Research Article
Effect of Zirconium Oxide and Zinc Oxide
Nanoparticles on Physicochemical Properties and Antibiofilm
Activity of a Calcium Silicate-Based Material

Juliane Maria Guerreiro-Tanomaru,1 Adinael Trindade-Junior,1

Bernardo Cesar Costa,1 Guilherme Ferreira da Silva,1 Leonardo Drullis Cifali,1

Maria Inês Basso Bernardi,2 and Mario Tanomaru-Filho1

1 Department of Restorative Dentistry, Araraquara Dental School, São Paulo State University (UNESP),
Rua Humaitá 1680, P.O. Box 331, 14.801-903 Araraquara, SP, Brazil

2 Institute of Physics, University of São Paulo (USP), Avenida Trabalhador São-Carlense 400, 13566-590 São Carlos, SP, Brazil

Correspondence should be addressed to Mario Tanomaru-Filho; tanomaru@uol.com.br

Received 30 July 2014; Revised 10 October 2014; Accepted 16 October 2014; Published 6 November 2014

Academic Editor: Cornelis H. Pameijer

Copyright © 2014 Juliane Maria Guerreiro-Tanomaru 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.

The aim of the present study was to evaluate the antibiofilm activity against Enterococcus faecalis, compressive strength. and
radiopacity of Portland cement (PC) added to zirconiumoxide (ZrO

2
), as radiopacifier, with orwithout nanoparticulated zinc oxide

(ZnO).The following experimental materials were evaluated: PC, PC + ZrO
2
, PC + ZrO

2
+ZnO (5%), and PC +ZrO

2
+ZnO (10%).

Antibiofilm activity was analyzed by using direct contact test (DCT) on Enterococcus faecalis biofilm, for 5 h or 15 h. The analysis
was conducted by using the number of colony-forming units (CFU/mL).The compressive strength was performed in a mechanical
testing machine. For the radiopacity tests, the specimens were radiographed together with an aluminium stepwedge. The results
were submitted to ANOVA and Tukey tests, with level of significance at 5%.The results showed that all materials presented similar
antibiofilm activity (𝑃 > 0.05). The addition of nanoparticulated ZnO decreased the compressive strength of PC. All materials
presented higher radiopacity than pure PC. It can be concluded that the addition of ZrO

2
and ZnO does not interfere with the

antibiofilm activity and provides radiopacity to Portland cement. However, the presence of ZnO (5% or 10%) significantly decreased
the compressive strength of the materials.

1. Introduction

Calcium silicate- (CS-) based materials, such as mineral
trioxide aggregate (MTA), have been widely used in den-
tistry for different applications, including pulp capping and
pulpotomy, sealing of radicular or furcation perforations,
internal or external resorption, apexification, and root-end
filling in endodontic surgery due to its excellent biological
and adequate physicochemical properties [1–4].

Portland cement (PC) is the main component of MTA
[1, 5] and both show similar physicochemical and biolog-
ical characteristics [6, 7]. It has been reported that Port-
land cement exhibits biocompatibility and high compressive

strength allowing this material to be also suitable for medical
indications, such as in orthopedic applications [8]. However,
PC does not exhibit the radiopacity required to differentiate
from surrounding anatomic structures. SoMTA composition
includes bismuth oxide (Bi

2
O
3
) as radiopacifier agent [3, 9–

11].
Despite advantages of MTA when compared to other

materials, it is well documented that Bi
2
O
3
interferes with

some properties of the material. Bismuth oxide interferes
with the hydration mechanism of MTA and precipitation of
calcium hydroxide in the hydrated paste [12]. Furthermore,
the association of Bi

2
O
3
changes the microstructure of the

cement by acting as flaws within the cement matrix [13]

Hindawi Publishing Corporation
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Volume 2014, Article ID 975213, 6 pages
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2 The Scientific World Journal

and, consequently, increases the porosity and solubility of the
Portland cement reducing its resistance [13, 14]. Regarding
the biocompatibility, it has been shown that Bi

2
O
3
interferes

with cell growth [15], increases the cytotoxicity of thematerial
[16], and promotes inflammatory reaction on subcutaneous
tissue [14].

Thus, the association of PC with other radiopacifier
agents has been studied [10, 11, 17–19]. Among several
radiopacifiers studied in association with PC, zirconium
oxide (ZrO

2
) has demonstrated satisfactory results [18, 19].

The association of PC with 30% of ZrO
2
exhibits radiopacity,

compressive strength, setting time, water absorption, and
solubility similar to MTA ProRoot and resulted in a calcium
silicate hydrated calcium hydroxide and a minimum amount
of monosulfate and ettringite (natural hydrous calcium alu-
minum sulfate) [17]. It was already observed that the associ-
ation of PC with ZrO

2
promoted satisfactory pH, solubility,

calcium ions release, and setting time [14]. It was also verified
that zirconium oxide added to Portland cement promoted
better biological response than association of bismuth oxide
to PC in rat subcutaneous tissue [14].

The addition of nanoparticulated substances to differ-
ent materials can improve some properties, such as the
antimicrobial activity. Zinc oxide (ZnO) is currently being
investigated as an antibacterial agent in both microscale and
nanoscale formulations. Results have indicated that ZnO
nanoparticles show antibacterial activity greater than for
microparticles [20]. Besides, it was already demonstrated that
the use of nanoparticulated zinc oxide (ZnO) increases the
antimicrobial activity of some products, including against
biofilms of Staphylococcus aureus and Enterococcus faecalis
[21–24].

The antimicrobial potential of MTA and PC has been
evaluated by using agar diffusion test, showing that PC-
based cements have antimicrobial activity against some
microorganisms [25]. Additionally to agar diffusion test,
the antibiofilm activity can be performed by direct contact
test (DCT) on Enterococcus faecalis biofilm as proposed by
Faria-Júnior et al. [26]. When evaluated by this method, the
Sealapex and MTA Fillapex sealers promoted reduction of
bacteria on biofilms. The authors concluded that the direct
contact test is a reliable method to evaluate the antibiofilm
activity of cements after their initial setting. Studies on
the antibiofilm activity of MTA and MTA- and PC-based
materials have not been reported. Thus, the aim of this
study was to evaluate the antibiofilm activity, compressive
strength, and radiopacity of PC associated with ZrO

2
and

nanoparticulated ZnO at different proportions (5% and 10%).

2. Materials and Methods

The evaluated radiopacifiers and the proportions used in
their manipulation are described in Table 1. Since this is a
preliminary study, Portland cement was used as the main
component due its similar composition to commercial MTA.

2.1. Antibiofilm Activity. Bovine central incisors with com-
pletely formed roots were used as substrate for biofilm

development. The roots were sectioned longitudinally. Sec-
tions of dentin blocks measuring 5 × 5 × 0.7mm (width
× length × thickness) were obtained by using a diamond
disc (Isomet, Buehler, Lake Bluff, IL, USA) at low speed and
under irrigation. The resulting blocks were placed in a test
tube containing distilled water and sterilized by autoclaving
at 121∘C for 20min.

The microbiological procedures and manipulation of
the sterilized dentin blocks were carried out in a laminar
flow chamber (Veco Flow Ltd., Campinas, SP, Brazil). A
standard strain of Enterococcus faecalis (ATCC 29212) was
used for biofilm formation. After the purity of the strain
was confirmed by Gram staining and colony morphology,
the microorganism was reactivated in 4.0mL of sterile brain
heart infusion broth (BHI, Difco Laboratories Inc., Detroit,
MI, USA) and kept in an oven at 37∘C, for 12 hours.
The optical density of the medium was measured with a
spectrophotometer (Model 600 Plus, Femto, São Paulo, SP,
Brazil) set at 600 nm wavelength. Next, an aliquot equivalent
to 1% of the volume used for the contamination of the
specimens was added and homogenized to the sterile culture
medium.

The bovine dentin blocks were placed in 24-well cell
culture plates and each well received 2.0mL of pure BHI
broth containing 1% of the bacterial suspension, leaving the
dentin blocks all submersed. The plates were kept in an
incubator (model Q816M20, Quimis Aparelhos Cient́ıficos
Ltd., Diadema, SP, Brazil) under constant agitation, in
microaerophilic environment at 37∘C for 14 days. The BHI
medium of each specimen was completely changed every
48 h, without adding new microorganisms to assure enough
nutrients for the bacterial cells.

After the postmanipulation periods of 2 days, each
material sample was removed from the mould, sterilized
through UV light, and positioned over one of the dentin
blocks containing biofilm, which were previously washed in
saline solution to remove planktonic bacteria. The dentin
block/material sample assemblies were placed on 48-well
plates. Over each assembly, 20𝜇L of sterile saline solution
was dropped to avoid their drying.The plates were kept in an
oven at 37∘C for contact times of 5 h and 15 h. Six specimens
(dentin block/material) were used for each contact period.
The control group comprised noncontact of the biofilm to
any cement, allowing the comparison of the results. After the
contact periods elapsed, the cement discs were removed and
the dentin blocks containing the remaining biofilm, including
those belonging to the control group, were individually
stored in test tubes containing 1mL of sterile saline solution
and glass pearls. The tubes were agitated in vortex mixer
(model Q220, Quimis Aparelhos Cient́ıficos Ltd., Diadema,
SP, Brazil) for 1min to disrupt the biofilm.

Following that, serial decimal dilutions of E. faecalis were
obtained. At the end of the dilutions, three aliquots of 20𝜇L of
each suspensionwere inoculated onto Petri dishes containing
m-Enterococcus agar medium (Difco Laboratories, Becton,
Dickinson and Company, USA). Dishes were incubated at
37∘C, in microaerophilic environment, for 48 h.



The Scientific World Journal 3

Table 1: Experimental materials and their manufacturers.

Group Material Manufacturer

PC Portland cement (PC)
330 𝜇L of distilled water PC-CPB-40 structural Votoran, Votorantim Cimentos, Brazil

PC + ZrO2
PC (70%) + ZrO2 (30%)
330 𝜇L of distilled water

PC-CPB-40 structural Votoran, Votorantim Cimentos, Brazil
ZrO2—Sigma-Aldrich Brazil Ltd., São Paulo, SP, Brazil

PC + ZrO2 + ZnO (5%)
PC (65%) + ZrO2 (30%) + ZnO
(5%)
330 𝜇L of distilled water

PC-CPB-40 structural Votoran, Votorantim Cimentos, Brazil
ZrO2—Sigma-Aldrich Brazil Ltd., São Paulo, SP, Brazil
ZnO—Nanotechnology Laboratory of the Physics Institute of São Carlos, SP,
Brazil

PC + ZrO2 + ZnO (10%)
PC (60%) + ZrO2 (30%) + ZnO
(10%)
330 𝜇L of distilled water

PC-CPB-40 structural Votoran, Votorantim Cimentos, Brazil
ZrO2—Sigma-Aldrich Brazil Ltd., São Paulo, SP, Brazil
ZnO—Nanotechnology Laboratory of the Physics Institute of São Carlos, SP,
Brazil

PC: Portland cement.
ZrO2: zirconium oxide.
ZnO: zinc oxide.

The readings for each Petri dish resulted frommean CFU
mL−1 in the three areas of the bacterial growth, at dilutions
that generated between 5 and 50 colonies per field. From
these means, the number of CFU mL−1 was calculated for
each contact period of the filling cements with the biofilm
developed onto the dentin blocks. Data were subjected to
logarithmic transformation and the result was presented as
the mean of the six specimens in each group.

2.2. Compressive Strength. The compressive strength was
determined according to the method recommended by the
BSI [27]. To the test, 6 specimens, measuring 12mm in height
by 6mm in diameter, were performed as previously described
[14, 28]. The specimens were maintained at 37∘C and 100%
relative humidity by a gauze moistened in distilled water
until the tests were performed. Each experimental group
was subjected to testing at 24 hours and at 21 days after
manipulation of the cements [28].

The surface of each specimen was smoothed using a
600-grit sandpaper. The compression strength was evaluated
using a universal testing machine (EMIC DL 2000, Emic
Equipamentos, São José dos Pinhais, PR, Brazil) at crosshead
speed of 0.5mm/swith a load of 5 kN.Allmeasurements were
recorded in kg and converted to megapascal (MPa).

2.3. Radiopacity. The specimens used for radiopacity test
were prepared according to the ISO 6876/200121 standard
for dental root-sealing materials [29]. Six samples, with
10mm diameter by 1.0mm thickness, of each group were
subjected to the radiopacity test [14, 25]. After the mixing
of the materials, they were stored in 100% humidity at 37∘C
for 48 hours to set. Subsequently, they were positioned
on five occlusal radiographic films (Insight-Kodak Comp,
Rochester, NY, USA) and exposed, along with an aluminum
stepwedge with variable thickness (from 2 to 16mm, in
2-mm increments). An X-ray device set at 60 kV, 7mA,
15 pulses/s, and focal distance of 30 cmwas used. Radiographs
were digitized using a desktop scanner (SnapScan 1236-Agfa,
Deutschland) and the digitized images were imported to

the Image Tool 3.0 (UTHSCSA, San Antonio, Texas, USA).
The equal-density tool was used to identify equal-density
areas in the images [11]. This procedure allowed comparison
between the radiographic density of the cements and the
radiopacity of the different aluminum stepwedge thicknesses.
The area corresponding to the specimen was selected in each
radiographic image to verify the thickness of the aluminum
stepwedge detected by the software as equivalent to the
material’s radiographic density. Thus, the radiopacity of the
evaluated materials was estimated from the thickness of
aluminum (in millimeters) by using a conversion equation
[11]. The values recorded for each material were averaged to
obtain a single value in mmAl.

2.4. Statistical Analysis. Thedata were subjected to normality
test. Once the normal distribution was verified, data were
submitted to ANOVA (parametric test) and Tukey tests (𝑃 ≤
0.05).

3. Results

3.1. Antibiofilm Activity. All experimental groups showed
similar antibiofilm activity which was greater than control
group (𝑃 < 0.05). The biofilm was not completely removed
in any of the evaluated groups (Table 2).

3.2. Compressive Strength. At both periods, assessed, pure
PC obtained compression strength higher than the other
materials.The addition of 5% and 10% nanoparticulated ZnO
decreased the compression strength at both experimental
periods (Table 2).

3.3. Radiopacity. The addition of different radiopacifiers
significantly increased the radiopacity of the materials when
compared to pure PC. PC + ZrO

2
+ ZnO (10%) exhibited

radiopacity higher than other groups (Table 2).



4 The Scientific World Journal

Table 2: Mean and standard deviation values of the different cements tested.

Tests PC PC + ZrO2 PC + ZrO2 + ZnO (5%) PC + ZrO2 + ZnO (10%) Control
DCT-5 h (UFC) 5.84a ± 0.44 5.67a ± 0.67 5.90a ± 0.40 5.72a ± 0.36 7.11b ± 0.48
DCT-15 h (UFC) 5.07a ± 3.78 5.09a ± 0.15 5.06a ± 0.67 5.15a ± 0.46 6.85b ± 0.18
24 h compression strength (MPa) 32.11a ± 3.64 24.09b ± 1.22 0.58c ± 0.03 0.62c ± 0.06 —
21 d compression strength (MPa) 67.88a ± 7.35 57.43b ± 7.0 30.90c ± 5.32 27.83c ± 4.77 —
Radiopacity (mmAl) 1.15c ± 0.12 3.70b ± 0.06 3.50b ± 0.16 3.92a ± 0.18 —
Mean ± standard deviation.
Similar letters indicate statistical similarity (𝑃 ≥ 0.05).

4. Discussion

The agar diffusion antimicrobial test allows the comparison
of the antimicrobial effect of different materials, but it has
limitations once its results depend directly on the material
solubility. Other methods to assess antimicrobial activity use
the direct contact of the materials to planktonic bacteria [30].

Notwithstanding, the microorganisms of the root canal
system are organized as biofilm, which makes them more
resistant. In the present study, the methodology enabled the
antimicrobial effect evaluation of cements after setting on
bacteria organized as biofilm, according to Faria-Júnior et al.
[26], but different from the studies on materials over plank-
tonic bacteria. Enterococcus faecalis is capable of surviving in
alkaline environments and forming biofilm [31]. The bovine
dentin substrate provides adequate biofilm formation after
the period of 14 days [32].

The use of nanoparticulated ZnO was evaluated by Seil
and Webster [33], demonstrating its antimicrobial effect
against suspensions of S. aureus and P. aeruginosa [24].
Kishen et al. [21] showed ZnO antimicrobial effect against E.
faecalis suspension. Shrestha et al. [22] evaluated ZnO both
on biofilm and on planktonic E. faecalis, showing bacteria
elimination in suspension and the decrease of biofilm thick-
ness, which is in agreement with the results of this study, as
observed for all materials.

Regarding MTA- and PC-based materials, their antimi-
crobial effect was demonstrated by Asgary and Kamrani [34]
using agar diffusion test. Guerreiro-Tanomaru et al. [32]
showed antimicrobial effectiveness of PC associated with
different radiopacifiers, including ZrO

2
.

Although ZnO has presented a satisfactory antimicrobial
effect in other researches [21–23, 33], in the present study, the
materials withZnO showedpartial effect onE faecalis biofilm.
This result can be associated with the hydration reaction
of MTA with ZnO particles, resulting in a material with
low solubility and, consequently, reducing the antimicrobial
effect.

The reduction of bacteria observed in the other groups
can be related to high pH values exhibited by PC-based
materials. According to Guerreiro-Tanomaru et al. [32],
the pH of either pure PC or PC in addition to different
radiopacifiers including ZrO

2
is about 10.2. Faria-Júnior et al.

[26] observed similar results forMTA,with values close to the
required to achieve effectiveness against E. faecalis [35].

The results of the present study demonstrated that PC
associated with microparticulated ZrO

2
and nanoparticu-

lated ZnO present an adequate radiopacity, ranging from

3.50mmAl to 3.92mmAl, above the minimum value recom-
mended by ANSI/ADA specification n.57 of 3 millimeters of
aluminum [36]. These findings are in accordance with those
values previously observed for PC associated with ZrO

2
by

Bortoluzzi et al. [10].
Regarding compression strength, all materials showed

higher values at 21-day period when compared with 24-hour
period. This increase in resistance occurs because of the
ending of hydration phase, providing more hardness to the
material. Saldana et al. [37] demonstrated that ZrO

2
favors

the mechanical properties of the material, corroborating the
results observed in the present study. Notwithstanding, the
values of the association PC + ZrO

2
were smaller than PC

which is in accordance with Silva et al. [14].
Furthermore, the nanoparticulated zinc oxide dramat-

ically reduced the compressive strength of the materials,
especially at 24 hours. At least in part, this finding can
be related to the reaction mechanism of nanoparticles with
PC and ZrO

2
, culminating in a material with flaws in the

microstructure and low compressive strength.
ZrO
2
seems to be an adequate alternative radiopacifier

for PC since it shows biocompatibility and low toxicity
[14], provides satisfactory radiopacity [10, 14] and physic-
ochemical properties [14, 15, 17, 18], and maintains the
antimicrobial activity of PC [32]. However, considering the
results of the present study, further researches are needed
for better comprehension of the interaction between ZnO
nanoparticles and calcium silicate-based cements with ZrO

2
.

MTA was formulated from commercial Portland cement
combined with bismuth oxide powder for radiopacity. How-
ever, the composition, fineness, setting time, and strength of
Portland cement are not controlled or guaranteed. Portland
cement is an unsuitable substitute for MTA based on several
characteristics that are essential to the MTA performance.
Thus, this study was performed in order to evaluate the
effect of the association of zinc oxide nanoparticles in physic-
ochemical and antimicrobial properties of calcium silicate
cements. Additional studies are required for this or similar
associations in order to verify the possibilities for clinical use.

5. Conclusion

It can be concluded that the addition of ZrO
2
and ZnO

does not interfere in the antibiofilm activity and provides
radiopacity to Portland cement. However, the presence of
ZnO significantly decreased the compressive strength of the
material.



The Scientific World Journal 5

Conflict of Interests

The authors declare that there is no conflict of interests
regarding the publication of this paper.

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