Cyclodextrin and TiF<sub>4</sub> Nanocomplex on Enamel Demineralization

Vieira, Thiago; Alexandria, Adílis K.; Amaral, Lilian H.; Neves, Aline de A.; Lopes, Ricardo T.; Cabral, Lúcio M.; Valença, Ana M. G.; Maia, Lucianne C.

doi:10.1590/0103-6440202002531

Abstract

The aim of this study was to assess the effect of a newly developed nanocomplex formed of hydroxypropyl-b-cyclodextrin and 1% titanium tetrafluoride (TiF₄) after distinct complexation periods (12/72 h) on demineralization of bovine enamel in vitro. Enamel blocks (n=60) were allocated in different groups: Mili-Q water, hydroxypropyl-b-cyclodextrin, 1% TiF₄, hydroxypropyl-b-cyclodextrin + 1% TiF₄ after 12 h of complexation and hydroxypropyl-b-cyclodextrin + 1% TiF₄ after 72 h of complexation. The samples were evaluated by surface microhardness, cross-sectional microhardness and micro-CT. Scanning electron microscopy and energy dispersive X-ray spectrometry (SEM/EDX) were also obtained. Hydroxypropyl-b-cyclodextrin + 1% TiF₄ after 12 h complexation resulted in lower percentage of surface microhardness loss compared to Mili-Q water, hydroxypropyl-b-cyclodextrin, 1% TiF₄ and hydroxypropyl-b-cyclodextrin + 1% TiF₄ after 72 h of complexation group, with a large effect size (from 1.307 to 2.943) and high power (84.9 to 99%). All groups resulted in similar integrated mineral loss (ΔZ) obtained by both internal microhardness and micro-CT techniques. Enamel treated with TiF₄ and TiF₄ + hydroxypropyl-b-cyclodextrin groups showed a TiO₂ glaze-layer, while EDX evaluation identified Ti. The solution containing the inclusion complex of hydroxypropyl-b-cyclodextrin + TiF₄ with 12 h of complexation period demonstrated a significant ability to reduce surface demineralization of sound enamel under an artificial cariogenic challenge.

Key Words:
dental caries; cyclodextrins; tooth demineralization; enamel; fluorides.

Resumo

O objetivo deste estudo foi avaliar o efeito da 1-etil-3- (3-dimetilaminopropil) carbodiimida (EDC) na resistência de união de pinos de fibra de vidro em canais radiculares obturados com diferentes cimentos endodônticos. Setenta e oito pré-molares inferiores foram obturados com três cimentos endodônticos (n=26): Endofill (END), AH Plus (AHP) e Endosequence BC Sealer (EBS). Após o preparo do espaço para pino, dois subgrupos formaram-se conforme a cimentação dos pinos (n=13): com EDC e sem EDC (controle - CON). Os espécimes foram submetidos ao teste pull-out, classificação do modo de falha e avaliação da superfície do canal radicular por microscopia eletrônica de varredura após o deslocamento. Quanto à força de resistência de união, uma diferença estatisticamente significativa ocorreu entre os subgrupos EDC e CON apenas no END (p=0,001). Não foi detectada diferença entre os subgrupos CON (p=0,339). Contudo, no subgrupo EDC, o AHP apresentou maiores valores (END versus AHP: p=0,001; AHP versus EBS: p=0,016). Acerca da classificação dos modos de falha, o escore 1 (≥50% de cimento) foi o mais comumente observado, exceto para END + EDC. Restos de cimentos endodônticos e cimentos resinosos foram encontrados no terço cervical, mas sem diferença estatística (p=0,269), enquanto no terço médio, houve diferença (p=0,004). Em conclusão, o EDC diminui a resistência de união quando associado ao cimento END, sem alterar o modo de falha entre o cimento resinoso e o pino de fibra de vidro. O melhor desempenho foi observado quanto o EDC foi usado com o cimento AHP.

Introduction

Dental caries is still the most prevalent oral disease in the world, and for this reason, a worldwide public health problem. Moreover, Latin America presents the higher occurrence of untreated caries in permanent dentition compared to global indicators ¹1 .Kassebaum NJ, Smith AGC, Bernabé E, Fleming TD, Reynolds AE, Vos T, et al. Global, Regional, and National Prevalence, Incidence, and Disability-Adjusted Life Years for Oral Conditions for 195 Countries, 1990-2015: A Systematic Analysis for the Global Burden of Diseases, Injuries, and Risk Factors. J Dent Res 2017;96: 380-387.. The current understanding on the establishment and development of carious lesions are directly linked to undisturbed biofilm accumulation over the tooth surfaces ²2 .Kidd EA, Fejerskov O. What constitutes dental caries? Histopathology of carious enamel and dentin related to the action of cariogenic biofilms. J Dent Res 2004;83:C35-38.. In this context, sucrose or other fermentable carbohydrates increase, while fluoride reduces the speed in which the lesions will progress ³3 . Paes Leme AF, Koo H, Bellato CM, Bedi G, Cury JA. The role of sucrose in cariogenic dental biofilm formation--new insight. J Dent Res2006;85:878-887.^,⁴4 .Tenuta LM, Cury JA. Fluoride: Its role in dentistry. Braz Oral Res 2010;1:9-17..

In fact, fluoride effectively inhibits enamel dissolution by the formation of CaF₂ reservoirs, which slowly release fluoride into the plaque fluid in order to interact during enamel dissolution ⁵5 .Tenuta LM, Zamataro CB, Del Bel Cury AA, Tabchoury CP, Cury JA. Mechanism of fluoride dentifrice effect on enamel demineralization. Caries Res 2009;43:278-285.. For this reason, frequent contacts with fluoride should be emphasized in order to provide a balance on the de- and remineralization kinetics of dental hard tissues.

Titanium tetrafluoride (TiF₄) has been, for many years a promising caries preventive agent due to its capacity of inducing the formation of calcium fluoride and a relatively insoluble layer of titanium dioxide on the tooth surface ⁶6 .Buyukyilmaz T, Ogaard B, Rolla G. The resistance of titanium tetrafluoride-treated human enamel to strong hydrochloric acid. Eur J Oral Sci1997;105:473-477.. The majority of laboratorial studies agree that a single application of this product is enough to provide a significant decrease in enamel dissolution ⁷7 .Castro RA, Chevitarese O, Souza IPR. Action of titanium tetrafluoride on occlusal human enamel in situ. Fluoride 2003;36:252-262.^,⁸8 .Comar LP, Wiegand A, Moron BM, Rios D, Buzalaf MA, Buchalla W, et al. In situ effect of sodium fluoride or titanium tetrafluoride varnish and solution on carious demineralization of enamel. Eur J Oral Sci 2012;120:342-348.^,⁹9 .Reed AJ, Bibby BG. Preliminary report on effect of topical applications of titanium tetrafluoride on dental caries. J Dent Res1976;55:357-358.. However, its hydrolysis ¹⁰10. Buslaev YA, Dyer DS, Ragsdale RO. Hydrolysis of titanium tetrafluoride. Inorg Chem 1967;6:2208-2212. and very acidic pH has always limited its clinical use ¹¹11. Wahengbam P, Tikku AP, Lee WB. Role of titanium tetrafluoride (tif(4)) in conservative dentistry: A systematic review. J Conserv Dent 2011;14:98-102.. To overcome these problems and to improve the stability of this agent, research has been focusing on the development of new titanium tetrafluoride delivery systems, such as the association with cyclodextrin complexes ¹²12. Nassur C, Alexandria AK, Pomarico L, de Sousa VP, Cabral LM, Maia LC. Characterization of a new TiF(4) and beta-cyclodextrin inclusion complex and its in vitro evaluation on inhibiting enamel demineralization. Arch Oral Biol2013;58:239-247.^,¹³13. Vieira TI, Câmara JVF, Cardoso JG, Alexandria AK, Pintor AVB, Villaça JC, et al. Cytotoxicity of novel fluoride solutions and their influence on mineral loss from enamel exposed to a Streptococcus mutans biofilm. Arch Oral Biol2018;91:57-62..

Cyclodextrin inclusion complexes formed with certain drugs may have physical, chemical, and biological properties which are dramatically different from those of either the parent drug or the cyclodextrin molecule ¹⁴14. Aree T, Chaichit N. Crystal structure of beta-cyclodextrin-benzoic acid inclusion complex. Carbohydr Res2003;338:439-446.. These complexes can be used to increase solubility and dissolution rate, decrease volatility, alter release rates, modify local inflammatory potential, and increase the stability of drugs. Cyclodextrins with six to eight dextrose units have been named a-, b-, and g-cyclodextrins, respectively ¹⁵15. Rajewski RA, Stella VJ. Pharmaceutical applications of cyclodextrins. 2. In vivo drug delivery. J Pharm Sci 1996;85:1142-1169.. Among the natural cyclodextrins, b-cyclodextrin is the most widely used, because of its high availability, low cost and dimensions of its cavity, which is able to accommodate a large number of drug molecules ¹⁶16. Szente L, Szejtli J. Highly soluble cyclodextrin derivatives: chemistry, properties, and trends in development. Adv Drug Deliv Rev 1999;36:17-28..

A b-cyclodextrin inclusion complex formed with TiF₄ has shown some potential to reduce enamel demineralization ¹²12. Nassur C, Alexandria AK, Pomarico L, de Sousa VP, Cabral LM, Maia LC. Characterization of a new TiF(4) and beta-cyclodextrin inclusion complex and its in vitro evaluation on inhibiting enamel demineralization. Arch Oral Biol2013;58:239-247. and to increase the hardness of enamel subsurface ¹⁷17. Vieira TI, Nassur C, Alexandria AK, Pomarico L, Sousa VP, Cabral LM, et al. Effect of the inclusion nanocomplex formed of titanium tetrafluoride and b-cyclodextrin on enamel remineralization. J Pharm Bioallied Sci 2017:9;201-207.. The nanocomplexes of hydroxypropryl-b-cyclodextrin with TiF₄ (12 and 72 h of complexation) also prevented enamel dissolution from a cariogenic challenge caused by a monospecies-biofilm ¹³13. Vieira TI, Câmara JVF, Cardoso JG, Alexandria AK, Pintor AVB, Villaça JC, et al. Cytotoxicity of novel fluoride solutions and their influence on mineral loss from enamel exposed to a Streptococcus mutans biofilm. Arch Oral Biol2018;91:57-62.. However, the effect of these nanocomplexes under a pH-cycling regimen, which provides a more controlled ion exchange environment, has not been studied yet. Thus, the aim of this study was to investigate the effect of a water-soluble polymer cyclodextrin inclusion nanocomplex (hydroxypropyl-b-cyclodextrin) formed with 1% TiF₄ after distinct complexation periods (12 or 72 h) on demineralization of bovine enamel in vitro.

Material and Methods

Preparation and Characterization of b-Cds and TiF ₄ Nanocomplexes

To produce the 1% TiF₄-b-cyclodextrin nanocomplexes, 0.1974g of TiF₄ (Sigma Aldrich®, St Louis, MO, USA; purity 37 to 39% of titanium) and 2.0112 g of hydroxypropyl-b-cyclodextrin (Sigma Aldrich®) were mixed in 20 mL of distilled water using a magnetic stirrer for 12 or 72 h. The mean pH value and total fluoride concentration (µg F/mL) from the nanocomplexed solutions were 1.78±0.07 and 6123.67±343.56, respectively ¹⁸18. Vieira TI, Alexandria AK, Menezes JCV, Amaral LH, Santos TMP, Neves AA, et al. Characterization and effect of nanocomplexed fluoride solutions on the inhibition of enamel demineralization created by a multispecies cariogenic biofilm model. Clin Oral Investig 2020 [Epub Ahead of Print. Doi: 10.1007/s00784-020-03261-0].
https://doi.org/10.1007/s00784-020-03261... . After that, the solutions were frozen in liquid nitrogen and lyophilized. Particle size was calibrated using a 40-mesh sieve and the inclusion yield was calculated by UV spectroscopy. Further, these nanosystems were characterized by X-ray powder diffraction, Fourier transform infrared spectroscopy and differential scanning calorimetry, as described previously ¹²12. Nassur C, Alexandria AK, Pomarico L, de Sousa VP, Cabral LM, Maia LC. Characterization of a new TiF(4) and beta-cyclodextrin inclusion complex and its in vitro evaluation on inhibiting enamel demineralization. Arch Oral Biol2013;58:239-247..

Preparation of Bovine Enamel Blocks

To determine the sample size, Hedge’s G value of 1.97 was used from a previous study (unpublished data), a two-tailed significance level of 5% and a power test of 97.45%, resulting in a sample size of 9. Twelve blocks per group were used to compensate for sample loss (30%).

Sixty enamel blocks (4 mm x 4 mm) were obtained from sterile bovine incisors by slicing the buccal surfaces with a diamond disk mounted in a low speed cutting machine (Isomet, Lake Bluff, IL, USA). The blocks were embedded in acrylic resin and ground sequentially using 600 and 1200 grit Al₂O₃ paper in a semi-automatic polisher (model PLF, Fortel, São Paulo, SP, Brazil) in order to obtain a ‘window’ of flattened and polished enamel in each specimen.

Enamel Blocks Selection and Allocation

Enamel specimens were selected by surface microhardness. Knoop hardness values were obtained by means of a microhardness tester (Buehler, Micromet 5104, 679-MIT4-00335, Japan) with a load of 50 g for 5 s ¹²12. Nassur C, Alexandria AK, Pomarico L, de Sousa VP, Cabral LM, Maia LC. Characterization of a new TiF(4) and beta-cyclodextrin inclusion complex and its in vitro evaluation on inhibiting enamel demineralization. Arch Oral Biol2013;58:239-247.. The first set of measurements was obtained in order to select enamel specimens presenting microhardness values within ±10% around the mean (341±10%KHN) to achieve homogeneity of the samples. The selected blocks were randomly allocated to each treatment group (5 groups / 12 enamel blocks per group): Mili-Q water, hydroxypropyl-b-cyclodextrin, 1% TiF₄, hydroxypropyl-b-cyclodextrin + 1% TiF₄ after 12 h of complexation and hydroxypropyl-b-cyclodextrin + TiF₄ after 72 h of complexation.

Enamel Surface Treatment and pH-Cycling Regimen

Immediately after preparation, the solutions were applied on the enamel surface for 1 min by a blinded operator, before the start of the pH-cycling regimen. After that, the specimens were washed with deionized water and dried with a soft absorbent paper.

The pH-cycling regimen followed a methodology previously described ¹⁹19. Queiroz CS, Hara AT, Paes Leme AF, Cury JA. pH-cycling models to evaluate the effect of low fluoride dentifrice on enamel de- and remineralization. Braz Dent J 2008;19:21-27.. Briefly, the blocks remained during 4 h in the demineralizing solution and 20 h in remineralizing solution at 37 °C during 8 days. The demineralizing solution consisted of 0.05 M acetate buffer (pH 5.0), 1.28 mM calcium, 0.74 mM phosphorus, 0.03 mg/mL fluoride. The remineralizing solution consisted of 1.5 mmol/L calcium, 0.9 mmol/L of phosphorus, 150 mmol/L potassium chloride, 0.05 mg of fluoride/ml in 0.1 mol/L Tris buffer (pH 7.0). On the fourth day of pH cycling, all solutions were replaced with freshly prepared ones. After the eighth day of the cycle, the blocks remained in remineralizing solution for an additional 24 h before starting further analysis. The proportion of demineralizing and remineralizing solutions per area of block was 6.25 mL/mm² and 3.12 mL/mm², respectively.

Surface Microhardness Determination

After specimen selection, five indentations, spaced by 100 µm were performed at the surface of each enamel block before and after the pH cycling regimen. Surface microhardness indentations performed after the pH cycling regimen were taken far from those already carried out at baseline. The operator was also blinded regarding the groups in this phase.

The percentage of enamel surface microhardness loss (%SML) was obtained by the following formula ⁸8 .Comar LP, Wiegand A, Moron BM, Rios D, Buzalaf MA, Buchalla W, et al. In situ effect of sodium fluoride or titanium tetrafluoride varnish and solution on carious demineralization of enamel. Eur J Oral Sci 2012;120:342-348.:

where, SM=surface microhardness

100 x \frac{({S M}_{b e f o r e} - {S M}_{a f t e r)}}{{S M}_{b e f o r e}}

Internal Microhardness Determination

After surface microhardness determination, the enamel blocks were longitudinally sectioned with a diamond disk mounted on a low-speed cutting machine (Isomet, Buehler). One of the halves was embedded in acrylic resin and the exposed surface was polished with 600 and 1200 grit Al₂O₃ paper, as described previously. Two sequences of 15 indentations were taken: the first started at 10 µm from the enamel surface up to 100 µm depth at 10 µm intervals; the second set started at 100 µm from the enamel surface to 200 µm depth at 20 µm intervals ¹²12. Nassur C, Alexandria AK, Pomarico L, de Sousa VP, Cabral LM, Maia LC. Characterization of a new TiF(4) and beta-cyclodextrin inclusion complex and its in vitro evaluation on inhibiting enamel demineralization. Arch Oral Biol2013;58:239-247.. The integrated mineral loss (ΔZ) was calculated as the integrated area (% vol. min. x µm) of post-pH cycling treatments (Z1), with projection to normal enamel (Z) using the formula ²⁰20. Featherstone JD, ten Cate JM, Shariati M, Arends J. Comparison of artificial caries-like lesions by quantitative microradiography and microhardness profiles. Caries Res 1983;17:385-391.:

∆ Z = 100 \frac{(Z 1 - Z)}{Z}

Micro-CT Analysis

The blocks in each group were scanned in a high energy micro-CT device (Skyscan 1173, Bruker micro-CT, Kontich, Belgium) after the pH cycling using the following acquisition parameters: 70 kV, 114 µA, 7.12 µm image pixel size, 1 mm Al filter, 1 s exposure time per frame, 0.5° rotation step over 360°, frame averaging of 5 and random movement parameter set to 20. The projections were reconstructed into cross-section slices by means of a proprietary software (Nrecon v.1.6.9.4, Bruker micro-CT) using standardized parameters to minimize artefacts: 50% beam hardening correction, ring artefact correction of 5, and input of similar contrast limits (0-0.08).

The enamel blocks cross-section slices were imported in a open-source image analysis software (ImageJ, FIJI implementation) ²¹21. Schindelin J, Arganda-Carreras I, Frise E, Kaynig V, Longair M, Pietzsch T, Preibisch S, et al. Fiji: An open-source platform for biological-image analysis. Nat Methods 2012;9:676-682. and resliced into longitudinal slices. An average density projection was obtained from each sample stack and gray value density profiles were taken from 2-line profiles in each image stack. The line profiles started from the outer enamel surface up to 200 µm deep into the enamel layer. Eight-bit gray values were taken at each pixel unit (7.12 µm) and the plots were exported to a separate worksheet. An integrated density profile, represented by the area under the plots (Z) was calculated for each profile (n=4/group), as described previously ²²22. Delbem ACB, Vieira AEM, Sassaki KT, Cannon ML, Stock SR, Xiao X, et al. Quantitative analysis of mineral content in enamel using synchrotron microtomography and microhardness analysis</title>. Proc of SPIE 2006;6318:631824-1-631824-5.. Data from each group were averaged and presented in a graphic form and submitted to descriptive analysis.

Scanning Electron Microscopy (SEM) and Energy Dispersive X-Ray Spectrometry (EDX) Assessment

Two specimens from each group were mounted on aluminum stubs and evaluated using an environmental scanning electron microscope (Jeol-JSM 6460LV, Tokyo, Japan). The topography of the enamel surfaces was analyzed in secondary electrons at 20 kV voltage, low vacuum mode (45 Pa) to obtain images with a 1000x magniﬁcation.

Assessment of mineral content was carried out in EDX mode with link and using Kontron automatic image analyzer system to identify chemical elements and its percentage in weight at the enamel surfaces after the pH cycling.

Data Analysis

Data were considered normally distributed whether kurtosis and skewness presented variations of ± 2 ²³23. Field A. Discovering Statistics Using SPSS. London: SAGE; 2009.. Data were considered homogeneous whether a ratio until 3 between the largest and the lowest variances were observed ²⁴24. Dean A, Voss D. Design and Analysis of Experiments. New York: Springer; 1999.. One-way ANOVA was used to analyze the %SML. Unpaired t-test was used for homogeneous and non-homogeneous variances (a two-tailed significance level of 5%) for comparison between pairs of groups in the post hoc test.

Mann-Whitney post hoc test was adopted to analyze ΔZ microhardness. Statistical significance, effect size, its 95% CI, and power for ANOVA and the each pairwise comparison were included for parametric data. Statistical significance, effect size and power were included for non-parametric data ²⁵25. Greenland S, Senn SJ, Rothman KJ, Carlin JB, Poole C, Goodman SN, et al. Statistical tests, P values, confidence intervals, and power: a guide to misinterpretations. Eur J Epidemiol 2016;31:337-350.. ΔZ micro-CT was descriptively assessed. SEM micrographs and EDX analysis were qualitatively evaluated. All analysis was carried out by SPSS (Statistical Package for Social Sciences - version 21.0, Chicago, IL, USA) and Microsoft® Office Excel (Microsoft Corporation).

Results

Descriptive statistics are shown in Table 1. Table 2 shows one-way ANOVA assessment. The null hypothesis was rejected (p=0.0003). The potential of the nanocomplexed fluoride solutions was significant with an effect size of 0.312 and a statistical power of 98.9%. Hydroxypropyl-b-cyclodextrin + 1% TiF₄ after 12 h complexation resulted in lower percentage of surface microhardness loss compared to Mili-Q water, hydroxypropyl-b-cyclodextrin, 1% TiF₄ and hydroxypropyl-b-cyclodextrin + 1% TiF₄ after 72 h of complexation group, with a large effect size (from 1.307 to 2.943) and high power (84.9 to 99%) (Table 3).

All groups resulted in similar integrated mineral loss (ΔZ) obtained by both internal microhardness and micro-CT techniques (Table 1 and Table 4). Figure 1 discloses profiles of microhardness or mineral density obtained by micro-CT for the control and experimental groups.

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Table 1
Descriptive analysis of %SML (mean±SD) and ΔZ microhardness and ΔZ micro-CT (median (minimum;maximum/interquatile range))

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Table 2
One-way ANOVA test results for the effects of the nanocomplexed fluoride solutions on surface microhardness loss

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Table 3
Findings from post-hoc pairwise comparisons regarding %SML

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Table 4
Results of pairwise comparisons regarding ΔZ microhardness

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Table 5
Values (percentage in weight) of the analyzed elements

Figure 1
Internal microhardness values (KHN) (A) and enamel mineral density values (g/cm3 hydroxyapatite) (B) from the surface to the inner enamel after treatment with the control/experimental solutions and pH cycling. Note: HP-β-CD=hydroxypropyl-β-cyclodextrin; TiF4=titanium tetrafluoride.

SEM analysis indicated the formation of TiO₂ glaze-layer on the surface of the slabs treated with hydroxypropyl-b-cyclodextrin + TiF₄ and TiF₄ compared to a control solution without TiF₄ (Fig. 2). EDX assessment showed the presence of titanium on the surface of the blocks treated with TiF₄ and TiF₄ after cyclodextrin complexation (Table 5). Figure 3 discloses profile of demineralizing areas corresponding to artificial enamel carious lesions measured by micro-CT.

Figure 2
Representative surface SEM images from a sample after treatment with hydroxypropyl-β-cyclodextrin (A), plain TiF4 solution (B) and hydroxypropyl-β-cyclodextrin + 1% TiF4 after 12 h of complexation (C).

Figure 3
Representative qualitative micro-CT specimen showing demineralized areas such carious-like lesions (white arrows).

Discussion

pH-cycling studies are employed to assess the caries/demineralization protection or rehardening effects of several compounds ²⁶26. Amaechi BT. Protocols to Study Dental Caries In Vitro: pH Cycling Models. Methods Mol Biol 2019;1922:379-392. because they simulate dental caries in vivo ²⁷27. Ten Cate JM. In vitro studies on the effects of fluoride on de- and remineralization. J Dent Res1990;614-9:634-6.. The main advantage of this protocol is related to its low cost compared with more rigorous and methodologically refined studies such as clinical research ²⁸28. White DJ. The comparative sensitivity of intra-oral, in vitro, and animal models in the 'profile' evaluation of topical fluorides. J Dent Res 1992;71:884-94.. However, the main shortfall is related to the impaired assessment of antibacterial effect from the fluoride agents tested ²⁷27. Ten Cate JM. In vitro studies on the effects of fluoride on de- and remineralization. J Dent Res1990;614-9:634-6..

The connection of TiF₄ to the enamel surface happens promptly and that coating is acid-insoluble and not readily removed by washing ²⁹29. Tveit AB, Tötdal B, Klinge B, Nilvéus R, Selvig KA. Fluoride uptake by dentin surfaces following topical application of TiF4, NaF and fluoride varnishes in vivo. Caries Res 1985;19:240-7.. Moreover, titanium fluoride complexes bind to the tooth surface by establishment of Ti-O (phosphate) bonds. It is expected that the titanium atom presents a high affinity for an oxygen atom that is part of a phosphate group in hydroxyapatite. The phosphate groups are disseminated on both enamel and root surfaces ³⁰30. Tveit AB, Hals E, Isrenn R, Tøtdal B. Highly acid SnF2 and TiF4 solutions. Effect on and chemical reaction with root dentin in vitro. Caries Res 1983;17:412-8.. Professional fluoride application compounds (solution, gel, foam and varnishes) have high fluoride concentrations and when applied locally to dental surfaces react either with enamel or dentin, resulting in reaction products. The main reaction product is called calcium fluoride-like (CaF₂-like) deposits. Over 90% of the reaction product is CaF₂, but there is also fluorapatite formation ³¹31. Arends J, Christoffersen J. Nature and role of loosely bound fluoride in dental caries. J Dent Res 1990;601-5:634-6.. And the fluoride released to biofilm fluid from CaF₂ formed on enamel reduces enamel demineralization ³²32. Tenuta LM, Cerezetti RV, Del Bel Cury AA, Tabchoury CP, Cury JA. Fluoride release from CaF2 and enamel demineralization. J Dent Res 2008;87:1032-6.. In the current study, the reaction products (CaF₂, fluorapatite, TiO₂ layer) were allowed in this in vitro context. Considering the above mentioned, the experimental conditions adopted in the present study allowed the fluorapatite formation as well as reaction products such as CaF₂ and TiO₂ layer.

TiF₄ is composed by a polyvalent metal ion in association with fluorides. This compound presents, in aqueous solution, antimicrobial effect against Streptococcus mutans and Lactobacillus casei³³33. Abbatepaulo GL, Gangana TMMC, Martinez EF, Turssi CP, França FMG, Amaral FLB, et al. TiF4 Incorporated into a self-etching primer in different concentrations: antimicrobial properties and effects on demineralisation inhibition around the restoration/enamel-dentin interface. Oral Health Prev Dent 2019;17:57-67.. Some conflicting findings in relation to the effectiveness of TiF₄ in inhibiting tooth demineralization are reported. While some studies show mineral loss reduction ¹²12. Nassur C, Alexandria AK, Pomarico L, de Sousa VP, Cabral LM, Maia LC. Characterization of a new TiF(4) and beta-cyclodextrin inclusion complex and its in vitro evaluation on inhibiting enamel demineralization. Arch Oral Biol2013;58:239-247.^,¹³13. Vieira TI, Câmara JVF, Cardoso JG, Alexandria AK, Pintor AVB, Villaça JC, et al. Cytotoxicity of novel fluoride solutions and their influence on mineral loss from enamel exposed to a Streptococcus mutans biofilm. Arch Oral Biol2018;91:57-62., others reported that this phenomenon was not observed ³³33. Abbatepaulo GL, Gangana TMMC, Martinez EF, Turssi CP, França FMG, Amaral FLB, et al. TiF4 Incorporated into a self-etching primer in different concentrations: antimicrobial properties and effects on demineralisation inhibition around the restoration/enamel-dentin interface. Oral Health Prev Dent 2019;17:57-67.. In this sense, new studies are still needed to confirm the effects of TiF₄ in on enamel demineralization.

Cyclodextrins are cyclic oligosaccharides composed of dextrose units joined by a a-1,4 linkage. If composed of seven dextrose units, they have been named b-cyclodextrins, while hydroxypropyl-b-cyclodextrin is formed by addition of a water-soluble polymer ((CH₂CH(OH)CH₃). Inclusion complexes formed between certain drugs and cyclodextrins may show extremely different properties from those of the parent drug, including the increase in solubility and dissolution rate of the parent compound, modification in local inflammatory properties, decrease in volatility and increase of the stability of the original drug ¹⁵15. Rajewski RA, Stella VJ. Pharmaceutical applications of cyclodextrins. 2. In vivo drug delivery. J Pharm Sci 1996;85:1142-1169..

Several studies have been undertaken in order to evaluate the impact of formulations containing cyclodextrins as inclusion complexes on the stability and bioavaliability of the complexed drug. This is due, among other things, to the ability of cyclodextrins to create inclusion complexes with a large number of molecules ³⁴34. Cal K, Centkowska K. Use of cyclodextrins in topical formulations: Practical aspects. Eur J Pharm Biopharm 2008;68:467-478.. For these reasons, cyclodextrins have been selected as TiF₄ carriers in the present study. Addition of water-soluble polymers enhances the complexation efficacy and bioavailability of the parent drug. The specific time of 72 h of complexation with b-cyclodextrin solely has been already examined in the literature ¹²12. Nassur C, Alexandria AK, Pomarico L, de Sousa VP, Cabral LM, Maia LC. Characterization of a new TiF(4) and beta-cyclodextrin inclusion complex and its in vitro evaluation on inhibiting enamel demineralization. Arch Oral Biol2013;58:239-247.. Taking into account these considerations, the present study was designed to evaluate one cyclodextrin carrier (hydroxypropyl-b-cyclodextrin) in two different complexation periods (12 or 72 h) in order to explore the effect of these nanocomplexes on bovine enamel demineralization.

Regarding surface findings, previous studies demonstrated that solutions containing TiF₄/TiF are able to decrease microhardness loss ⁷7 .Castro RA, Chevitarese O, Souza IPR. Action of titanium tetrafluoride on occlusal human enamel in situ. Fluoride 2003;36:252-262.^,⁸8 .Comar LP, Wiegand A, Moron BM, Rios D, Buzalaf MA, Buchalla W, et al. In situ effect of sodium fluoride or titanium tetrafluoride varnish and solution on carious demineralization of enamel. Eur J Oral Sci 2012;120:342-348.^,¹²12. Nassur C, Alexandria AK, Pomarico L, de Sousa VP, Cabral LM, Maia LC. Characterization of a new TiF(4) and beta-cyclodextrin inclusion complex and its in vitro evaluation on inhibiting enamel demineralization. Arch Oral Biol2013;58:239-247.^,¹³13. Vieira TI, Câmara JVF, Cardoso JG, Alexandria AK, Pintor AVB, Villaça JC, et al. Cytotoxicity of novel fluoride solutions and their influence on mineral loss from enamel exposed to a Streptococcus mutans biofilm. Arch Oral Biol2018;91:57-62.^,³⁵35. Exterkate RA, ten Cate JM. Effects of a new titanium fluoride derivative on enamel de- and remineralization. Eur J Oral Sci 2007;115:143-147.. In the present study, the ability of hydroxypropyl-b-cyclodextrin + TiF₄ nanocomplex after 12 h of complexation to decrease enamel softening under adverse conditions (pH-cycling) was shown (Table 3). The improved effect of this solution compared to the other experimental or controls solutions could be attributed to the sustained release ³⁶36. Zhang L, Liu M, Lu C, Ren D, Fan G, Liu C, et al. The hydroxypropyl-b-cyclodextrin complexation of toltrazuril for enhancing bioavailability. Drug Des Devel Ther 2018;12:583-589. of fluoride, keeping a constant concentration of fluoride available for interaction with the enamel surface during its application and decreasing surface demineralization.

In relation to subsurface data, internal integrated mineral loss data showed that all TiF₄ containing solutions were not effective in reducing overall mineral loss in enamel. Data from micro-CT also showed a non-protective effect for all groups tested. Micro-CT is a non-destructive technique which can be used to evaluate mineral changes in enamel after preventive or therapeutic treatments ²²22. Delbem ACB, Vieira AEM, Sassaki KT, Cannon ML, Stock SR, Xiao X, et al. Quantitative analysis of mineral content in enamel using synchrotron microtomography and microhardness analysis</title>. Proc of SPIE 2006;6318:631824-1-631824-5.^,³⁷37. Lee HS, Berg JH, Garcia-Godoy F, Jang KT. Long-term evaluation of the remineralization of interproximal caries-like lesions adjacent to glass-ionomer restorations: A micro-ct study. Am J Dent 2008;21:129-132.. Another aspect to be emphasized is the formation of a TiO₂ layer on the surface of the enamel treated with TiF₄⁶6 .Buyukyilmaz T, Ogaard B, Rolla G. The resistance of titanium tetrafluoride-treated human enamel to strong hydrochloric acid. Eur J Oral Sci1997;105:473-477.^,⁷7 .Castro RA, Chevitarese O, Souza IPR. Action of titanium tetrafluoride on occlusal human enamel in situ. Fluoride 2003;36:252-262.. After a topical application, this coating is formed by the reaction between titanium and the oxygen groups derived from water or phosphate-bound oxygen ³⁸38. Tveit AB, Klinge B, Totdal B, Selvig KA. Long-term retention of TiF4 and SnF2 after topical application to dentin in dogs. Scand J Dent Res 1988;96:536-540. and acts like a diffusion barrier. This barrier may block the transport of calcium and phosphate, protecting the subsurface enamel from further demineralization ³⁵35. Exterkate RA, ten Cate JM. Effects of a new titanium fluoride derivative on enamel de- and remineralization. Eur J Oral Sci 2007;115:143-147.. The acid-resistant barrier of TiO₂ was observed on the surface of the blocks treated with TiF₄ and TiF₄ + hydroxypropyl-b-cyclodextrin (Fig. 2). One can speculate that the TiO₂ glaze-layer added by a sustained release of fluoride from the 1% TiF₄ + hydroxypropyl-b-cyclodextrin solutions hindered enamel dissolution. The sustained release of fluoride is related to the 1-min application from the nanocomplexed fluoride solutions in contrast with the plain TiF₄ solution in which this behavior is not expected.

The adsorption capacity and substantivity are directly related to mineral loss control, especially for TiF₄-solutions. Previous study had already demonstrated that one-minute application of 4% TiF₄ solution showed an irregular TiO₂ layer on human enamel blocks surface ³⁹39. Alcântara PCC, Alexandria AK, Souza IPR, Maia LC. Energy dispersive x-ray spectroscopy evaluation of demineralized human enamel after titanium tetrafluoride application. J Clin Pediatr Dent 2015;39:124-127.. This coating was not uniform in quantity and was found in distinct areas on the same tooth ³⁹39. Alcântara PCC, Alexandria AK, Souza IPR, Maia LC. Energy dispersive x-ray spectroscopy evaluation of demineralized human enamel after titanium tetrafluoride application. J Clin Pediatr Dent 2015;39:124-127.^,⁴⁰40. Chevitarese AB, Chevitarese O, Chevitarese LM, Dutra PB. Titanium penetration in human enamel after TiF4 application. J Clin Pediatr Dent2004;28:253-256.. One may suppose that this specific glaze was not uninterrupted enough to protect subsurface demineralization. SEM findings from the present study show that such properties were more pronounced in the enamel blocks treated with hydroxypropyl-b-cyclodextrin + 1% TiF₄ after 12 h of complexation. Future studies are necessary to better understand this phenomenon in this nanotechnology (cyclodextrin-based-products) context.

This is the first pH-cycling study which evaluated the potential of hydroxypropyl-b-cyclodextrin + TiF₄ on reducing bovine enamel dissolution under cariogenic challenge in vitro. Cytotoxic assessment revealed that these solutions did not induce critical cytotoxic effects at the experimental time points against L929 cells. Moreover, until the period of 30 min, all products showed cell viability above 70% indicating a non-cytotoxic effect ¹³13. Vieira TI, Câmara JVF, Cardoso JG, Alexandria AK, Pintor AVB, Villaça JC, et al. Cytotoxicity of novel fluoride solutions and their influence on mineral loss from enamel exposed to a Streptococcus mutans biofilm. Arch Oral Biol2018;91:57-62.. Future studies should be carried out to evaluate its performance in in situ conditions and to observe if the fluoride delivery from the solutions with cyclodextrins employed here demonstrates the same performance throughout time.

Although testing the acid value of the products was not the objective of the study, the pH of the products was evaluated and it was verified that both the TiF₄ and the nanocomplex solutions presented a pH lower than 2.0. The association of TiF₄ to the nanocarriers used here promoted a very small reduction of the acidity.

A limitation is the lack of free oral calcium which is expected to be found in saliva and biofilm fluid that could interact and form CaF₂. In the present work, only calcium extracted from enamel was available in order to simulate a professional fluoride application. This may not represent what happens in in vivo condition in which both salivary/biofilm fluid calcium and calcium extracted from enamel might be available for CaF₂ establishment ⁴¹41. Vogel GL. Oral fluoride reservoirs and the prevention of dental caries. Monogr Oral Sci 2011;22:146-157..

Within the limitations of the present study, the current nanocompound represents a valid nanosystem for the prevention of dental caries especially in high risk patients, patients with impaired oral hygiene, individuals with exposed root surfaces and patients with reduced salivary flow.

A single application of hydroxypropyl-b-cyclodextrin + 1% TiF₄ with 12 h of complexation was significantly able to reduce the enamel surface demineralization while internal enamel demineralization was similar between the groups under cariogenic challenge.

Acknowledgements

This study was conducted during the master´s degree of the first author. This study was supported by Fundação de Amparo à Pesquisa do Estado do Rio de Janeiro (FAPERJ - grant E-26/202.924/2017) and National Council for Scientific and Technological Development (CNPq - grant 303535/2016-4). This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil - (CAPES) - Finance code 001. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. The authors declare that they have no conflicting interests.

References

¹
Kassebaum NJ, Smith AGC, Bernabé E, Fleming TD, Reynolds AE, Vos T, et al. Global, Regional, and National Prevalence, Incidence, and Disability-Adjusted Life Years for Oral Conditions for 195 Countries, 1990-2015: A Systematic Analysis for the Global Burden of Diseases, Injuries, and Risk Factors. J Dent Res 2017;96: 380-387.
²
Kidd EA, Fejerskov O. What constitutes dental caries? Histopathology of carious enamel and dentin related to the action of cariogenic biofilms. J Dent Res 2004;83:C35-38.
³
Paes Leme AF, Koo H, Bellato CM, Bedi G, Cury JA. The role of sucrose in cariogenic dental biofilm formation--new insight. J Dent Res2006;85:878-887.
⁴
Tenuta LM, Cury JA. Fluoride: Its role in dentistry. Braz Oral Res 2010;1:9-17.
⁵
Tenuta LM, Zamataro CB, Del Bel Cury AA, Tabchoury CP, Cury JA. Mechanism of fluoride dentifrice effect on enamel demineralization. Caries Res 2009;43:278-285.
⁶
Buyukyilmaz T, Ogaard B, Rolla G. The resistance of titanium tetrafluoride-treated human enamel to strong hydrochloric acid. Eur J Oral Sci1997;105:473-477.
⁷
Castro RA, Chevitarese O, Souza IPR. Action of titanium tetrafluoride on occlusal human enamel in situ. Fluoride 2003;36:252-262.
⁸
Comar LP, Wiegand A, Moron BM, Rios D, Buzalaf MA, Buchalla W, et al. In situ effect of sodium fluoride or titanium tetrafluoride varnish and solution on carious demineralization of enamel. Eur J Oral Sci 2012;120:342-348.
⁹
Reed AJ, Bibby BG. Preliminary report on effect of topical applications of titanium tetrafluoride on dental caries. J Dent Res1976;55:357-358.
¹⁰
Buslaev YA, Dyer DS, Ragsdale RO. Hydrolysis of titanium tetrafluoride. Inorg Chem 1967;6:2208-2212.
¹¹
Wahengbam P, Tikku AP, Lee WB. Role of titanium tetrafluoride (tif(4)) in conservative dentistry: A systematic review. J Conserv Dent 2011;14:98-102.
¹²
Nassur C, Alexandria AK, Pomarico L, de Sousa VP, Cabral LM, Maia LC. Characterization of a new TiF(₄) and beta-cyclodextrin inclusion complex and its in vitro evaluation on inhibiting enamel demineralization. Arch Oral Biol2013;58:239-247.
¹³
Vieira TI, Câmara JVF, Cardoso JG, Alexandria AK, Pintor AVB, Villaça JC, et al. Cytotoxicity of novel fluoride solutions and their influence on mineral loss from enamel exposed to a Streptococcus mutans biofilm. Arch Oral Biol2018;91:57-62.
¹⁴
Aree T, Chaichit N. Crystal structure of beta-cyclodextrin-benzoic acid inclusion complex. Carbohydr Res2003;338:439-446.
¹⁵
Rajewski RA, Stella VJ. Pharmaceutical applications of cyclodextrins. 2. In vivo drug delivery. J Pharm Sci 1996;85:1142-1169.
¹⁶
Szente L, Szejtli J. Highly soluble cyclodextrin derivatives: chemistry, properties, and trends in development. Adv Drug Deliv Rev 1999;36:17-28.
¹⁷
Vieira TI, Nassur C, Alexandria AK, Pomarico L, Sousa VP, Cabral LM, et al. Effect of the inclusion nanocomplex formed of titanium tetrafluoride and b-cyclodextrin on enamel remineralization. J Pharm Bioallied Sci 2017:9;201-207.
¹⁸
Vieira TI, Alexandria AK, Menezes JCV, Amaral LH, Santos TMP, Neves AA, et al. Characterization and effect of nanocomplexed fluoride solutions on the inhibition of enamel demineralization created by a multispecies cariogenic biofilm model. Clin Oral Investig 2020 [Epub Ahead of Print. Doi: 10.1007/s00784-020-03261-0].
» https://doi.org/10.1007/s00784-020-03261-0
¹⁹
Queiroz CS, Hara AT, Paes Leme AF, Cury JA. pH-cycling models to evaluate the effect of low fluoride dentifrice on enamel de- and remineralization. Braz Dent J 2008;19:21-27.
²⁰
Featherstone JD, ten Cate JM, Shariati M, Arends J. Comparison of artificial caries-like lesions by quantitative microradiography and microhardness profiles. Caries Res 1983;17:385-391.
²¹
Schindelin J, Arganda-Carreras I, Frise E, Kaynig V, Longair M, Pietzsch T, Preibisch S, et al. Fiji: An open-source platform for biological-image analysis. Nat Methods 2012;9:676-682.
²²
Delbem ACB, Vieira AEM, Sassaki KT, Cannon ML, Stock SR, Xiao X, et al. Quantitative analysis of mineral content in enamel using synchrotron microtomography and microhardness analysis</title>. Proc of SPIE 2006;6318:631824-1-631824-5.
²³
Field A. Discovering Statistics Using SPSS. London: SAGE; 2009.
²⁴
Dean A, Voss D. Design and Analysis of Experiments. New York: Springer; 1999.
²⁵
Greenland S, Senn SJ, Rothman KJ, Carlin JB, Poole C, Goodman SN, et al. Statistical tests, P values, confidence intervals, and power: a guide to misinterpretations. Eur J Epidemiol 2016;31:337-350.
²⁶
Amaechi BT. Protocols to Study Dental Caries In Vitro: pH Cycling Models. Methods Mol Biol 2019;1922:379-392.
²⁷
Ten Cate JM. In vitro studies on the effects of fluoride on de- and remineralization. J Dent Res1990;614-9:634-6.
²⁸
White DJ. The comparative sensitivity of intra-oral, in vitro, and animal models in the 'profile' evaluation of topical fluorides. J Dent Res 1992;71:884-94.
²⁹
Tveit AB, Tötdal B, Klinge B, Nilvéus R, Selvig KA. Fluoride uptake by dentin surfaces following topical application of TiF₄, NaF and fluoride varnishes in vivo. Caries Res 1985;19:240-7.
³⁰
Tveit AB, Hals E, Isrenn R, Tøtdal B. Highly acid SnF₂ and TiF₄ solutions. Effect on and chemical reaction with root dentin in vitro. Caries Res 1983;17:412-8.
³¹
Arends J, Christoffersen J. Nature and role of loosely bound fluoride in dental caries. J Dent Res 1990;601-5:634-6.
³²
Tenuta LM, Cerezetti RV, Del Bel Cury AA, Tabchoury CP, Cury JA. Fluoride release from CaF₂ and enamel demineralization. J Dent Res 2008;87:1032-6.
³³
Abbatepaulo GL, Gangana TMMC, Martinez EF, Turssi CP, França FMG, Amaral FLB, et al. TiF₄ Incorporated into a self-etching primer in different concentrations: antimicrobial properties and effects on demineralisation inhibition around the restoration/enamel-dentin interface. Oral Health Prev Dent 2019;17:57-67.
³⁴
Cal K, Centkowska K. Use of cyclodextrins in topical formulations: Practical aspects. Eur J Pharm Biopharm 2008;68:467-478.
³⁵
Exterkate RA, ten Cate JM. Effects of a new titanium fluoride derivative on enamel de- and remineralization. Eur J Oral Sci 2007;115:143-147.
³⁶
Zhang L, Liu M, Lu C, Ren D, Fan G, Liu C, et al. The hydroxypropyl-b-cyclodextrin complexation of toltrazuril for enhancing bioavailability. Drug Des Devel Ther 2018;12:583-589.
³⁷
Lee HS, Berg JH, Garcia-Godoy F, Jang KT. Long-term evaluation of the remineralization of interproximal caries-like lesions adjacent to glass-ionomer restorations: A micro-ct study. Am J Dent 2008;21:129-132.
³⁸
Tveit AB, Klinge B, Totdal B, Selvig KA. Long-term retention of TiF₄ and SnF₂ after topical application to dentin in dogs. Scand J Dent Res 1988;96:536-540.
³⁹
Alcântara PCC, Alexandria AK, Souza IPR, Maia LC. Energy dispersive x-ray spectroscopy evaluation of demineralized human enamel after titanium tetrafluoride application. J Clin Pediatr Dent 2015;39:124-127.
⁴⁰
Chevitarese AB, Chevitarese O, Chevitarese LM, Dutra PB. Titanium penetration in human enamel after TiF₄ application. J Clin Pediatr Dent2004;28:253-256.
⁴¹
Vogel GL. Oral fluoride reservoirs and the prevention of dental caries. Monogr Oral Sci 2011;22:146-157.

Publication Dates

Publication in this collection
04 Sept 2020
Date of issue
Jul-Aug 2020

History

Received
27 Sept 2019
Accepted
22 Apr 2020

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

[1] ¹
Kassebaum NJ, Smith AGC, Bernabé E, Fleming TD, Reynolds AE, Vos T, et al. Global, Regional, and National Prevalence, Incidence, and Disability-Adjusted Life Years for Oral Conditions for 195 Countries, 1990-2015: A Systematic Analysis for the Global Burden of Diseases, Injuries, and Risk Factors. J Dent Res 2017;96: 380-387.

[2] ²
Kidd EA, Fejerskov O. What constitutes dental caries? Histopathology of carious enamel and dentin related to the action of cariogenic biofilms. J Dent Res 2004;83:C35-38.

[3] ³
Paes Leme AF, Koo H, Bellato CM, Bedi G, Cury JA. The role of sucrose in cariogenic dental biofilm formation--new insight. J Dent Res2006;85:878-887.

[4] ⁴
Tenuta LM, Cury JA. Fluoride: Its role in dentistry. Braz Oral Res 2010;1:9-17.

[5] ⁵
Tenuta LM, Zamataro CB, Del Bel Cury AA, Tabchoury CP, Cury JA. Mechanism of fluoride dentifrice effect on enamel demineralization. Caries Res 2009;43:278-285.

[6] ⁶
Buyukyilmaz T, Ogaard B, Rolla G. The resistance of titanium tetrafluoride-treated human enamel to strong hydrochloric acid. Eur J Oral Sci1997;105:473-477.

[7] ⁷
Castro RA, Chevitarese O, Souza IPR. Action of titanium tetrafluoride on occlusal human enamel in situ. Fluoride 2003;36:252-262.

[8] ⁸
Comar LP, Wiegand A, Moron BM, Rios D, Buzalaf MA, Buchalla W, et al. In situ effect of sodium fluoride or titanium tetrafluoride varnish and solution on carious demineralization of enamel. Eur J Oral Sci 2012;120:342-348.

[9] ⁹
Reed AJ, Bibby BG. Preliminary report on effect of topical applications of titanium tetrafluoride on dental caries. J Dent Res1976;55:357-358.

[10] ¹⁰
Buslaev YA, Dyer DS, Ragsdale RO. Hydrolysis of titanium tetrafluoride. Inorg Chem 1967;6:2208-2212.

[11] ¹¹
Wahengbam P, Tikku AP, Lee WB. Role of titanium tetrafluoride (tif(4)) in conservative dentistry: A systematic review. J Conserv Dent 2011;14:98-102.

[12] ¹²
Nassur C, Alexandria AK, Pomarico L, de Sousa VP, Cabral LM, Maia LC. Characterization of a new TiF(₄) and beta-cyclodextrin inclusion complex and its in vitro evaluation on inhibiting enamel demineralization. Arch Oral Biol2013;58:239-247.

[13] ¹³
Vieira TI, Câmara JVF, Cardoso JG, Alexandria AK, Pintor AVB, Villaça JC, et al. Cytotoxicity of novel fluoride solutions and their influence on mineral loss from enamel exposed to a Streptococcus mutans biofilm. Arch Oral Biol2018;91:57-62.

[14] ¹⁴
Aree T, Chaichit N. Crystal structure of beta-cyclodextrin-benzoic acid inclusion complex. Carbohydr Res2003;338:439-446.

[15] ¹⁵
Rajewski RA, Stella VJ. Pharmaceutical applications of cyclodextrins. 2. In vivo drug delivery. J Pharm Sci 1996;85:1142-1169.

[16] ¹⁶
Szente L, Szejtli J. Highly soluble cyclodextrin derivatives: chemistry, properties, and trends in development. Adv Drug Deliv Rev 1999;36:17-28.

[17] ¹⁷
Vieira TI, Nassur C, Alexandria AK, Pomarico L, Sousa VP, Cabral LM, et al. Effect of the inclusion nanocomplex formed of titanium tetrafluoride and b-cyclodextrin on enamel remineralization. J Pharm Bioallied Sci 2017:9;201-207.

[18] ¹⁸
Vieira TI, Alexandria AK, Menezes JCV, Amaral LH, Santos TMP, Neves AA, et al. Characterization and effect of nanocomplexed fluoride solutions on the inhibition of enamel demineralization created by a multispecies cariogenic biofilm model. Clin Oral Investig 2020 [Epub Ahead of Print. Doi: 10.1007/s00784-020-03261-0].
» https://doi.org/10.1007/s00784-020-03261-0

[19] ¹⁹
Queiroz CS, Hara AT, Paes Leme AF, Cury JA. pH-cycling models to evaluate the effect of low fluoride dentifrice on enamel de- and remineralization. Braz Dent J 2008;19:21-27.

[20] ²⁰
Featherstone JD, ten Cate JM, Shariati M, Arends J. Comparison of artificial caries-like lesions by quantitative microradiography and microhardness profiles. Caries Res 1983;17:385-391.

[21] ²¹
Schindelin J, Arganda-Carreras I, Frise E, Kaynig V, Longair M, Pietzsch T, Preibisch S, et al. Fiji: An open-source platform for biological-image analysis. Nat Methods 2012;9:676-682.

[22] ²²
Delbem ACB, Vieira AEM, Sassaki KT, Cannon ML, Stock SR, Xiao X, et al. Quantitative analysis of mineral content in enamel using synchrotron microtomography and microhardness analysis</title>. Proc of SPIE 2006;6318:631824-1-631824-5.

[23] ²³
Field A. Discovering Statistics Using SPSS. London: SAGE; 2009.

[24] ²⁴
Dean A, Voss D. Design and Analysis of Experiments. New York: Springer; 1999.

[25] ²⁵
Greenland S, Senn SJ, Rothman KJ, Carlin JB, Poole C, Goodman SN, et al. Statistical tests, P values, confidence intervals, and power: a guide to misinterpretations. Eur J Epidemiol 2016;31:337-350.

[26] ²⁶
Amaechi BT. Protocols to Study Dental Caries In Vitro: pH Cycling Models. Methods Mol Biol 2019;1922:379-392.

[27] ²⁷
Ten Cate JM. In vitro studies on the effects of fluoride on de- and remineralization. J Dent Res1990;614-9:634-6.

[28] ²⁸
White DJ. The comparative sensitivity of intra-oral, in vitro, and animal models in the 'profile' evaluation of topical fluorides. J Dent Res 1992;71:884-94.

[29] ²⁹
Tveit AB, Tötdal B, Klinge B, Nilvéus R, Selvig KA. Fluoride uptake by dentin surfaces following topical application of TiF₄, NaF and fluoride varnishes in vivo. Caries Res 1985;19:240-7.

[30] ³⁰
Tveit AB, Hals E, Isrenn R, Tøtdal B. Highly acid SnF₂ and TiF₄ solutions. Effect on and chemical reaction with root dentin in vitro. Caries Res 1983;17:412-8.

[31] ³¹
Arends J, Christoffersen J. Nature and role of loosely bound fluoride in dental caries. J Dent Res 1990;601-5:634-6.

[32] ³²
Tenuta LM, Cerezetti RV, Del Bel Cury AA, Tabchoury CP, Cury JA. Fluoride release from CaF₂ and enamel demineralization. J Dent Res 2008;87:1032-6.

[33] ³³
Abbatepaulo GL, Gangana TMMC, Martinez EF, Turssi CP, França FMG, Amaral FLB, et al. TiF₄ Incorporated into a self-etching primer in different concentrations: antimicrobial properties and effects on demineralisation inhibition around the restoration/enamel-dentin interface. Oral Health Prev Dent 2019;17:57-67.

[34] ³⁴
Cal K, Centkowska K. Use of cyclodextrins in topical formulations: Practical aspects. Eur J Pharm Biopharm 2008;68:467-478.

[35] ³⁵
Exterkate RA, ten Cate JM. Effects of a new titanium fluoride derivative on enamel de- and remineralization. Eur J Oral Sci 2007;115:143-147.

[36] ³⁶
Zhang L, Liu M, Lu C, Ren D, Fan G, Liu C, et al. The hydroxypropyl-b-cyclodextrin complexation of toltrazuril for enhancing bioavailability. Drug Des Devel Ther 2018;12:583-589.

[37] ³⁷
Lee HS, Berg JH, Garcia-Godoy F, Jang KT. Long-term evaluation of the remineralization of interproximal caries-like lesions adjacent to glass-ionomer restorations: A micro-ct study. Am J Dent 2008;21:129-132.

[38] ³⁸
Tveit AB, Klinge B, Totdal B, Selvig KA. Long-term retention of TiF₄ and SnF₂ after topical application to dentin in dogs. Scand J Dent Res 1988;96:536-540.

[39] ³⁹
Alcântara PCC, Alexandria AK, Souza IPR, Maia LC. Energy dispersive x-ray spectroscopy evaluation of demineralized human enamel after titanium tetrafluoride application. J Clin Pediatr Dent 2015;39:124-127.

[40] ⁴⁰
Chevitarese AB, Chevitarese O, Chevitarese LM, Dutra PB. Titanium penetration in human enamel after TiF₄ application. J Clin Pediatr Dent2004;28:253-256.

[41] ⁴¹
Vogel GL. Oral fluoride reservoirs and the prevention of dental caries. Monogr Oral Sci 2011;22:146-157.

		% SML (Mean ±SD)	ΔZ microhardness (Me (Min;Max/interquatile range))	ΔZ micro-CT (Me (Min;Max/interquatile range))
Control groups	Mili-Q water	29.97±11.54	790.20(-8.00;1534.60/342.13)	3172.75(3065.00;3241.00/152.88)
	Hydroxypropyl-b-cyclodextrin	32.40±5.64	823.00(319.80;1628.00/718.13)	4702.50(4566.50;4801.50/206.75)
	1% TiF₄	26.45±6.73	533.10(214.40;1192.10/417.95)	4449.00(4263.50;4714.00/424.63)
Experimental groups	Hydroxypropyl-b-cyclodextrin + 1% TiF₄ 12 h	16.49±5.16	414.95(268.30;1244.90/500.83)	4662.00(4636.50;4791.50/128.00)
Experimental groups	Hydroxypropyl-b-cyclodextrin + 1% TiF₄ 72 h	27.64±10.90	447.20(-244.10;1112.30/412.05)	4562.50(4429.50;4709.50/272.25)

Groups	p value	Hedge’s G	Lower 95% CI	Upper 95% CI	Power
Mili-Q water X Hydroxypropyl-b-cyclodextrin	0.522	0.267	-0.606	1.141	0.080
Mili-Q water X 1% TiF₄	0.694	0.372	-0.481	1.226	0.129
Mili-Q water X Hydroxypropyl-b-cyclodextrin+ 1% TiF4 12 h	0.002	1.508	0.521	2.494	0.930
Mili-Q water X Hydroxypropyl-b-cyclodextrin+ 1% TiF₄ 72 h	0.794	0.207	-0.641	1.056	0.065
Hydroxypropyl-b-cyclodextrinX 1% TiF₄	0.507	0.958	0.064	1.852	0.606
Hydroxypropyl-b-cyclodextrinX Hydroxypropyl-b-cyclodextrin+ 1% TiF₄ 12 h	3.17 x 10^-7	2.943	1.721	4.165	0.999
Hydroxypropyl-b-cyclodextrinX Hydroxypropyl-b-cyclodextrin+ 1% TiF4 72 h	0.197	0.548	-0.333	1.430	0.224
1% TiF₄ X Hydroxypropyl-b-cyclodextrin+ 1% TiF₄ 12 h	0.0005	1.660	0.679	2.642	0.970
1% TiF₄ X Hydroxypropyl-b-cyclodextrin+ 1% TiF₄ 72 h	0.894	0.131	-0.716	0.978	0.046
Hydroxypropyl-b-cyclodextrin+ 1% TiF₄ 12 h X Hydroxypropyl-b-cyclodextrin+ 1% TiF₄ 72 h	0.005	1.307	0.348	2.266	0.849

Groups	p value	Hedge’s G	Power
Mili-Q water X Hydroxypropyl-b-cyclodextrin	0.772	0.091	0.047
Mili-Q water X 1% TiF₄	0.043	1.081	0.524
Mili-Q water X Hydroxypropyl-b-cyclodextrin+ 1% TiF4 12 h	0.037	1.649	0.547
Mili-Q water X Hydroxypropyl-b-cyclodextrin+ 1% TiF₄ 72 h	0.073	1.330	0.432
Hydroxypropyl-b-cyclodextrinX 1% TiF₄	0.056	0.771	0.478
Hydroxypropyl-b-cyclodextrinX Hydroxypropyl-b-cyclodextrin+ 1% TiF₄ 12 h	0.009	1.104	0.738
Hydroxypropyl-b-cyclodextrinX Hydroxypropyl-b-cyclodextrin+ 1% TiF4 72 h	0.094	0.966	0.387
1% TiF₄ X Hydroxypropyl-b-cyclodextrin+ 1% TiF₄ 12 h	0.644	0.463	0.067
1% TiF₄ X Hydroxypropyl-b-cyclodextrin+ 1% TiF₄ 72 h	0.908	0.304	0.032
Hydroxypropyl-b-cyclodextrin+ 1% TiF₄ 12 h X Hydroxypropyl-b-cyclodextrin+ 1% TiF₄ 72 h	0.686	0.117	0.059

	Mineral content (weight %)
	C	O	Na	Mg	Al	P	Cl	K	Ca	Ti
Mili-Q water	26.95	25.61	0.37	-	0.24	15.32	0.34	-	31.19	-
1% Hydroxypropyl-b-cyclodextrin	34.20	23.48	0.44	-	-	13.63	0.30	-	27.94	-
1% TiF₄	24.08	28.46	-	-	0.16	15.42	0.47	-	30.98	0.43
Hydroxypropyl-β-cyclodextrin: 1% TiF₄ 12 h	31.42	25.38	0.49	-	-	13.85	0.33	-	28.26	0.28
Hydroxypropyl-β-cyclodextrin: 1% TiF₄ 7 2h	30.17	25.74	0.45	-	-	14.05	0.47	0.32	28.02	0.77

Brasil

Brasil

Cyclodextrin and TiF4 Nanocomplex on Enamel Demineralization

Abstract

Resumo

Introduction

Material and Methods

Preparation and Characterization of b-Cds and TiF 4 Nanocomplexes

Preparation of Bovine Enamel Blocks

Enamel Blocks Selection and Allocation

Enamel Surface Treatment and pH-Cycling Regimen

Surface Microhardness Determination

Internal Microhardness Determination

Micro-CT Analysis

Scanning Electron Microscopy (SEM) and Energy Dispersive X-Ray Spectrometry (EDX) Assessment

Data Analysis

Results

Discussion

Acknowledgements

References

Publication Dates

History

Cyclodextrin and TiF₄ Nanocomplex on Enamel Demineralization

Preparation and Characterization of b-Cds and TiF ₄ Nanocomplexes