67

Dental Journal
(Majalah Kedokteran Gigi)

2022 June; 55(2): 67–70

Original article

Effects of tooth preparation on the microleakage of fissure 
sealant

Gesti Kartiko Sari1, Sri Kuswandari2, Putri Kusuma Wardani Mahendra2
1Paediatric Dentistry Specialty Program, Department of Paediatric Dentistry, Faculty of Dentistry, Universitas Gadjah Mada, Yogyakarta, Indonesia
2Department of Paediatric Dentistry, Faculty of Dentistry, Universitas Gadjah Mada, Yogyakarta, Indonesia

ABSTRACT
Background: Fissure sealing can be achieved by preparing and sealing the deep pits and fissures in the teeth with a sealant to prevent 
caries. Fissure sealing is performed using resin modified glass ionomer cement (RMGIC) and failure is most often due to weak adhesion 
between the material and the tooth, resulting in microleakage. Purpose: The study aimed to determine the effect of a preparation technique 
with bur and acid application on potential RMGIC fissure sealant microleakage. Methods: Twenty-four extracted maxillary premolars 
were divided into four treatment groups. Group 1 underwent enameloplasty with a round bur and application of 37% phosphoric acid; 
group 2 with a tapered bur and 37% phosphoric acid; group 3 with a round bur and 10% polyacrylic acid; and group 4 with a tapered 
bur and 10% polyacrylic acid. The application of 37% phosphoric acid was carried out for 15 seconds, while 10% polyacrylic acid was 
applied for 20 seconds, before RMGIC filling. The teeth were stored in artificial saliva at 37°C for 24 hours, then thermocycled 100 
times at 5°C and 55°C for 20 seconds each. The teeth were immersed in a 1% methylene blue solution for 24 hours at 37°C, then cut 
crosswise. The length of the microleakage was observed with a stereo microscope at 8 times magnification and measured using raster 
image application. Data was analysed with one-way ANOVA. Results: Significant differences were found between treatment groups 
(F=562.14; p<0.05). The deepest mean microleakage was in the round bur and 10% polyacrylic acid group (1657.87 ± 78.08) and 
the shallowest was in the round bur and 37% phosphoric acid group (500.70 ± 38.55). Conclusion: The preparation method, type of 
bur and acid solution have an effect on microleakage potential of RMGIC fissure sealing. Round bur preparation and 37% phosphoric 
acid resulted in shallow microleakage.

Keywords: preparation technique; fissure sealant; microleakage

Correspondence: Sri Kuswandari, Department of Pediatric Dentistry, Faculty of Dentistry, Universitas Gadjah Mada. Jl. Denta 1, Sekip 
Utara, Yogyakarta, 55281, Indonesia. Email: ndaribacrun@ugm.ac.id; kuswandarisri@gmail.com

INTRODUCTION

Pit and fissure sealant was introduced by Buonocore in 
1971. He started using an acid etch before sealing fissures 
for preventing caries. Various fissure sealing preparation 
methods were observed by Agarwal, such as air abrasion, 
increased etching time, air polishing, application of pumice 
slurry, brushing, and mechanical bur preparation.1 Fissure 
sealing aims to seal the deep fissures of the teeth as a 
physical barrier to prevents the entry of food debris into 
those fissures.2

Fissure sealing is performed using a low viscosity 
dental material, namely resin modified glass ionomer 
cement (RMGIC).3 RMGIC combines the advantages of 

glass ionomer materials and composite resins. RMGIC 
releases fluoride which can prevent and control caries. 
The material hardens upon light curing.4 Adhesion of the 
material will occur after the light curing process, but the 
literature reveal that the sealant will lose about 5-10% 
efficacy per year.5

Failure of the fissure sealant in the form of microleakage 
causes bacteria to easily enter through the gap and continue 
to develop into dental caries. As microleakage occurs due to 
poor adhesion of the material to the tooth, the preparation 
method before fissure sealing treatment needs to be 
considered.6 The adhesion and bond strength between the 
sealant and the tooth is influenced by the preparation of the 
tooth before the application of the sealant.7 Fissure sealing 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 158/E/KPT/2021. 
Open access under CC-BY-SA license. Available at https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v55.i2.p67–70

mailto:ndaribacrun@ugm.ac.id
mailto:kuswandarisri@gmail.com
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68Sari et al./Dent. J. (Majalah Kedokteran Gigi) 2022 June; 55(2): 67–70

preparation, among others, takes the form of prophylaxis 
with pumice, application of acid to the enamel, air abrasion, 
or enameloplasty. The preparation is carried out on the 
enamel surface prior to sealant application. Preparation 
can be divided into two types, namely mechanical 
and chemical.5 Chemical preparation is performed 
through acid application, which serves for the adhesion 
of fissure sealants.8 According to the manufacturer’s 
recommendations, fissure sealing with RMGIC is preceded 
by the application of 10% polyacrylic acid to remove the 
smear layer.9 Chemical preparation can also be carried out 
with the application of 37% phosphoric acid to increase the 
mechanical strength of the sealant.5 Acid application on the 
tooth surface can form enamel micropores within which the 
material will form resin tags.

Mechanical preparation can create access to deep fissure 
areas, remove debris, enable deeper sealant penetration, 
and increase retention.5 One of the commonly used 
mechanical preparations techniques is enameloplasty. It 
is a prophylactic procedure that removes enamel in the 
pits and fissures of the tooth to produce a smooth and 
sloping surface.10 Enameloplasty is performed with a 
cutting instrument in the form of a bur, which can cut 
the enamel effectively.11 Most dentists use round burs to 
perform enameloplasty.5 It can also be performed with a 
tapered bur, often called a fissurotomy bur. Enameloplasty 
can determine the penetration depth of the sealant.5 A 
combination of mechanical and chemical preparation 
techniques plays an important role in increasing the bond 
strength between the tooth and the material, which in turn 
can affect the success of fissure sealing.7 One indicator 
of efficacy is the microleakage test. This study aims to 
determine the effect of the preparation method with various 
bur and acid applications on the microleakage potential of 
RMGIC fissure sealant.

MATERIALS AND METHODS

The research protocol was reviewed by the Ethical 
Committee of Faculty of Dentistry and was granted ethical 
clearance with certificate number of 00476/KKEP/FKG-
UGM/EC/2020. This experimental laboratory research 
included 24 extracted human maxillary premolars, free of 
caries. Human premolars extracted for orthodontic reasons 
were included in this study. The teeth were stored in a 
saline solution for 6 months extraction and divided into 
four groups (n=6 each). Teeth were randomly selected 
and distributed into the four experimental groups (coded 
1, 2, 3, and 4). Groups 1 and 3 underwent enameloplasty 

with a 1/4 round bur (SS White, Lakewood, New Jersey), 
2 and 4 with a tapered bur (SS White, Lakewood, New 
Jersey). The depth of the enameloplasty was adjusted 
to the diameter and height of the bur head. Afterwards, 
37% phosphoric acid (3M, Saint Paul, Minnesota) was 
applied for 15 seconds in groups 1 and 2, while groups 3 
and 4 used 10% polyacrylic acid (GC, Tokyo, Japan) for 
20 seconds. Fissure sealing was performed with RMGIC 
(GC, Tokyo, Japan) in all groups after acid application. 
The teeth were immersed in artificial saliva (MIPA 
UGM laboratory, Sleman, Indonesia) for 24 hours in an 
incubator at 37oC, then thermocycled for 100 cycles at 
5oC and 55oC. The apical part of the tooth was coated 
with nail polish and sticky wax before immersing in a 
1% methylene blue solution (Pudak Scientific, Bandung, 
Indonesia) for 24 hours at 37oC. The soaked teeth were 
cleaned from nail polish and wax, then rinsed in water. 
The teeth were dried and cut crosswise in the mesial-distal 
centre using a benchtop micro milling machine (Proxxon, 
Hickory, North Carolina). Microleakage was observed 
with a binocular microscope (Olympus, Tokyo, Japan) 
at 8 times magnification and measured in micrometres 
(µm) using Image Raster application version 3 (Miconos, 
Sleman, Indonesia). The data was then statistically tested 
with one-way ANOVA, SPSS version 22 (IBM, New 
York, USA).

RESULTS

The mean results obtained in each group are presented in 
Table 1. The deepest microleakage (mean value) was in 
the round bur enameloplasty and 10% polyacrylic acid 
application group. The shallowest microleakage (mean 
value) was in the group with round bur enameloplasty and 
37% phosphoric acid application group.

The one-way ANOVA test was used to determine the 
effect of the type of bur and acid in the preparation on 
RMGIC fissure sealant microleakage; results can be seen 
in Table 2. Results show an F value of 562.14 (p<0.05), 

Table 1. Mean and standard deviation of RMGIC fissure sealant 
microleakage based on preparation method (µm)

Treatment group n Mean + SD (µm)

Round bur and 37% phosphoric acid 6 500.70 ± 38.55

Tapered bur and 37% phosphoric acid 6 900.55 ± 10.53

Round bur and 10% polyacrylic acid 6 1,657.87 ± 78.08

Tapered bur and 10% polyacrylic acid 6 998.39 ± 46.29

Table 2. One-way ANOVA test between treatment groups

Sum of square Degree of freedom Mean square F p
Between groups 4,146,928.49 3 1,382,309.49 562.14 <0.001
Within groups 49,180.03 20 2,459.00

Total 4,196,108.52 23

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 158/E/KPT/2021. 
Open access under CC-BY-SA license. Available at https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v55.i2.p67–70

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https://doi.org/10.20473/j.djmkg.v55.i2.p67-70


69 Sari et al./Dent. J. (Majalah Kedokteran Gigi) 2022 June; 55(2): 67–70

so it can be assumed that the preparation method has an 
influence on the microleakage potential of the fissure 
sealant. Comparative analysis of the study groups by a 
post hoc LSD test (Table 3) showed significant differences 
(p<0.05) between treatment groups.

DISCUSSION

Deep pits and fissures are a reason why teeth are prone 
to caries, so prevention is necessary. Fissure sealing 
functions as a physical barrier to the entry of food debris 
and to plaque retention into the dental fissures.2 The 
material used for fissure sealing in this study is RMGIC. 
Excess RMGIC can bind to the hard tooth tissue directly. 
Mechanical (enameloplasty) and chemical (acid application) 
preparations in the fissure sealing procedure are carried out 
to reduce the possibility of microleakage.12

The results showed that the type of enameloplasty 
bur and acid application had a significant effect on the 
microleakage of the RMGIC fissure sealing. The shallowest 
leakage was observed after a preparation method using a 
round bur and 37% phosphoric acid. Results in this group 
were better than with a tapered bur and 37% phosphoric 
acid group due to the difference in the preparation surface 
area, which is wider with a round bur than with a tapered 
bur. It can be determined by the following calculation: 

Surface area of round bur = (Ω x 4 x π x r2) + (π x d x t)
 = (2 x 3.14 x 0.352) + (3.14 x 0.7 x 0.77) x mm2

 = 2.46 mm2

Surface area of tapered bur = π x r x s
 = 3.14 x 0.39 mm x 1.86 mm
 = 2.27 mm2

The fissure surface of the teeth prepared with a round bur 
(2.46 mm2) is wider than the surface of the fissure prepared 
with a tapered bur (2.27 mm2), so more resin tags will 
form in the sealant applied to the fissure after a round bur 
preparation. This is in accordance with Parihar and Pilania, 
stating that the number of resin tags can affect the retention 
of the bond between the sealant and the tooth; the higher 
the tagging, the stronger the bond will be. 13 The “U” 
shaped fissure resulting from the round bur preparation also 
facilitates material filling due to the blunt fissure base. The 
round bur creates a fissure shape with the same diameter 

from top to bottom, in contrast to the shape of the fissure 
after a tapered bur preparation, which gets narrower towards 
the bottom. This is in accordance with findings from Tzifa 
et al. that increasing the width of the fissure makes the 
penetration of the material more optimal.5

Results from this study showed that the shallowest 
microleakage occurred in teeth with the application of 37% 
phosphoric acid after preparation with a round bur, while 
the deepest followed the application of 10% polyacrylic acid 
and the use of a round bur. This is because 37% phosphoric 
acid can dissolve the prism core and form a type 1 enamel 
etching pattern, while polyacrylic acid does not change 
the configuration of tooth enamel.14 The enamel etching 
pattern produced by 37% phosphoric acid causes the filling 
material to enter the enamel prism, and increases the bond 
strength between sealant and enamel. As such, it can reduce 
the risk of microleakage.15 Application of 37% phosphoric 
acid can also produce a coarse and porous layer as deep as 
5-50 µm.16 Chemical preparation with 10% polyacrylic acid 
only produces an average micro-tag depth of about 8.73 
µm.17 The use of 37% phosphoric acid produces deeper 
micro-tags, so the retention and bond strength between 
the material and the tooth will be better than with 10% 
polyacrylic acid.16 Ion exchange between glass ionomer and 
tooth coating without a smear layer will result in a stronger 
bond, whereas bonding to a smear layer would mean weaker 
tooth structure.8 Hydroxyapatite in the tooth will interact 
with the material. Demineralisation of the dentin and the 
submicron interdiffusion layer creates micromechanical 
retention for the cement against the tooth.18

Another factor that can influence microleakage is the 
storage period of the tooth from extraction to study, which is 
different for each tooth. All research objects were obtained 
from the extraction of premolars within a period of 6 
months with the same storage media (saline).19 According 
to research conducted by Secilmis et al.,20 dental minerals 
can dissolve quickly in saline. The calcium mineral of 
the teeth will decrease with increasing storage time and 
cause decreasing tooth hardness, which will affect the 
occurrence of microleakage. Based on this research, if 
using the manufacturer’s recommendation of RMGIC with 
10% polyacrylic acid application, mechanical preparation 
with a tapered bur (fissurotomy) is advised; however, for 
the best results, it is recommended to use RMGIC after 
tooth preparation with a combination of round bur and 37% 
phosphoric acid before sealant application.

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Table 3. LSD test between treatment groups

Between groups Mean difference p
1 and 2  -399.85 0.000
1 and 3 -1,157.17 0.000
1 and 4 -497.69 0.000
2 and 3 -757.32 0.000
2 and 4 -97.84 0.033
3 and 4 659.47 0.000

Group information:
1= round bur and 37% phosphoric acid
2= tapered bur and 37% phosphoric acid
3= round bur and 10% polyacrylic acid
4= tapered bur and 10% polyacrylic acid

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 158/E/KPT/2021. 
Open access under CC-BY-SA license. Available at https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v55.i2.p67–70

https://e-journal.unair.ac.id/MKG/index
https://doi.org/10.20473/j.djmkg.v55.i2.p67-70


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Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 158/E/KPT/2021. 
Open access under CC-BY-SA license. Available at https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v55.i2.p67–70

https://e-journal.unair.ac.id/MKG/index
https://doi.org/10.20473/j.djmkg.v55.i2.p67-70