The In Situ Effect of Titanium Tetrafluoride Gel on Erosion/Abrasion Progression in Human Dentin

Mantilla, Taís Fonseca; Turssi, Cecilia Pedroso; Ramos-Oliveira, Thayanne Monteiro; Silva, Camila Vieira da; Suzuki, Luis Cláudio; Freitas, Patricia Moreira de

doi:10.1590/0103-6440201601247

Abstract

Erosion incidence is increasing and its control is still a challenge in clinical practice. This study evaluated 4% TiF₄-gel effects on eroded human dentin subjected to in situ erosive/abrasive episodes. Seventy-two previously eroded dentin slabs (0.05 M citric acid, pH 2.3, 20 min) were allocated to 6 groups (n=12) according to the treatment to be performed during the in situ phase and number of erosive/abrasive cycles, as follows: 4% TiF₄-gel applied once (TiF₄1), twice (TiF₄2) or three times (TiF₄3) followed by 1, 2 and 3 erosive/abrasive cycles, respectively. Gel was applied before the beginning of the next cycle. Control groups were subjected to 1 (C1), 2 (C2) and 3 (C3) erosive/abrasive cycles only. A seventh group (n=12) comprised in vitro uneroded samples (UN) subjected to 3 erosive/abrasive cycles. Each cycle corresponded to 2 days of erosive (citric acid 0.5%, pH 2.6, 6x/day) and abrasive (electric toothbrush, 10 s/sample, 1 x/day) challenges. Samples were evaluated under profilometry and environmental scanning electron microscopy (ESEM). Atomic force microscopy images (AFM) were also made (n=3). Repeated measures 2-way ANOVA and Tukey test (p<0.001) showed that TiF₄2, which did not differ from TiF₄1 and TiF₄3, revealed a significant reduction in surface loss compared to all control groups. TiF₄1 and TiF₄3 showed no significant difference from C1, but both groups demonstrated significantly smaller surface loss than C2 and C3. ESEM and AFM micrographs suggested alterations on treated surfaces compared to samples from control groups, showing reduced diameters of dentinal tubules lumens. Therefore, TiF₄ was able to reduce the progression of erosive/abrasive lesions.

Key Words:
TiF₄; fluoride; tooth wear; scanning electron microscopy; atomic force microscopy.

Resumo

A incidência da erosão tem aumentado e o seu controle ainda é um desafio na prática clínica. Este estudo avaliou os efeitos do gel de TiF₄ a 4% sobre a dentina humana erodida submetida a episódios erosivos/abrasivos in situ. Setenta e dois fragmentos de dentina previamente erodida (ácido cítrico 0,05 M, pH 2,3, 20 min) foram distribuídas em 6 grupos (n=12) de acordo com o tratamento a ser realizado durante a fase in situ e o número de ciclos erosivos/abrasivos, como descrito a seguir: gel de TiF₄ a 4% aplicado uma (TiF₄1), duas (TiF₄2) ou três vezes (TiF₄3) seguido de 1, 2 e 3 ciclos erosivos/abrasivos, respectivamente. As aplicações dos géis foram realizadas antes do início do ciclo erosivo seguinte. Grupos controle foram submetidos a 1 (C1), 2 (C2) e 3 (C3) ciclos erosivos/abrasivos apenas. Um sétimo grupo (n=12) compreendia amostras sem erosão in vitro (UN) submetidas a 3 ciclos erosivos/abrasivos. Cada ciclo correspondia a 2 dias de desafios erosivos (ácido cítrico a 0,5%, pH 2,6, 6x/dia) e abrasivos (escova de dentes elétrica, 10 s/amostra, 1x/dia). As amostras foram avaliadas em perfilômetro e Microscopia Eletrônica de Varredura Ambiental (MEV). Imagens de microscopia de força atômica (AFM) também foram capturadas (n=3). ANOVA a 2-fatores para medidas repetidas e o teste de Tukey (p<0,001) demonstraram que TiF₄2, que não diferiu do TiF₄1 e TiF₄3, revelou redução significativa na perda de superfície quando comparado a todos os grupos controle. TiF₄1 e TiF₄3 não apresentaram diferença estatisticamente significativa em relação ao C1, mas ambos os grupos demonstraram perda de superfície significativamente menor que C2 e C3. Micrografias de MEV e AFM sugeriram alterações nas superfícies tratadas quando comparadas a amostras dos grupos controle, apresentando redução no diâmetro das luzes dos túbulos dentinários. Portanto, o TiF₄ foi capaz de reduzir a progressão das lesões erosivas/abrasivas.

Introduction

Dental erosion is a chemical process, characterized by chronic and pathological dissolution of dental hard tissues due to exposure to a variety of non-bacterial acids ¹1 Lussi, A; Schlueter N; Rakhmatullina E; Ganss, C. Dental erosion - an overview with emphasis on chemical and histopathological aspects. Caries Res 2011;45:2-12.. Preventive and control measures to interrupt the progression of the erosive lesion have been proposed and include the strategy of increasing the acid resistance of dental hard tissues, which is the potential role of fluoride products.

In fact, fluoride products commonly used for caries prevention, as sodium fluoride, amine fluoride and acidulated phosphate fluoride, have proven to be partially effective in controlling erosive lesions ²2 Vieira, A; Ruben, JL; Huysmans, MCDNJM. Effect of titanium tetrafluoride, amine fluoride and fluoride varnish on enamel erosion in vitro. Caries Res 2005;39:371-379.^,³3 Magalhães, AC; Dos Santos, MG; Comar, LP; Buzalaf, MA; Ganss, C; Schlueter, N. Effect of a single application of TiF4 varnish versus daily use of a low-concentrated TiF4/NaF solution on tooth erosion prevention in vitro. Caries Res 2016;50:462-470., as they promote the precipitation of minerals like calcium fluoride (CaF₂) on the eroded surface ⁴4 Wahengbam, P; Tikku, AP; Lee, WB. Role of titanium tetrafluoride (TiF4) in conservative dentistry: A systematic review. J Conserv Dent 2011;14:98-102.. They form a layer that acts as a physical barrier to the action of acids, apart from acting as a mineral reservoir, which under erosive challenge is able to release calcium and fluoride ⁵5 Wiegand, A; Magalhães, AC; Attin ,T. Is titanium tetrafluoride (TiF4) effective to prevent carious and erosive lesions? A review of the literature. Oral Health Prev Dent 2010;8:159-164..

Currently, fluoride compounds of polyvalent metal ions, especially titanium tetrafluoride (TiF₄), have been studied due to their unique interaction with the tooth structure, leading to the formation of an acid-resistant glaze-like layer capable of adhering strongly to the tooth surface ⁶6 Basting, RT; Leme, AA; Bridi, EC; Amaral, FL; França, FM; Turssi, CP; et al.. Nanomechanical properties, SEM and EDS microanalysis of dentin treated with 2.5% titanium tetrafluoride, before and after an erosive challenge. J Biomed Mater B Appl Biomater 2015;103:783-789.. Among the existing theories to explain its action, one is that titanium is capable of reacting with the oxygen atoms of the phosphate groups of the dental tissue, forming stable titanium oxides ⁷7 Tveit, AB; Klinge, B; Tötdal, 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. or organometallic complexes that can act as a diffusion barrier ⁸8 Mundorff, SA; Little, MF; Bibby, BG. Enamel dissolution: II. Action of titanium tetrafluoride. J Dent Res 1972;51:1567-1571..

In order to determine the most effective treatment for erosion control, there is need for more precise indication of the available fluoride products. TiF₄ has a peculiar mechanism of action and a significant potential in reducing erosion progression ³3 Magalhães, AC; Dos Santos, MG; Comar, LP; Buzalaf, MA; Ganss, C; Schlueter, N. Effect of a single application of TiF4 varnish versus daily use of a low-concentrated TiF4/NaF solution on tooth erosion prevention in vitro. Caries Res 2016;50:462-470., however, there is still no consensus on the ideal formulation for this fluoride’s clinical use ²2 Vieira, A; Ruben, JL; Huysmans, MCDNJM. Effect of titanium tetrafluoride, amine fluoride and fluoride varnish on enamel erosion in vitro. Caries Res 2005;39:371-379.^,⁹9 Wiegand, A; Magalhães, AC; Sener, B; Waldheim, E; Attin, T. TiF4 and NaF at pH 1.2 but not at pH 3.5 are able to reduce dentin erosion. Arch Oral Biol 2009;54:790-795..

The present study investigated the possible anti-erosive effects produced by 4% TiF₄ gel, under in situ conditions, with a simulated high incidence of erosive/abrasive episodes. In case of positive results regarding the control of erosion progression, it could give professionals an effective alternative for erosive lesions’ in-office treatment.

The hypothesis tested was that dentin treated with 4% TiF₄ gel - applied once, twice or three times - will be more resistant to recurrent erosive challenges than untreated dentin.

Material and Methods

Experimental design

The present two-phase-designed in situ study was conducted with 12 volunteers. The independent variables were “volunteer” and “treatment” at seven levels: three control groups subjected to 1 (C1), 2 (C2) and 3 (C3) erosive/abrasive cycles solely; an extra control group comprising in vitro uneroded samples (UN) subjected to 3 erosive/abrasive cycles and three experimental groups, in which 4% TiF₄ gel was applied once (TiF₄1), twice (TiF₄2) or three times (TiF₄3) followed by 1, 2 and 3 erosive/abrasive cycles, respectively. The dependent variable was surface loss, measured by profilometry (in µm). Furthermore, micrographs were obtained in Environmental Scanning Electron Microscope (ESEM) and Atomic Force Microscope (AFM) to observe the surface morphology produced by the tested treatments.

Sample Preparation

One hundred and thirty samples were obtained from cervical areas of 65 third molar roots, stored in chloramine-T solution (4 °C) for up to three months after extraction by a low-speed water-cooled diamond saw (ISOMET 1000; Buehler Ltd., Lake Bluff, IL, USA). Dentin slabs (3x3x1 mm) were polished with Al₂O₃ sandpaper (#600 and #1200), followed by 0.3 µm alumina (Alfa Micropolish; Buehler Ltd.) suspension. All slabs were examined in stereoscopic loupe (40x magnification) to check for possible defects on the dentin surface (visible cracks, enamel remaining, unpolished surfaces). Surface microhardness was tested (Microhardness tester HMV-2000; Shimadzu, Kyoto, Japan) to standardize the hardness of samples selected for the study. Three indentations were made per sample with a Knoop indenter (10 g for 10 s, 50 µm apart). Eleven samples presented outlier microhardness values and were discarded. After that, the remaining 119 samples were evaluated in optical profilometer (3D PROSCAN 2100; Scantron, Eagan, MN, USA) for determination of surface curvature. From them, the 84 samples with the smallest surface curvature were selected and included in the study (mean surface curvature = 0.27±0.18 µm and mean surface microhardness = 78.62±8.13).

All selected samples were sterilized with gamma radiation and randomly distributed in 7 groups (n=12). All samples had their surfaces protected by two strips of adhesive tape (UPVC Graphic Tape; Chartpak, Leeds, AL, USA) (1.0 mm width each), leaving a central window (3x1 mm) exposed and two lateral reference areas (3x1 mm on each side).

Erosive-like Lesions Formation

Before the surface treatment, samples from groups C1, C2, C3, TiF₄1, TiF₄2 and TiF₄3 were subjected to immersion in a 0.05 M citric acid (pH 2.3) solution (citric acid monohydrate; Sigma-Aldrich Brazil Ltd., São Paulo, SP, Brazil) ¹⁰10 Ganss, C; Lussi, A; Sommer, N; Klimek, J; Schlueter, N. Efficacy of fluoride compounds and stannous chloride as erosion inhibitors in dentine. Caries Res 2010;44:248-252., at room temperature and under constant stirring (20 min, 35 rpm).

At the end of the in vitro erosion process, surface profilometry was conducted (scan - 2 mm (X axis) x 1 mm (Y axis)), in order to confirm the homogeneity of the obtained lesions (mean = 3.92±0.35 µm). All samples were then examined under ESEM (Hitachi Analytical Microscope TM3000 Table Top; Hitachi, Tokyo, Japan) (1000x and 3000x magnifications), as further described.

Selection of Volunteers

G*Power 3.1.5 software was used for a priori calculation of the required sample size. Twelve volunteers were enrolled assuming a significance level of a=0.05, a desired power of a=0.85 and an anticipated large effect size between groups. This study was conducted in accordance with the principles established in Declaration of Helsinki and approved by the Ethics Committee of the Dental School of Universidade de São Paulo (Protocol no. 544.566). All volunteers (female, 20-35 years) selected to participate of the in situ phase were given informed, written consent. The following criteria for inclusion of the participants were considered: to have all teeth; to be in good oral health; to live in the urban area of São Paulo and present stimulated salivary flow >0.7 mL/min. The exclusion criteria were: those who presented any sort of systemic pathology; visible plaque, cavities, gingivitis or periodontal disease; orthodontic devices; gastroesophageal reflux disease; had regular use of tobacco and alcoholic beverages and/or were pregnant or breastfeeding.

Setting of Intraoral Devices

In both stages was performed permutation of samples in the niches, so that the sample’s position would not influence the results, since most of the volunteers were right-handed. Samples were placed bilaterally in mandibular intraoral devices. Devices were made of acrylic resin and contained two niches (4x4x2 mm) (Fig. 1). Surfaces of samples were set with a recess of 0.5 mm in relation to the limits of the niches, avoiding abrasion from contact with the mucosa.

Figure 1
In situ intraoral devices. Front (A) and side (B) views.

To prevent the influence of fluoride in the control samples, groups were separated in two phases as shown in Figure 2. During both phases of the study, samples were randomly placed.

Figure 2
Division of the groups during the in situ phases.

In situ Phase

Before the beginning of in situ stage and between the Control and Experimental phases of the study, was included a run-in period of 2 days and a wash-out of 5 days. In this period and through the entire in situ phase, all volunteers performed their dental hygiene without the in situ devices, with a fluoridated toothpaste (Colgate Maximum Protection Anti-Caries® 1,500 ppm F-; Colgate-Palmolive, Osasco, SP, Brazil), toothbrush and dental floss provided by the researcher.

Throughout in situ phase, the devices were inserted 2 h before the first erosive challenge to form the acquired pellicle. Then were performed the erosive challenges, which consisted on 6 ex vivo immersions a day (2 min each) with 1.5 h intervals between them, in 20 mL of 0.5% citric acid (pH 2.6) ¹¹11 Schlueter, N; Klimek, J; Ganss, C. Effect of a chitosan additive to a Sn2+-containing toothpaste on its anti-erosive/anti-abrasive efficacy - a controlled randomized in situ trial. Clin Oral Invest 2014;18:107-115.. As each cycle corresponded to 2 days of erosive/abrasive cycling, one cycle comprised 12 acid challenges. After each immersion, the excess acid was poured onto an absorbent paper and the device was reinserted in the mouth. Demineralizing solution was replaced at the beginning of each day and had its pH monitored. The devices were stored overnight and during meals in moistened gauze with distilled water in the refrigerator. After meals, drinks and oral hygiene, volunteers were instructed to wait 15 min for reinsertion of the device in the mouth.

Toothbrush abrasion was performed 60 min after the last erosive challenge of each day. Following the protocol proposed by Schlueter et al. ¹¹11 Schlueter, N; Klimek, J; Ganss, C. Effect of a chitosan additive to a Sn2+-containing toothpaste on its anti-erosive/anti-abrasive efficacy - a controlled randomized in situ trial. Clin Oral Invest 2014;18:107-115., volunteers used an electric toothbrush equipped with a pressure sensor, which is activated in 2.5 N (Oral B Professional Care 3000; Oral B, Schwalbacham Taunus, Germany). The brushing was always started on the occlusal surfaces of the volunteer’s own mandibular teeth for 15 s to produce a toothpaste (Colgate Maximum Protection Anti-Caries® 1,500 ppm F-, Colgate-Palmolive)/saliva slurry. After that, brushing was performed intraorally for 10 s on each sample, followed by rinsing with running water for 3 s and removal of the device ¹¹11 Schlueter, N; Klimek, J; Ganss, C. Effect of a chitosan additive to a Sn2+-containing toothpaste on its anti-erosive/anti-abrasive efficacy - a controlled randomized in situ trial. Clin Oral Invest 2014;18:107-115.. The device was then rinsed with water for 1 min to remove remnants of toothpaste, reinserted in the mouth and used for another 30 min.

TiF ₄ Application

During experimental phase, 4% TiF₄ gel applications were performed on the 1st, 3rd and 5th days of cycling (Table 1). Three samples (two in one side and one in the other) were positioned on each device in this phase. Before each application (3rd and 5th), one sample was removed in order to avoid the possible influence of other applications (presence of fluoride in the mouth) on this one and was not reinserted, because of the possible contamination of samples during analysis. So, on samples of TiF₄1 group, TiF₄ was applied once, on TiF₄2 samples, twice and on TiF₄3 samples, three times. As samples were removed, they were kept in relative humidity and stored at 4 ºC. In the control phase, in order to allow the comparison between phases, four samples were placed on each device (two in each side) and were removed before the beginning of the next erosive/abrasive cycle.

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Table 1
Steps followed during the experimental phase

For the fluoride treatment, samples were dried with absorbent paper and subjected to application of 4% TiF₄ gel (24,530 ppmF) ²2 Vieira, A; Ruben, JL; Huysmans, MCDNJM. Effect of titanium tetrafluoride, amine fluoride and fluoride varnish on enamel erosion in vitro. Caries Res 2005;39:371-379.. Fluoride was manipulated by the researcher addiing 0.4 g of titanium fluoride (IV) (Sigma-Aldrich Brazil Ltd.) in 10 mL of distilled water. Next, 1.0 g of carboxymethylcellulose (Sigma-Aldrich Brazil Ltd.) (pH 1.5) was added. In the predetermined times, 20 µL of TiF₄ were applied on each sample (active application, 4 min). Excess fluoride gel was removed with cotton and the dentin surface dried with absorbent paper.

Profilometric Analysis

Profilometric analysis was performed in an optical profilometer (3D PROSCAN 2100, Scantron). After removing the tape, the sensor of the equipment was positioned on the left top of each sample and moved 1 mm down and 0.5 mm right in order to start the scanning always at the same point. A central area of each sample [2 mm (X axis) x 1 mm (Y axis)] - corresponding to the treated area and reference surfaces on both sides- was scanned, thus obtaining the depth of the lesion (3-pt step height). Samples were kept at relative humidity until scanning time in order to prevent dentin dehydration. Immediately before analysis, the excess water was removed with an absorbent paper ¹²12 Magalhães, AC; Levy, FM; Rios, D; Buzalaf, MAR. Effect of a single application of TiF4 and NaF varnishes and solutions on dentin erosion in vitro. J Dent 2010;38:153-157.. All samples were analyzed in profilometer three times during the experiment: curvature analysis, standardization of erosive-like lesions formed in vitro and in situ post-treatment evaluation.

Environmental Scanning Electron Microscope (ESEM) Analysis

All samples were analyzed under ESEM (Hitachi Analytical Microscope TM3000 Table Top; Hitachi) in two experimental times, before and after in situ phase. Samples were fixed with cyanoacrylate-based adhesive on aluminium stubs and positioned as on profilometry, in order to perform the scanning always in the same area (1000´ and 3000´ magnifications).

Atomic Force Microscope (AFM) Analysis

Three samples from each experimental group were randomly selected and observed in AFM (Nanosurf AFM Flex; Nanosurf, Liestal, Switzerland). One sample at a time was placed under the mechanical silicon probe with high frequency and resonance to scan in tapping mode. A scan rate of 20 µm/s and a resolution of 256 x 256 pixels were used. For each sample, a three-dimensional image of 20 µm x 20 µm was obtained and allowed the observation of treated surfaces.

Statistical Analysis

The difference between surface losses measured after the in situ phase and the erosive-like-lesion was used as the outcome value for each specimen. Before data analysis, normality of distribution was verified with Shapiro-Wilk tests, which showed that data violated normal distribution. To fit normality, data were root-square transformed and two outliers identified in the Box-Plot were excluded. Transformed data were evaluated using a repeated-measures two-way analysis of variance (ANOVA), according to the general linear model, to examine the effects of the independent variables Treatment and Volunteers on surface loss (dependent variable). Post-hoc comparisons were performed using Tukey’s test. Significance level was set at 5% and statistical procedures were carried out using SPSS 20.0 (SPSS Inc., Chicago, IL, USA).

Results

Profilometry

In order to ensure the reliability of this study results, the statistical power was calculated (0.72) and considered satisfactory ¹³13 Keskin, B; Aktas, A. Statistical power analysis. The 7th International Days of Statistics and Economics, 2013;578-587.. Repeated-measures two-way ANOVA, performed with transformed data, showed that surface loss was significantly affected by the treatments (p<0.001). Tukey test demonstrated that the specimens from the TiF₄ 2 group (2 cycles), which did not differ from any of the other two TiF₄-treated groups, revealed significantly lower surface loss when compared to all the untreated control groups. TiF₄1 and TiF₄3 groups (1 and 3 applications, respectively) did not differ from C1 group, but both TiF₄4-treated groups presented significantly lower surface loss than that noticed for the remaining untreated control groups (C2 and C3). The highest change in surface loss was found in C3 and in the in vitro uneroded group (UN) (Table 2).

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Table 2
Mean values (standard deviation) of the original data, in µm, of surface loss of human dentin measured after the in vitro erosion, after the surface treatment and in situ erosion, followed by the corresponding difference (Surface loss after in situ stage minus erosive like-lesions)

Scanning Electron Microscopy

Figure 3 shows the pattern of surface morphology presented by the samples of the in vitro uneroded control (UN) group and C3, before and after the in situ phase. Prior to the erosive/abrasive cycling performed during the in situ phase, the UN group (Fig. 3A) had a flat surface with open and homogeneously distributed dentin tubules. Compared with UN, the C3 group, (Fig. 3B - before in situ phase), presented a more irregular surface pattern, with more open dentinal tubules. After the in situ phase and without being subjected to any additional treatment beyond the erosive/abrasive cycling, UN group (Fig. 3C) showed surface damage caused by erosive/abrasive challenges, although the tubular opening pattern shown before the in situ phase was maintained. However, samples from C3 group (Fig. 3D), which were removed from the oral cavity after the same amount of cycles that UN, showed a change in surface pattern with a lesser amount of exposed tubules.

Figure 3
Electromicrographs of the UN and C3 groups (equivalent amount of cycles) before (A and B, respectively) and after (C and D) respectively) the in situ stage. 3000× magnification.

Comparing the control groups (Figs. 4A, 4C and 4E) and experimental groups (Figs. 4B, 4D and 4F), it appears that the TiF₄, regardless of the amount of applications, has caused changes in the characteristics of treated surfaces, promoting an apparent reduction of the diameter of the tubule lumens, which became squashed (diamond shaped).

Figure 4
Electromicrographs of C1 (A), TiF41 (B), C2 (C), TiF42 (D), C3 (E) and TiF43 (F) groups after the in situ stage. 3000× magnification.

Atomic Force Microscopy

The applications of TiF₄ (Figs. 5B, 5D and 5F) modified the surface topography of the samples compared to all control groups (Figs. 5A, 5C, 5E and 5G) and, despite that tubules remained open, they appeared partially obliterated and in reduced amount. Furthermore, the rough appearance of the samples without treatment was decreased by TiF₄.

Figure 5
Photomicrographs obtained in AFM of C1 (A), TiF41 (B), C2 (C), TiF42 (D), C3 (E), TiF43 (F) and UN (G) groups after the in situ stage.

Discussion

This study was conducted following an in situ model, approaching at maximum the physicochemical conditions that occur in the oral cavity during the erosion, in which the presence of saliva ¹⁴14 Lussi, A; von Salis-Marincek, M; Ganss, C; Hellwig, E; Cheaib, Z; Jaeggi, T. Clinical study monitoring the pH on tooth surfaces in patients with and without erosion. Caries Res 2012;46:507-512. and acquired pellicle ¹⁵15 Moazzez, RV; Austin, RS; Rojas-Serrano, M; Carpenter, G; Cotroneo, E; Proctor, G et al. Comparison of the possible protective effect of the salivary pellicle of individuals with and without erosion. Caries Res 2014;48:57-62. are capable of modifying the formation of erosive lesions.

For assessment of the effects by surface treatments, the optical profilometer was used ¹⁶16 Borges, AB; Scaramucci, T; Lippert, F; Zero, DT; Hara, AT. Erosion protection by calcium lactate/sodium fluoride rinses under different salivary flows in vitro. Caries Res 2014;48:193-199., as it allows the measurement of surface loss without damaging the demineralized organic matrix that may remain after exposure to oral environment. The matrix, even though suggested to be removed prior to laboratorial analysis ¹⁷17 Ganss, C; Lussi, A; Scharmann, I; Hardt, M; Klimek, J; Schlueter, N. Comparison of calcium analysis, longitudinal microradiography and profilometry for the quantitative assessment of erosion in dentine. Caries Res 2009;43:422-429., may have been important to inhibit the progression of erosive lesions, especially when treated with TiF₄. Some authors reported that TiF₄ produces a glaze on the dentin surface ⁶6 Basting, RT; Leme, AA; Bridi, EC; Amaral, FL; França, FM; Turssi, CP; et al.. Nanomechanical properties, SEM and EDS microanalysis of dentin treated with 2.5% titanium tetrafluoride, before and after an erosive challenge. J Biomed Mater B Appl Biomater 2015;103:783-789.^,¹⁸18 Büyükyilmaz, T; Ogaard, B; Rolla, G. The resistance of titanium tetrafluoride-treated human enamel to strong hydrochloric acid. Eur J Oral Sci 1997;105:473-477. and one of the strongest actual theories to explain this formation considers the direct interaction between titanium and the organic matrix ⁸8 Mundorff, SA; Little, MF; Bibby, BG. Enamel dissolution: II. Action of titanium tetrafluoride. J Dent Res 1972;51:1567-1571..

The current study had its hypothesis accepted since the treatment with 4% TiF₄ gel showed positive results in the control of erosive progression compared to untreated dentin. TiF₄ treated groups led to lower dentin surface loss compared to controls with equivalent amounts of erosive/abrasive cycles. These results may indicate formation of a glaze layer on the tooth surface since the first moment of TiF₄ application ³3 Magalhães, AC; Dos Santos, MG; Comar, LP; Buzalaf, MA; Ganss, C; Schlueter, N. Effect of a single application of TiF4 varnish versus daily use of a low-concentrated TiF4/NaF solution on tooth erosion prevention in vitro. Caries Res 2016;50:462-470.. The glaze acts as a diffusion barrier and a reservoir of fluoride ions ⁵5 Wiegand, A; Magalhães, AC; Attin ,T. Is titanium tetrafluoride (TiF4) effective to prevent carious and erosive lesions? A review of the literature. Oral Health Prev Dent 2010;8:159-164., which may have been responsible for reducing the surface loss of the experimental groups compared to control groups, since it is able to slow down the dissolution of dental tissue facing acid challenges ⁵5 Wiegand, A; Magalhães, AC; Attin ,T. Is titanium tetrafluoride (TiF4) effective to prevent carious and erosive lesions? A review of the literature. Oral Health Prev Dent 2010;8:159-164.. Although it could not be identified on the electromicrographs, probably due to the employed technique, treated surfaces appeared to have different characteristics compared to the untreated ones. After TiF₄ application, samples presented a more regular surface and partially obliterated tubules, which confirms that the TiF₄ gel was able to alter the pattern of the eroded surfaces.

These favorable properties of TiF₄ are, however, dependent on the concentration, pH and presentation form used for application ²2 Vieira, A; Ruben, JL; Huysmans, MCDNJM. Effect of titanium tetrafluoride, amine fluoride and fluoride varnish on enamel erosion in vitro. Caries Res 2005;39:371-379.^,⁹9 Wiegand, A; Magalhães, AC; Sener, B; Waldheim, E; Attin, T. TiF4 and NaF at pH 1.2 but not at pH 3.5 are able to reduce dentin erosion. Arch Oral Biol 2009;54:790-795.. As there is still no consensus on the ideal formulation, the manipulated product used in this study was determined by the feasibility and probability of its clinical use in the future. It was decided to apply TiF₄ gel ²2 Vieira, A; Ruben, JL; Huysmans, MCDNJM. Effect of titanium tetrafluoride, amine fluoride and fluoride varnish on enamel erosion in vitro. Caries Res 2005;39:371-379., because it would be an easy form to be used by the dentist and a comfortable presentation for the patient, since it can be rapidly applied and has no unpleasant taste. The native pH was used because of the efficiency demonstrated in other studies concerning the precipitate formation and demineralization reduction ⁹9 Wiegand, A; Magalhães, AC; Sener, B; Waldheim, E; Attin, T. TiF4 and NaF at pH 1.2 but not at pH 3.5 are able to reduce dentin erosion. Arch Oral Biol 2009;54:790-795.. The concentration of 4% obtained better results compared to lower concentrations, possibly due to its capability of forming a thicker and tenacious glaze after treatment ¹⁸18 Büyükyilmaz, T; Ogaard, B; Rolla, G. The resistance of titanium tetrafluoride-treated human enamel to strong hydrochloric acid. Eur J Oral Sci 1997;105:473-477..

On the other hand, with the protocol applied in the present study, even after repeated applications, TiF₄ did not show cumulative effects. As its protection is basically produced by glaze formation, once all sites are complexed with Ti ions, it may not be possible to enhance it. Especially considering that the used gel had a high concentration of TiF₄ in its formulation, which may increase the amount of Ti available on the mouth since thefirst application.

Concerning its clinical application perspectives, this lack in dose-response could be positive, since it would not be necessary to reapply the product in a short time, minimizing its possible side effects. In this regard, it should be considered that TiF₄ hydrolyzation generates an acidic solution, because of H⁺ ions release, which may lead to a relative cytotoxicity when applied directly onto cells, compared to sodium fluoride application ¹⁹19 Sen, BH; Kazemi, RB; Spangberg, LSW. Morphologic effects on L929 fibroblasts of titanium tetrafluoride application. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 1998;86:341-346.. However, its cytotoxicity was not higher than the acidulated phosphate fluoride, which is commercially available ¹⁹19 Sen, BH; Kazemi, RB; Spangberg, LSW. Morphologic effects on L929 fibroblasts of titanium tetrafluoride application. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 1998;86:341-346.. Also, when TiF₄ (0.12%) was administered intragastrically to rats, they did not show signs of systemic toxicity ²⁰20 Shresta, BM. Effect of systemic titanium fluoride (TiF4) on fluoride uptake by developing rat enamel. Caries Res 1983;17:264-266.. In this sense, if applied topically, it may be considered safe to patients.

Although erosion could be reduced in the present study, treatment application was not able to interrupt completely its progression. Even considering the presence of a dense demineralized organic matrix layer, which provides partial protection against erosive challenges ²¹21 Hara, AT; Ando, M; Cury, JA; Serra, MC; González-Cabezas, C; Zero, DT. Influence of the organic matrix on root dentine erosion by citric acid. Caries Res 2005;39:134-138., its association with the glaze seems to have been insufficient to inhibit dentin loss. This may indicate that the demineralized dentin layer was not able to resist to the erosive cycling, possibly due to the intensity of the chosen cycling ¹¹11 Schlueter, N; Klimek, J; Ganss, C. Effect of a chitosan additive to a Sn2+-containing toothpaste on its anti-erosive/anti-abrasive efficacy - a controlled randomized in situ trial. Clin Oral Invest 2014;18:107-115.. Another possibility would be the degradation of the organic matrix by MMPs in dentin and saliva ²²22 Tjäderhane, L; Larjava, H; Uitto, VJ; Larmas, M; Salo, T. The activation and function of host matrix metalloproteinases in dentin matrix breakdown in caries lesions. J Dent Res 1998;77:1622-1629., activated by the fall and subsequent pH neutralization of the oral environment ²²22 Tjäderhane, L; Larjava, H; Uitto, VJ; Larmas, M; Salo, T. The activation and function of host matrix metalloproteinases in dentin matrix breakdown in caries lesions. J Dent Res 1998;77:1622-1629.. Regardless the reason, with the removal of the protection conferred by collagen fibres, the partially demineralized layer beneath it is exposed and becomes susceptible to the action of acids, giving rise to the progression of mineral loss ¹1 Lussi, A; Schlueter N; Rakhmatullina E; Ganss, C. Dental erosion - an overview with emphasis on chemical and histopathological aspects. Caries Res 2011;45:2-12..

This uncertainty on the maintenance of organic matrix after erosive/abrasive cycling performance may be considered a limitation of the present study, since the method chosen to evaluate surface loss is sensitive to the presence of any artifact on the measuring area. However, optical profilometry allows the performance of multiple scans on the same sample, which made possible evaluations after erosive-like lesions formation and at the in situ phase. Considering that results may be influenced by matrix shrinkage/compression - caused by dentin dehydration and abrasive procedure -, in order to minimize possible bias, there was a thorough moisture control during analysis ¹²12 Magalhães, AC; Levy, FM; Rios, D; Buzalaf, MAR. Effect of a single application of TiF4 and NaF varnishes and solutions on dentin erosion in vitro. J Dent 2010;38:153-157. and standardization of intraoral abrasion ¹¹11 Schlueter, N; Klimek, J; Ganss, C. Effect of a chitosan additive to a Sn2+-containing toothpaste on its anti-erosive/anti-abrasive efficacy - a controlled randomized in situ trial. Clin Oral Invest 2014;18:107-115..

Another limitation of the present study might be the absence of a positive control group. Recent literature presents unsatisfactory results for NaF when tested as an agent for erosion control ³3 Magalhães, AC; Dos Santos, MG; Comar, LP; Buzalaf, MA; Ganss, C; Schlueter, N. Effect of a single application of TiF4 varnish versus daily use of a low-concentrated TiF4/NaF solution on tooth erosion prevention in vitro. Caries Res 2016;50:462-470.. Carboximetilcellulose placebo gels have been also tested and presented little protection as well ²³23 Barbour, ME; Shellis, RP; Parker, DM; Allen, GC; Addy, M. An investigation of some food-approved polymers as agents to inhibit hydroxyapatite dissolution. Eur J Oral Sci 2005;113:457-461.. Nowadays, the gold-standard treatment for erosive lesions might be the Elmex Erosion ²⁴24 Rakhmatullina, E; Beyeler, B; Lussi, A. Inhibition of enamel erosion by stannous and fluoride containing rinsing solutions. Schweiz Monatsschr Zahnmed 2013;123:192-198.; however, as it is a solution with daily use recommendation, the comparison between results obtained would not be possible. Based on that, authors of the present study decided to compare TiF₄ effects only with untreated samples, since the inclusion of additional groups on the in situ phase would make it longer and demand extra cooperation from volunteers. Anyway, considering the positive results presented by TiF₄ applications, this fluoride may represent an alternative for in-office treatment for erosion and further studies aiming to develop more stable formulations, which could be stored for longer periods, are strongly advised. After that, clinical trials could confirm the results and provide the professionals the necessary support for safe clinical use.

Despite the potential effect of TiF₄, there is still the need for patient education on the modification of harmful eating habits ²⁵25 Zero, DT. Etiology of dental erosion - extrinsic factors. Eur J Oral Sci 1996;104:162-177. and other attitudes able to accelerate the progression of erosive lesions ²⁵25 Zero, DT. Etiology of dental erosion - extrinsic factors. Eur J Oral Sci 1996;104:162-177.. Therefore, in spite of the protection provided by the fluoride applied, the lesion progression may be delayed, but not inhibited. Under this assumption, the action of TiF₄ could present even more promising results if the erosive challenges have ceased, since the presence of acid did not inhibit the formation of the glaze. Clinically, with a reduction of risk factors ²⁵25 Zero, DT. Etiology of dental erosion - extrinsic factors. Eur J Oral Sci 1996;104:162-177., a re-precipitation of the mineral on the surface could be possible and the loss of dental substrate could be interrupted. However, in the absence of modification of the patient habits, there may be the need of new TiF₄ applications so its action is prolonged and may prevent the continuation of the erosive process.

Within the limitations of this study, 4% gel TiF₄ was able to reduce the progression of erosive/abrasive lesions in dentin in thefirst application and multiple applications reduced the evolution of the erosive process.

Acknowledgements

The authors would like to thank the financial support given by CAPES, FAPESP(Fundação de Amparo à Pesquisa do Estado de São Paulo) and CNPq (Conselho Nacional de Desenvolvimento Científico e Tecnológico). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. We also thank CNPEM for the technical assistance with the Atomic Force Microscopies.

References

¹
Lussi, A; Schlueter N; Rakhmatullina E; Ganss, C. Dental erosion - an overview with emphasis on chemical and histopathological aspects. Caries Res 2011;45:2-12.
²
Vieira, A; Ruben, JL; Huysmans, MCDNJM. Effect of titanium tetrafluoride, amine fluoride and fluoride varnish on enamel erosion in vitro. Caries Res 2005;39:371-379.
³
Magalhães, AC; Dos Santos, MG; Comar, LP; Buzalaf, MA; Ganss, C; Schlueter, N. Effect of a single application of TiF4 varnish versus daily use of a low-concentrated TiF4/NaF solution on tooth erosion prevention in vitro. Caries Res 2016;50:462-470.
⁴
Wahengbam, P; Tikku, AP; Lee, WB. Role of titanium tetrafluoride (TiF4) in conservative dentistry: A systematic review. J Conserv Dent 2011;14:98-102.
⁵
Wiegand, A; Magalhães, AC; Attin ,T. Is titanium tetrafluoride (TiF4) effective to prevent carious and erosive lesions? A review of the literature. Oral Health Prev Dent 2010;8:159-164.
⁶
Basting, RT; Leme, AA; Bridi, EC; Amaral, FL; França, FM; Turssi, CP; et al.. Nanomechanical properties, SEM and EDS microanalysis of dentin treated with 2.5% titanium tetrafluoride, before and after an erosive challenge. J Biomed Mater B Appl Biomater 2015;103:783-789.
⁷
Tveit, AB; Klinge, B; Tötdal, 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.
⁸
Mundorff, SA; Little, MF; Bibby, BG. Enamel dissolution: II. Action of titanium tetrafluoride. J Dent Res 1972;51:1567-1571.
⁹
Wiegand, A; Magalhães, AC; Sener, B; Waldheim, E; Attin, T. TiF4 and NaF at pH 1.2 but not at pH 3.5 are able to reduce dentin erosion. Arch Oral Biol 2009;54:790-795.
¹⁰
Ganss, C; Lussi, A; Sommer, N; Klimek, J; Schlueter, N. Efficacy of fluoride compounds and stannous chloride as erosion inhibitors in dentine. Caries Res 2010;44:248-252.
¹¹
Schlueter, N; Klimek, J; Ganss, C. Effect of a chitosan additive to a Sn2+-containing toothpaste on its anti-erosive/anti-abrasive efficacy - a controlled randomized in situ trial. Clin Oral Invest 2014;18:107-115.
¹²
Magalhães, AC; Levy, FM; Rios, D; Buzalaf, MAR. Effect of a single application of TiF4 and NaF varnishes and solutions on dentin erosion in vitro. J Dent 2010;38:153-157.
¹³
Keskin, B; Aktas, A. Statistical power analysis. The 7th International Days of Statistics and Economics, 2013;578-587.
¹⁴
Lussi, A; von Salis-Marincek, M; Ganss, C; Hellwig, E; Cheaib, Z; Jaeggi, T. Clinical study monitoring the pH on tooth surfaces in patients with and without erosion. Caries Res 2012;46:507-512.
¹⁵
Moazzez, RV; Austin, RS; Rojas-Serrano, M; Carpenter, G; Cotroneo, E; Proctor, G et al. Comparison of the possible protective effect of the salivary pellicle of individuals with and without erosion. Caries Res 2014;48:57-62.
¹⁶
Borges, AB; Scaramucci, T; Lippert, F; Zero, DT; Hara, AT. Erosion protection by calcium lactate/sodium fluoride rinses under different salivary flows in vitro. Caries Res 2014;48:193-199.
¹⁷
Ganss, C; Lussi, A; Scharmann, I; Hardt, M; Klimek, J; Schlueter, N. Comparison of calcium analysis, longitudinal microradiography and profilometry for the quantitative assessment of erosion in dentine. Caries Res 2009;43:422-429.
¹⁸
Büyükyilmaz, T; Ogaard, B; Rolla, G. The resistance of titanium tetrafluoride-treated human enamel to strong hydrochloric acid. Eur J Oral Sci 1997;105:473-477.
¹⁹
Sen, BH; Kazemi, RB; Spangberg, LSW. Morphologic effects on L929 fibroblasts of titanium tetrafluoride application. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 1998;86:341-346.
²⁰
Shresta, BM. Effect of systemic titanium fluoride (TiF4) on fluoride uptake by developing rat enamel. Caries Res 1983;17:264-266.
²¹
Hara, AT; Ando, M; Cury, JA; Serra, MC; González-Cabezas, C; Zero, DT. Influence of the organic matrix on root dentine erosion by citric acid. Caries Res 2005;39:134-138.
²²
Tjäderhane, L; Larjava, H; Uitto, VJ; Larmas, M; Salo, T. The activation and function of host matrix metalloproteinases in dentin matrix breakdown in caries lesions. J Dent Res 1998;77:1622-1629.
²³
Barbour, ME; Shellis, RP; Parker, DM; Allen, GC; Addy, M. An investigation of some food-approved polymers as agents to inhibit hydroxyapatite dissolution. Eur J Oral Sci 2005;113:457-461.
²⁴
Rakhmatullina, E; Beyeler, B; Lussi, A. Inhibition of enamel erosion by stannous and fluoride containing rinsing solutions. Schweiz Monatsschr Zahnmed 2013;123:192-198.
²⁵
Zero, DT. Etiology of dental erosion - extrinsic factors. Eur J Oral Sci 1996;104:162-177.

Publication Dates

Publication in this collection
May-Jun 2017

History

Received
16 Aug 2016
Accepted
14 Mar 2017

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

[1] ¹
Lussi, A; Schlueter N; Rakhmatullina E; Ganss, C. Dental erosion - an overview with emphasis on chemical and histopathological aspects. Caries Res 2011;45:2-12.

[2] ²
Vieira, A; Ruben, JL; Huysmans, MCDNJM. Effect of titanium tetrafluoride, amine fluoride and fluoride varnish on enamel erosion in vitro. Caries Res 2005;39:371-379.

[3] ³
Magalhães, AC; Dos Santos, MG; Comar, LP; Buzalaf, MA; Ganss, C; Schlueter, N. Effect of a single application of TiF4 varnish versus daily use of a low-concentrated TiF4/NaF solution on tooth erosion prevention in vitro. Caries Res 2016;50:462-470.

[4] ⁴
Wahengbam, P; Tikku, AP; Lee, WB. Role of titanium tetrafluoride (TiF4) in conservative dentistry: A systematic review. J Conserv Dent 2011;14:98-102.

[5] ⁵
Wiegand, A; Magalhães, AC; Attin ,T. Is titanium tetrafluoride (TiF4) effective to prevent carious and erosive lesions? A review of the literature. Oral Health Prev Dent 2010;8:159-164.

[6] ⁶
Basting, RT; Leme, AA; Bridi, EC; Amaral, FL; França, FM; Turssi, CP; et al.. Nanomechanical properties, SEM and EDS microanalysis of dentin treated with 2.5% titanium tetrafluoride, before and after an erosive challenge. J Biomed Mater B Appl Biomater 2015;103:783-789.

[7] ⁷
Tveit, AB; Klinge, B; Tötdal, 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.

[8] ⁸
Mundorff, SA; Little, MF; Bibby, BG. Enamel dissolution: II. Action of titanium tetrafluoride. J Dent Res 1972;51:1567-1571.

[9] ⁹
Wiegand, A; Magalhães, AC; Sener, B; Waldheim, E; Attin, T. TiF4 and NaF at pH 1.2 but not at pH 3.5 are able to reduce dentin erosion. Arch Oral Biol 2009;54:790-795.

[10] ¹⁰
Ganss, C; Lussi, A; Sommer, N; Klimek, J; Schlueter, N. Efficacy of fluoride compounds and stannous chloride as erosion inhibitors in dentine. Caries Res 2010;44:248-252.

[11] ¹¹
Schlueter, N; Klimek, J; Ganss, C. Effect of a chitosan additive to a Sn2+-containing toothpaste on its anti-erosive/anti-abrasive efficacy - a controlled randomized in situ trial. Clin Oral Invest 2014;18:107-115.

[12] ¹²
Magalhães, AC; Levy, FM; Rios, D; Buzalaf, MAR. Effect of a single application of TiF4 and NaF varnishes and solutions on dentin erosion in vitro. J Dent 2010;38:153-157.

[13] ¹³
Keskin, B; Aktas, A. Statistical power analysis. The 7th International Days of Statistics and Economics, 2013;578-587.

[14] ¹⁴
Lussi, A; von Salis-Marincek, M; Ganss, C; Hellwig, E; Cheaib, Z; Jaeggi, T. Clinical study monitoring the pH on tooth surfaces in patients with and without erosion. Caries Res 2012;46:507-512.

[15] ¹⁵
Moazzez, RV; Austin, RS; Rojas-Serrano, M; Carpenter, G; Cotroneo, E; Proctor, G et al. Comparison of the possible protective effect of the salivary pellicle of individuals with and without erosion. Caries Res 2014;48:57-62.

[16] ¹⁶
Borges, AB; Scaramucci, T; Lippert, F; Zero, DT; Hara, AT. Erosion protection by calcium lactate/sodium fluoride rinses under different salivary flows in vitro. Caries Res 2014;48:193-199.

[17] ¹⁷
Ganss, C; Lussi, A; Scharmann, I; Hardt, M; Klimek, J; Schlueter, N. Comparison of calcium analysis, longitudinal microradiography and profilometry for the quantitative assessment of erosion in dentine. Caries Res 2009;43:422-429.

[18] ¹⁸
Büyükyilmaz, T; Ogaard, B; Rolla, G. The resistance of titanium tetrafluoride-treated human enamel to strong hydrochloric acid. Eur J Oral Sci 1997;105:473-477.

[19] ¹⁹
Sen, BH; Kazemi, RB; Spangberg, LSW. Morphologic effects on L929 fibroblasts of titanium tetrafluoride application. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 1998;86:341-346.

[20] ²⁰
Shresta, BM. Effect of systemic titanium fluoride (TiF4) on fluoride uptake by developing rat enamel. Caries Res 1983;17:264-266.

[21] ²¹
Hara, AT; Ando, M; Cury, JA; Serra, MC; González-Cabezas, C; Zero, DT. Influence of the organic matrix on root dentine erosion by citric acid. Caries Res 2005;39:134-138.

[22] ²²
Tjäderhane, L; Larjava, H; Uitto, VJ; Larmas, M; Salo, T. The activation and function of host matrix metalloproteinases in dentin matrix breakdown in caries lesions. J Dent Res 1998;77:1622-1629.

[23] ²³
Barbour, ME; Shellis, RP; Parker, DM; Allen, GC; Addy, M. An investigation of some food-approved polymers as agents to inhibit hydroxyapatite dissolution. Eur J Oral Sci 2005;113:457-461.

[24] ²⁴
Rakhmatullina, E; Beyeler, B; Lussi, A. Inhibition of enamel erosion by stannous and fluoride containing rinsing solutions. Schweiz Monatsschr Zahnmed 2013;123:192-198.

[25] ²⁵
Zero, DT. Etiology of dental erosion - extrinsic factors. Eur J Oral Sci 1996;104:162-177.

Brasil

Brasil

The In Situ Effect of Titanium Tetrafluoride Gel on Erosion/Abrasion Progression in Human Dentin

Abstract

Resumo

Introduction

Material and Methods

Experimental design

Sample Preparation

Erosive-like Lesions Formation

Selection of Volunteers

Setting of Intraoral Devices

In situ Phase

TiF ₄ Application

Profilometric Analysis

Environmental Scanning Electron Microscope (ESEM) Analysis

Atomic Force Microscope (AFM) Analysis

Statistical Analysis

Results

Profilometry

Scanning Electron Microscopy

Atomic Force Microscopy

Discussion

Acknowledgements

References

Publication Dates

History

Brasil

Brasil

The In Situ Effect of Titanium Tetrafluoride Gel on Erosion/Abrasion Progression in Human Dentin

Abstract

Resumo

Introduction

Material and Methods

Experimental design

Sample Preparation

Erosive-like Lesions Formation

Selection of Volunteers

Setting of Intraoral Devices

In situ Phase

TiF 4 Application

Profilometric Analysis

Environmental Scanning Electron Microscope (ESEM) Analysis

Atomic Force Microscope (AFM) Analysis

Statistical Analysis

Results

Profilometry

Scanning Electron Microscopy

Atomic Force Microscopy

Discussion

Acknowledgements

References

Publication Dates

History

TiF ₄ Application