88

Dental Journal
(Majalah Kedokteran Gigi)

2020 June; 53(2): 88–92

Research Report

Efficacy of topical hydrogel Epigallocatechin-3-gallate against 
neutrophil cells in perforated dental pulp

Kun Ismiyatin, Ari Subiyanto, Michelle Suhartono, Paramita Tanjung Sari, Olivia Vivian Widjaja and Ria Puspita Sari
Department of Conservative Dentistry,
Faculty of Dental Medicine, Universitas Airlangga
Surabaya – Indonesia

ABSTRACT
Background: One cause of pulpitis is mechanical trauma such as pulp perforation. The emergency treatment of pulpitis in a clinic 
uses eugenol. Eugenol in a high concentration causes cytotoxicity, which causes local necrosis and inhibits the recovery process, 
while in lower doses it can cause oral mucosal hypersensitivity. Due to these side effects, it is worth considering other biocompatible 
materials with minimal side effects, such as epigallocatechin-3-gallate (EGCG), which is found in green tea. As a polyphenol, EGCG 
has a radical scavenging ability, which has an effect on reducing the number of neutrophils. The application of EGCG is expected to 
reduce neutrophils on the second day after injury so the rehabilitation process is completed more quickly and ongoing inflammation 
and pulp necrosis is prevented. Purpose: To analyse the efficacy of topical hydrogel EGCG in reducing the number of neutrophils 
after 48 hours in the perforated dental pulp of Wistar rats. Methods: 20 Wistar rats were divided equally into four groups, which 
were designated control (C) and treatment groups (T1, T2, T3). The upper first molar teeth of each rat were perforated and then T1, 
T2, and T3 were given 60 ppm, 90 ppm and 120 ppm hydrogel EGCG respectively. On the second day, the rats were sacrificed. HPA 
preparations were made to calculate the number of neutrophils in each group. Data was analysed using Kolmogorov–Smirnov, Levene’s, 
one-way ANOVA and Tukey HSD test (p<0.05). Results: There were significant differences between T2 and T3 compared with C and 
T1 (p<0.05), but no significant differences in the comparison of T1 with C and of T2 with T3 (p>0.05). Conclusion: 90 ppm hydrogel 
EGCG is effective in reducing the number of neutrophils in the perforated dental pulp of Wistar rats.

Keywords: epigallocatechin-3-gallate (EGCG); inflammation; neutrophil; pulp perforation

Correspondence: Kun Ismiyatin, Department of Conservative Dentistry, Faculty of Dental Medicine, Universitas Airlangga, JI. Mayjen. 
Prof. Dr. Moestopo 47, Surabaya 60132, Indonesia. Email: kun-is@fkg.unair.ac.id

INTRODUCTION

According to the Indonesian Health Profile of 2010, 
pulpitis was seventh out of the top ten causes of 
outpatient care in hospitals in Indonesia and dental pulp 
treatment had the highest rate compared to other dental 
treatments.1 According to the American Association of 
Endodontics (AAE) 2013, reversible pulpitis is a dental 
pulp inflammation that should be resolved and the pulp 
return to normal following appropriate management of 
the etiology. One of the treatments is excavation of the 
infected tissue, which can cause mechanical trauma such 
as iatrogenic errors. Pulpal perforation due to iatrogenic 

errors occurs in approximately 2–12% of teeth receiving 
endodontic treatment.2,3 Inflammation that continues to 
be chronic can cause failure in the tissue and this can 
lead to pulp necrosis.4 Neutrophils are the first immune 
cells that arrive to lesions5 and will undergo apoptosis 
after 1–2 days.6 If neutrophils remain in injured tissue 
then the transition of proinflammatory M1 phenotype 
macrophages (classically activated macrophages) to 
reparative M2 phenotype macrophages (alternatively 
activated macrophages) will be inhibited, resulting in 
the slowing of the tissue-repair process by the reparative 
M2. At the site of infection or injury, neutrophil cells 
recognise and phagocyte microbes, then kill pathogens 

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.v53.i2.p88–92

mailto:kun-is@fkg.unair.ac.id
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89Ismiyatin et al./Dent. J. (Majalah Kedokteran Gigi) 2020 June; 53(2): 88–92

through cytotoxic damage. This method instigates the 
production of reactive oxygen species (ROS) as well as the 
release of antimicrobial peptides.7 Emergency treatment 
of pulpitis currently uses eugenol with concentrations of 
up to 74.3%.8 Eugenol can have cytotoxic effects and also 
adversely affects fibroblast cells and osteoblasts, which 
causes local necrosis and inhibits the healing process. 
While at lower doses, eugenol can cause hypersensitivity 
reactions in the oral mucosa, inducing contact stomatitis 
and contact dermatitis.9

In view of these side effects, it is important to consider 
the use of other biocompatible materials with minimal side 
effects, such as the epigallocatechin-3-gallate (EGCG) in 
green tea. EGCG is the most concentrated polyphenol in 
green tea, which makes up around 50–80% of the total 
catechins.10 As a polyphenol, the structure of EGCG has 
eight -OH groups.11 With more -OH groups, EGCG is 
expected to be more effective in reacting with and binding 
to ROS compared to eugenol, causing a more effective 
radical scavenging. The more effective radical scavenging 
is expected to lead to a faster decrease in the number 
of neutrophils that move toward the affected tissue, 
meaning the inflammatory and healing processes can be 
completed more quickly. EGCG has been shown to affect 
several cellular mechanisms, including inflammation. 
EGCG in cells inhibits neutrophil migration through 
endothelial cells and decreases the number of oxidative 
stress markers.12 In the pulpal inflammation of a rat tooth, 
topical 0.01% and 0.1% EGCG were shown to inhibit 
pain distribution.13 As a polyphenol, EGCG has a radical 
scavenging ability to clear ROS, either directly by reacting 
with ROS or indirectly by regulating the pathways that 
control the clearance of ROS and enzymes.14 The study 
was carried out with the consideration that pure EGCG 
is toxic to gingival fibroblast cells at a concentration of 
150 μM, which is equal to 68.7 ppm.15

In general, hydrogels are used as a drug delivery 
system because of their ability to regulate drug release, 
protect drug contents from the outside environment16 and 
effectively disperse.17 In dental pulp regeneration therapy, 
hydrogel preparations can induce the release of fibroblast 
growth factor-2 (FGF-2) gradually and continuously.18 The 
most commonly used gel base in hydrogel preparations is 
polyethylene glycol (PEG).16 PEG is a hydrophilic polymer 
with low toxicity, immunogenicity and antigenicity but 
with excellent biocompatibility. The basic property of 
PEG is hydrophilic, which makes PEG the best choice of 
polymer for the hydrogel base.19 The good biocompatibility 
of PEG leads to a better maintenance of cell viability.20 
Until now, there has been no research conducted to 
examine the concentration of topical hydrogel EGCG that 
is effective in reducing the number of neutrophil cells as 
acute inflammatory cells in the dental pulps which are 
given lesions until perforated. This study was conducted 
to examine the effect of 60 ppm, 90 ppm, and 120 ppm 
hydrogel EGCG application on the number of neutrophil 
cells in a tooth cavity that has been perforated.

MATERIALS AND METHODS

Ethical clearance was approved by the Ethical Eligibility 
Committee of the Dentistry Faculty, Universitas Airlangga 
(Number: 412/HRECC.FODM/VI/2019). This study was 
laboratory in vivo experimental research with posttest-
only control group design that used 20 healthy male 
Wistar rats (Rattus norvegicus), approximately 3 months 
old and weighing 200–300 grams, as animal subjects. The 
subjects were divided equally into four groups (n=5): a 
control group (C) that received cavity preparation but 
no EGCG application and three treatment groups that 
received cavity preparation and topical application of 
60 ppm (T1), 90 ppm (T2) and 120 ppm (T3) hydrogel 
EGCG respectively.

PEG hydrogel was produced by mixing 80% PEG 400 
(Schuchardt OHG, Germany) with 20% PEG 4000 (Sigma-
Aldrich, St. Louis, USA).15 EGCG hydrogel was produced 
by mixing EGCG (Xi’An Rongsheng Biotechnology Co., 
Ltd., Shaanxi, China. Batch number: 190702) with 80% 
PEG 400 and 20% PEG 4000.

Before cavity preparation, Wistar rats were anaesthetised 
using a 0.2 cc intra-muscular injection of a mixture of 
ketamine (Kepro B.V., Deventer, Holland) and Xyla® 

xylazine base (PT Tekad Mandiri, Bandung, Indonesia) 
with a 1:1 ratio. Preparation was performed on the occlusal 
surface of the upper right first molar tooth using a 0.8 mm 
diameter round bur (Edenta®, Edenta Corp., Switzerland) 
at low speed until it reached the pulp.21 The depth of 
preparation was as large as the bur head. Perforation of 
the pulp chamber was performed using a 0.8 mm diameter 
round bur (Edenta®, Edenta Corp., Switzerland). To dry 
the cavity and confirm the presence of bleeding, which 
is a sign of pulp perforation, a fine paper point (Inline®, 
B.M. Dentale S.a.s., Torno, Italy) was used. WateroneTM 

saline (PT Jayamas Medica Industri, Indonesia) was used 
to clean up the bleeding.

EGCG hydrogel was measured using a micropipette 
(Acura® Manual 825, Socorex Isba SA, Switzerland) then 
applied using a microbrush (TPC®, TPC Advances Tech. 
Inc., USA) to the base of the cavity of the upper right first 
molar tooth in the treatment groups that had been prepared. 
60 ppm, 90 ppm and 120 ppm of EGCG hydrogel were 
applied respectively to the T1, T2 and T3 groups. After 
the application, the cavities were filled with glass ionomer 
cement (GIC) (Fuji 9, GC Corp, Tokyo, Japan).

The Wistar rats were sacrificed 2x24 hours after 
completion of the treatment in order to obtain analysis 
specimens by surgically removing the upper right first molar 
tooth along with the jaw. The maxillae were then fixed with 
10% buffered formalin (Polysciences, Polysciences Inc., 
USA) and decalcified using 10% ethylen diamin tetraacetyc 
acid (EDTA) (RPI, RPI Corp., USA) at pH 7.4 with the 
solution being replaced every three days during 30 days of 
immersion at room temperature. The samples were taken 
from the dental pulp of the teeth. The specimens were 
dehydrated by soaking in stratified alcohol followed by 

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.v53.i2.p88–92

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90 Ismiyatin et al./Dent. J. (Majalah Kedokteran Gigi) 2020 June; 53(2): 88–92

the purifying material. Next, the specimens were placed 
into xylol-paraffin (1:1), followed by pure paraffin I, pure 
paraffin II and pure paraffin III for 60 minutes each. Pure 
paraffin was poured into the box, up to the brim, without 
any air bubbles inside the paraffin block. The specimen was 
then inserted into the paraffin block using pointed tweezers. 
The tissue position was arranged so that when the block was 
cut it would provide longitudinal pieces. After the paraffin 
block hardened, a 6 μm thick paraffin slice was cut to be 
painted with hematoxylin eosin (HE) staining.

Observation of the number of neutrophils in each 
specimen was carried out using a light microscope 
(Olympic, USA) under 400x magnification and then a 
photo preparation was made. Calculation of the number of 
neutrophil cells was carried out in the area under the cavity 
preparation with eight different fields of view and counting 
was performed manually through photos with the help of 
ocular micrometer (graticule). The results were divided 
into eight, according to the number of fields of view, to 
obtain the average number of neutrophil counts for each 
sample in each group. Total calculation of the average for 

each sample in each group was then divided by the number 
of samples in each group to obtain the average number of 
neutrophils in each group. The averages and the standard 
deviation of the study were calculated. All the data obtained 
was analysed with the Statistical Package for the Social 
Sciences (SPSS) version 20 (IBM, New York, USA), using 
the Kolmogorov-Smirnov test to find out whether the data 
was normally distributed. After confirming that the data was 
normally distributed, Levene’s test was used to evaluate 
homogeneity. A one-way ANOVA was then carried out, 
followed by a Tukey HSD test to determine significant 
differences between groups. Significant differences were 
considered to be present in p<0.05.

RESULTS

The data in Table 1 shows the mean and the standard 
deviation (SD) of neutrophil cells in the control and 
treatment groups. The expression of neutrophil cells can be 
seen in Figure 1. The results of normality and homogeneity 

Table 1. The mean number (𝐱 ̅) and standard deviation (SD) of 
neutrophil cells in each control and treatment group.

Groups n Mean and SD (𝐱̅ ± SD)

C 5 11 ± 1

T1 5 11 ± 1.225

T2 5 7.2 ± 0.837

T3 5 6.2 ± 0.837
Notes: n= number of samples; C= given injury but not given any 

treatment; T1= treated with 60 ppm hydrogel EGCG; T2= 
treated with 90 ppm hydrogel EGCG; T3= treated with 120 
ppm hydrogel EGCG.

Table 2. Tukey HSD test results of neutrophil cells between 
groups.

C T1 T2 T3

C 1.000 0.000* 0.000*

T1 0.000* 0.000*

T2 0.406

T3
Notes: *= significantly different; C= given injury but not given 

any treatment; T1= treated with 60 ppm hydrogel EGCG; 
T2= treated with 90 ppm hydrogel EGCG; T3= treated 
with 120 ppm hydrogel EGCG.

T2 T3 

T1 C 

 Figure 1. Expression of neutrophil cells in HPA preparation with 400x magnification. The black arrows indicate positive expressions.
C group was given injury but not given any treatment, T1 group was treated with 60 ppm hydrogel EGCG, T2 group was 
treated with 90 ppm hydrogel EGCG and T3 group was treated with 120 ppm hydrogel EGCG.

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.v53.i2.p88–92

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91Ismiyatin et al./Dent. J. (Majalah Kedokteran Gigi) 2020 June; 53(2): 88–92

tests showed that the data was normally distributed and 
homogeneous so that it fulfilled the requirements for 
parametric tests using one-way ANOVA. The one-way 
ANOVA test results showed that there were significant 
differences in the number of neutrophils between groups 
(p<0.05). The Tukey HSD test (Table 2) was then carried 
out to investigate significant differences between groups 
and it showed that there was no significant difference 
(p>0.05) in the decrease of neutrophil cells between C 
group and T1 group. The neutrophil cells were significantly 
lower (p<0.05) in groups T2 and T3 than in the groups C 
and T1, but there was no significant difference (p>0.05) 
in the decrease of neutrophil cells between T2 group and 
T3 group.

DISCUSSION

In the inflammatory process, nitric oxide (NO) triggers 
the formation of reactive radical species through chemical 
reactions with oxygen. In the first 48 hours, NO mainly has 
a role in vasodilation, antimicrobial activity, antiplatelet 
aggregation activity and in the induction of vascular 
permeability.22 NO can cause vasodilation so that 
inflammatory cells, including neutrophils as acute 
inflammatory cells, migrate towards injury.23,24

EGCG extract, which was used in this study, is a 
polyphenol that acts as a radical scavenger. NO, which 
is a free radical, also binds to the -OH groups of EGCG. 
Furthermore, EGCG as an anti-inflammatory inhibits the 
activation of nuclear factor-κB (NF-κB) and activator 
protein-1 (AP-1), thereby reducing inducible nitric oxide 
synthesis (iNOS) expression. The application of EGCG 
in lesions also has the effect of inhibiting the production 
of iNOS, which is induced by interleukin-1β (IL-1β) and 
interferon-γ (IFN-γ), and decreasing mRNA iNOS and 
protein iNOS, causing a decrease in NO expression in 
blood vessels.25 A previous study showed that various cells 
could express IL-6 and IL-8, both of which are believed 
to participate in tissue injury related to inflammation or 
neutrophils.26 This results in vasoconstriction of blood 
vessels, which in turn results in capillary permeability 
decrease, so that the migration of neutrophil cells into the 
affected tissue is inhibited and the number of neutrophil 
cells that reach the affected tissue is reduced, causing 
the acute phase of inflammation to end more quickly. 
Modulation of the decrease in neutrophil cells facilitates 
the safe clearance of neutrophils from lesions, which is 
through macrophage cells, which happens within a few 
days, with minimal damage to tissue. This is beneficial 
because the mobilisation and ongoing activity of neutrophils 
can trigger chronic pathological responses.12 It was found 
that administration of EGCG extract can reduce the number 
of neutrophil cells in the dental pulp of Wistar rats that have 
perforated tooth cavities. When compared to the control 
group, significant reduction in neutrophils was found in 

the group that was given 90 ppm hydrogel EGCG and the 
group that was given 120 ppm hydrogel EGCG.

Significant differences between the number of 
neutrophils in the control group and the groups that were 
given 90 ppm and 120 ppm hydrogel EGCG showed that 
there was a decrease in the number of neutrophil cells 
toward the lesion in the groups that were given 90 ppm 
and 120 ppm hydrogel EGCG. The results of this study 
are in line with the previous study that stated that EGCG 
with higher concentrations has a greater antioxidant 
activity than EGCG with lower concentrations. In that 
study, the comparison was between 100 ppm EGCG and 
50 ppm EGCG in the form of emulsion.27 A decrease in 
the number of neutrophil cells present at an injury can lead 
to an increase in neutrophil apoptosis, which can shorten 
the inflammatory process and minimise tissue damage.28 
However, the group that was given 60 ppm hydrogel EGCG 
did not experience a significant decrease in neutrophils 
compared to the control group, which suggests that 60 ppm 
hydrogel EGCG was not concentrated enough to effectively 
perform radical scavenging activities.

If the number of hydroxyl groups increases, the radical 
scavenging will become stronger.11 Therefore, there was 
a significant decrease in the number of neutrophil cells 
in the group given 90 ppm and the group given 120 ppm 
hydrogel EGCG compared to the control group. There was 
no significant decrease in neutrophils in the group that was 
given 120 ppm hydrogel EGCG compared to the group that 
was given 90 ppm hydrogel EGCG. But an insignificant 
difference between the groups that were given 90 ppm and 
120 ppm hydrogel EGCG was shown by the number of 
neutrophils in the same amount. This shows that hydrogel 
EGCG at a concentration of 90 ppm is effective in reducing 
the number of neutrophil cells in the perforated dental pulp 
of Wistar rats and increasing the number of neutrophils 
is almost the same as 120 ppm hydrogel EGCG. This is 
possibly related to the EGCG saturated concentration 
binding to PEG29 and the self-oxidation properties of 
EGCG. In the mixture of EGCG with PEG, sediment is 
produced due to the bond between EGCG and the polymer 
that produces colloids and aggregates. Colloids increase 
the difficulty in formulation and reduce the efficacy of 
polyphenols.30 Several studies have shown that high 
concentrations of EGCG can cause self-oxidation and 
function as pro-oxidants by producing hydroxyl radicals, 
hydrogen peroxide and quinonoid intermediates, which 
cause cytotoxicity. The study by Chen et al.31 found that 
catechol-quinone produced by self-oxidation of EGCG and 
EGC can crosslink with erythrocyte membrane proteins 
as a crosslinking link, thus leading to membrane protein 
aggregates; the galloyl group is an important group of 
catechins that have a pro-oxidative effect. Furthermore, 
in physiological concentrations (1–2 μM to 10 μM), 
EGCG can produce a small number of reactive oxygen 
species to activate several signalling pathways and 
generate appropriate cellular protection mechanisms, thus 

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.v53.i2.p88–92

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92 Ismiyatin et al./Dent. J. (Majalah Kedokteran Gigi) 2020 June; 53(2): 88–92

presenting an antioxidant effect.32 The biological effects 
of EGCG are likely to be related to its metabolic product.33 
The pro-oxidant effect of EGCG can result in neutrophil 
infiltration.34

This study proves that the application of EGCG on the 
dental pulp in the perforated tooth cavity of Wistar rats can 
cause a decrease in the number of neutrophil cells on the 
second day after the administration to a mechanical trauma 
lesion. However, the limitation of this study is that it was 
conducted on Wistar rats. Further studies need to be done 
before clinical application can be conducted.

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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.v53.i2.p88–92

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v53.i2.p88-92