Vol 51 No 3 Jul - Sep 2018_pus.indd


133

Cytoxicity test of NaOCl and Mangosteen (Garcinia Mangostin L.) 
peel extract used as an irrigation solution in human periodontal 
ligament fibroblast cells (HPdLFc)

Tamara Yuanita, Dina Rystiawati and Karlina Samadi 
Department of Conservative Dentistry 
Faculty of Dental Medicine, Universitas Airlangga 
Surabaya - Indonesia

ABSTRACT

Background: Root canal irrigation is an important stage in root canal treatment as it is requires to eliminate necrotic and debris 
tissue as well as root canal wetting. Unfortunately, root canal irrigation can cause the material utilised to pass into the apical foramen 
leading to periapical complications. Consequently, the irrigation solution should have low toxicity. Sodium hypochlorite (NaOCl) is a 
commonly used irrigation solution since it has antibacterial properties. Moreover, NaOCl is also known to have the ability to dissolve 
necrotic tissue, vital pulp tissue and organic components of dentin and biofilms. Nevertheless, it can still cause damage when coming 
into contact with periapical tissues. On the other hand, Mangosteen peel extract (Garcinia mangostana L.), also has antibacterial 
activities. Hence, Mangosteen peel extract is assumed to be employable as an alternative irrigation solution. Purpose: This research 
aimed to reveal the toxicity levels of NaOCl and Mangosteen peel extract (Garcinia mangostin L.) used as irrigation solution in human 
periodontal ligament fibroblast cells (HPdLFc). Methods: HPdLFc were obtained from periapical tissues taken from one third of the 
first premolar teeth cultured. These cells were subsequently divided into several groups exposed to NaOCl and Mangosteen peel extract 
at certain concentrations. A toxicity test was then conducted using MTT assay. The results were analyzed with an Elisa reader. Cell 
deaths and LC50 were then calculated. Results: NaOCl became toxic at a concentration of 0.254 μl/ml or 0.025%, while Mangosteen 
peel extract became so at one of 2.099 ug/ml or 0.209%. Conclusion: NaOCl can be toxic at a concentration of 0.254 μl/ml or 0.025% 
and Mangosteen peel extract at one of 2.099 μg/ml or 0.209%.

Keywords: Cytotoxicity; NaOCl; Mangosteen peel extract; HPDLFc

Correspondence: Tamara Yuanita, Department of Conservative Dentistry, Faculty of Dental Medicine, Universitas Airlangga. Jl. 
Mayjend. Prof. Dr. Moestopo no. 47 Surabaya 60132, Indonesia. E-mail: tamara-y@fkg.unair.ac.id

Dental Journal
(Majalah Kedokteran Gigi)
2018 September; 51(3): 133–137

Research Report

INTRODUCTION

Root canal treatment is the most common form applied 
in the field of endodontics. Its main goal within endodontic 
therapy is to improve and regenerate periapical tissue. In 
achieving this, root canals must be biomechanically cleaned 
of bacteria and debris without causing irreversible damage 
to the surrounding periapical tissues.1

Root canal treatment can be divided into three stages: 
biomechanical preparation (cleaning and shaping), dressing 
and obturation. Biomechanical preparation is a process 
intended to remove not only all infected pulp tissues, both 
in vital and non-vital conditions, but also microorganisms 

from inside the root canal. However, root canal irrigation 
is still required to eliminate necrotic and debris tissue, as 
well as root canal wetting. The number of microorganisms 
in the root canals can, as a result, be reduced since unclean 
root canal walls can become a breeding ground for bacteria, 
reducematerial attachment, increase apical cleft and cause 
root canal blockage.2

The most commonly used irrigation solution is sodium 
hypochlorite (NaOCl) which has antibacterial abilities. 
Moreover, NaOCl also has the ability to dissolve necrotic 
tissue, vital pulp tissue and organic components of dentin 
and biofilms and is commonly used as an irrigation solution 
at concentrations of 0.5-5.25%.3 Unfortunately, NaOCl has 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
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134Yuanita, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 Sept; 51(3): 133–137

several disadvantages, such as increasing toxicity as its 
concentration increases, producing unpleasant odors and 
tastes and causing damage when coming into contact with 
periradicular tissue.4 In addition, when NaOCl passes from 
the root canal into the periapical tissues it can also cause 
complications, one of which is chemical burns which can 
ultimately result in tissue necrosis. Inflammatory reactions 
then will occur with the potential to cause both swelling 
and pain in the surrounding mucosa.5

In recent years, there have been a number of reports on 
the activities and possible applications of natural ingredients 
as a form of root canal disinfection. Natural irrigation can 
be used as an alternative in order to avoid the toxic effects 
of chemical irrigation materials. For instance, Mangosteen 
(Garcinia mangostana L.) is a plant indigenous to Indonesia 
and several parts of Southeast Asia. Mangosteen peel contains 
active ingredients, including: xanthones, flavonoids, saponins, 
tannins, garcinon, gartanin, vitamins B1, B2, terpenes, 
anthocyanins, phenol and other bioactive substances.6

Mangosteen (Garcinia mangostana L.) peel extract 
also performs antioxidant, anti-inflammatory and 
antibacterial biological functions. Xanthone, an active 
ingredient of α-mangostain derivates, even has the 
ability to protect against increased oxidative stress and 
antioxidant deficiency. Meanwhile, γ-mangosten inhibits 
COX-1 and COX-2 activities at concentrations of 0.8 
and 2 μM.7 Matsuo8 argues that flavonoids can act as 
antioxidants, protect against oxidative stress, while also 
inhibiting endothelial human umbilical vein cells (HUVE) 
and PC12 cells from lipid peroxidase. Nevertheless, at 
high concentrations, Mangosteen peel extract can also 
cause mitochondrial cell disorders, an increase in reactive 
oxidation stress (ROS) and loss of potential mitochondrial 
membranes, leading to cell death.9

Irrigation solutions can come into contact with pulp 
and periapical tissues. Blood and irrigation solutions that 
are expelled from the apical foramen can then lead to 
periapical complications. Cytotoxic effects of materials 
used in endodontic treatment are, consequently, considered 
to be of particular concern since they can cause damage 
and irritation leading to periapical tissue degeneration and 
wound healing delay.1 Since irrigation solutions must also 
be biocompatible, cytoxicity tests can be used as an initial 
biocompatibility assessment of the irrigation solutions used 
against certain organisms. One cytoxicity test method is the 
enzymatic test using (3- (4.5-dimethylthiaziol-2yl) -2.5-
diphenyl-tetrazolium bromide (MTT) assay. The basis of 
the MTT test is to measure the ability of living cells based 
on the mitochondrial activities of cell cultures. By using the 
cytoxicity test, an irrigation solution can be confirmed as 
toxic-based according to the toxicity parameters of median 
lethal concentration (LC50), indicating the ability of the 
material to cause 50% death of cell cultures.10 In other 
words, an irrigation solution is considered to be toxic if the 
post-exposure percentage of living cells is below 50%.11

Other previous research conducted by Karkehabadi1 on 
the cytoxicity test of NaOCl irrigation solution in human 

periodontal ligament fibroblast cells (HPdLFc) found that 
NaOCl became toxic at a concentration of 0.025%, while at 
one of 0.4%, it caused the death of all cells. Unfortunately, 
the cytoxicity test of Mangosteen peel extract in human 
periodontal ligament fibroblast cells (HPdLFc) has yet to be 
conducted. According to Freshney,12 the initial assessment 
of biocompatibility and toxic effects of a material are 
supposed to be directly performed on cell culture. 

The cytotoxicity of NaOCl and Mangosteen peel extract 
(Garcinia mangostana Linn.) used as irrigation solutions 
for human periodontal ligament fibroblast cells (HPdLFc) 
needs to be established since they have an important role in 
the development, function, and regeneration of periodontal 
tissues. Furthermore, HPdLFc are considered the first cells 
to come into contact with the irrigation solutions emerging 
from the root canal. Consequently, these cells, commonly 
studied for periodontal regeneration, are also recognised 
as the main cells reacting to endodontic material in the 
periapic tissues.13,14

MATERIALS AND METHODS 

This research was a laboratory experimental study 
with post-test only control group design. The materials 
used in this research were sodium hypochlorite (NaOCl), 
mangosteen peel extract, the first premolar teeth, 
Dulbecco’s Modified Eagle Medium culture media 
(DMEM), 10% Fetal Bovine Serum (FBS), MTT reagent 
[2- (4,5-Dimethylthiazol- 2-yl) -2, 5-diphenyl tetrazolium 
bromide], Phosphate Buffer Saline (PBS), 70% ethanol and 
sterile distilled water. The research was conducted at the 
Integrated Research and Testing Laboratory, Universitas 
Gajah Mada, Yogyakarta.

Mangosteen peel extract was produced and identified 
by Materia Medika, Batu, Malang. Mangosteen peels 
were extracted and dried by maceration method using 
70% ethanol solvent. The internal and external surfaces of 
the mangosteen peels were washed with running water to 
remove any dirt, before being drained and dried in an oven 
at 50° for 24 hours. The peels were milled, sieved, weighed 
and divided into 200gm batches and then immersed in 70% 
ethanol solvent for 24 hours, agitated in a digital shaker at a 
speed of 50 rpm, filtered and placed in a rotary evaporator 
for three hours. The extract was dissolved in DMEM 
medium in a series of doses at concentrations of 4μg/ml, 
2μg/ml, 1μg/ml, 0.5μg/ml, 0.25μg/ml and 0.125μg/ml.

Human periodontal ligament fibroblasts cells (HPdLFc) 
were obtained by culturing the first premolar teeth extracted 
during orthodontic treatment. Immediately after extraction, 
each tooth was placed in a 10ml tube containing DMEM 
medium to which fungizone and penstrep had been added. 
The periodontal ligament of each tooth was then carefully 
removed from one third of the periapical with a scalpel. 
The resulting fragment was placed in DMEM with a 
combination of 10% serum fetal bovine serum (FBS) 
and antibiotics before being cultured at 37°C with an 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
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135 Yuanita, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 Sept; 51(3): 133–137

atmospheric humidity of 5% CO2 and 95% water. Once 
every four days, the medium was discarded and replaced. 
The cells were observed until the level of confluence 
reached 90% .

A cytotoxicity test was subsequently carried out 
using MTT Assay. There were 12 groups, namely: a 1μl/
ml NaOCl treatment group, a 0.5μl/ml NaOCl treatment 
group, a 0.25μl/ml NaOCl treatment group, a 0.125μl/ml 
NaOCl treatment group, a 0.0625μl/ml NaOCl treatment 
group, a 0.03125μl/ml NaOCl treatment group, a 4μg/
ml Mangosteen peel extract treatment group, a 2μg/ml 
Mangosteen peel extract treatment group, a 1μg/ml 
Mangosteen peel extract treatment group, a 0.5μg/ml 
Mangosteen peel extract treatment group, a 0.25μg/ml 
Mangosteen peel extract treatment group and a 0.125μg/
ml Mangosteen peel extract treatment group. Each group 
consisted of three samples. The fibroblast cells were then 
divided according to the criterion of a cell density of 2 x 
104/ 20,000 cells/ well in 96 well plates. Thereafter, 100ul 
NaOCl and 100ul Mangosteen peel extract were added at 
various concentrations, with the plates being incubated in 
5% CO2 at 37º C for 24 hours. Following the incubation 
period, the cell medium was discarded and a maximum of 
10μl. 100ul MTT was added to each well. Stop Solution 
was also introduced into each of the wells and incubated 
overnight. The Optical Density values of the Formazan 
crystalline formed were read by spectrophotometry using an 
ELISA reader at a wavelength of 550 nm. The percentage 
of cell deaths was then calculated using the following 
formula:

RESULTS

The research findings were presented in the form 
of reading results produced by an ELISA Reader and 

revealed the absorbance levels or Optical Density values 
quantifying both the living cells and cell death percentages. 
At this point in the procedure, the observation and reading 
results of the absorbance values of the toxicity tests on the 
NaOCl and Mangosteen peel extract in human periodontal 
ligament fibroblasts cells (HPdLFc) were divided into 12 
groups (each undergoing the treatment on three occasions) 
accompanied by the controls depicted in Figures 1 and 2.

According to the content of Figure 1, the higher the 
concentration, the higher the cell death rate. The highest 
percentage recorded, namely 87.195%, was that at a 
concentration of 1μl/ml, while the lowest occurred at one of 
0.0625μl/ml. Based on the statistics in Figure 2, the higher 
the concentration of mangosteen peel extract, the greater the 
number of cells which died. The highest percentage of cell 
death, in this case 57.17%, was at a concentration of 4mg/
ml, while the lowest was recorded at one of 0.125μg/ml.

The results of a Shapiro-Wilk test, conducted to analyze 
the normality of the data distrbution, indicated that it was 
normal. Moreover, those of a Levene test confirmed that 
the data was homogeneous. A one-way Anova test was 
then carried out to identify any differences between the 
groups (Table 1). 

Probit analysis was subsequently performed to 
determine the LC50 value of each irrigation solution based 
on its concentration and cell death percentage. The LC50 
value of NaOCl, based on the probit analysis, was obtained 
at a concentration of 0.25μl/ml (as illustrated in Figure 
3). On the other hand, the LC50 value of Mangosteen peel 
extract, was obtained at one of 2.09μg/ml (as demonstrated 
in Figure 4).

Figure 1. The mean percentage of the cell death of human 
periodontal ligament fibroblasts cells (HPdLFc) 
exposed to NaOCl.

Figure 2. The mean percentage of the cell death of human 
periodontal ligament fibroblasts cells (HPdLFc) 
exposed to mangosteen peel extract.

Table 1. The one-way Anova test

Sum of 
squares

Meandf
square

Sig.F

0.000288.321 22.14961729.925Between groups
13.01714182.244Within groups

201912.169Total

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
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136Yuanita, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 Sept; 51(3): 133–137

DISCUSSION

In this research, the cytoxicity tests of the NaOCl and 
mangosteen peel extract (Garcinia Mangostin L.) used as 
irrigation solutions were carried out by MTT Assay method 
to measure the biocompatibility of these solutions before 
they could be applied clinically. The optical density value 
results were then read by a spectrophotometer with the 
data being calculated to reveal the percentage of cell death. 
Probit analysis was then performed to determine the values 
of a lethal concentration of 50% (LC50).

Sodium hypochlorite (NaOCl) is one of the most widely 
known and used endodontic irrigation solutions due to 
its antimicrobial activity and ability to dissolve organic 
and necrotic tissue remnants. Unfortunately, NaOCl can 
become toxic when exposed to cells and tissues around 
the root canal.

The death of periodontal ligament fibroblast cells is 
likely to be blocked by the presence of ROS in oxidative 
stress conditions. Reactive oxygen compounds, including 
hydroxyl groups, are strong oxidants. Negative effects on 
cells can arise due to reactivation of these compounds which 
can also damage cell components important to maintaining 
the integrity of cell life. Reactive oxygen species (ROS) are 
reactive oxygen compounds, well-known as free radicals 
which can be derived from the mitochondrial respiration 
chain and reactive chemical auto-oxidation.15

NaOCl, when in contact with the tissue, will produce 
hydroxyl ions and hypochlorous acid (HOCl¯). The 
NaOCl-produced hydroxyl ions will then react with oxygen 
produced by mitochondria in human periodontal ligament 
fibrous cells to form hydroxyl radicals through a process 
of autoxidation. If ROS production exceeds the capture 
capacity of antioxidants, it will lead to a condition called 
oxidative stress.14

The presence of oxidative stress will cause lipid 
peroxidation reactions in the plasma membrane and 
organelles. Thereafter, the unstable bond of fatty acids 
with free radicals will form lipid radicals that react with 
oxygen to form peroxyl radical lipids. These then react 
with other lipid radicals to become lipid peroxide, resulting 
in more severe membrane damage. ROS can also cause 

oxidation of amino acid chains, formation of covalent 
protein bonds and oxidation of proteins, leading to damage 
to the protein structure and an increase in proteasomal 
protein degradation. In addition, ROS can cause DNA 
damage and cross-linking DNA chains. This mechanism is 
what causes cell death indicated by high levels of NaOCl 
cytotoxicity.14

In this research, a cytoxicity test was also conducted on 
Mangosteen peel extract obtained by means of a maceration 
method at UPT Materia Medica, Batu, Malang. Based on 
probit analysis, the LC50 value of Mangosteen peel extract 
was found at a concentration of 2.099μg/ml. In other words, 
the concentration of Mangosteen peel extract killing 50% 
of periodontal ligament fibroblasts cells was 2.099μg/ml 
or 0.209%. This means that mangosteen peel extract at this 
concentration can become toxic. 

The results showed that mangosteen peel extract must 
be more concentrated to cause 50% of cell death. Several 
active compounds contained in Mangosteen peel were 
reported to be responsible for several pharmacological 
activities. The active compounds identified at the Industrial 
Research and Consultation Center in Surabaya included: 
xanthones (4.01%), flavonoids (2.38%), tannin (12.05%) 
and saponin (4.38%).

The death of human periodontal ligament firoblast 
cells due to the application of mangosteen peel extract in 
this research may also have been caused by an increase in 
ROS which causes an imbalance in oxidant and antioxidant 
status as well as a proloferation of pro-oxidants, referred 
to as oxidative stress.13

Xanthones are categorized into a polyphenolic class. 
The most important xanthone derivative in mangosteen peel 
extract is α-mangostin. When reacting with oxygen produced 
by mitochondria in human periodontal ligament fibroblast 
cells through an auto-oxidation process, the hydroxyl group 
of α-mangostin will result in the formation of free radicals/
ROS/semiquinone radicals. As a result, oxidative stress can 
compromise mitochondrial integrity. The active ingredient 
of flavonoids which plays a role is Quercetin. The hydroxyl 
groups of Quercethane then interact with oxygen through 
the autoxidation process also producing ROS/free radicals, 

Figure 3. Determination of LC50 value of NaOCl.

 NaOCl Probit Analysis

Concentration

Figure 4. Determination of LC50 value of mangosteen skin 
extract.

Mangosteen Peel Extract Probit Analysis

Concentration

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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137 Yuanita, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 Sept; 51(3): 133–137

namely o-quiones. The overload of ROS will cause the 
release of Ca2+ due to the opening of mitochondrial pores 
(mPTP).9 Excessive Ca 2+ will, in turn, lead to distubances 
in membrane permeability as well as excessive reaction to 
the synthesis of the tricarboxylic acid chain. It can increase 
electron flow, resulting in oxidative phosphorillation failure 
and ATP depletion, while stimulating a reaction to lipid 
peroxidation in plasma membranes and organelles. Bonding 
fatty acids with unstable free radicals can then cause more 
damage to the membrane.16

Like xanthones, tannins and saponins at inappropriate 
concentrations can also interfere with the permeability of 
fibroblast cell membranes. Tannins have a high affinity 
for proteins that can form complex bonds with them, 
causing cytoplasmic disturbances (Moosophin et al., 
2010). Meanwhile, saponins can break down the lipids 
in cell membranes, leading to disruptions to membrane 
permeability resulting in an imbalance of influx and exflux 
of ions (Ca2+, Na2+, K+). Those reactions then cause cell 
death.16

Mangosteen peel extract at high concentrations has 
antioxidant ability9 due to the xanthone, flavonoids and 
tannin it contains. Its hydrogen chain can release and 
combine with O2•

¯, leading to the stable formation of 
phenoxil radicals. Besides inhibiting the occurrence of 
lipid peroxidation, it can prevent changes in the Globally 
Harmonized System (GHS) and Superoxide dismutase 
(SOD) and also return to near normal levels. Hence, 
mangosteen peel extract can prevent SOD depletion, in 
this case, glutathione (GSH), the best antioxidants playing 
an important role as antioxidant enzymes.9 In other words, 
mangosteen peel extract is very effective at reducing the 
formation of reactive oxygen species (ROS), resulting in 
reduced cell death. Its antioxidant ability causes mangosteen 
peel extract to demonstrate lower cytotoxicity.

Previous research conducted by Kumar17 also found 
that the anti-inflammatory effect of Garcinia mangostana 
L extract occurs through the down regulation of nitric 
oxide (NO) production. At concentrations of 0.976μg/
ml to 15.625μg/ml, it can cause a down regulation in NO 
production. Its cytotoxic potency measured during this 
research using MTT assay was at the same concentration, 
i.e. at concentrations of 0.906μg/ml to 15.625μg/ml. 

In conclusion, NaOCl irrigation solution can become 
toxic at a concentration of 0.254μl/ml or 0.025%, while 
mangosteen peel extract becomes toxic at one of 2.099μg/
ml or 0.209%.

REFERENCES

Karkehabadi H, Yousefifakhr H, Zadsirjan S. Cytotoxicity of endo-1.
dontic irrigants on human periodontal ligament cells. Iran Endod J. 
2018; 13(3): 390–4. 
Gutmann JL, Lovdahl PE. Problem solving in endodontics. 52. th ed. 
Missouri: Mosby Elsevier; 2011. p. 209-12. 
Hargreaves KM, Berman LH, Rotstein I. Cohen’s pathways of the3.
pulp. 11th ed. St. Louis: Mosby Elsevier; 2016. p. 251-2. 
Harris J. Comparison of STERIPLEX4. TM HC and sodium hypochlorite 
cytotoxicity on primary human gingival fibroblasts. Thesis. Virginia: 
Virginia Commonwealth University; 2012. p. 1-25. 
Faras F, Abo-Alhassan F, Sadeq A, Burezq H. Complication of im-5.
proper management of sodium hypochlorite accident during root canal 
treatment. J Int Soc Prev Community Dent. 2016; 6(5): 493–6. 
Kaomongkolgit R, Jamdee K, Pumklin J, Pavasant P. Laboratory6.
evaluation of the antibacterial and cytotoxic effect of alpha-mangostin 
when used as a root canal irrigant. Indian J Dent. 2013; 4: 12–7. 
Pedraza-Chaverri J, Cárdenas-Rodríguez N, Orozco-Ibarra M,7.
Pérez-Rojas JM. Medicinal properties of mangosteen (Garcinia 
mangostana). Food Chem Toxicol. 2008; 46(10): 3227–39. 
Matsuo M, Sasaki N, Saga K, Kaneko T. Cytotoxicity of flavonoids8.
toward cultured normal human cells. Biol Pharm Bull. 2005; 28(2): 
253–9. 
Martínez-Abundis E, García N, Correa F, Hernández-Reséndiz S,9.
Pedraza-Chaverri J, Zazueta C. Effects of α-mangostin on mitochon-
drial energetic metabolism. Mitochondrion. 2010; 10(2): 151–7. 

10. Zhang M, Aguilera D, Das C, Vasquez H, Zage P, Gopalakrishnan 
V, Wolff J. Measuring cytotoxicity: a new perspective on LC50. 
Anticancer Res. 2007; 27: 35–8. 

11. Khoswanto C, Arijani E, Soesilawati P. Cytotoxicity test of 40, 50 
and 60% citric acid as dentin conditioner by using MTT assay on 
culture cell line. Dent J (Maj Ked Gigi). 2008; 41(3): 103–6. 

12. Freshney RI. Culture of animal cells: a manual of basic technique 
and specialized applications. 6th ed. New Jersey: John Wiley & Sons, 
Inc.; 2011. p. 1-8, 111-4, 187-206, 365-77. 

13. Scanlon CS, Marchesan JT, Soehren S, Matsuo M, Kapila YL. Cap-
turing the regenerative potential of periodontal ligament fibroblasts. 
J Stem Cells Regen Med. 2011; 7: 54–6. 

14. Ok E, Adanir N, Hakki S. Comparison of cytotoxicity of various 
concentrations origanum extract solution with 2% chlorhexidine 
gluconate and 5.25% sodium hypochlorite. Eur J Dent. 2015; 9: 
6–10. 

15. Saraswati W. Apoptosis sel odontoblas pulpa akibat resin bonding 
agent HEMA. Thesis. Surabaya: Universitas Airlangga; 2009. 

16. Arabski M, W�gierek-Ciuk A, Czerwonka G, Lankoff A, Kaca W. 
Effects of saponins against clinical E. coli strains and eukaryotic cell 
line. J Biomed Biotechnol. 2012; 2012: 1–6. 

17. Kumar V, Abbas AK, Aster JC. Robbins and Cotran pathologic basis 
of disease. 9th ed. Philadelphia: Elsevier Saunders; 2015. p. 44-52. 

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.v51.i3.p133–137

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v51.i3.p133-137