Vol 49 No 1 Jan-Mrt 2016.indd


2727

Research Report

Dental Journal
(Majalah Kedokteran Gigi)

2016 March; 49(1): 28–32

Effects of Anadara granosa shell combined with Sardinella 
longiceps oil on oesteoblast proliferation in bone defect healing 
process

Rima Parwati Sari,1 Eddy Hermanto,2 Dinda Divilia,1 Indira Candra,1 Wisnu Kuncoro,1 and Tantri Liswanti1
1Department of Oral Biology
2Department of Oral Surgery
Faculty of Dentistry, Universitas Hang Tuah
Surabaya - Indonesia

ABSTRACT

Background: Alveolar bone damage is the most common case in dentistry. One way to fix the bone damage is by using bone 
graft. Anadara granosa shell is a potential bone substitute since it is rich in calcium which can be processed into hydroxyapatite. The 
addition of Sardinella longiceps oil rich in omega-3 can modulate inflammation, thus accelerating the healing process. Purpose: 
This study aimed to determine effects of application of Anadara granosa shell combined with Sardinella longiceps oil on osteoblast 
proliferation in the healing process of bone defects. Method: The subjects were 32 male rats type Wistar divided into 4 groups (n = 
8). Making defect was performed on the right bone of the femurs with a half of the diameter of round Mcisinger® Germany bur sized 
18. The first group (K) is a negative control group that was not given anything. The second group (AG) was given Anadara granosa 
pasta. The third group (AM10) was given Anadara granosa pasta combined with 10% Sardinella longiceps oil. And, the fourth group 
(AM30) was given Anadara granosa pasta combined with 30% Sardinella longiceps oil. Next, preparations and animal euthanasia were 
performed on the 7th day after the treatment. The number of osteoblasts then was measured after making preparations for HPA with 
Hematoxylin eosin staining (HE). Afterward, tabulation of data followed by statistical analysis of Anova and HSD Tukey was carried 
out. Result: The average number of osteoblasts in Groups K, AG, AM10, and AM30 was 19.00, 34.63, 33.50, and 38.50. The results 
of Anova test showed a significant difference (p<0.05). Similarly, the results of Tukey-HSD test also showed significant differences (p 
<0.05) between Group K and all other groups (AG, AM10, and AM30). Nevertheless, there were no significant differences between 
Group AG and Groups AM10 and AM30, as well as between Group AM10 and Group AM30. Conclusion: The application of the 
combination of Anadara granosa shell and Sardinella longiceps oil can not increase the proliferation of osteoblasts in the healing 
process of bone defects. 

Keywords: Anadara granosa; sardinella longiceps oil; bone graft; osteoblasts; bone healing

Correspondence: Rima Parvati Sari, Department of Oral Biology, Faculty of Dentistry, Universitas Hang Tuah. Jl. Arif Rahman Hakim 
No. 150 Surabaya 60111, Indonesia. E-mail: rimaparwatisari@gmail.com

INTRODUCTION

Bone damage usually can occur because of trauma, 
tumor, congenital abnormalities, infection, inadequate 
prosthesis, and systemic disease.1 In dentistry, alveolar 
bone damage as the highest prevalence of bone damage 
is commonly caused by periodontal disease. Periodontal 
disease is an oral and dental problem with the prevalence 
of the disease reached 96.58% in Indonesia.2 In addition, 

complications after tooth extraction due to sizeable trauma 
can cause damage to the alveolar bone.3

Naturally, abnormal condition can occur in the body. 
For instance, bone defects can be cured by mechanical 
balance in the body. This process is known as bone healing. 
The process of bone healing plays an important role after 
the treatment in dentistry.4 Generally, bone healing requires 
a long period to get back on the normal state.5 The bone 
tissue healing process is generally the same as wound 

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.p27-31



28 Sari, et al./Dent. J. (Majalah Kedokteran Gigi) 2016 March; 49(1): 27–31

healing process in soft tissue, but the difference is related 
to physiological ability to repair the hard tissues during the 
healing process.6

The bone healing process begins with the formation of 
hematoma and the response of inflammatory cells lasting 
for 24-48 hours followed by reparative phase occurred in 
the first few days before the inflammation is reduced, and 
then last for several weeks, resulting in the development of 
tissue repair. In this phase, pluripotential mesenchymal cells 
start to form other cells, such as fibroblasts, chondroblasts, 
and osteoblasts.5

Osteoblast activity appears first at reparative phase. 
Osteoblasts will be seen in the cortex of the bone, a few 
millimeters from the defect area.7 Osteoblasts function as 
the main cells in the bone healing process. Osteoblasts 
then will produce, secrete, depose, and mineralize bone 
matrix.8 Based on these functions, it is necessary to increase 
the activity of osteoblasts to accelerate the bone healing 
process. A small number of osteoblastic activities occur 
continuously in all the living bone tissue (about 4 percent 
of all the bone surfaces in adults at various times), resulting 
in the least number of new bone formed constantly.9

Bone formation, moreover, can occur due to several 
factors affecting the acceleration of healing process, such 
as use of bone graft. Bone graft has been widely used as 
a substituting bone material, especially in periodontal 
therapy.10 Graft tissue including bone, has been widely 
used until now. In general, there are two main functions 
of bone graft for recipients’ bone, namely to encourage 
osteogenesis (bone formation) and to provide mechanical 
support in the framework of the recipients.11

Bone graft, furthermore, is used to stimulate bone 
healing and stabilize the dimensions of the alveolar bone 
in the field of dentistry.12 Bone graft is also considered as 
an appropriate action to increase the height of the alveolar 
crest, remodel jawbone, transfer microvascular free tissue, 
and reshape the alveolar crest.13

In addition, xenograft is one form of bone grafts that 
has biocompatible properties in humans and has higher 
osteoconductive properties than alloplast. Additionally, 
xenograft can provide a suitable medium for osteogenesis 
by bone marrow cells.14 Currently, xenograft materials 
widely used are derived from bone bovine.

The main compound used in bone graft is calcium 
phosphate as the major component of bone mineral 
constituent. The calcium phosphate compound is an 
inorganic material that has bioactive and biocompatible 
properties. Calcium phosphate compound used as bone 
graft can be in a crystalline phase or in an amorphous 
phase, namely tricalcium phosphate (Ca3 (PO4) 2) and 
hydroxyapatite (CA10 (PO4) 6OH2).15 The form of the 
most stable calcium phosphate is hydroxyapatite (HA). 
HA is not only considered as a bioactive ceramic material 
with high bioaffinity as well as non-corrosive, non-toxic 
and biocompatible properties to the human body, but also 
as one of the calcium phosphate crystals that give the tough 
nature in bone.16

One of the natural ingredients found as a valuable 
economic resource, which generally has not been utilized 
is Anadara granosa. Anadara granosa is mostly used as 
food rich in protein. Meanwhile, the shell is discarded 
into the waste. Several researches actually have been 
conducted to increase the additional value of Anadara 
granosa. For instance, Anadara granosa shells containing 
a lot of calcium are used for bone healing process. Anadara 
granosa shells also contain other minerals, such as CaC 
(98.7%), Mg (0.05%), Na (0.9%), P (0.02%) and other 
elements (0.2%).1

Similarly, a research conducted by Hafisko et al.18 
showed that Anadara granosa shells contains CaCO3 that 
can be converted into more biocompatible hydroxyapatite 
compounds than calcium carbonate alone, so the process 
is more osteoconductive conditioned by inducing BMP-2. 
BMP-2 can increase the differentiation of periosteal 
cells, derivatives of mesenchymal stem cell (MSC) in the 
formation of chondroblasts and osteoblas.19 Thus, the use 
of HA bone graft can effectively improve bone healing.

Another stimulus to accelerate the bone healing process 
is omega-3. Some studies suggest that omega-3 can 
reduce the production of proinflammatory cytokines and 
eicosanoids by inhibiting the metabolism of arachidonic 
acid (AA), the substrates of eicosanoids (prostaglandin). 
Omega-3 may also alter the inflammatory gene expression 
through transcription factor activity, therefore, omega-3 can 
be potentially considered as anti-inflammatory.20

High omega-3 diet, lead to an increase in both activity 
of serum isoenzyme of alkaline phosphatase (ALP), 
an enzyme marker of osteoblast activity, and activity 
of osteoblasts.21 High omega-3 diet can also lower the 
production of prostaglandin E2 (PGE2).22 PGE2 and 
proinflammatory cytokines are mediators which play an 
important role for the occurrence of bone resorption. High 
omega-3 diet, consequently, can result in a decrease in the 
formation and activity of osteoclasts, which serve to bone 
resorption.23 

Fish species in Indonesia mostly consisted of fish oil 
is Sardinella longiceps. Fish oil derived from Sardinella 
longiceps contains a lot of omega-3, namely 13.70% 
eicosapentaenoic acid (EPA) and 8.91% docosahexaenoic 
acid (DHA). Sardinella longiceps is a type of pelagic fish 
(containing oil) distributed in all waters in Indonesia. The 
largest number of Sardinella longiceps is found in the Strait 
of Bali, around Muncar near Banyuwangi (East Java).24 

The use of Sardinella longiceps oil as a therapy in 
wound healing has already been proven by Wijaya25 who 
observed the healing of cut wound in Wistar rats using 
ointment of Sardinella longiceps oil as the test material. 
The research also shows that at concentrations of 10%, 
Sardinella longiceps oil can make cut wound cover 100% 
within 7 days. Finally, based on the description above, 
this research aimed to to know effects of application of 
Anadara granosa shell combined with Sardinella longiceps 
oil on osteoblast proliferation in the healing process of 
bone defects.

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.p27-31



2929Sari, et al./Dent. J. (Majalah Kedokteran Gigi) 2016 March; 49(1): 27–31

MATERIALS AND METHOD

This research was a true experimental research with 
completely randomized design. It means that the control 
group and the selection of experimental animals in the 
treatment groups were randomly conducted. Experimental 
animals used in this research were 32 male rats aged 5 
months old and weighed 200-250 grams.

Tools used in this research, moreover, were animal 
cages, storage tubes for femurs’ right bones, scissors, 
scalpels, anatomical tweezers, resparatorium, scales for 
animals, food and beverage, microtome for cutting, light 
microscopy, glass objects, glass cover, bottles, shelves 
for painting, syringes 3cc, round bur (straight and piece) 
of Mcisinger® Germany sized 18, micromotor 1200 rpm, 
fur shaver, probe for eating, dappen Glass, as well as 
separating disc. Meanwhile, materials used were Anadara 
granosa powder processed by Hafisko et al. with Nano 
size.18 Sardinella longiceps oil processing in Banyuwangi, 
membranes, sewing silk thread, needles, cotton or tissue, rat 
food, distilled water to drink those rats replaced every today, 
10% buffered formalin, ketamine hydrochloride, xylazine 
hydrochloride, 10% povidine iodine, 30%, 50%, 70%, 80%, 
and 96% alcohol, novalgin, as well as 10% EDTA.

Before conducting the research, Anadara granosa 
shell pasta (AG), a combination of Anadara granosa and 
10% Sardinella longiceps oil (AM10), and a combination 
of Anadara granosa and 30% Sardinella longiceps oil 
(AM30) were made. AG shell pasta was made from 5 grams 
of Anadara granosa shell powder mixed with glycerin to 
obtain 1 ml of pasta. The pasta was mixed and condensed 
until well blended and homogeneous, and viscosity values 
obtained were quite thick, so easy to apply. Preparations 
of AM10 and AM30 then were made by mixing 5 grams of 
Anadara granosa powder, 0.1 ml and 0.3 ml of Sardinella 
longiceps oil, and glycerin to obtain 1 ml of pasta. 

All those rats were acclimatized for one week. They 
were kept in cages with a size of 40 cm (L) x 30 cm (L) 
x 14cm (T). Afterwards, they were divided into 4 groups, 
namely the negative control group (C), the group AG using 
Anadara granosa pasta, the group AM10 using Anadara 
granosa pasta combined with Sardinella longiceps oil 
10%, and the group AM30 using Anadara granosa pasta 
combined with Sardinella longiceps oil 30%. Each group 
consisted of 3-4 rats. Then those were given food in a small 
container every morning, afternoon, and evening, while 
drink was supplied in bottles of 300 ml equipped with a 
small pipe filled with cooked water (Ad libitum).

Bone defects then were performed on the femurs’ right 
bone with the following procedure. First, anesthetics was 
performed using 1 mL of ketamine mixed with 0.5 mL 
of xylazine, then injected with a dose of 1.5 mL / 100 g 
BM on the femurs’ right bone intramuscularly.26 Second, 
after they began to be unconscious, fur in part to be done 
the defect was sheared. Third, 10% povidine iodine was 
applied on the area around the defect for five minutes.27 
Fourth, the soft tissue (skin and muscle) around the defect 

area was incised about 2 cm using a scalpel and removed 
using a periosteal elevator. After finding femurs’ right 
bone, a hole defect then was made using bone bur (straight 
and piece) sized half of the diameter of round Mcisinger® 
Germany bur sized 18.

In the first group, the holes then were not given any 
materials because it was used as a negative control (C). In 
the second group, the holes were given Anadara granosa 
pasta (AG). In the third group, the holes were given AM10, 
while in the fourth group, the holes were given AM30. After 
filling, the holes were covered with membrane materials and 
sewed to cover the soft tissue and the skin on the femurs’ 
right bone, so the graft materials would not be wasted (out 
of the defect areas). 28 Analgesics then was given one hour 
after the surgery, ie novalgin® at a dose of 175 mg / kg 
dissolved in saline to control swelling and pain.29

Afterward, making preparations and animal euthanasia 
were performed on the 7th day after the treatment. Those 
rats were sacrificed first with ether, and the tissues of the 
femurs’ right bone were removed. The tissues then were 
peeled to take the bone part after bone grafting by cutting 
with a separating disc, and put in 10% buffered formalin 
solution so that the tissues would not be rot and hard, 
and the affinity values of tissue against staining material 
increased.27 After tissue fixation process, decalcification 
process was conducted using EDTA for 2 months. 
Specimens of the femurs were made in the form of a 
sagittal slice preparation with HE staining. The number 
of osteoblasts in the defect areas then was observed using 
light microscope with a magnification of 400x. Next, the 
acquired data were tabulated. And, several statistical tests 
were performed using a parametric test, oneway Anova 
test, followed by Tukey-HSD test. 

RESULTS

The results of the histological examination showed that 
there were osteoblasts in the defect areas of all the research 
groups (Figure 1). The calculation results, moreover, 
showed that the average number of osteoblasts in group K 
was 19.00 ± 1.74, in group AG was 34.63 ± 1.94, in group 
AM10 was 33.50 ± 2.94, while in group AM30 was 38.50 
± 2.28. Figure 2 shows that the lowest average of osteoblast 
count was found in the control group, while the highest 
average of osteoblast count was found in group AM30.

The results of the statistical test using SPSS 18.0, 
moreover, indicated that the data were normally distributed 
with (p> 0.05) and homogeneous (p = 0.324). The results of 
the statistical test using one way Anova test, furthermore, 
showed that there was a significant difference. Another 
statistical test, Tukey-HSD test, was then performed to 
compare one group to another group.

In addition, the results of Tukey HSD test showed 
that there was a significant difference between group K 
and the treatment groups using bone graft. There was no 
significant difference between group AG and both group 

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.p27-31



30 Sari, et al./Dent. J. (Majalah Kedokteran Gigi) 2016 March; 49(1): 27–31

AM10 and group AM30 as well as between group AM 10 
and group AM30.

DISCUSSION

Animals used in his research were male Wistar rats 
since there is no hormonal influence that can affect 
healing mechanisms. Decalcification process in Wistar 
rats is faster than in other experimental animals. A rat 
femur also has certain characteristics that are relatively 
similar to humans, for instance, histologically epicondyle 
of the femurs has trabecular bone growing well below the 
cortical bone, resulting in providing a substantial model for 
dentistry.30, 31

Moreover, improvements in bone defect healing process 
involve a complex physiological sequence. Once damage 
occurs, hematoma will appear around the site of trauma 
triggering fibrous tissues to form a lesion area and to 
develop into callus.32 In some ways, the bone will activate 
all intraosseous and periosteum osteoblasts maximally in 
the defect areas. Number of new osteoblasts are formed 
from progenitor cells as bone stem cells in the surface of 
the tissue covering the bones, called as bone membrane.9

Bone graft as a substituting bone material actually 
has been widely used because of its osteoconductive 
properties.10 Contribution of the graft begins during the 
osteoconductive process, namely to make framework as 
the bone matrix in the recipient tissue. This is followed 
by stimulation of bone formation during bone healing.11 

Hydroxyapatite possess good biocompatibility and 
bioactivity. Continually, HA will improve osteoconductive 

process. The use of HA bone graft can effectively improve 
bone healing caused by bone defect. The addition of HA 
bone graft can also attach bioactivity and osteoconductivity 
in making improvements during the mineral phase.33

Based on crystallography and chemical properties, HA 
approaches bone structure, thus providing an inorganic 
component in the form of crystalline hydroxyapatite 
together with sodium, magnesium, carbonate, and structural 
skeleton.34 Similarly, the results of this research showed a 
significant difference between the negative control and the 
treatment groups AG, AM10, and AM30.

Omega-3 is one of eicosanoids rich in eicosapentaenoic 
acid (EPA) and docosahexaenoic acid (DHA). EPA and 
DHA play a role in generating Resolvins and related 
compounds, such as protectins through pathways that involve 
cyclooxygenase and lipoxygenase enzymes. Resolvin E1, 
resolvin D1, and D1 protectin inhibit transendothelial 
migration of neutrophils, thereby preventing the infiltration 
of neutrophils at sites of inflammation. Resolvin D1 inhibits 
the production of IL-1β, while protectin D1 inhibit the 
production of TNF and IL-1β. Therefore, resolvins and 
related compounds play a very important role in stopping 
the ongoing inflammatory process and in limiting tissue 
damage. 

In addition, EPA and DHA in Sardinella longiceps 
oil can also inhibit inflammatory mediators, such as IL-6, 
IL-8, and TNF-α. Sardinella longiceps oil actually can 
decrease the activation of NFκB more than corn oil.35 
Decreasing in inflammation products can reduce the ratio of 
RANKL/OPG. OPG protects bone skeleton by preventing 
bond between RANKL and RANK as pre osteoclast 
receptors, thereby suppressing the formation of osteoclasts 

 
Figure 1. Histological results of osteoblasts in each group.

Group C (negative control), group AG using Anadara granosa 
pasta, group AM10 using Anadara granosa pasta combined with 
Sardinella longiceps oil 10%, and group AM30 using Anadara 
granosa pasta combined with Sardinella longiceps oil 30%. The 
presence of osteoblasts was indicated by green arrows.

C

Figure 2. The average number of osteoblasts in each group

Table 2. The results of Tukey-HSD test

Group AG AM10 AM30

C .030* .049* .005*

AG - 0.997 .883

AM10 - - .781

Control

34.625 33.5
38.5

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.p27-31



3131Sari, et al./Dent. J. (Majalah Kedokteran Gigi) 2016 March; 49(1): 27–31

and activating more osteoblasts then leading to new bone 
formation.36 

Although there was statistically no significant 
difference, the average number of osteoblasts in the groups 
using the combination of Anadara granosa shell pasta 
and Sardinella longiceps oil was higher than in the group 
using Anadara granosa shell powder only. This may be 
due to the non-optimal physicochemical and biomaterial 
properties of the preparation materials used. Thus, further 
researches need to be improve bone graft preparations. 
The tendency of increase in the number of osteoblasts with 
higher concentration may be the reason for increasing the 
concentration of Sardinella longiceps oil added to Anadara 
granosa shell powder. Finally, it can be concluded that the 
application of a combination of Anadara granosa shell and 
Sardinella longiceps oil can not increase the proliferation 
of osteoblasts in the healing process of bone defects.

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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.p27-31