
Hindawi Publishing Corporation
International Journal of Dentistry
Volume 2012, Article ID 347848, 6 pages
doi:10.1155/2012/347848

Research Article

Bleaching Gels Containing Calcium and Fluoride:
Effect on Enamel Erosion Susceptibility

Alessandra B. Borges,1 Carlos R. G. Torres,1 Paulo A. B. de Souza,1

Taciana M. F. Caneppele,1 Luciana F. T. F. Santos,1 and Ana Carolina Magalhães2

1 Department of Restorative Dentistry, School of Dentistry, Universidade Estadual Paulista (UNESP),
São José dos Campos, Av. Francisco José Longo, 777, 12245-000 São José dos Campos, SP, Brazil

2 Department of Biological Sciences, Bauru School of Dentistry, University of São Paulo (USP), Alameda Octavio Pinheiro Brisola,
9-75, 17012-901 Bauru, SP, Brazil

Correspondence should be addressed to Alessandra B. Borges, alessandra@fosjc.unesp.br

Received 24 May 2012; Revised 23 July 2012; Accepted 13 August 2012

Academic Editor: Alix Young

Copyright © 2012 Alessandra B. Borges et al. This is an open access article distributed under the Creative Commons Attribution
License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly
cited.

This in vitro study evaluated the effect of 35% hydrogen peroxide (HP) bleaching gel modified or not by the addition of calcium and
fluoride on enamel susceptibility to erosion. Bovine enamel samples (3 mm in diameter) were divided into four groups (n = 15)
according to the bleaching agent: control—without bleaching (C); 35% hydrogen peroxide (HP); 35% HP with the addition of 2%
calcium gluconate (HP + Ca); 35% HP with the addition of 0.6% sodium fluoride (HP + F). The bleaching gels were applied on
the enamel surface for 40 min, and the specimens were subjected to erosive challenge with Sprite Zero and remineralization with
artificial saliva for 5 days. Enamel wear was assessed using profilometry. The data were analyzed by ANOVA/ Tukey’s test (P < 0.05).
There were significant differences among the groups (P = 0.009). The most enamel wear was seen for C (3.37±0.80µm), followed
by HP (2.89 ± 0.98µm) and HP + F (2.72 ± 0.64µm). HP + Ca (2.31 ± 0.92µm) was the only group able to significantly reduce
enamel erosion compared to C. The application of HP bleaching agent did not increase the enamel susceptibility to erosion.
However, the addition of calcium gluconate to the HP gel resulted in reduced susceptibility of the enamel to erosion.

1. Introduction

Tooth whitening is a highly desirable esthetic treatment, as
the tooth color is one of the most important factors related
to the patients’ satisfaction with their appearance [1].

Dental bleaching treatments are mainly based on the
action of hydrogen peroxide, which is able to penetrate the
tooth structure and release free radicals, oxidizing the
chromophore molecules. Such molecules are mainly organic,
although inorganic molecules can also be affected by these
reactions [2]. Nevertheless, the free radical reaction is not
specific and it may also alter the organic component of
enamel [3]. Since the organic content contributes to the
integrity of enamel, different adverse effects on both mineral
and organic parts of bleached enamel have been observed [3].

Alterations in enamel surface morphology [3–6], chemi-
cal composition [7–10], and microhardness values [3, 11, 12]

after bleaching were previously reported. Furthermore, some
changes in bleached enamel were also described as slight
erosive effects promoted by the bleaching agent [6, 13].
Nevertheless, some authors claim that the erosive pattern on
the surface of bleached enamel only occurs when bleaching
gels with low pH are used [14, 15].

Attempts to minimize the adverse effects of bleach-
ing treatments by increasing enamel remineralization have
been conducted, however, the results are contradictory. De
Oliveira et al. [16] observed no significant increase of
bleached enamel microhardness when calcium and fluoride
were added to 10% carbamide peroxide gel. On the other
hand, Borges et al. [12] observed a significant increase of
enamel microhardness after bleaching with 35% hydrogen
peroxide agent with the addition of calcium and fluoride.
Chen et al. [6] also reported a less distinct erosion pattern
on the surface of enamel bleached with fluoridated gels.


2 International Journal of Dentistry

Crown section

Enamel specimens Polishing Microhardness measurement

Wear analysis Wear measurement
Erosive challenge

Bleaching

Enamel protection

Y (mm)
7.5

0
0.5

1

2
1.5

X (mm)

Figure 1: Schematic representation of sample preparation and analysis.

The association between the bleached enamel surface
alterations and the subsequent susceptibility to erosive
lesions resulting from the contact of bleached enamel with
demineralizing solutions has been discussed. In a previous
study, the application of carbamide peroxide gel rendered
enamel more susceptible to demineralization [17]. In other
studies, at-home bleaching technique did not increase the
susceptibility of enamel to erosion [18, 19]. However, the
effect of at-office bleaching agent (35% HP) on the enamel
susceptibility to erosion has not been properly discussed.

Considering the possibility that bleaching gels with high
concentration of HP could increase the susceptibility of
enamel to erosion, the addition of remineralizing ions into
bleaching gels would be beneficial for preventing a further
enamel demineralization [6].

Therefore, the objective of this in vitro study was to
evaluate the effect of bleaching agents based on 35% hydro-
gen peroxide modified or not by the addition of calcium or
fluoride on the susceptibility of enamel to erosion. The null
hypotheses tested were (1) 35% HP bleaching agent does not
increase the susceptibility of enamel to erosive challenges and
(2) there is no difference in erosion susceptibility of enamel
that has been treated with hydrogen peroxide compared to
enamel treated with hydrogen peroxide supplemented with
calcium or fluoride.

2. Materials and Methods

2.1. Preparation of the Samples. Freshly extracted nondam-
aged and intact bovine incisors were stored in a 0.1% thymol
solution and refrigerated at 4◦C, until required. Cylindrical
enamel samples (3 mm in diameter and 1 mm height) were
prepared from the labial surface of the tooth using a

trephine mill (Dentoflex, São Paulo, SP, Brazil). The enamel
surface was ground flat and polished with water-cooled
silicon carbide (SiC) paper discs (1200, 2500, and 4000 grit;
Fepa-P, Panambra, São Paulo, SP, Brazil), thereby removing
approximately 200 µm of the outermost layer as verified
with a micrometer (Micromar 40EXL, Mahr-Goettingen,
Germany).

The specimens were immersed in deionized water and
placed in an ultrasonic bath for 10 min (Ultrasonic Cleaner,
Odontobras, Ribeirao Preto, Brazil) for the removal of all
waste, and then stored in thymol solution at 0.1% for
rehydration.

After polishing, the enamel specimens were selected from
the average of the surface microhardness measured using a
Microhardness tester (FM-700, Future-Tech, Tokyo, Japan-
Knoop tip, average of three indentations, under 25 g-load
for 10 s) with an allowable variation within 20% of the
mean. Microhardness average of each specimen was used
for stratified allocation among 4 groups (n = 15), so that
the average microhardness for each group was similar. In
order to maintain the reference surfaces for lesion-depth
determination (profilometry), 2 layers of nail varnish were
applied on 2/3 of the surface of each sample (1/3 of each side)
exposing a central band area (see Figure 1).

2.2. Bleaching Procedures. The groups were divided as fol-
lows: C (control)-nonbleached, HP-bleached with 35%
hydrogen peroxide gel without addition of remineralizing
agents (pH = 6.35), HP + Ca-bleached with 35% hydrogen
peroxide gel with the addition of 2% calcium gluconate
(pH = 7.99), and HP + F-bleached with 35% hydrogen
peroxide gel modified by the addition of 0.6% sodium
fluoride (pH = 8.11).


International Journal of Dentistry 3

The experimental groups were subjected to 35% hydro-
gen peroxide-based bleaching agents and modified by the
manufacturer (based on Whiteness HP Blue formulation-
FGM Dental Products, Joinville, SC, Brazil). The pH of the
agents was measured using a pH meter (Digimed DM-20-
Digicrom Analı́tica Ltda., São Paulo, Brazil) fitted with an
electrode (DME-Digimed CV8) that was calibrated using
solutions with pH 4.01 and 6.86.

A layer of approximately 2 mm of the bleaching gel was
applied on the enamel surface for 40 minutes. The gel was
periodically shaken to remove the air bubbles formed during
the procedure. After this period, the specimens were rinsed
with deionized water to remove the bleaching agent (20 s).

2.3. Erosive Challenge. After the bleaching procedures, the
enamel samples were immersed in artificial saliva for 2 h
and then subjected to erosive challenges for 5 days. The
erosive cycles consisted of immersion in unstirred soft drink
(20 mL/sample, Sprite Zero, Companhia Fluminense de
Refrigerantes, Porto Real, RJ, Brazil), pH 2.8, four times per
day for 2 min each time [20], followed by a remineralizing
period of 2 h between erosive challenges (immersion in
unstirred artificial saliva, pH 7.0, 20 mL/sample), at room
temperature in small containers. The samples were kept in
artificial saliva overnight. The composition of the artificial
saliva was the same as used by Göhring et al. [21]: hydro-
gen carbonate (22.1 mmol/L), potassium (16.1 mmol/L),
sodium (14.5 mmol/L), hydrogen phosphate (2.6 mmol/L),
boric acid (0.8 mmol/L), calcium (0.7 mmol/L), thiocyanate
(0.4 mmol/L), and magnesium (0.2 mmol/L). The pH was
adjusted to 7.0 using concentrated HCl.

The beverage was replaced at the end of each challenge,
and artificial saliva was renewed daily.

2.4. Surface Wear Assessment. Profiles were obtained from
the enamel surfaces with a profilometer (MaxSurf XT 20,
Mahr-Goettingen, Germany) after the erosive challenge. To
determine the change in the surface profile after the experi-
ment, the nail varnish was carefully removed with a spatula
and a solution of acetone (1 : 1-acetone : water) to clean the
surface. The diamond stylus moved from the first reference
to the exposed area and then over to the other reference
area (2.5 mm long and 1.0 mm wide). The vertical distance
between the horizontal line drawn on the reference areas
and the horizontal line drawn on experimental area was
defined as tooth wear using the software (Software Mahr Surf
XT20, 2009). Five profile measurements were performed for
each specimen at intervals of 0.25 mm and the values were
averaged (µm).

A schematic representation of the sample preparation
and analysis is presented in Figure 1.

2.5. Statistical Analysis. Assumptions of normal distribution
of error and equality of variance (Kolmogorov-Smirnov and
Bartlett’s tests) were checked for all the variables tested. Since
the assumptions were justified, one-way ANOVA followed
by post hoc Tukey’s test were used to compare the different
bleaching agents in relation to the susceptibility of enamel
to erosive wear. Statistical analysis was performed with the

Table 1: Mean (standard deviation) of the erosive enamel wear
(µm) for the different tested groups.

Mean (standard deviation) Homogeneous Sets∗

C 3.37 (0.80) a

HP 2.82 (0.98) ab

HP + F 2.72 (0.64) ab

HP + Ca 2.31 (0.92) b
∗

Groups with different letters showed significant differences between them
(P < 0.05).

software Statistica for Windows (Statsoft, Tulsa, OK, USA),
with a significance level of 5%.

3. Results

One-way ANOVA revealed significant differences between
the groups (P = 0.009). Table 1 shows the results of post hoc
Tukey’s test. The bleaching groups HP, HP + F, and HP + Ca,
presented similar enamel wear values among them (n.s.).
However, specimens from group HP + Ca had significantly
less mean enamel wear compared to the control after the
erosive challenges, while the groups HP and HP + F did not
differ from the control.

4. Discussion

Although in-office bleaching is considered a short-term
treatment, it should not represent an additional risk for
subjects susceptible to erosion. In the present study, the
exposure of 35% HP-bleached enamel to the acid beverage
did not cause higher enamel surface wear compared to
control group (unbleached). Therefore, the first null hypoth-
esis tested was accepted. It may be suggested that possible
microstructural changes caused by the bleaching treatment
did not predispose the enamel to greater erosive wear.
These microstructural changes may have been repaired by
the adsorption and precipitation of salivary calcium and
phosphate, when immersed in artificial saliva for 2 h before
the erosive challenge [17]. The ability of saliva to reharden
and replenish lost minerals from bleached enamel has been
demonstrated previously [22, 23].

Although the adverse effects of bleaching agents on
enamel are mainly attributed to the concentration and pH
of the bleaching gel [14, 24], some surface alterations are
reported even with low-concentrated and nonacidic agents
[4, 5, 9]. In fact, the demineralization of bleached enamel can
occur as a result of mineral and organic content alterations
[4, 5, 25]. Even though these factors are considered reversible
with exposure to saliva [22], it might be speculated that
when the bleached enamel is exposed to acid, these minimal
changes could promote a greater spread of erosive agents
inside enamel, leading it to a more pronounced demineral-
ization [17].

Previous studies have shown that bleached enamel
exposed to 37% phosphoric acid, which is applied before
bonding procedures, presented a higher acid dissolution,
with increased amount of Ca2+ extracted from enamel and


4 International Journal of Dentistry

an uneven etched surface, compared to the unbleached
enamel [26, 27]. Nevertheless, other authors only reported
this increased decalcified effect when high-concentrated
hydrogen peroxide was used [28].

The association between carbamide peroxide bleaching
and erosion and abrasion were previously investigated.
Pretty et al. [18] applied 20 cycles of bleaching (2 h) using
carbamide peroxide gels, from 10 to 22% concentration,
and brushing (2 min), on enamel surface. The specimens
were then immersed in 0.1% citric acid for a total of 14 h.
The authors found no increased risk of enamel to acid dis-
solution. Engle et al. [19] also failed to demonstrate a
significant increase in the susceptibility of bleached enamel
to erosion/abrasion after a 5 days-bleaching treatment with
10% carbamide peroxide (10 h/day) associated with erosive
and abrasive challenges. Although the bleaching agent tested
in this study was more concentrated, which could increase
the adverse effects, the unique application time was shorter
(40 min) and, thus, similar results were achieved compared
to control.

This study simulated only one session of bleaching
treatment, however, multiple appointments are needed for
obtaining optimal bleaching outcomes [29]. Therefore, the
subsequent erosive wear of bleached enamel could be more
evident after successive bleaching, as more severe chemical
alterations have been observed in enamel bleached with
high-concentrated hydrogen peroxide for long periods of
exposure [30]. On the other hand, it might be speculated
that the alterations provoked by the bleaching agents could
be relevant only for the susceptibility of the enamel to initial
erosive lesions (“erosion” phase), in which enamel softening,
but not wear, is seen, as observed previously [17].

This experiment was conducted to simulate the effect of
the intake of soft drinks (Sprite Zero that has no potential
to stain the bleached enamel) after a session of in-office
bleaching treatment using a high-concentrated hydrogen
peroxide gel. The use of bovine enamel is considered a
convenient substitute for human enamel in erosion studies,
as they are easier to obtain, to handle, and standardize.
Nevertheless, it has to be considered that these two substrates
can behave in different physical and chemical manners and it
was shown that the demineralization occurs faster in bovine
enamel, due to its greater porosity [31–33].

The addition of potentially remineralizing agents in
bleaching gels was also investigated in this study. The calcium
and fluoride were added to the thickener phase of the gel,
resulting in a concentration of 2% and 0.6%, respectively,
after the final mixture, as these concentrations were com-
patible with the chemical formulation of the gel, without
impairing its thickness. It would be conceivable that the
bleaching gels containing remineralizing agents could act not
only as whitening agents but also as remineralizing agents
[34]. Supplements of fluoride and calcium in the bleaching
gels have been shown to minimize the deleterious effects on
enamel. It is supposed that the saturation of these ions in
the gel allow their incorporation into the enamel apatite,
increasing the resistance to demineralization [12, 35].

It was previously reported that the application of fluoride
gel after bleaching resulted in increased resistance of the

enamel against erosive attacks, compared to bleached/unflu-
oridated enamel [36]. However, when fluoride was added
to the bleaching gel, the protection against demineralization
was reported to be limited compared to fluoride only, since
peroxide reduced the fluoride uptake by bleached enamel
[34].

In the present study, the erosive challenges tested were
frequent (4 cycles of 2 min each per day, for 5 days); therefore,
the presence of fluoride into gel might have not been able
to provide protection against enamel wear. As a reduced
formation of KOH-soluble fluoride was observed in enamel
bleached with fluoridated agents [34], it can be speculated
that any “calcium fluoride-like” precipitation was readily
dissolved by the subsequent acid challenges [37].

In addition, it has to be considered that fluoride den-
tifrices are frequently used in the daily practice and this
additional source of fluoride can eventually contribute rem-
ineralizing the enamel surface after the bleaching procedures
and erosive challenges. Nevertheless, the fluoride dentifrice
was not included in this experimental model as this study
attempted to analyze the effect of remineralizing agents
added to the bleaching gel. Furthermore, fluoride dentifrice
application is usually associated with a brushing procedure,
which may increase the enamel erosive wear [38]. Due to
the fact that the focus of this study was only on enamel
susceptibility to erosion, brushing with fluoride dentifrice
was not included in the pH cycling model.

In contrast to the effect of adding fluoride into the
bleaching gel, the addition of calcium gluconate to the
bleaching gel resulted in a protective effect against the ero-
sion; thus, the second null hypothesis was rejected. In a
previous study, deposits of calcium on the surface of the
enamel bleached with calcium-added agent were shown
using scanning electron microscope analysis [23]. These
deposits may have acted as a physical barrier, minimizing
the contact of the acid to enamel, or providing additional
mineral to be dissolved during the acid challenge before
the underlying enamel was attacked. Another forms of cal-
cium combined with bleaching agents have been previously
investigated, such as the casein phosphopeptide-amorphous
calcium phosphate (CPP-ACP) [39, 40] and calcium chlo-
ride [12], resulting in increased mechanical properties of
bleached enamel.

Nevertheless, future studies should be conducted to
investigate the solubility of different presentation forms of
calcium salts, as well as their interaction with enamel surface,
so that the mechanism of action of calcium in improving the
resistance of bleached enamel to erosion can be established
in different phases of its development (erosion and erosive
wear).

5. Conclusion

Considering the experimental design, it can be concluded
that the application of 35% HP-based bleaching agents
did not alter the enamel susceptibility to erosion, and the
addition of calcium to the bleaching gel improved erosion
resistance of the bleached enamel.


International Journal of Dentistry 5

Acknowledgments

The authors wish to thank FGM Produtos Odontologicos for
providing the bleaching gels. This study was supported by the
State of São Paulo Research Foundation Grants no. (FAPESP
09/18588-9 and 12/16307-5).

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