Vol 50 No 4 Desember 2017.indd


178

Research Report

Composite resin shear bond strength on bleached dentin 
increased by 35% sodium ascorbate application

Tunjung Nugraheni,1 N. Nuryono,2 Siti Sunarintyas,3 and Ema Mulyawati1
1Department of Conservative Dentistry 
2Department of Chemistry 
3Department of Biomaterial 
Faculty of Dentistry, Universitas Gadjah Mada 
Yogyakarta – Indonesia

ABSTRACT

Background: Restoration of the teeth immediately after bleaching with 35% hydrogen peroxide (H2O2) is contraindicated due to 
the remnant of free radicals that will stay inside enamel and dentin for 1-3 weeks and reduce the adhesion of composite resin. Sodium 
ascorbate is an antioxidant substance known to bind free radical residues, thereby shortening the delay in restoration. Purpose: The 
purpose of this study was to examine the resin bond strength of bleached dentin influenced by the application of 35% sodium ascorbate. 
Methods: Nine premolars were divided into their crown and root sections, with the crown subsequently being cut into four equal 
parts to obtain 36 samples. These were then divided into four groups, each containing nine samples. Group A (control): samples were 
bleached using35% hydrogen peroxide, immersed in an artificial saliva, stored in an incubator at 37°C for seven days and then filled 
with a composite resin. Group B:samples were also bleached by means of 35% H2O2 followed by one application of 0.025 ml 35% 
sodium ascorbate for 5 minutes and restored with composite resin. Group C: samples were bleached with 35% H2O2, followed by two 
applications of 0.025 ml 35% sodium ascorbate for 5 minutes, and restored with a composite resin. Group D: dentin was bleached 
with 35% H2O2 followed by three applications of 0.025 ml sodium ascorbate 35% for 5 minutes and restored with a composite resin. 
The shear bond strength of the composite resin was measured by a universal testing instrument (Zwick, USA). Data was analyzed by 
means of one-way Anova and LSD. Results: The highest mean shear bond strength of composite resin was in group C, while the lowest 
was in group B. The result of one-way Anova indicated a difference in the shear bond strength of composite resin in the four treatment 
groups (p < 0.05). An LSD test showed there to be a difference in shear bond strength of composite resin between group A and groups 
C and D or between group B and groups C and D. There was no difference in shear bond strength of composite resin between group 
A and group B or between group C and group D. Conclusion: Application frequency of 35% sodium ascorbate affect on shear bond 
strength of composite resin restoration in bleached dentin by 35% H2O2.

Keywords: 35% sodium ascorbate; bleached dentin; 35% hydrogen peroxide; shear bond strength

Correspondence: Tunjung Nugraheni, Department of Conservative Dentistry, Faculty of Dentistry Universitas Gadjah Mada. 
Jl. Denta I, Sekip Utara Yogyakarta 55281, Indonesia. E-mail: tunjungnugraheni22@gmail.com.

INTRODUCTION

There are two kinds of bleaching procedure: extracoronal 
and intracoronal. The materials used for bleaching are 
sodium perborate, 30–38% hydrogen peroxide (H2O2) 
and 10–35% carbamide peroxide. The bleaching materials 
release free radicals perhydroxyl (HOO•) and oxygen 
nascen (On/O•). The free radicals react with the double 

bonds of chromogenic molecules in enamel and dentine, 
dividing into simpler molecules that are less reflective 
and cause the color of teeth to become brighter. Post-
treatment of intracoronal bleaching requires composite 
resin restoration to fill cavity that serves to prevent tooth-
recontamination by bacteria, thereby minimizing root canal 
failure. Restoration of the tooth immediately after bleaching 
is contraindicated since post- bleaching procedures often 

Dental Journal
(Majalah Kedokteran Gigi)
2017 December; 50(4): 178–182

DOI: 10.20473/j.djmkg.v50.i4.p178–182

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017.
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179179Nugraheni, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 December; 50(4): 178–182

have peroxide and residues inside the dentin tubule, between 
the collagen matrix and in the inteprismatic enamel, 
which remain active for a period of time. The trapped ion 
peroxide and residues can survive until eliminated by pulp 
microcirculation and then diffuse to external tooth surfaces.1 

The residue of peroxide and oxygen nascen are free radicals 
which can cause a decrease in adhesion of composite resin 
and an increase in microleakage.2 These molecules will 
interfere with the propagation of vinyl radical composite 
resin, causing the early termination of the polymer chain, 
and will also form polymers with such limited mechanical 
power that the strength of the bonding declines, resulting 
in weak adhesion and microleakage.3–5 Microleakage can 
lead to discoloration of marginal restoration and, ultimately, 
root canal treatment failure. H2O2 can alter the surface of 
the tag resin on composite resins. Resin tags on bleached 
teeth are fewer in number and shorter than on those that are 
not bleached. This is probably due to bleaching materials 
producing mechanical modifications to the inter tubular 
and peritubular dentine that can lead to biomechanical 
changes.6

Composite resin restoration must be undertaken 1–2 
weeks after bleaching is completed because it is expected 
that free radical residues on the bleached teeth will gradually 
reduce, resulted in the need for longer treatment. One way 
to shorten the delay time is through the application of 
antioxidants.7,8 Antioxidants are substances that can bind 
free radicals,one such recommended antioxidant being 
sodium ascorbate.8

Sodium ascorbate is a sodium salt of L-ascorbic acid, 
consisting of a white or yellowish, odorless, non-toxic, 
crystalline powder or solid, that is soluble in water and 
partially soluble in ethanol. Sodium ascorbate in liquid 
form has a pH of 6.5–8 and constitutes a biocompatible 
antioxidant.9 Sodium ascorbate will be oxidized to 
dehydroascorbic acid after contact with On.10

Controversy persists regarding the concentration, 
frequency and duration of sodium ascorbate applications 
necessary to reduce the residual bleaching material. The 
most widely used concentration in various studies is 10% 
sodium ascorbate.11 Previous research has shown that up 
to ten minutes’ application of 10% sodium ascorbate is 
effective in increasing the shear bond of composite resin 
in bleached teeth by 15–35% carbamide peroxide.12–
14Carbamide peroxide is the material commonly used 
for extra coronal bleaching on vital teeth. In intracoronal 
bleaching, the most commonly used material is 35% H2O2. 
Briso et al.6 showed that 10% sodium ascorbate increases 
the tensile strength of composite resin attachment in 
enamel bleached using10% carbamide peroxide, but 
proves ineffective on enamel and dentine bleached by 
means of 35% hydrogen peroxide. Similar results were 
demonstrated by Turkmen et al.,15 10% sodium ascorbate 
was ineffective in raising the shear bond strength of 
composite resins on teeth bleached using 35% and 38% 
H2O2. The higher concentrations of H2O2 would leave more 
free radical residue and, therefore, require antioxidants at 

higher concentrations. Freire et al.16confirm the amount of 
sodium ascorbate required to reduce H2O2 depends on the 
concentration of hydrogen peroxide used. Freire et al.17 
and Murad et al.18 also argued that longer time applications 
do not prove effective. According to Freire et al.17 

sodium ascorbate can rapidly lose its antioxidant power. 
Consequently, repeated applications are more effective than 
extending the application time. The aim of this study was 
to investigate the effectiveness of 35% sodium ascorbate 
to improve the shear bond strength of composite resin on 
dentin that bleached by 35% H2O2.

MATERIALS AND METHODS

Nine premolars free of caries and cracks were stored 
in a 10% saline buffer for a period of two months prior to 
the study. Nine premolars were separated into their crown 
and root sections, with the crown subsequently being cut 
into four equal parts to obtain 36 samples. The samples 
were divided into four groups consisting of nine parts 
each was embedded in 2 × 2 × 2 cm self-cured acrylic. 
The samples were bleached using 0.025 ml of 35% H2O2 
(Opalescene Endo, Ultradent Products, South Jordan, USA). 
Each sample was subsequently placed in a sterile plastic 
box and stored for 120 hours in an incubator at 37°C. The 
samples were washed with 5ml of distilled water before 
being dried for 10 seconds using a water syringe. Bleaching 
was repeated twice. All of the 36 samples were divided into 
four groups: A, B, C, and D. Group A (control) was soaked 
in artificial saliva and stored in an incubator at 37°C for 
seven days, before a restoration procedure was undertaken. 
Group B was administered with 0.025 ml of 35% sodium 
ascorbate (Sigma Eldrich, Singapura) for five minutes 
washed with 5 ml of distilled water by means of a syringe 
and dried for ten seconds, before undergoing a restoration 
procedure. 0.025 ml of 35% sodium ascorbate was applied 
by group C with the same procedure being repeated twice, 
prior to a restoration procedure. Group D was administered 
with 0.025 ml of 35% sodium ascorbate with the same 
procedure being repeated three times, followed by a 
restoration procedure. The restoration procedures applied 
to each sample were completed with a composite resin 
restoration (Z 350, 3M Espe, USA). A bonding agent (Tetric 
N-Bond Universal, Ivoclar Vivadent) was applied to each 
dentin surface of the sample and cured for ten seconds. A 
mould was mounted in the sample and filled with composite 
resin before being cured for 20 seconds. The samples were 
immersed in artificial saliva (Faculty of Mathematics and 
Science, Department of Chemistry Universitas Gadjah 
Mada) and stored in an incubator at 37°C for 24 hours. A 
shear bond strength test was performed on each sample 
using a universal testing instrument (Zwick, USA) at the 
Instrument Laboratory of the Faculty of Engineering, 
Universitas Gadjah Mada data was analyzed by means of 
one-way Anova and LSD.

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
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180 Nugraheni, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 December; 50(4): 178–182

RESULTS

The highest mean shear bond strength of composite 
resin in dentin bleached by 35% H2O2 was that of 
group C, while the lowest was in group B (Table 1). 
A one-way Anova test showed there to be difference in 
the shear bond strength of the composite resin in the four 
treatment groups (Table 2). An LSD test was subsequently 
conducted to quantify the difference between each group, 
the results of which can be seen in Table 3. An LSD test 
showed that there was a difference in shear bond strength 
of composite resin between group A (control) and groups 
C and D, and between group B and groups C and D. In 
contrast, no difference in shear bond strength of composite 
resin between group A (control) and group B, or between 
groups C and D existed.

DISCUSSION

Composite resin restoration is contra indication 
performed immediately after intracoronal bleaching, due 
to the presence of free radical residues that will affect the 
bond strength of the composite resin.19 The present study 
used 35% H2O2 because this material is often used in 
intracoronal bleaching techniques.20 Sodium ascorbate is an 
antioxidant reputed to capture free radicals. The frequency 
of 35% sodium ascorbate application that was performed 
(once, twice and three times) refers to the study by Freire 
which indicates that to remove all remaining free radicals, 
sodium ascorbate must be applied more than once.17

As an antioxidant, sodium ascorbate will provide one 
electron to bind to free radicals, becoming another more 
stable form of water and ascorbyl free radicals (AFR). 
The AFR pair produces one molecule of dehydroascorbic 
acid and one ascorbate. Dehydroascorbic acid reacts with 

oxidants of reactive oxygen compounds such as hydroxyl 
radicals.5,8

A one-way Anova test confirmed that there was a 
significant difference (p < 0.05) of shear bond strength 
of composite resin on dentine bleached with 35% H2O2 
which was applied at different frequencies with 35% 
sodium ascorbate. This is in accordance with the research of 
Freire et al.16 that showed the amount of sodium ascorbate 
required is directly proportional to the number of free 
radicals released by the bleaching materials. This study used 
35% H2O2, a compound which it could be assumed released 
numerous free radicals. The higher the numbers of free 
radicals are released by bleaching materials, the more likely 
a greater residual post-bleaching. To capture the remaining 
free radicals requires more sodium ascorbate.16

The free radicals resulting from the breakdown of 
H2O2 are highly electrophilic and unstable because they 
lack electron pairs. As a result, the free radicals will try to 
locate pairs of electrons in order to become more stable.9 If, 
in bleached teeth, free radical residue still exists, then the 
restoration with composite is applied to the surface enabling 
free radicals to react with the composite resin monomer. The 
polymerization of the composite resin at the propagation 
stage will be disrupted resulting in early polymerization. 
Inadequate polymerization produces polymers with low 
mechanical strength which, in turn, will result in low 
bonding to the tooth structure.8

The occurrence of shear bond strength may also be due 
to a loss of calcium or changes in the organic structure 
affecting tooth structure and leading to a decrease in 
bonding strength.21 The magnitude of changes that occur 
in tooth structure is related to the amount of free radicals 
released by bleaching materials. Examination using an 
electron microscope on the post-bleaching teeth showed 
that the resin tags are short and irregular while, on some 
surfaces, they are not even present at all.1,16 Freire et al. also 
highlighted granular and porous features with bubbles on 
the surface between the resin and bleached enamel. These 
bubbles can block the infiltration of the bonding material 
into the tooth structure.16

An LSD test showed that there was a significant 
difference in shear bond strength of composite resin 
between group A (control) and groups C and D, as well 
as between group B and groups C and D. The shear bond 
strength of composite resin in groups A and B is lower 
than in groups C and D. These results could probably be 
attributed to the fact that in groups A and B the remaining 
free radical residue was greater than in groups C and D. 

Table 2. One-way Anova of shear bond strength in dentin bleached with 35% H2O2 and with 35% sodium ascorbate applied

Variable Sum of squares df Mean square F Sig

Between Groups 119.913 3 39.971 6.884 0,001*

Within Groups 185.807 32 5.806

Total 305.720 35
*< 0,05 = significance.

Table 1. The mean shear bond strength of composite resin (N/
mm2) in dentin bleached by 35% H2O2 and with 35% 
sodium ascorbate applied

Group Mean ± SD Samples

A 10.68 ± 2.63 9

B 9.11 ± 2.14 9

C 13.40 ± 1.54 9

D 13.34 ± 3.05 9

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v50.i4.p178–182

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181181Nugraheni, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 December; 50(4): 178–182

This finding is in accordance with the study of Freire et al. 
which shows that to remove all residual free radicals after 
bleaching with 35% H2O2, the application of 35% sodium 
ascorbate should be carried out more than once.17

The remaining free radicals will result in early 
termination. Consequently, the mechanical properties of 
the composite resin in the group soaked in saliva for one 
week and receiving a one-off application of 35% sodium 
ascorbate are lower when compared to the mechanical 
properties of the composite resin in the group receiving two 
or three applications of 35% sodium ascorbate. More free 
radical residue will also result in greater loss of calcium 
and changes in the structure of more organic tissues, 
including collagen. To achieve a strong bond with dentin, 
collagen is required to create a dentin hybrid layer on a resin 
composite.19 Hydrogen peroxide can lead to denaturation of 
collagen so that no effective hybrid layer is formed resulting 
in weakly-formed bonds. The lower mechanical properties 
of the composite resin and the greater denaturation of 
collagen will result in lower shear strength.22

An LSD test showed no significant difference in 
shear bond strength between groups C and D. This result 
was probably due to free radical residue being attached 
when 35% sodium ascorbate is applied twice to dentin. 
When the application is propagated three times, it proves 
unsuccessful. The application of 35% sodium ascorbate 
more than once leaves no free radical. Therefore, complete 
composite resin polymerization can take place.17

This study showed that the application of 35% sodium 
ascorbate can improve the shear bond strength of composite 
resin on teeth bleached with 35% H2O2. Therefore, with 
composite resin restoration after bleaching a one-week 
delay is unnecessary. The shear bond strength of composite 
resin is higher if teeth bleached with 35% H2O2 had 
35% sodium ascorbate applied to them more than once. 
This study used sodium ascorbate in gel form due to the 
consideration greater ease and control of application. The 
selection of gel form was also based on the research of 
Awdah et al. which states that bleached teeth treated with 
sodium ascorbate gel form or solution showed the same 
shear bond strength. The gel form has a high viscosity, 
is easier to apply and can be applied to the tooth surface 
for a greater duration compared to a solution form.23 In 
conclusion application frequency of 35% sodium ascorbate 

affects on shear bond strength of composite resin restoration 
on bleached dentin by 35% H2O2. 

ACKNOWLEDGEMENT

The authors would like to thank the Indonesian 
government (BPDN) for the scholarship funding this article. 
This topic have been orally presented at the ICHS forum on 
August 18, 2017. The authors deny any conflicts of interest 
related to this study.

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Table 3.  LSD test of shear bond strength in dentin bleached by 
35% H2O2 and with 35% sodium ascorbate applied

Group A B C D

A – 0.177 0.023* 0.025*

B – – 0.001* 0.001*

C – – – 0.961

D – – – –
Note: *< 0,05 = significance; A (control) = soaked in saliva for 1 week; B 
= one application of 35% sodium ascorbate; C = two s application of 35% 
sodium ascorbate; D = three applications of 35% sodium ascorbate.

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v50.i4.p178–182

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Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v50.i4.p178–182

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