as previously reported in the literature ¹¹’1. Leite KLF, Vieira TI, Alexandria AK, Silva RFD, Silva ASS, Lopes RT, Fonseca-Gonçalves A, Neves AA, Cabral LM, Pithon MM, Cavalcanti YW, Maia LC. In vitro effect of experimental nanocomposites solutions on the prevention of dental caries around orthodontic brackets. Braz Dent J. 2021Jul-Aug;32(4):62-73. Doi: 10.1590/0103-6440202104331.
https://doi.org/10.1590/0103-64402021043... .

Thereafter, a sodium fluoride solution (Aldrich Chemical Co^®, Saint Louis, USA) was included, to which calcium (Ca) was added or not. The following experimental solutions were produced: 1) an experimental nanocomposite of mesoporous silica (MS) dopped with calcium and sodium fluoride (MSCaNaF) and 2) MS with NaF (MSNaF). The nanocomposites were analyzed by ICP-AES, prepared by a surfactant templated, base-catalyzed condensation procedure with Ca(NO₃)₂ added in the parent solution as a calcium precursor (in order to obtain the calcium concentration) and by ion chromatography with conductivity detection to obtain the fluoride concentration. ICP-AES results were 10.7 ± 0, 8% [w /w] of medium content. The determination of fluoride resulted in 9.3 ± 0.1% [w /w] of medium content ¹¹’1. Leite KLF, Vieira TI, Alexandria AK, Silva RFD, Silva ASS, Lopes RT, Fonseca-Gonçalves A, Neves AA, Cabral LM, Pithon MM, Cavalcanti YW, Maia LC. In vitro effect of experimental nanocomposites solutions on the prevention of dental caries around orthodontic brackets. Braz Dent J. 2021Jul-Aug;32(4):62-73. Doi: 10.1590/0103-6440202104331.
https://doi.org/10.1590/0103-64402021043... .

In vitro study

Study Design and Sample Size

The in vitro, randomized, controlled, single-blind study was based on a previous investigation that evaluated the enamel mineral loss reduction resulted from application of nanocomposite solutions containing calcium and fluoride that used a specific sample size (n=13 per group) ⁽¹¹’1. Leite KLF, Vieira TI, Alexandria AK, Silva RFD, Silva ASS, Lopes RT, Fonseca-Gonçalves A, Neves AA, Cabral LM, Pithon MM, Cavalcanti YW, Maia LC. In vitro effect of experimental nanocomposites solutions on the prevention of dental caries around orthodontic brackets. Braz Dent J. 2021Jul-Aug;32(4):62-73. Doi: 10.1590/0103-6440202104331.
https://doi.org/10.1590/0103-64402021043... . A 0.8 statistical power was used to detect a 50% significant difference in mean mineral loss in each treatment group compared to the control group (1.36% of NaF, 6135 ppm of F^-), using a one-tailed test with a 5% significance level (BioEstat 5.3^®, Instituto de Desenvolvimento Sustentável Mamirauá, Tefé, Brazil).

Specimen Preparation

Enamel specimens (4×4×4 mm³) were prepared from bovine crowns as described previously ¹²11. Hara AT, Queiroz CS, Paes Leme AF, Serra MC, Cury JA. Caries progression and inhibition in human and bovine root dentine in situ. Caries Res. 2003, 37:339-344.. Surface hardness was determined on the enamel specimens ¹³13. Cury JA, Rebelo MAB, Del Bel Cury AA, Derbyshire MTVC, Taubchoury CPM. Biochemical Composition and Cariogenicity of Dental Plaque Formed in the Presence of Sucrose of Glucose and Fructose. Caries Res. 2000, 34: 491-497. and those in the ±10% range were selected, according to the total mean of the baseline microhardness (320.76 kgF/mm²) and were randomized among the groups. From these groups, 130 sound enamel blocks were selected for the in vitro study. After that, half of the specimens’ surface were covered with an acid-resistant nail varnish in order to create an unexposed area (sound area) and one exposed area.

After random distribution of the specimens (Microsoft Excel^®) in each of the groups (n=13), the specimens were transferred to a 12-well polystyrene plate (K12-024, Kasvi^®, São José do Pinhal, Brazil), and sterilized under ultraviolet light (40W) for 1 h ¹⁴14. Katara G, Hemvani N, Chitnis S, Chitnis V, Chitnis DS. Surface disinfection by exposure to germicidal UV light. Indian J Med Microbiol. 2008, 26(3): 241-242.^,¹⁵15. Viana PS, Orlandi MO, Pavarina AC, Machado AL, Vergani CE. Chemical composition and morphology study of bovine enamel submitted to different sterilization methods. Clin Oral Investig. 2018, Mar;22(2):733-744..

A single blinded trained researcher actively applied the test products (100μL) in the exposed area using a microbrush (KG Sorensen^®, Cotia, Brazil) for 1 min on each enamel block before the cariogenic challenge.

Cariogenic Challenge

After reactivation of Streptococcus mutans (ATCC 25175), Streptococcus salivarius (ATCC 7073), Streptococcus sanguinis (ATCC 20556), and Lactobacillus casei (ATCC 393) strains, a bacterial suspension was prepared according to CLSI (2012) ¹⁶16. CLSI. (2012). Methods for dilution antimicrobial susceptibility tests for bacteria that grow aerobically; approved standard ninth edition. CLSI document M07-A9. Wayne, PA:Clinical and Laboratory Standards Institute.⁾ standards and transferred to BHI broth containing 2% sucrose (pH=7.10). Previously treated specimens were immersed in artificial saliva for 1 h ¹⁷17. Amaechi BT, Higham SM, Edgar WM. (1999). Techniques for the production of dental eroded lesions in vitro. Journal of Oral Rehabilitation, 26(2): 97-102. Doi: 10.1046/j.1365-2842.1999.00349.x.
https://doi.org/10.1046/j.1365-2842.1999... . After, 5 mL of the mixed inoculum (5 x 10⁵ CFU/mL of the final concentration) was added, and the specimens were incubated at 37 °C for 24 h and 48 h.

The growth control (GC) specimens contained a bacterial suspension (multispecies biofilm of Streptococcus spp. and Lactobacillus casei) prepared in BHI broth with 2% sucrose, while the sterility control (SC) specimens included BHI broth with 2% sucrose and both did not receive the experimental treatments. The following groups were produced: MSCaNaF and MSNaF (experimental groups), NaF (positive control), GC (negative control) and SC (sterility control).

Data Collection and Analysis

After 24h (n=65) and 48h (n=65), the specimens were sonicated for 1 min and the acidogenicity of culture medium was assessed by pH measurements (PHOX^®, Colombo, Brazil). The procedure was carried out in duplicate by a blinded trained examiner.

All enamel blocks of each group were reassessed after the cariogenic challenge by the same examiner to determine the final surface microhardness, according to the parameters established for the baseline assessment. The percent loss of surface mineral (%SML) was obtained after the experiment ¹³13. Cury JA, Rebelo MAB, Del Bel Cury AA, Derbyshire MTVC, Taubchoury CPM. Biochemical Composition and Cariogenicity of Dental Plaque Formed in the Presence of Sucrose of Glucose and Fructose. Caries Res. 2000, 34: 491-497..

For the analysis of mineral content in the lesion, randomly selected enamel blocks (n= 6, per group) were scanned on a high-energy micro-CT scanner (Skyscan 1173, Bruker, Kontich, Belgium) using the following acquisition parameters: 70 kVp, 114 mA, pixel size of 7.12 μm, and 1mm aluminum filter. The images were later reconstructed into cross sections using a dedicated software (NRecon, Bruker) and specific reconstruction parameters. The integrated mineral loss (∆Z) was calculated by drawing a profile across the enamel surface and measuring the integrated area under the curve, corresponding to the mineral density of the carious lesion ¹¹’1. Leite KLF, Vieira TI, Alexandria AK, Silva RFD, Silva ASS, Lopes RT, Fonseca-Gonçalves A, Neves AA, Cabral LM, Pithon MM, Cavalcanti YW, Maia LC. In vitro effect of experimental nanocomposites solutions on the prevention of dental caries around orthodontic brackets. Braz Dent J. 2021Jul-Aug;32(4):62-73. Doi: 10.1590/0103-6440202104331.
https://doi.org/10.1590/0103-64402021043... .

In situ study

Ethical Aspects and Sample Size

The in situ protocol was approved by the Research Ethics Committee (protocol No. 2.996.144/2019). The in situ study was based on the findings of the in vitro study (pilot of the study), which found that appropriate caries lesions were obtained in a 24h and 48h period of cariogenic challenge. Thus, the participants were requested to use additional extraoral sucrose dipping to enhance the caries process for the period of 24h and 7 days for this in situ study.

The obtained data were used to perform a sample size calculation for paired differences based on the reduction in enamel mineral loss. The calculation considered the mean difference between pairs and the standard deviation of the differences. Based on these data, we assumed that the study would require a power of 80% and a level of significance of 5%, and as a result, six blocks of bovine enamel were required per volunteer in each phase, with a minimum of nine volunteers. Considering 10% loss of volunteers, the present study was carried out with 12 volunteers.

Prior to enrolling into the study, an independent examiner, not otherwise involved in the study, conducted a clinical examination to assess caries status and to determine any treatment needs of the potential volunteers. These were undergraduate and postgraduate dental students, who fulfilled the inclusion criteria (salivary flow rate > 1mL/min, good general and oral health with no active caries lesions or periodontal treatment needs, ability to comply with the experimental protocol, no antibiotic use during the 1 month prior to the study, use of any form of medication that modifies salivary secretion, not using a fixed or removable orthodontic device) and consented to participate ¹⁸18. Alexandria AK, Nassur C, Nóbrega CBC, Valença AMG, Rosalen PL, Maia LC. (2017a) In situ effect of titanium tetrafluoride varnish on enamel demineralization. Brazilian Oral Research, Nov 6;31:e86. Doi: 10.1590/1807-3107BOR-2017.
https://doi.org/10.1590/1807-3107BOR-201... . The mean age of the subjects was 23.1 ± 4.0 years old; the mean colony forming units (CFU) count was 9.2 ± 2.3 (Log₁₀) and the mean ICDAS index was 2.3 ± 3.1.

Study Design

The study had an in situ, triple-blind (by operator and volunteers regarding product use and by the examiner assessing the outcomes), crossover design and was conducted in four experimental phases of seven days each. A minimum of 48 hours was considered as washout periods. The subjects used palatal appliances containing three sound enamel specimens on each side, with predetermined initial surface hardness. In each phase, groups of volunteers were subjected to one of the following treatments: MSCaNaF, MSNaF, NaF (positive control) and negative control (deionized water) applied once on each specimen at the beginning of the experimental phase. After the first 24h of appliance use, sucrose was dropped three times per day on sound specimens to simulate a cariogenic challenge. At the end of each phase, the concentration of soluble and insoluble extracellular polysaccharides (SEPS and IEPS) in the biofilm was assessed. The caries preventive effect of each treatment was evaluated by surface hardness. Also, volumetric roughness (Sa) was used to assess enamel topography. For all analyses, the samples were blindly analyzed using codes (Figure 1).

Specimens Preparation

Enamel specimens (4×4×2 mm) were prepared from bovine incisor crowns, as described previously ¹²11. Hara AT, Queiroz CS, Paes Leme AF, Serra MC, Cury JA. Caries progression and inhibition in human and bovine root dentine in situ. Caries Res. 2003, 37:339-344.. After baseline microhardness measurements (314.42 kgF/mm²) the specimens were randomized across the groups. From these groups, 240 sound enamel blocks were selected for the in situ study. An unexposed area (sound area) and the exposed area were also created on the specimens (Figure 1).

Figure 1
Study design: 1- Specimen preparation; 2- Baseline microhardness; 3- Sample randomization; 4- Sterilization of the appliances; 5- Experimental protocol; 6- Analysis of the dental biofilm; 7- Microhardness analysis; 8- Surface topography analysis.

Palatal Appliance Preparation

Six specimens were randomly attached in each acrylic resin palatal appliance, with three enamel blocks on each side of the appliance (Figure 1). The random sequence of specimens started from the anterior to posterior. This appliance setup was fixed for each volunteer at the different phases. A plastic mesh was fixed 1 mm above the dental specimens to favor biofilm accumulation¹². After, the appliance was sterilized under ultraviolet light (40 W) (t = 1h) ¹⁴14. Katara G, Hemvani N, Chitnis S, Chitnis V, Chitnis DS. Surface disinfection by exposure to germicidal UV light. Indian J Med Microbiol. 2008, 26(3): 241-242.^,¹⁵15. Viana PS, Orlandi MO, Pavarina AC, Machado AL, Vergani CE. Chemical composition and morphology study of bovine enamel submitted to different sterilization methods. Clin Oral Investig. 2018, Mar;22(2):733-744..

Experimental Protocol

The sequence of experimental protocol followed by the volunteers in each phase was randomized in blocks of twelve, generated using https://www.random.org/. The randomization list was kept blinded by one researcher (L.C.M) and this list remained secured until the completion of all data collection in the main study. Thus, in each phase, all test products were used by groups of volunteers such as at the end of the experiment, all volunteers experienced all products. The crossover study was conducted in four phases of seven days each, in which the volunteers were randomly allocated to the following test products: MSCaNaF, MSNaF, NaF, and control group (CG) (deionized water).

At the beginning of each phase, the volunteers placed the device in the mouth for 5 min to allow saliva pellicle formation. After that, the appliances were removed and a blinded researcher (K.L.F.L) applied the test products (100 μL) using a micropipette for 1 min on each enamel block, before the cariogenic challenge.

The volunteers used the appliances for 24 h and after this period, they were instructed to drop a 20% sucrose solution onto the specimens three times a day, with the appliance outside the mouth. The sucrose solution was allowed to rest onto each enamel block for 5 min. After 48 h, three enamel blocks were removed from the same side of appliance. The same procedure was performed for the other side at the end of the experimental protocol (7 days). Washout periods of at least 48 hours were established between each phase.

During the experiment and in the washout periods, the volunteers brushed their teeth and the appliance outside the mouth (except for the area containing the specimens) with a fluoridated toothpaste (Oral B, Procter & Gamble^®, USA) and were instructed not to use mouth rinses. Considering the crossover design of this study, no restrictions were made regarding the volunteer’s diet. The volunteers used the appliances throughout the whole experimental phase, removing them only during the sucrose treatment, during food consumption, beverage intake and during oral hygiene procedures.

Data Collection and Analysis

After each experimental phase, the biofilms formed in each specimen were collected. This sample was used to evaluate the concentration of soluble (SEPS) and insoluble (IEPS) extracellular polysaccharides. To the collected biofilm, 1 mL of 0.9% NaCl solution was added in each microtube and, after being vortexed, the suspension was centrifuged at 3000 g for 10 min. An aliquot of 500 μL of the sonicated biofilm suspension was used for extraction of polysaccharides, as described previously ¹⁹19. Aires CP, Del Bel Cury AA, Tenuta LMA, Klein MI, Koo H, Duarte S, Cury JA. Effect of Starch and Sucrose on Dental Biofilm Formation and on Root Dentine Demineralization. Caries Res, 2008, v. 42, n. 5, p. 380-386, sep.. The total amount of carbohydrates in each sample was quantified by the phenol sulfuric method with glucose as standard ²⁰20. Dubois, M.; Gilles, K. A.; Hamilton, J. K.; Rebers, P. A.; Smith, F. Colorimetric method for determination of sugars and related substances. Anal Chem. 1956, v. 28, n. 3, p. 350-356.^,²¹11. Ccahuana-Vásquez RA & Cury JA. S. Mutans biofilm model to evaluate antimicrobial substances and enamel demineralization. Braz Oral Res. 2010, 24(2): 135-41.. Samples were analyzed in a spectrophotometer (490 nm) and the absorbance values were interpolated in a standard curve with known concentrations (μg/mL) of glucose.

After data collection for SEPS and IEPS, the surface microhardness of the enamel blocks was measured in all groups in the same way as performed initially and after, the %SML was calculated.

The surface roughness of the samples was measured by 3D non-contact profilometry (Nanovea PS50 Optical, Nanovea, Irvine, USA). A 1 mm² assessment area on the enamel blocks were standardized. A chromatic confocal sensor using a white light axial source, with a scan velocity of 2 mm/s and a refraction index of 10,000 were used to capture 3D images. The means for the three volumetric roughness (Sa) (ISO 25178) (250 μm²) measurements were obtained for each specimen ²²22. Alencar CM, Leite KLF, Ortiz MIG, Magno MB, Rocha GM, Silva CM, Maia LC. Morphological and chemical effects of in-office and at-home desensitising agents containing sodium fluoride on eroded root dentin. Arch Oral Biol. 2020Feb;110:104619..

Statistical Analysis

The normal distribution of data was tested for all variables using the Shapiro-Wilk test. For the in vitro study, Wilcoxon, Kruskal Wallis and Mann Whitney tests (p < 0.05) were considered for the pH, %SML and ΔZ considering the periods of 24 h and 48 h. For the in situ study, data that did not satisfy assumptions of equality of variances and thus, normal distribution of errors were transformed. The data were independently analyzed at each period and between them (48 h and 7 days). Analysis of Variance (ANOVA) checked the effect of the treatments with repeated measures, with Tukey and Bonferroni post-hoc tests, considering p < 0.05, and volunteers were considered as statistical blocks in those analyses.

Results

For the in vitro study, pH measurements were different after 24h and 48h for all groups, except for the SC group (Figure 2). No difference in the MSCaNaF and MSNaF groups was seen after 24h (p<0.05), but after 48h, pH was similar (p>0.05).

The MSCaNaF and MSNaF groups resulted in lower % SML and ΔZ (p<0.05) than CG and NaF after 24h. However, after 48h these were similar to NaF (p>0.05) and different from CG (p<0.05) (Table 1 and 2 and Figure 3).

Figure 2
pH values after 24 h and 48 h of biofilm formation for each experimental group.

Thumbnail

Table 1
Surface microhardness analysis before and after the experiments and percentage of enamel surface microhardness loss for the in vitro study.

Thumbnail

Table 2
Mineral loss analysis (∆Z) for the in vitro study.

Figure 3
Photomicrograph of enamel surface assessed by micro-CT in the in vitro study. The delimited region indicates the area and depth of the carious lesion, from where ΔZ values were obtained.

For the in situ study, two volunteers were excluded due to the use of antibiotics. Therefore, this study was carried out with two 240 enamel blocks distributed in 10 volunteers. No adverse effects were observed in any of the intervention groups. The amount of SEPS and IEPS increased between periods of 48h to 7 days for all groups (p<0.05). In the 48h period, values of SEPS and IEPS were similar for all groups, however, after the 7 day period, SEPS values of the nanocomposites were similar (p>0.05) but differed from CG (p<0.05), while NaF was similar to CG (p>0.05). All experimental groups had similar values of IEPS (p>0.05) which were lower than those for the CG (p<0.05) (Table 3).

In relation to surface microhardness, significant intragroup differences in the %SML were found for the evaluated periods. After 48h, MSCaNaF and MSNaF groups were more effective compared with NaF in reducing demineralization, with the lowest %SML observed (p<0.05). However, after 7 days, the MSCaNaF, MSNaF and NaF groups were similar (p>0.05) (Table 3).

Regarding roughness, the 7 days values were higher than the 48 h values for all groups (p<0.05). The greatest inhibition of tooth structure loss occurred when specimens were treated with MSCaNaF for both analyzed periods (p<0.05) (Table 4). The solutions prevented greater surface changes generated by acids from bacterial metabolism for all groups. The highest roughness values were observed in the CG (Figure 4).

Thumbnail

Table 3
Mean and standard deviation of the concentration of soluble (SEPS) and insoluble (IEPS) extracellular polysaccharides and enamel surface microhardness analysis, according to the periods of 48 h and 7 days.

Thumbnail

Table 4:
Mean and standard deviation of surface enamel obtained via non-contact profilometry for Sa of groups after caries challenge.

Figure 4:
Photomicrographs of the surface of the enamel blocks after the caries challenge obtained via non-contact profilometry. The left side of the image represents the Sa eroded.t

Discussion

As seen in the present in vitro and in situ study, the use of MS-nanoparticles associated with fluoride and calcium is effective for dental caries prevention. Mesoporous silica nanoparticles have indeed attracted considerable attention for their application in drug delivery and biomedicine, due to the large surface area and pore volume ⁴4. Wang Y, Zhao Q, Han N, Bai L, Li J, Liu J, Che E, Hu L, Zhang Q, Jiang T, Wang S. Mesoporous silica nanoparticles in drug delivery and biomedical applications. Nanomedicine. 2015Feb;11(2):313-27.^,⁵5. Kavoosi F, Modaresi F, Sanaei M, Rezaei Z. Medical and dental applications of nanomedicines. APMIS. 2018, Oct;126(10):795-803.^,²³23. Gu J, Huang M, Liu J, Li Y, Zhao W, Shi J. Calcium doped mesoporous silica nanoparticles as efficient alendronate delivery vehicles. New Journal of Chemistry, 2012, v. 36, p. 1717-1720., and thus, studies with new preventive products are welcome in dental practice.

Several studies report the recent advances in MS-nanoparticles, including immediate and sustained delivery systems, as well as controlled release and targeted drug delivery systems ²⁴24. Florek J, Caillard R, Kleitz F. Evaluation of mesoporous silica nanoparticles for oral drug delivery - current status and perspective of msns drug carriers. Nanoscale. 2017, Oct 19;9(40):15252-15277.^,²⁵25. Li Z, Zhang Y, Feng N. Mesoporous silica nanoparticles: synthesis, classification, drug loading, pharmacokinetics, biocompatibility, and application in drug delivery. Expert Opin Drug Deliv. 2019, Mar;16(3):219-237.. In dentistry, the development of nanohydroxyapatite with MS for therapeutic management of dentin surfaces ²⁶26. Yu J, Yang H, Li K, Ren H, Lei J, Huang C. Development of Epigallocatechin-3-gallate-Encapsulated Nanohydroxyapatite/Mesoporous Silica for Therapeutic Management of Dentin Surface. ACS Appl Mater Interfaces. 2017, Aug 9;9(31):25796-25807. and the antibacterial dental composites with chlorhexidine-based MS ²⁷27. Zhang JF, Wu R, Fan Y, Liao S, Wang Y, Wen ZT, Xu X. Antibacterial dental composites with chlorhexidine and mesoporous silica. J Dent Res. 2014, Dec;93(12):1283-9.^,²⁸28. Yan H, Yang H, Li K, Yu J, Huang C. Effects of Chlorhexidine-Encapsulated Mesoporous Silica Nanoparticles on the Anti-Biofilm and Mechanical Properties of Glass Ionomer Cement. Molecules. 2017, Jul 21;22(7). have been reported. However, no previous results on the action of these proposed new mesoporous silica nanoparticles with fluoride products in the enamel were found.

Our in vitro model showed that MSCaNaF and MSNaF were effective in reducing enamel demineralization (% SML and ΔZ). Even though no statistically significant difference was found between nanocomposites and NaF after 48 h, enamel samples treated with nanocomposites presented a higher protective effect compared with NaF in 24h. Therefore, the MSCaNaF and MSNaF groups may be considered promising alternatives in the clinical control of dental caries since results were also similar in the in situ study. However, in both in vitro and in situ studies, their long-term maintenance of F levels has reduced over time. In the present study, these products were applied only once before the cariogenic challenge, in an attempt to evaluate their preventive effect. The in situ study was carried out over a longer period, and nevertheless, in the period of 7 days, these products were still able to maintain the same levels of demineralization compared to NaF. Possibly, the nanocomposites are more effective at the beginning of the demineralization process (24h and 48h period).

Although the amount of SEPS and IEPS in the 48h period was the same for all products at the end of the cariogenic challenge, all test products showed higher values of both SEPS and IEPS. This increase in the polysaccharide values can be considered as a possible explanation for the caries progression in all groups over the experimental period. However, the authors emphasize that this increase was higher in the control group compared to the experimental, meaning that all fluoride products were able to reduce the progression of dental caries lesions formation.

In general, nanocomposites of MSCaNaF and MSNaF showed better results compared with NaF, and this may be due to the nanocomposite particles with a high silica encapsulation efficiency. It seems there was no synergism between calcium and fluoride since there was no statistical difference between the nanoparticles. In the present study, the authors used the products in solution form, which may have resulted in low fluoride retention in the dental enamel, and this hindered the maintenance of the preventive effect during the 7 days. Other formulations, such as varnishes, present greater retentivity, and, probably, a greater amount of fluoride is released over a long-term²⁹. It is possible that the effectiveness of the nanocomposites was compromised due to their presentation, since solutions have less adhesion on the dental surface than other formulations, such as varnishes and gels ³⁰30. Urquhart O, Tampi MP, Pilcher L, Slayton RL, Araujo MWB, Fontana M, Guzmán-Armstrong S, Nascimento MM, Nový BB, Tinanoff N, Weyant RJ, Wolff MS, Young DA, Zero DT, Brignardello-Petersen R, Banfield L, Parikh A, Joshi G, Carrasco-Labra A. Nonrestorative Treatments for Caries: Systematic Review and Network Meta-analysis. J Dent Res. 2019, Jan;98(1):14-26.. Despite this, the solutions from the present study managed to release loosely bound fluoride that may be an important source of fluoride on the enamel surface to induce remineralization and reduce demineralization during periods of cariogenic challenge.

Regarding the enamel morphological characteristics, the groups treated with MS-nanocomposites showed a decrease in surface roughness (Sa), mainly after 48h. High concentrations of NaF can be a physical barrier, inhibiting contact of the acid with the dental surface and/or acting as a fluoride reservoir since it is able to promote the precipitation of CaF₂³¹31. Borges, A.B., Scaramucci, T., Lippert, F., Zero, D.T. & Hara, A.T. Erosion protection by calcium lactate/sodium fluoride rinses under different salivary flows in vitro. Caries Research, 2014, 48, 193-199.. However, although the NaF group has equal fluoride concentration as the nanocomposites, different results were observed. It could be justified by the gradual F^- release of the nanocomposites, extending the effect of these products. The enamel morphological characteristic is corroborated by the photomicrographs of the surface of the enamel specimens, where it is possible to observe larger exposure of enamel prisms in the NaF and control groups. After 7 days, the photomicrographs showed that the MSCaNaF and MSNaF could not completely protect the enamel surface during all cariogenic challenges.

As the present study was the first to be carried out in an in vitro and in situ model, more clinical studies are desirable to identify the effects of these experimental nanoparticles, against dental caries, with other presentation forms and different concentrations, for a long time and with periodic exposure.

Conclusion

MSCaNaF and MSNaF were able to decrease the enamel demineralization, mainly in the initial periods evaluated. Although there was a reduction in the efficacy of the nanocomposite products over the in vitro and in situ experimental period, they were similar to sodium fluoride and superior to negative control for all parameters analyzed.

References

¹
Gao SS, Zhang S, Mei ML, Lo EC, Chu CH. Caries remineralisation and arresting effect in children by professionally applied fluoride treatment - a systematic review. BMC Oral Health. 2016Feb 1;16:12. Doi: 10.1186/s12903-016-0171-6.
» https://doi.org/10.1186/s12903-016-0171-6
²
Bijle MNA, Yiu CKY, Ekambaram M. Calcium-Based Caries Preventive Agents: A Meta-evaluation of Systematic Reviews and Meta-analysis. J Evid Based Dent Pract. 2018Sep;18(3):203-217.e4. Doi: 10.1016/j.jebdp.2017.09.003.
» https://doi.org/10.1016/j.jebdp.2017.09.003.
³
Singh A, Purohit BM. Caries Preventive Effects of High-fluoride vs Standard-fluoride Toothpastes - A Systematic Review and Meta-analysis. Oral Health Prev Dent. 2018, 16(4):307-314.
⁴
Wang Y, Zhao Q, Han N, Bai L, Li J, Liu J, Che E, Hu L, Zhang Q, Jiang T, Wang S. Mesoporous silica nanoparticles in drug delivery and biomedical applications. Nanomedicine. 2015Feb;11(2):313-27.
⁵
Kavoosi F, Modaresi F, Sanaei M, Rezaei Z. Medical and dental applications of nanomedicines. APMIS. 2018, Oct;126(10):795-803.
⁶
Kuang Y, Zhai J, Xiao Q, Zhao S, Li C. Polysaccharide/mesoporous silica nanoparticle-based drug delivery systems: A review. Int J Biol Macromol. 2021Oct 25:S0141-8130(21)02299-6. Doi: 10.1016/j.ijbiomac.2021.10.142.
» https://doi.org/10.1016/j.ijbiomac.2021.10.142.
⁷
Ashour MM, Mabrouk M, Soliman IE, Beherei HH, Tohamy KM. Mesoporous silica nanoparticles prepared by different methods for biomedical applications: Comparative study. IET Nanobiotechnol. 2021May;15(3):291-300. Doi: 10.1049/nbt2.12023.
» https://doi.org/10.1049/nbt2.12023.
⁸
Canto FMT, Alexandria AK, Vieira TI, Justino IBS, Cabral LM, Silva RF, Maia LC. Comparative effect of calcium mesoporous silica versus calcium and/or fluoride products against dental erosion Braz. Dent. J. 2020aMar; 31(2): 164-170. Doi: 10.1590/0103-6440202002557.
» https://doi.org/10.1590/0103-6440202002557.
⁹
Canto FMT, Alexandria AK, Justino IBS, Rocha GM, Cabral LM, Silva RF, Pithon MM, Maia LC. The use of a new calcium mesoporous silica nanoparticle versus calcium and/or fluoride products in reducing the progression of dental erosion. J. Appl. Oral Sci. 2020bJan; 28. Doi: 10.1590/1678-7757-2020-0131.
» https://doi.org/10.1590/1678-7757-2020-0131.
¹⁰
Justino IBS, Alexandria AK, Canto FMT, Leite KLF, Vieira TI, Cabral LM, Silva RF, Maia LC. Comparative effect of calcium mesoporous silica versus calcium and/or fluoride products on the reduction of erosive tooth wear and abrasive enamel lesion. Pesqui. Bras. Odontopediatria Clín. Integr. 2020; 20. Doi: 10.1590/pboci.2020.146.
» https://doi.org/10.1590/pboci.2020.146.
^’1
Leite KLF, Vieira TI, Alexandria AK, Silva RFD, Silva ASS, Lopes RT, Fonseca-Gonçalves A, Neves AA, Cabral LM, Pithon MM, Cavalcanti YW, Maia LC. In vitro effect of experimental nanocomposites solutions on the prevention of dental caries around orthodontic brackets. Braz Dent J. 2021Jul-Aug;32(4):62-73. Doi: 10.1590/0103-6440202104331.
» https://doi.org/10.1590/0103-6440202104331.
¹¹
Hara AT, Queiroz CS, Paes Leme AF, Serra MC, Cury JA. Caries progression and inhibition in human and bovine root dentine in situ. Caries Res 2003, 37:339-344.
¹³
Cury JA, Rebelo MAB, Del Bel Cury AA, Derbyshire MTVC, Taubchoury CPM. Biochemical Composition and Cariogenicity of Dental Plaque Formed in the Presence of Sucrose of Glucose and Fructose. Caries Res 2000, 34: 491-497.
¹⁴
Katara G, Hemvani N, Chitnis S, Chitnis V, Chitnis DS. Surface disinfection by exposure to germicidal UV light. Indian J Med Microbiol 2008, 26(3): 241-242.
¹⁵
Viana PS, Orlandi MO, Pavarina AC, Machado AL, Vergani CE. Chemical composition and morphology study of bovine enamel submitted to different sterilization methods. Clin Oral Investig 2018, Mar;22(2):733-744.
¹⁶
CLSI. (2012). Methods for dilution antimicrobial susceptibility tests for bacteria that grow aerobically; approved standard ninth edition. CLSI document M07-A9 Wayne, PA:Clinical and Laboratory Standards Institute.
¹⁷
Amaechi BT, Higham SM, Edgar WM. (1999). Techniques for the production of dental eroded lesions in vitro. Journal of Oral Rehabilitation, 26(2): 97-102. Doi: 10.1046/j.1365-2842.1999.00349.x.
» https://doi.org/10.1046/j.1365-2842.1999.00349.x.
¹⁸
Alexandria AK, Nassur C, Nóbrega CBC, Valença AMG, Rosalen PL, Maia LC. (2017a) In situ effect of titanium tetrafluoride varnish on enamel demineralization. Brazilian Oral Research, Nov 6;31:e86. Doi: 10.1590/1807-3107BOR-2017.
» https://doi.org/10.1590/1807-3107BOR-2017.
¹⁹
Aires CP, Del Bel Cury AA, Tenuta LMA, Klein MI, Koo H, Duarte S, Cury JA. Effect of Starch and Sucrose on Dental Biofilm Formation and on Root Dentine Demineralization. Caries Res, 2008, v. 42, n. 5, p. 380-386, sep.
²⁰
Dubois, M.; Gilles, K. A.; Hamilton, J. K.; Rebers, P. A.; Smith, F. Colorimetric method for determination of sugars and related substances. Anal Chem 1956, v. 28, n. 3, p. 350-356.
¹¹
Ccahuana-Vásquez RA & Cury JA. S. Mutans biofilm model to evaluate antimicrobial substances and enamel demineralization. Braz Oral Res 2010, 24(2): 135-41.
²²
Alencar CM, Leite KLF, Ortiz MIG, Magno MB, Rocha GM, Silva CM, Maia LC. Morphological and chemical effects of in-office and at-home desensitising agents containing sodium fluoride on eroded root dentin. Arch Oral Biol 2020Feb;110:104619.
²³
Gu J, Huang M, Liu J, Li Y, Zhao W, Shi J. Calcium doped mesoporous silica nanoparticles as efficient alendronate delivery vehicles. New Journal of Chemistry, 2012, v. 36, p. 1717-1720.
²⁴
Florek J, Caillard R, Kleitz F. Evaluation of mesoporous silica nanoparticles for oral drug delivery - current status and perspective of msns drug carriers. Nanoscale 2017, Oct 19;9(40):15252-15277.
²⁵
Li Z, Zhang Y, Feng N. Mesoporous silica nanoparticles: synthesis, classification, drug loading, pharmacokinetics, biocompatibility, and application in drug delivery. Expert Opin Drug Deliv 2019, Mar;16(3):219-237.
²⁶
Yu J, Yang H, Li K, Ren H, Lei J, Huang C. Development of Epigallocatechin-3-gallate-Encapsulated Nanohydroxyapatite/Mesoporous Silica for Therapeutic Management of Dentin Surface. ACS Appl Mater Interfaces 2017, Aug 9;9(31):25796-25807.
²⁷
Zhang JF, Wu R, Fan Y, Liao S, Wang Y, Wen ZT, Xu X. Antibacterial dental composites with chlorhexidine and mesoporous silica. J Dent Res 2014, Dec;93(12):1283-9.
²⁸
Yan H, Yang H, Li K, Yu J, Huang C. Effects of Chlorhexidine-Encapsulated Mesoporous Silica Nanoparticles on the Anti-Biofilm and Mechanical Properties of Glass Ionomer Cement. Molecules 2017, Jul 21;22(7).
²⁹
Falcão A, Masson N, Leitão TJ, Botelho JN, Ferreira-Nobilo Nde P, Tabchoury CP, Tenuta LM, Cury J A: Fluoride rinse effect on retention of caf 2 formed on enamel/dentine by fluoride application. Braz Oral Res 2016, 30:e31.
³⁰
Urquhart O, Tampi MP, Pilcher L, Slayton RL, Araujo MWB, Fontana M, Guzmán-Armstrong S, Nascimento MM, Nový BB, Tinanoff N, Weyant RJ, Wolff MS, Young DA, Zero DT, Brignardello-Petersen R, Banfield L, Parikh A, Joshi G, Carrasco-Labra A. Nonrestorative Treatments for Caries: Systematic Review and Network Meta-analysis. J Dent Res 2019, Jan;98(1):14-26.
³¹
Borges, A.B., Scaramucci, T., Lippert, F., Zero, D.T. & Hara, A.T. Erosion protection by calcium lactate/sodium fluoride rinses under different salivary flows in vitro. Caries Research, 2014, 48, 193-199.

Funding

This paper is part of first author's dissertation was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil (CAPES), Finance Code 001; by Conselho Nacional de Ciência e Tecnologia (CNPQ), Finance Code 303535/2016-4; and Fundação de Amparo à Pesquisa do Estado do Rio de Janeiro- Brasil (FAPERJ) process numbers E- 26/200.945/2019, E-26/202.924/2017, E-26/201.175/2021 and E-26/202.037/2021.

Publication Dates

Publication in this collection
17 July 2023
Date of issue
May-Jun 2023

History

Received
09 Mar 2023
Accepted
25 May 2023

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

[1] ¹
Gao SS, Zhang S, Mei ML, Lo EC, Chu CH. Caries remineralisation and arresting effect in children by professionally applied fluoride treatment - a systematic review. BMC Oral Health. 2016Feb 1;16:12. Doi: 10.1186/s12903-016-0171-6.
» https://doi.org/10.1186/s12903-016-0171-6

[2] ²
Bijle MNA, Yiu CKY, Ekambaram M. Calcium-Based Caries Preventive Agents: A Meta-evaluation of Systematic Reviews and Meta-analysis. J Evid Based Dent Pract. 2018Sep;18(3):203-217.e4. Doi: 10.1016/j.jebdp.2017.09.003.
» https://doi.org/10.1016/j.jebdp.2017.09.003.

[3] ³
Singh A, Purohit BM. Caries Preventive Effects of High-fluoride vs Standard-fluoride Toothpastes - A Systematic Review and Meta-analysis. Oral Health Prev Dent. 2018, 16(4):307-314.

[4] ⁴
Wang Y, Zhao Q, Han N, Bai L, Li J, Liu J, Che E, Hu L, Zhang Q, Jiang T, Wang S. Mesoporous silica nanoparticles in drug delivery and biomedical applications. Nanomedicine. 2015Feb;11(2):313-27.

[5] ⁵
Kavoosi F, Modaresi F, Sanaei M, Rezaei Z. Medical and dental applications of nanomedicines. APMIS. 2018, Oct;126(10):795-803.

[6] ⁶
Kuang Y, Zhai J, Xiao Q, Zhao S, Li C. Polysaccharide/mesoporous silica nanoparticle-based drug delivery systems: A review. Int J Biol Macromol. 2021Oct 25:S0141-8130(21)02299-6. Doi: 10.1016/j.ijbiomac.2021.10.142.
» https://doi.org/10.1016/j.ijbiomac.2021.10.142.

[7] ⁷
Ashour MM, Mabrouk M, Soliman IE, Beherei HH, Tohamy KM. Mesoporous silica nanoparticles prepared by different methods for biomedical applications: Comparative study. IET Nanobiotechnol. 2021May;15(3):291-300. Doi: 10.1049/nbt2.12023.
» https://doi.org/10.1049/nbt2.12023.

[8] ⁸
Canto FMT, Alexandria AK, Vieira TI, Justino IBS, Cabral LM, Silva RF, Maia LC. Comparative effect of calcium mesoporous silica versus calcium and/or fluoride products against dental erosion Braz. Dent. J. 2020aMar; 31(2): 164-170. Doi: 10.1590/0103-6440202002557.
» https://doi.org/10.1590/0103-6440202002557.

[9] ⁹
Canto FMT, Alexandria AK, Justino IBS, Rocha GM, Cabral LM, Silva RF, Pithon MM, Maia LC. The use of a new calcium mesoporous silica nanoparticle versus calcium and/or fluoride products in reducing the progression of dental erosion. J. Appl. Oral Sci. 2020bJan; 28. Doi: 10.1590/1678-7757-2020-0131.
» https://doi.org/10.1590/1678-7757-2020-0131.

[10] ¹⁰
Justino IBS, Alexandria AK, Canto FMT, Leite KLF, Vieira TI, Cabral LM, Silva RF, Maia LC. Comparative effect of calcium mesoporous silica versus calcium and/or fluoride products on the reduction of erosive tooth wear and abrasive enamel lesion. Pesqui. Bras. Odontopediatria Clín. Integr. 2020; 20. Doi: 10.1590/pboci.2020.146.
» https://doi.org/10.1590/pboci.2020.146.

[11] ^’1
Leite KLF, Vieira TI, Alexandria AK, Silva RFD, Silva ASS, Lopes RT, Fonseca-Gonçalves A, Neves AA, Cabral LM, Pithon MM, Cavalcanti YW, Maia LC. In vitro effect of experimental nanocomposites solutions on the prevention of dental caries around orthodontic brackets. Braz Dent J. 2021Jul-Aug;32(4):62-73. Doi: 10.1590/0103-6440202104331.
» https://doi.org/10.1590/0103-6440202104331.

[12] ¹¹
Hara AT, Queiroz CS, Paes Leme AF, Serra MC, Cury JA. Caries progression and inhibition in human and bovine root dentine in situ. Caries Res 2003, 37:339-344.

[13] ¹³
Cury JA, Rebelo MAB, Del Bel Cury AA, Derbyshire MTVC, Taubchoury CPM. Biochemical Composition and Cariogenicity of Dental Plaque Formed in the Presence of Sucrose of Glucose and Fructose. Caries Res 2000, 34: 491-497.

[14] ¹⁴
Katara G, Hemvani N, Chitnis S, Chitnis V, Chitnis DS. Surface disinfection by exposure to germicidal UV light. Indian J Med Microbiol 2008, 26(3): 241-242.

[15] ¹⁵
Viana PS, Orlandi MO, Pavarina AC, Machado AL, Vergani CE. Chemical composition and morphology study of bovine enamel submitted to different sterilization methods. Clin Oral Investig 2018, Mar;22(2):733-744.

[16] ¹⁶
CLSI. (2012). Methods for dilution antimicrobial susceptibility tests for bacteria that grow aerobically; approved standard ninth edition. CLSI document M07-A9 Wayne, PA:Clinical and Laboratory Standards Institute.

[17] ¹⁷
Amaechi BT, Higham SM, Edgar WM. (1999). Techniques for the production of dental eroded lesions in vitro. Journal of Oral Rehabilitation, 26(2): 97-102. Doi: 10.1046/j.1365-2842.1999.00349.x.
» https://doi.org/10.1046/j.1365-2842.1999.00349.x.

[18] ¹⁸
Alexandria AK, Nassur C, Nóbrega CBC, Valença AMG, Rosalen PL, Maia LC. (2017a) In situ effect of titanium tetrafluoride varnish on enamel demineralization. Brazilian Oral Research, Nov 6;31:e86. Doi: 10.1590/1807-3107BOR-2017.
» https://doi.org/10.1590/1807-3107BOR-2017.

[19] ¹⁹
Aires CP, Del Bel Cury AA, Tenuta LMA, Klein MI, Koo H, Duarte S, Cury JA. Effect of Starch and Sucrose on Dental Biofilm Formation and on Root Dentine Demineralization. Caries Res, 2008, v. 42, n. 5, p. 380-386, sep.

[20] ²⁰
Dubois, M.; Gilles, K. A.; Hamilton, J. K.; Rebers, P. A.; Smith, F. Colorimetric method for determination of sugars and related substances. Anal Chem 1956, v. 28, n. 3, p. 350-356.

[21] ¹¹
Ccahuana-Vásquez RA & Cury JA. S. Mutans biofilm model to evaluate antimicrobial substances and enamel demineralization. Braz Oral Res 2010, 24(2): 135-41.

[22] ²²
Alencar CM, Leite KLF, Ortiz MIG, Magno MB, Rocha GM, Silva CM, Maia LC. Morphological and chemical effects of in-office and at-home desensitising agents containing sodium fluoride on eroded root dentin. Arch Oral Biol 2020Feb;110:104619.

[23] ²³
Gu J, Huang M, Liu J, Li Y, Zhao W, Shi J. Calcium doped mesoporous silica nanoparticles as efficient alendronate delivery vehicles. New Journal of Chemistry, 2012, v. 36, p. 1717-1720.

[24] ²⁴
Florek J, Caillard R, Kleitz F. Evaluation of mesoporous silica nanoparticles for oral drug delivery - current status and perspective of msns drug carriers. Nanoscale 2017, Oct 19;9(40):15252-15277.

[25] ²⁵
Li Z, Zhang Y, Feng N. Mesoporous silica nanoparticles: synthesis, classification, drug loading, pharmacokinetics, biocompatibility, and application in drug delivery. Expert Opin Drug Deliv 2019, Mar;16(3):219-237.

[26] ²⁶
Yu J, Yang H, Li K, Ren H, Lei J, Huang C. Development of Epigallocatechin-3-gallate-Encapsulated Nanohydroxyapatite/Mesoporous Silica for Therapeutic Management of Dentin Surface. ACS Appl Mater Interfaces 2017, Aug 9;9(31):25796-25807.

[27] ²⁷
Zhang JF, Wu R, Fan Y, Liao S, Wang Y, Wen ZT, Xu X. Antibacterial dental composites with chlorhexidine and mesoporous silica. J Dent Res 2014, Dec;93(12):1283-9.

[28] ²⁸
Yan H, Yang H, Li K, Yu J, Huang C. Effects of Chlorhexidine-Encapsulated Mesoporous Silica Nanoparticles on the Anti-Biofilm and Mechanical Properties of Glass Ionomer Cement. Molecules 2017, Jul 21;22(7).

[29] ²⁹
Falcão A, Masson N, Leitão TJ, Botelho JN, Ferreira-Nobilo Nde P, Tabchoury CP, Tenuta LM, Cury J A: Fluoride rinse effect on retention of caf 2 formed on enamel/dentine by fluoride application. Braz Oral Res 2016, 30:e31.

[30] ³⁰
Urquhart O, Tampi MP, Pilcher L, Slayton RL, Araujo MWB, Fontana M, Guzmán-Armstrong S, Nascimento MM, Nový BB, Tinanoff N, Weyant RJ, Wolff MS, Young DA, Zero DT, Brignardello-Petersen R, Banfield L, Parikh A, Joshi G, Carrasco-Labra A. Nonrestorative Treatments for Caries: Systematic Review and Network Meta-analysis. J Dent Res 2019, Jan;98(1):14-26.

[31] ³¹
Borges, A.B., Scaramucci, T., Lippert, F., Zero, D.T. & Hara, A.T. Erosion protection by calcium lactate/sodium fluoride rinses under different salivary flows in vitro. Caries Research, 2014, 48, 193-199.

Groups	24 h			48 h
Groups	SMH Before	SMH After	%SML	SMH Before	SMH After	%SML
MSCaNaF	328.29 ± 5.17^Aa	259.65 ± 13.63^Ba	8.64 ± 2.48 ^a	329.64 ± 2.19^Aa	205.57 ± 24.72^Ba	27.28 ± 7.75^a
MSNaF	339.01 ± 3.77^Aa	262.95 ± 18.09^Ba	6.06 ± 5.76 ^a	320.26 ± 3.14^Aa	194.20 ± 17.81^Ba	28.82 ± 9.39^a
NaF	339.88 ± 3.66^Aa	210.07 ± 20.75^Bb	15.60 ± 6.66^b	325.55 ± 3.38^Aa	185.07 ± 25.74^Ba	37.52 ± 5.32 ^a
CG	336.25 ± 2.45^Aa	178.63 ± 16.99^Bc	36.87 ± 10.57^c	334.11 ± 5.50^Aa	94.35 ± 24.39^Bb	69.81 ± 7.00^b
SC	327.69 ± 4.33^Aa	306.86 ± 10.87^Bd	3.39 ± 3.13^d	330.14 ± 4.94^Aa	301.54 ± 13.91^Bc	3.58 ± 4.20^c

Groups	∆Z (8-bit gray values)
Groups	24 h	48 h
MSCaNaF	37.15 ± 9.88 ^Aa	67.65 ± 7.45 ^Ba
MSNaF	41.32 ± 7.81 ^Aa	71.87 ± 12.11 ^Ba
NaF	55.71 ± 8.13 ^Ab	80.15 ± 7.89 ^Ba
CG	131.23 ± 16.43 ^Ac	217.19 ± 22.65 ^Bb
SC	22.95 ± 6.34 ^Ad	26.62 ± 8.25 ^Ac

Groups	SEPS		IEPS		% SML
Groups	48 h	7 days	48 h	7 days	48 h	7 days
MSCaNaF	9.65 ^Aa ± 14.28	25.67 ^Ab ± 34.83	5.14 ^Aa ± 18.48	51.87 ^Ab ± 24.06	15.65 ^Aa ± 7.86	32.11 ^Ab ± 6.86
MSNaF	9.26 ^Aa ± 14.19	33.44 ^ABb ± 29.78	7.64 ^Aa ± 14.63	64.92 ^Ab ± 26.95	18.67 ^Aa ± 5.94	32.32 ^Ab ± 7.74
NaF	16.87 ^Aa ± 15.81	50.66 ^BCb ± 44.72	17.44 ^Aa ± 19.80	73.55 ^Ab ± 27.32	23.90 ^Ba ± 8.39	33.72 ^ABb ± 11.77
CG	15.69 ^Aa ± 44.92	81.10 ^Cb ± 48.87	24.13 ^Aa ± 14.31	106.16 ^Bb ± 40.89	33.88 ^Ca ± 6.67	45.43 ^Bb ± 14.96

Groups	Sa sound		Sa caries challenge
Groups	48 h	7 days	48 h	7 days
MSCaNaF	0.62 ^Aa ± 0.22	0.62 ^Aa ± 0.27	1.14 ^Ab ± 0.34	1.63 ^Ac ± 0.41
MSNaF	0.49 ^Aa ± 0.23	0.53 ^Aa ± 0.15	1.33 ^ABb ± 0.38	1.88 ^ABc ± 0.36
NaF	0.54 ^Aa ± 0.32	0.48 ^Aa ± 0.27	1.67 ^Bb ± 0.31	2.10 ^Bc ± 0.37
CG	0.60 ^Aa ± 0.22	0.63 ^Aa ± 0.19	2.23 ^Cb ± 0.48	3.60 ^Cc ± 0.95

Brasil

Brasil

In vitro and in situ caries-preventive effect of a new combined fluoride and calcium experimental nanocomposite solution.

Abstract

Introduction

Materials and Methods

Preparation of the Experimental Nanocomposites

In vitro study

Study Design and Sample Size

Specimen Preparation

Cariogenic Challenge

Data Collection and Analysis

In situ study

Ethical Aspects and Sample Size

Study Design

Specimens Preparation

Palatal Appliance Preparation

Experimental Protocol

Data Collection and Analysis

Statistical Analysis

Results

Discussion

Conclusion

References

Funding

Publication Dates

History