Vol 49 No 1 Jan-Mrt 2016.indd


1717

The thickness of odontoblast-like cell layer after induced by 
propolis extract and calcium hydroxide

Irfan Dwiandhono,1 Ruslan Effendy,2 and Sri Kunarti2
1Faculty of Medicine, Universitas Jenderal Soedirman, Purwokerto - Indonesia
2Department of Conservative Dentistry, Faculty of Dental Medicine, Universitas Airlangga, Surabaya - Indonesia

ABSTRACT

Background: Propolis is a substance made from resin collected by bees (Apis mellifera) from variety of plants, mixed with its 
saliva and various enzymes to build a nest. Propolis has potential antimicrobial and antiinflammatory agents with some advantages 
over calcium hydroxide (Ca(OH)2). Ca(OH)2 has been considered as the “gold standard” of direct pulp-capping materials, but there 
are still some weakness of its application. First, it can induce pulp inflammation which last up to 3 months. Second, the tissue response 
to Ca(OH)2 is not always predictable. Third, the tunnel defect can probably formed in dentinal bridge with possible bacterial invasion 
in that gap. Purpose: This study was aimed to determine and compare the thickness of odontoblast-like cells layer after induced by 
propolis extract and Ca(OH)2 in rat’s pulp tissue. Method: Class 1 preparation was done in maxillary first molar tooth of wistar mice 
until the pulp opened. The Ca(OH)2 and propolis extract was applied to induce the formation of odontoblast-like cells, the cavity was 
filled with RMGIC. The teeth were extracted (after 14 and 28 days of induction). The samples were then processed for histological 
evaluation. Result: There were significant differences between the thickness of odontoblast-like cells after induced by propolis extract 
and Ca(OH)2. Conclusion: The propolis extract as the direct pulp capping agent produces thicker odontoblast-like cell layer compared 
to Ca(OH)2.

Keywords: odontoblast-like cells; propolis; calcium hydroxide

Correspondence: Irfan Dwiandhono, Faculty of Medicine, Universitas Jenderal Soedirman. Jl. Dr. Gumbreg No. 1 Purwokerto 53123, 
Jawa Tengah, Indonesia. E-mail: irfandrg@gmail.com Telp. +62 281 643744.

Research Report

Dental Journal
(Majalah Kedokteran Gigi)

2016 March; 49(1): 17–21

INTRODUCTION

The aim of direct pulp capping treatment is to maintain 
the pulp’s vitality, by protecting the pulp from bacterial 
penetration and inducing dentinal bridge formation. The 
success of the pulp capping procedure greatly depends upon 
the capacity of the capping material to perfectly seal the 
tubuli, non irritative, protect the pulp from the mechanical, 
chemical, and bacterial irritation, induce fibroblast and 
odontoblast cell to form reparative dentin and dentinal 
bridge.1

Calcium hydroxide [Ca(OH)2] is the most accepted and 
commonly used pulp capping material. It stimulates the 
pulp tissue on the formation of dentinal bridge and inhibits 

bacterial growth. Nevertheless, application of calcium 
hydroxide in direct pulp capping has some drawbacks. The 
high pH (12.5) of Ca(OH)2 suspensions causes liquefaction 
necrosis at the surface of the pulp tissue with the formation 
of a necrotic layer at the material-pulp interface. The 
toxicity of Ca(OH)2 reduced in deeper pulp layer, causing 
coagulation necrosis to the average degree of irritation. 
In this zone of coagulation necrosis, the differentiaton of 
odontoblast-like cells and the formation of dentinal bridge 
occured.2

Several studies related to pulp capping materials had 
been conducted to determine the most appropriate pulp 
capping material with good biocompatibility. The success 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v49.i1.p17-21



18 Dwiandhono, et al./Dent. J. (Majalah Kedokteran Gigi) 2016 March; 49(1): 17–21

rate of calcium hydroxide as pulp capping material were 
80,1% after a year, 68,0% after 5 years, and 58,7% after 
9 years.3 

The drawbacks of Ca(OH)2 as pulp capping material 
are: (1) it can induce pulp inflammation which last up to 3 
months, (2) unpredictable tissue response, (3) the reparative 
dentin formed below Ca(OH)2 is irregular, the and the 
tunnel defect can probably formed. The defect is formed 
because of the tissue inclusion on the dentinal bridge. This 
resulted in increasing dentinal bridge’s permeability for 
possible bacterial invasion.4

Propolis is a substance made from resin collected by 
bees (Apis mellifera) from variety of plants, mixed with 
its saliva and various enzymes to be a whole different 
kind of resin, and used by bees to build a nest.5 The 
color of this whole new resin is brown to dark brown. 
It is sticky at room temperature, but hard and fragile at 
low temperature. Propolis has broad-spectrum biological 
and pharmacological activity, anti-bacterial, anti-virus, 
anti-oxidant, and anti-inflammation material. Propolis 
consists of 55% resin, 30% bee’s wax and aromatic oils, 
5% bee pollen, and 10% other substances (amino acid, 
minerals, ethanol/alcohol, vitamin A, B complex, E, and 
bioflavonoid).6

Many studies related to propolis extract as direct 
pulp capping material has been conducted, but the exact 
mechanism of action remains unclear. Propolis extract with 
flavonoid was proven to reduce inflammation and to form 
dentinal-bridge in 4th weeks after pulp capping treatment 
on Sprague-Dawley rats.7 

Direct pulp capping treatment with propolis and mineral 
trioxide aggregate (MTA) in human was succeed to form 
dentinal bridge on the 15th day, whereas in the group 
treated with Ca(OH)2 the dentinal bridge was not found.

8 
In other study, MTA and novel endodontic cement (NEC) 
in dog’s teeth after 8 weeks was giving better result in 
pulp capping and dentinal bridge formation compared to 
calcium hydroxide.9

The aim of this study was to analyze histological process 
of dentinal bridge formation by measuring the thickness of 
the odontoblast like cells on the pulp of Wistar rats’ teeth 
after pulp capping treatment using propolis and Ca(OH)2. 

MATERIALS AND METHODS

This research was an experimental laboratory study, 
with 42 male Wistar rats as samples (healthy, weighing 
200-250 gr, 8-16 month-old, with fully erupted molars). 
The adaptation time given was 2 weeks. The samples were 
divided into 6 groups as follow: Group I (Control Group 
I/the pulp was perforated, filled with GIC, observed on 
the14th day), Group II (Control Group II/ the pulp was 
perforated, filled with GIC, observed on the 28th day), 
Group III (the pulp was perforated, applied with propolis 

extract, filled with GIC, observed on the 14th day), Group 
IV (the pulp was perforated, applied with propolis extract, 
filled with GIC, observed on the 28th day), Group V (the 
pulp was perforated, applied with calcium hydroxide, filled 
with GIC, observed on the 14th day), and Group VI (the 
pulp was perforated, applied with calcium hydroxide, filled 
with GIC, observed on the 28th day). The pulp capping 
material amount was 0,5 mg for each application. 

The euthanasia process was performed, followed by 
decapitation and maxilla separation. Rat’s molars were 
sectioned parallel to the axis using microtome to 7μm. The 
samples were then stained with hematoxylin and eosin. 
Assessment of the normality of the data was determined 
with Kolmogorrov smirnov test. Assessment of the 
homogenity of the data was determined with Levene test. 
The statistically significant differences were determined 
with Independent T-test.

RESULT

The histological examination to see the thickness of 
odontoblast-like cells was done at 200x magnification. 
The thickness of odontoblast-like cells was defined as the 
thickness of the new cells found below the perforation 
area. The result of the thickness of the dentin can be seen 
in Figure 1.

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

A B 

D C 

E F 

Figure 1. The thickness of the odontoblast-like cells in rats’ teeth 
(at 200x magnification). The red marked area shows 
the thickness of the odontoblast-like cells. A. Control 
group on the 14th day, B. Control group in 28th day, 
C. Ca(OH)2 group on the 14

th day, D. Ca(OH)2 group 
on the 28th day, E. Propolis extract group on the 14th 
day, F. Propolis extract group on the 28th day.

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v49.i1.p17-21



1919Dwiandhono, et al./Dent. J. (Majalah Kedokteran Gigi) 2016 March; 49(1): 17–21

in the thickness of odontoblast-like cells between 14th day 
and 28th day of positive control group, Ca(OH)2 group, 
and propolis extract group. Kruskall-wallis revealed that 
there were significant differences between all groups. 
Independent t-test revealed that there that there were 
significant differences in the thickness of odontoblast-like 
cells between 14th day and 28th day of positive control 
group, Ca(OH)2 group, and propolis extract group. 

DISCUSSION

The basic principle of conservation treatment is to 
maintain the condition and function of the dentin-pulp 
complex, especially in the case when the pulp is perforated. 
Like the other connective tissues, pulp tissue has the 
capacity to repair themself. The characteristic of healing 
process of the perforated pulp tissue is the reorganization of 
the damaged soft tissue, fibroblast cell differentiation into 
odontoblast-like cells, and the reparative dentin formation 
on the perforated soft tissue.10

The damage in the pulp tissue will resulted in 
inflammation reaction to eliminate the substance that 
endanger the tissue or to avoid further destruction of the 
pulp tissue. The inflammation reaction is the early step 
of the healing process. At the time when tissue is injured, 
the fibroblasts would soon migrate toward the wound, 
proliferate and produce large amounts of collagen matrix 
that will help to isolate and repair the damaged tissue.11 

Growth factor plays an important role in responding 
to the injury and tissue repair.12 Caries is estimated to 
trigger the odontoblast activity to increase the expression 
of TGF-β1. The TGF-β1 that was dissolved in matrix is 
released.13 TGF-β1 is an important regulator in proliferation 
and differentiation of the human’s pulp cells during the 
formation and dentin repair process.14 TGF-β1 binds to 
TGF-βR, the TGF-β1 receptor, which then activates the cell 
cycle to proliferate. TGF-β1 will regulate the proliferation 
process, the cell cycle running normally, and ready for 
the next step. The cell undergo the mitosis process to 
differentiate into odontoblast-like cells, characterized by 

Table 1. Mean and standard deviation of odontoblast-like cells 
thickness in 14th and 28th day

Groups
Mean (mm) Std.

Deviation 

14th day Positive Control 0,022 0,005

Ca(OH)2 0,035 0,013

Propolis 0,084 0,012

28th day Positive Control 0,032 0,005

Ca(OH)2 0,056 0,015

Propolis 0,104 0,012

Table 2. Independent t-test result of odontoblast-like cells 
thickness on the 14th and 28th day

Groups 
Ca(OH)2 Propolis

14th day 28th day 14th day 28th day

Positive 
Control

14th day 0,037*  0,000*  

28th day  0,004*  0,000*

Ca(OH)2 14
th day -  0,000*  

28th day  -  0,000*

* p< 0,05 = there was signficant difference

Table 3. Independent t-test result of odontoblast-like cells 
thickness on the 14th and 28th day

Groups
Positive Control 

28th day
Ca(OH)2 
28th day

Propolis 
28th day

Positive Control 
14th day

0,010*   

Ca(OH)2 
14th day

 0,017*  

Propolis 
14th day

  0,030*

* p< 0,05 = there was signficant difference

Kruskall-wallis revealed that there was significant 
difference in the thickness of odontoblast-like cells after 
14 days and 28 days of treatment (p<0,05) on Table 1. 
Independent t-test revealed that there was significant 
difference (p<0,05) between Ca(OH)2 groups and propolis 
extract groups. 

Table 2 shows that on the 14th day, there was significant 
difference (p<0,05) between the three groups (positive 
control group, Ca(OH)2 group, and propolis extract group). 
The thickness of odontoblast-like cells in positive control 
group was thinner than the propolis extract group. The 
significant difference was also found between Ca(OH)2 
group and propolis extract group, it shows that the thickness 
of odontoblast-like cells in Ca(OH)2 group was thinner than 
the propolis extract group 

Independent t-test revealed that on the 28th day, there 
was significant difference (p<0,05) between the three 
groups (positive control group, Ca(OH)2 group, and 
propolis extract group). The thickness of odontoblast-like 
cells in positive control group was thinner than the Ca(OH)2 
group and propolis extract group. The significant difference 
was also found between Ca(OH)2 group and propolis extract 
group, it shows that the thickness of odontoblast-like cells 
in Ca(OH)2 group was thinner than the propolis extract 
group. 

Table 3 shows that there were significant differences 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v49.i1.p17-21



20 Dwiandhono, et al./Dent. J. (Majalah Kedokteran Gigi) 2016 March; 49(1): 17–21

the type I collagen and dentin matrix protein (DMP1), as 
well as an increase in activity of alkaline phospatase (ALP). 
Increased ALP activity stimulates the release of minerals 
from the cell to start mineralization, then the process of 
mineral formation occurs. The hydroxy-apatite deposite and 
merge into collagen matrix in mineralization process. The 
sythesis of DMP1 increases, interact with type 1 collagen 
to form a sequence and undergo mineralization, and the 
reparative dentin formation occurs.15

The results of this study showed that the dead 
odontobloast was only found below the perforated area. 
In the intact dentin at the edge of the perforated area the 
damaged odontoblast was found. The growth area of the 
odontoblast-like cells was presumably derived from the 
differentiation process of fibroblasts in the pulp tissue. 
There are three possible sources of forming odontoblast-
like cells. First, odontoblast-like cells formed by progenitor 
cells of odontoblast, known as undifferentiated mesenchym. 
These cells are located in the cell-rich zone of Hohl. Second, 
odontoblast-like cells derived from pulp fibroblasts, as 
fibroblasts belongs to stable cell that can differentiate when 
there is injury or stimuli. The third is the de-differentiation 
of odontoblasts. Although odontoblasts belongs to 
postmitosis, but the possibility of differentiation is still 
open even if it’s small.16 

All primary odontoblasts is an irreversible injury 
in the area of perforation. Post-mitotic, a terminal 
cell differentiation can not proliferate to replace dead 
or damaged odontoblasts. As the result, this primary 
odontoblasts should be replaced by a new generation of 
cell odontoblast-like cells. New odontoblast-like cells 
proliferate from other pulp cells and migrate to perforated 
area, the place where the reparative dentin secreted. 
Progenitor cells of new odontoblast-like cells assumed as 
cells from the subodontoblast layer or pulp fibroblasts.17 

In the de-differentiation process, the odontoblast cell 
is not turned young and pluripotent, but still unipotent 
and just divide from the cell with the same structure and 
function with the related cell. There are two mechanisms 
of reparative dentinogenesis. First, the direct differentiation 
induced by dentin matrix, and second, the odontoblast-like 
cells differentiation through fibrodentin matrix that acts as 
the basal lamina for the differentiation of odontoblast-like 
cells for tooth repair.18,19

The thickness of the odontoblast-like cells layer in 
Ca(OH)2 group in 14th and 28th day is thinner than the 
propolis extract’s. The high pH (12.5) of calcium hydroxide 
suspensions causes liquefaction necrosis at the surface of 
the pulp tissue, causing coagulation necrosis in the area 
between necrotic pulp and vital pulp. When the pure form 
of Ca(OH)2 is applied on the pulp, it actually will destroy 
some of the pulp’s tissue, causing a persistent inflammation. 
Moleculary, the calcium ions released by Ca(OH)2 
stimulates the synthesis of fibronectin and glycoproteins 
tenascin in dental pulp, triggering differentiation of dental 
pulp cells into cells forming minerals that are the main cells 

to form dentin bridge. Ca(OH)2 also stimulates the release 
of adrenomedullin and TGF-β1 of human dentin matrix, 
both are pluripotent growth factors.4,16

Propolis extract has known to have antibacterial activity, 
anti-inflammatory, antioxidant and immunomodulator. 
The prevention of infection and the promotion of cell 
regeneration ease the the healing process in the dental 
pulp that begins with the collagen fibers formation.7 
Flavonoids and caffeic acid in propolis extract can reduce 
the inflammatory response by inhibiting arachidonic acid 
lipoxygenase pathway. As antibacterial agent, propolis 
destroys the bacteria’s cell wall and prevents bacterial cell 
division.

Propolis extract was more effective to form dentin 
compared to calcium hydroxide or zinc oxide. 7,20 Propolis 
extract inhibits the translation of NFkβ into the nucleus to 
prevent the apoptosis. The inhibition of apoptosis result in 
prevention of drastic decreasing amount of fibroblast in 
the pulp and activation of NFkβ. The activation of NFkβ 
inhibits the transcription of genes that secrete TNF-α. 

The increase of TGF-β1 expression is a host defense 
mechanism. Dentin formation after pulp capping involves 
differentiation of odontoblast-like cells that form reparative 
dentin and the biosynthetic activity of the components 
around the primary odontoblast. It requires an interaction 
between extra cellular matrix molecules and TGF-β1, which 
is a growth factor that is known to play an important role 
in the differentiation of odontoblast-like cells.

Propolis extract enhances the formation of odontoblast-
like cells and stimulates the production of TGF-β1.7 TGF-
β1 stimulatesthe proliferation of fibroblasts, a fibrogenic 
substance that stimulates the fibroblasts chemotaxis 
to increase the formation of collagen, fibronectin, and 
proteoglycans.21 

This ability of propolis extract to inhibit inflammation, 
suppress apoptosis, stimulates the production of TGF-β1 
and differentiation of fibroblasts explains the result of this 
study, where the thickness of odontoblast-like cells layer 
in perforated rat’s pulp after the application of propolis 
extract is significantly thicker than the calcium hydroxide 
group. The conclusion, the propolis extract as the direct 
pulp capping agent produces thicker odontoblast-like cell 
layer compared to Ca(OH)2. 

REFERENCES

 1. Torabinejad M, Walton RE. Endodontics: principles and practice. 
4th ed. Missouri: Saunders; 2009. p. 9-14.

 2. Hargreaves KM, Berman LH, Cohen S. Cohen’s pathways of the 
pulp expert consult. 10th ed. St. Louis: Mosby; 2011. p. 490, 518, 
626, 812.

 3. Willershausen B, Willershausen I, Ross A, Velikonja S, Kasaj A, 
Blettner M. Retrospective study on direct pulp capping with calcium 
hydroxide. Quintessence Int 2011; 42(2): 165-71.

 4. Janebodin K, Horst OV, Osathanon T. Dental pulp response to pulp 
capping materials and bioactive molecules. CU Dent J 2010; 33: 
229-48.

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v49.i1.p17-21



2121Dwiandhono, et al./Dent. J. (Majalah Kedokteran Gigi) 2016 March; 49(1): 17–21

 5. Bankova V, Castro SD, Marcucci M. Propolis: recent advances in 
chemistry and plant origin. Apidologie, Springer Verlag 2000; 31(1): 
3–15.

 6. Almas K, Dahlan A, Mahmoud A. Propolis as a natural remedy: an 
update. Saudi Dent J 2001; 13(1): 45-9.

 7. Sabir A, Tabbu CR, Agustiono P, Sosroseno W. Histological analysis 
of rat dental pulp tissue capped with propolis. J Oral Sci 2005; 47(3): 
135-8.

 8. Parolia A, Thomas MS, Kundabala M, Mohan M. Propolis and its 
potential uses in oral health. Int J Med Med Sci 2010; 2(7): 210-5.

 9. Asgary S, Eghbal MJ, Parirokh M, Ghanavati F, Rahimi H. A 
comparative study of histologic response to different pulp capping 
materials and a novel endodontic cement. Oral Surg Oral Med Oral 
Pathol Oral Radiol Endod 2008; 106(4): 609-14.

 10. Tziafas D, Smith AJ, Lesot H. Designing new treatment strategies 
in vital pulp therapy. J Dent 2000; 28(2): 77-92.

 11. Hargreaves KM, Goodis HE. Seltzer and Bender’s dental pulp. 
Hanover Park: Quintessence Publishing Co, Inc; 2002. p. 247-79.

 12. About I, Bottero MJ, de Denato P, Camps J, Franquin JC, Mitsiadis 
TA. Human dentin production in vitro. Exp Cell Res 2000; 258(1): 
33-41.

 13. Sloan AJ, Perry H, Matthews JB, Smith AJ. Transforming growth 
factor-beta isoform expression in mature human healthy and carious 
molar teeth. Histochem J 2000; 32(4): 247-52.

 14. Shirakawa M, Shiba H, Nakanishi K, Ogawa T, Okamoto H, Noshiro 
M, Kato Y. Transforming growth factor-beta-1 reduces alkaline 
phosphatase mRNA and activity and stimulates cell proliferation 
in cultures of human pulp cells. J Dent Res 1994; 73(9): 1509-14.

 15. Widjiastuti I, Yuanita T, Hutagalung J, Rukmo M, Safitri I. 2014. East 
java propolis inhibits cytokine pro-inflammatory in odontoblast-like 
cells human pulp. Journal of Agricultural Science and Technology 
A 2014; 4(1): 27-32.

 16. Kunarti S. Pulp tissue inflammation and angiogenesis after pulp 
capping with transforming growth factor β1. Dent J (Majalah 
Kedokteran Gigi) 2008; 41(2): 88-90.

 17. Murray PE, Windsor LJ, Smyth TW, Hafez AA, Cox CF. Analysis 
of pulpal reactions to restorative procedures, material, pulp capping, 
and future therapies. Crit Rev Oral Biol Med 2002; 13(6): 509-20.

 18. Yatim W. Biologi sel lanjut. Bandung: Tarsito; 2003. p. 1-84.
 19. Goldberg M, Smith AJ. Cell and extracellular matrices of dentin 

and pulp: a biological basis for repair and tissue engineering. Crit 
Rev Oral Biol Med 2004; 15(1): 13-27.

 20. Ahangari Z, Naseri M, Jalili M, Mansouri Y, Mashhadiabbas F, 
Torkaman A. Effect of propolis on dentin regeneration and the 
potential role of dental pulp stem cell in Guinea pigs. Cell J 2012; 
13(4): 223-8.

 21. Kumar, Abbas, Fausto. Robbins & Cotran Dasar Patologis Penyakit. 
7th ed. Jakarta: EGC; 2010. p. 101.

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v49.i1.p17-21