138

Research Report

Dental Journal
(Majalah Kedokteran Gigi)
2017 September; 50(3): 138–143

Grafting effectiveness of Anadara granosa shell combined with 
sardinella longiseps gel on the number of osteoblast-osteoclast 
cells

Eddy Hermanto,1 Rima Parwati Sari,2 Asri Cahyadita Dwi Imaniar,1 and Kevin Anggoro1
1Department of Oral Surgery
2Department of Oral Biology
Faculty of Dentistry, Universitas Hang Tuah
Surabaya - Indonesia

abstract

Background: Bone grafts derived from Anadara granosa shells contain calcium carbonate that possesses bone-healing properties. 
The combination of Sardinella Longiceps fish oil, containing EPA and DHA, and Anadara granosa shells was assumed to regulate 
the number of osteoblasts-osteoclasts during the bone-healing process. Purpose: This study aimed to determine the effectiveness of 
Anadara granosa shell grafts, combined with Sardinella Longiceps fish oil, in the bone-healing process by observing the ratio of 
osteoblasts-osteoclasts in Rattus novergicus rats. Methods: The Wistar rat subjects (n = 25) were divided into five groups, namely: 
one untreated group (control), one group treated with bone grafts derived from Anadara granosa shells (P1), and the other three 
groups treated with a combination of Anadara granosa shells and Sardinella longiceps fish oil at concentrations of 10%, 20%, and 
30% (P2, P3, and P4). Then, a wound equivalent in size to half the diameter of a round bur (±1.5mm) was intentionally inflicted on 
the right femur of all the subjects. The rats were subsequently sacrificed on day 14, their femur in the transversal side being cut before 
HE staining was completed. Thereafter, the ratio of osteoblasts to osteoclasts was measured by means of a light microscopy. The data 
was subsequently analyzed using one-way ANOVA. Results: The average number of osteoblasts in all research groups increased, viz: 
9.420±0.8044 for control group (K), 12.080±0.79811 for group P1, 20.020±0.7190 for group P2, 25.940±0.7197 for group P3, and 
36.280±0.9985 for group P4. Similarly, the number of osteoclasts in all groups subject to analysis also increased, namely: 1.73±0.098 
for group K, 2.19±0.305 for group P1, 1.60±0.088 for group P2, 1.60±0.724 for group P3, and 1.80±1.302 for group P4. Moreover, 
the results of the One-way Anova test confirmed that there were no significant differences in osteoclasts between all research groups 
(p>0.05). The results of the one-way ANOVA and LSD tests confirmed there to be significant differences (p <0.05) between group K 
and other treatment groups (P1, P2, P3, and P4). Conclusion: The grafts derived from the combination of Anadara granosa shells 
and Sardinella longiceps gel can induce the production of osteoblasts, but not in the numbers necessary during the healing processin 
the femurs in Rattus novergicus rats. 

Keywords: Bone graft; Anadara granosa; Sardinella longiceps; osteoblasts; osteoclasts

Correspondence: Eddy Hermanto, Department of Oral Surgery, Faculty of Dentistry, Universitas Hang Tuah. Jl. Arif Rahman Hakim 
no. 150 Surabaya 60111, Indonesia. E-mail: eddyhermanto_tarka@yahoo.com

introduction

In dentistry, the main causes of bone damage are 
predominantly those of tooth extraction (90%), trauma, and 
conditions, such as cysts or tumors affecting the jaw. Post-
extraction, the alveolar bone will undergo an anatomical 
change in its shape involving several stages. This condition 

can, in turn, cause the jawbone to shrink and become thin 
and brittle, thus facilitating fractures, reducing the success 
of other dental treatments, and decreasing the function of 
mastication and food digestion.1,2

Damage to the alveolar bone is a post-tooth extraction 
complication potentially impacting negatively on an 
individual’s health, while also having an undesirable 

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.v50.i3.p138-143

mailto:eddyhermanto_tarka@yahoo.com
http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v50.i3.p138-143


139139Hermanto, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 September; 50(3): 138–143

aesthetic effect. The damage can, nevertheless, be corrected 
by bone grafts that serve to restore the contours of bones 
or stimulate the formation of new bone. Bone grafting is a 
surgical procedure whereby missing bone is replaced with 
substitutes either taken from the patient’s own body or 
which are artificial, synthetic or naturally occurring. Bone 
grafting is feasible since bone tissue demonstrates the ability 
to regenerate effectively, given the availability of space 
for bone growth. Bone formation can then occur owing 
to several factors influencing the acceleration of healing. 
Bone graft is one option to precipitate the bone healing 
process, incorporating the use of a material that promotes 
reconstruction, stabilizes the structure and bonding of 
bones, and stimulates the process of osteogenesis and the 
healing of large bone defects.3–5

The bone graft material normally utilised is derived 
from non-metallic synthetic materials obtainable from 
ceramic materials (potassium), composites, and polymers. 
This material must be biocompatible and osteoconductive 
and can also be fused with bone, thereby enhancing the 
bone regeneration process.4 In general, bone grafts can 
be classified into four common types, namely: autograft, 
allograft, xenograft, and alloplast. Xenograft involves 
the use of bone derived from donors drawn from species 
other than that of the recipient, such as Anadara granosa 
shells.5 

Anadara granosa shell is of a type commonly 
found in both East and Southeast Asia and contains red 
blood pigment/hemoglobin enabling the shell to exist 
in conditions with relatively low levels of oxygen.6,7 
Anadara granosa shell is also classified as a mineral since 
biopolymer composites consist of between 95% and 99% 
CaCO3 in the form of aragonite crystals.

8 Unfortunately, 
Anadara granosa shells are relatively little used, usually 
being thrown away and allowed to break up naturally.

In addition, according to previous research, the presence 
of nano-calcium carbonate (CaCO3) crystals derived from 
shells can be used in bone tissue engineering since they 
possess the potential to mimic the original composition, 
structure, and bone properties.9 The investigation referred 
to also showed that an increase in osteogenic activity of 
alkaline phosphatase may accelerate the differentiation of 
mesenchymal stem cells. Therefore, the activity of alkaline 
phosphatase is considered to be an indicator, or bone 
marker, that signifies the presence of mineralized bone and 
promotes the formation of HA in osteoblast matrix vesicles 
by releasing it into the extracellular matrix and increasing 
osteoblast cell differentiation. Subsequently, calcium 
carbonate stimulates macrophages in areas containing 
defects, with the macrophages, together with inflammatory 
cells, strengthening angiogenesis processes.10

On the other hand, fish oil is rich in omega-3 
polyunsaturated fatty acid (PUFA), composed of 
eicosapentaenoid acid (EPA) and docohexaenoic acid 
(DHA), which plays an important role in maintaining 
human health.11 Similarly, Sardinella longiceps fish oil 
contains n-3 PUFA, 13.70% (EPA), and 8.91% DHA.12 

The high levels of EPA and DHA contained in Sardinella 
longiceps fish oil possess the potential to regulate the 
formation and activity of osteoblasts and osteoclasts. 
Meanwhile, omega-3 PUFA has the ability to act as a 
vasoconstrictor and platelet aggregation secreting growth 
factors, such as VEGF, that directly affect the formation 
of new blood vessels.13 Previous research confirmed that 
omega-3 PUFA is also able to increase mediators of bone 
and tooth formation.14 

The study reported here aimed to evaluate the 
effectiveness of bone graft derived from a combination of 
Anadara granosa shells and Sardinella longiceps fish oil 
gel by measuring the number of osteoblasts and osteoclasts 
during the bone healing process in animal subjects.

materials dan method

The research was truly experimental in character with a 
completely randomized design. Thus, animal subjects used 
in both the control and treatment groups were randomly 
selected and consisted of two-month old, male Wistar rats 
weighing between 150 and 357 grams. The total number 
of animal subjects used as samples was 25, divided into 
five groups. The research was then conducted following 
approval from the Ethical Commission for Animal Subjects 
Faculty of Dentistry, Universitas Hang Tuah, Surabaya 
No.193/KEPK/IX/2016.

The bone graft was prepared by collecting, boiling 
and cleaning Anadara granosa shells taken from seaweed 
waste.15 The shell powder was then sterilized by the 
application of gamma-ray radiation at BATAN’s Jakarta 
laboratory. Thereafter, 0.2 grams of Sardinella longiceps 
fish oil was mixed with 2 ml of 10% gelatin to produce 
10% Sardinella longiceps gel. In addition to producing 
Sardinella longiceps gel at concentrations of 20% and 30%, 
0.4 grams and 0.6 grams of Sardinella longiceps fish oil 
were mixed with 2 ml of 10% gelatin.

The experimental procedure which the animal subjects 
underwent began with seven days of acclimatization. The 
Wistar rats were then divided into five groups, namely: 
one group not receiving treatment (control/K), one group 
treated with bone grafts derived from Anadara granosa 
shells (P1), and the other three groups administered a 
combination of Anadara granosa shells and Sardinella 
longiceps fish oil at concentrations of 10%, 20%, and 30% 
(P2, P3, and P4) respectively. Following the acclimatization 
process, surgery was performed on the dextral side of the 
subjects’ femurs along the lines of the procedure performed 
by Fleckhell.16 

The Wistar rats were anesthetized by the administering 
of ketamine and xylazine intramuscularly at a dose of 0.11 
mL/100 gr BM.17 Once unconscious, subjects’ fur in the 
area where the defect had been induced was shaved using a 
Gillete razor. 10% povidine iodine was applied to the area 
for five minutes as an antiseptic.18 A two-centimetre long 
incision was made using a One Med Indonesia surgical 

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.v50.i3.p138-143

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v50.i3.p138-143


140 Hermanto, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 September; 50(3): 138–143

knife, before the removal of soft tissue (skin and muscle) 
by means of an Osung periosteal elevator. Defects as deep 
as a half the diameter of the bur (1.5mm) were produced on 
the dextral and lateral areas of the femur using a German-
made, size 18, Mcisinger® round bur, together with a 
straight hand piece. After defects in the femur had formed, 
all research groups received different types of treatment. 
Then, the application of membrane was performed. Each 
surgical procedure invariably culminated in suturing to 
close skin wounds and cover soft tissue.19 The subsequent 
administering of novalgin consisted of a dose 0.09 cc/200 
gr BM, before the antibiotic interflox was given as a dose 
of 0.1 cc/100 gr BM for three days. In short, this procedure 
was usually required in order to control inflammation and 
pain.20

At this point, the rats were euthanized using ether before 
their femur was taken from the dextral side on day 14.17 The 
femur specimens collected were hulled in order to access 
the bone after grafting by cutting it with a separating disc, 
and then inserting it into 10% formalin buffer solution. 
This was intended to keep the tissue from decomposing 
and hardening, as well as to increase the affinity of the 
tissue against the paint.19 After the process of tissue 
fixation, a decalcification process was induced by means of 
administering ethylene diamine tetra acid (EDTA) over two 
months. The femur specimens collected were then subjected 
to sagittal piece preparations before haematoxylin eosin 
(HE) staining was carried out. Thereafter, the number of 
osteoblasts and osteoclasts in the defect areas was measured 
with a light microscope (Olympus® CX21, Japan) at 400X 
magnification. The data obtained was analyzed to obtain 
details of data distribution and data summary in order to 
clarify the results. The hypothesis was then tested using 
a parametric statistical test, a one-way ANOVA test and, 
finally, a least significance difference (LSD) test.

results

Clinically, the defects in the dextral and lateral sides of 
the femurs of Group P1 subjects were slightly closed due to 
a less than optimal process of bone formation. There were 

also significant differences in the number of osteoblasts 
between group P1 and groups P2, P3, and P4. group P1 had 
fewer osteoblasts than groups P2, P3, and P4. 

The histological features indicated significant differences 
in the number of osteoblasts and osteoclasts located at the 
defect sites in all research groups (Figures 1 and 2). The 
results also revealed that the average number of osteoblasts 
in all research groups increased, viz: 9.420 ± 0.8044 for 
group K, 12.080 ± 0.79811 for group P1, 20.020 ± 0.7190 
for group P2, 25.940 ± 0.7197 for group P3 and 36.280 
± 0.9985 for group P4. Similarly, the average number 
of osteoclasts in all research groups also increased, 1.73 
± 0.10 for group K, 2.19 ± 0.305 for group P1, 1.60 ± 
0.09 for group P2, 1.60 ± 0.07 for group P3, and 1.80 ± 
0.302 for group P4. Moreover, the results illustrated the 
morphologies of osteoblasts and osteoclasts in the defect 
sites of all research groups. 

In Figure 2, the lowest number of osteoblasts was 
found in group K, while the highest was that of group 
P3. Similarly, the average number of osteoclasts showed 
almost the same results. Furthermore, the statistical test 
results using SPSS 18.0 confirmed the data as being both 
normally distributed (p>0.05) and homogeneous (p=0.324) 
with a significance level of 0.05. Furthermore, the one-way 
ANOVA test results indicated a significant difference in 
the presence of osteoblast indicators, but not those of the 
osteoclast variety. Another further statistical test, a LSD 
test, was then performed in order to compare osteoblast 
indicators between one group and another (Table 1). The 

Figure 1. The histologic features of osteoblasts in each research group.

Note: K (negative control), P1 (group with the administration of calcium powder derived from Anadara granosa shells), P2 (group 
with the administration of HA powder derived from Anadara granosa shells and 10% Sardinella longiceps fish oil), P3 (group with 
the administration of HA powder derived from Anadara granosa shells and oil 20% Sardinella longiceps fish oil), and P4 (group with 
the administration of HA powder derived from Anadara granosa shells and 30% sardinella longiceps fish oil). Yellow arrows indicate 
the presence of osteoblasts, while osteoclasts are indicated by green arrows.

Figure 2. The average number of osteoblasts and osteoclasts in 
each research group (n=5).

Osteoblast Osteoclast

K P1 P3P2 P4

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.v50.i3.p138-143

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v50.i3.p138-143


141141Hermanto, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 September; 50(3): 138–143

results of this LSD assay showed that there were significant 
differences between one group and another (p<0.05).

discussion

Anadara granosa shells combined with Sardinella 
longiceps gel at concentrations of 10% and 30% did not 
effectively induce osteoblast proliferation, although at these 
concentrations there was a tendency to increase osteoblast 
proliferation.20 Therefore, this research used Sardinella 
longiceps fish oil of 10% and 30% concentrations as a 
reference, while also employing the gel form to improve 
the attachment of the test materials to bone defects.

The animal subjects used in this research were Wistar 
rats since they not only possessed certain characteristics 
relatively similar to those of humans but also demonstrated 
similarities to the physiological aspects of human 
metabolism.21 This research specifically used Wistar rat 
femurs since they possess a trabecular bone formation that 
is well developed in the cortical bone. This is identical 
to the alveolar bone in Wistar rats, allowing it to be used 
as a model to study the regeneration of the jawbone.22 

Furthermore, male Wistar rats were selected as samples for 
this research based on the consideration of their lacking or 
having relatively little estrogen, as well as their enjoying 
more stable hormonal conditions. Stress levels in females 
are also known to be higher than those of males.23 Besides, 
the effects of estrogen in suppressing osteoclastic activity 
are known to occur indirectly through their action on 
osteoblastic receptors. One of the cytokines produced by 
osteoblasts, transfoming growth factor-β (TGF-β), can even 
be suppressed by estrogen. In fact, TGF-ß plays a role in 
osteoclast differentiation.24

The normal bone healing process begins with 
inflammation since the cells of first defense, such as 

leukocytes, lymphocytes, monocytes, and macrophages 
are activated. Macrophages are phagocytic cells 
produced in bone marrow that play an important role in 
inflammation, while they also remove cytokines consisting 
of proinflammatory, anti-inflammatory, and growth factors. 
The macrophages will then trigger the secretion of pro-
inflammatory cytokines, such as tumor necrosis factor 
(TNF), interleukin-1 (IL-1), and interleukin-6 (IL-6) as 
inflammatory mediators to strengthen the immune response 
and increase metabolic processes.25 The presence of 
proinflammatory cytokines will, as a result, increase the 
production of preosteoclasts so that receptor activator of 
nuclear factor kappa (RANK) are also widely produced. 
RANK will subsequently bind to receptor activators of 
nuclear factor kappa ligand (RANKL), thus inducing 
osteoclasts to increase bone damage.26

The proliferative or reparative phase begins when the 
inflammatory phase releases the cytokines and growth 
factors, resulting in the proliferation of fibroblasts to 
form extracellular matrix and calcium salts through an 
attachment, thus forming a woven bone.27 This can be seen 
in group K, a group with normal bone healing process, 
in which the osteoblasts remained visible, although 
without any treatment. Osteoblasts are known not only 
to take various forms, from cuboid to cylindrical within 
the basophil cytoplasm, but also to be visible around the 
osteoidous layer where new bone is formed. Meanwhile, 
the osteoclasts are known to have very large branched 
shapes with multiple cores.28 In group K, defects were not 
clinically closed since the process of bone formation was 
undetected.

On the other hand, group P1 was a group given bone 
grafts derived from Anadara granosa shells containing 
calcium carbonate. This material was expected to accelerate 
the bone healing process since calcium carbonate serves 
as a skeleton in bone formation, improves the wound 
healing process and acts as a mineral reservoir that helps 
in new bone formation.29 Bone grafts derived from 
Anadara granosa shells is beneficial in the treatment of 
bone defects.29 The structure of Anadara granosa shells 
is generally similar to cancellous bone and demonstrates 
bone-like mechanical properties. The shells are also known 
to contain high concentrations of calcium carbonate which 
has biocompatible, osteoconductive, and biodegrable 
properties. Moreover, the shells act as an adequate carrier 
for growth factors and enable cell attachment, cell growth, 
cell spread, and cell differentiation.30 However, Anadara 
granosa shell powder can trigger an inflammatory response 
and increase the number of osteoclasts. Therefore, group 
P1 had a higher number of osteoblasts compared to that of 
group K (Table 1). Nevertheless, the number of osteoclasts 
in group P1 tended to be descriptively higher than in group 
K, although there was no statistically significant difference 
(p>0.05).

Group P1 was treated only with bone graft derived 
from shells in the form of a brittle powder. This made it 
rather difficult for bone to be formed based on the required 

Table 1. Results of the Post-Hoc LSD test for osteoblast

Average
Mean difference (I-J) P valvue

Group (I) Group (J)

K 

P1 -2.3400* .048

P2 -11.2800* .000

P3 -16.2000* .000

P4 -26.5400* .000

P1

P2 -8.9400* .000

P3 -13.8600* .000

P4 -24.2000* .000

P2
P3 -4.9200* .000

P4 -15.2600* .000

P3 P4 -10.3400* .000

Note: This table shows the comparison of the mean number of 
osteoblasts between groups. The average number of osteoblasts 
in group P> group K. The higher the concentration of group P, 
the greater the average number of osteoblasts.

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.v50.i3.p138-143

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v50.i3.p138-143


142 Hermanto, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 September; 50(3): 138–143

substituting graft material. The powder used for the graft 
on the damaged bone usually suffers from weakness that 
does not promote stable grown as a graft.31

Furthermore, groups P2, P3, and P4 were given bone 
grafts at concentrations of 10%, 20% and 30%, derived 
from a combination of Anadara granosa shells containing 
calcium carbonate and Sardinella longiceps gel containing 
omega-3. Anadara granosa shells, can be selected as bone 
replacement biomaterials since they are known to contain 
calcium carbonate compounds.31 CaCO3 crystals derived 
from shellfish can facilitate osteoblast proliferation, 
differentiation and adhesion. The osteogenic activity of 
alkali phosphatase can also be enhanced by CaCO3 crystals. 
Increased osteogenic activity of alkali phosphatase can then 
increase the differentiation of mesenchymal cells.9 

Sardinella longiceps fish oil contains 12.5% n-3 PUFAs. 
n-3 PUFAs consist of EPA and DHA and are capable of 
producing resolvin that can serve as an anti-inflammatory 
mediator.32 Resolvin promotes the elimination of 
inflammation by creating a macrophage 2 (M2) phenotype 
which releases high levels of IL-10 inhibiting TNFα, 
IL-6, and IL-1.32 These proinflammatory cytokines then 
trigger the formation of RANKL in osteoblasts that can 
bind to RANK in the pre-osteoclast to differentiate into 
osteoclasts.33 As proinflammatory cytokines decrease, the 
number of osteoclasts is also expected to decline, while that 
of osteoblasts is anticipated to increase. Proinflammatory 
cytokines can directly stimulate osteoblast apoptosis 
and its precursors, or do so indirectly by stimulating Fas 
expression of potential proapoptotic mediators.33 The bone 
graft used in this research was derived from a combination 
of Anadara granosa shells and Sardinella longiceps gel of 
three different concentrations in order to determine the most 
effective in the bone healing process. Although within the 
investigation reported here the number of osteoclasts in all 
research groups was largely similar, the results of the one-
way ANOVA test highlighted a significant difference in the 
number of osteoblasts. This suggests that osteoclasts might 
be used as the only indicator. Therefore, the osteoblast-
osteoclast ratio needs to be monitored during the healing 
process since it is considered an appropriate indicator of 
healing or bone formation.34

From a clinical perspective, in groups P2, P3, and P4 
the defects were effectively, although not optimally, closed. 
Closure defects were due to the administration of bone grafts 
derived from the combination of Anadara granosa shells 
and Sardinella longiceps fish oil gel. Effective material 
attachment to the defects was usually expected to accelerate 
the bone healing process.35 Thus, the provision of bone graft 
derived from the combination of Anadara granosa shells 
and Sardinella longiceps gel in this research was expected 
to accelerate the healing process since it could serve as a 
scaffold for new bone formation.35 The stimulation of bone 
grafts was then expected to improve the cellular biology 
activity by analyzing the osteoclast ratio (Figure 2). During 
the bone healing process, bone graft usually stimulates 

and triggers osteoblast proliferation, before migrating 
to the defect site.33 It can be concluded that bone grafts 
derived from the combination of Anadara granosa shells 
and Sardinella longiceps gel can successfully generate 
osteoblasts and osteoclasts indicating a more effective 
healing process. The most effective concentration of 
Sardinella longiceps gel used was 30%.

references

 1.  Hamzah Z, Kar tikasari N. Pencabutan gigi yang ir rasional 
mempercepat penurunan struktur anatomis dan fungsi tulang 
alveolar. Stomatognatic. 2015; 12(2): 61–6. 

 2.  Mezzomo LA, Shinkai RS, Mardas N, Donos N. Alveolar ridge 
preservation after dental extraction and before implant placement: 
a literature review. Rev Odonto Ciência. 2011; 26(1): 77–83. 

 3.  Kumar P, Vinitha B, Fathima G. Bone grafts in dentistry. J Pharm 
Bioallied Sci. 2013; 5(Suppl 1): S125-7. 

 4.  Ardhiyanto HB. Peran hidroksiapatit sebagai bone graft dalam proses 
penyembuhan tulang. Stomatognatic. 2011; 8(2): 118–21. 

 5.  Amini AR, Laurencin CT, Nukavarapu SP. Bone tissue engineering: 
recent advances and challenges. Crit Rev Biomed Eng. 2012; 40(5): 
363–408. 

 6.  Haslaniza H, Maskat MY, Wan Aida WM, Mamot S, Saadiah I. 
Optimization of enzymatic hydrolysis of cockle (Anadara Granosa) 
meat wash water precipitate for the development of seafood flavor. 
Int Food Res J. 2013; 20(6): 3053–9. 

 7.  Arita S, Adipati AS, Sari DP. Pembuatan katalis heterogen dari 
cangkang kerang darah (Anadara Granosa) dan diaplikasikan pada 
reaksi transesterifikasi dari crude palm oil. J Teknik Kimia. 2014; 
20(3): 31–7. 

 8.  Saryati, Giat S, Handayani A, Supardi, Untoro P, Sugeng B. 
Hidroksiapatit berpori dari kulit kerang. J Sains Materi Indonesia. 
2012; Edisi Khus(Desember): 31–5. 

 9.  Kamba AS, Zakaria ZAB. Osteoblasts growth behaviour on bio-
based calcium carbonate aragonite nanocrystal. Biomed Res Int. 
2014; 2014: 215097. 

10.  Mu r phy W L , Si m mons CA, K a igler D, Mooney DJ. Bone 
regeneration via a mineral substrate and induced angiogenesis. J 
Dent Res. 2004; 83(3): 204–10. 

11.  Pike IH, Jackson A. Fish oil: production and use now and in the 
future. Lipid Technol. 2010; 22(3): 59–61. 

12.  Udari AHGS, Wickramasinghe I, Attygalle MVE. Effects of 
cooking on Omega 3 content of Sardinella longiceps emphasizing 
an innovative method to elevate Omega 3 intake. Int J Innov Res 
Technol. 2015; 2(3): 68–75. 

13.  Wang W, Zhu J, Lyu F, Panigrahy D, Ferrara KW, Hammock B, 
Zhang G. ω-3 polyunsaturated fatty acids-derived lipid metabolites 
on angiogenesis, inflammation and cancer. Prostaglandins Other 
Lipid Mediat. 2014; 113–115: 13–20. 

14.  McMahon MS. Beneficial effect of Omega-3 fatty acids on bone 
metabolism. Orthopedics. 2012; 35(9): 735–6. 

15.  Li Y, Chen S-K, Li L, Qin L, Wang X-L, Lai Y-X. Bone defect animal 
models for testing efficacy of bone substitute biomaterials. J Orthop 
Transl. 2015; 3(3): 95–104. 

16.  Rokn AR, Khodadoostan MA, Reza Rasouli Ghahroudi AA, 
Motahhary P, Kharrazi Fard MJ, Bruyn H De, Afzalifar R, Soolar 
E, Soolari A. Bone formation with two types of grafting materials: 
a histologic and histomorphometric study. Open Dent J. 2011; 5: 
96–104. 

17.  Kopschina MI, Marinowic DR, Klein CP, Araujo CA, Freitas TA, 
Hoff G, da Silva JB. Effect of bone marrow mononuclear cells plus 
platelet-rich plasma in femoral bone repair model in rats. Brazilian 
J Vet Res Anim Sci. 2012; 49(3): 179–84. 

18.  Schmidlin PR, Nicholls F, Kruse A, Zwahlen RA, Weber FE. 
Evaluation of moldable, in situ hardening calcium phosphate bone 
graft substitutes. Clin Oral Implants Res. 2013; 24(2): 149–57. 

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.v50.i3.p138-143

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v50.i3.p138-143


143143Hermanto, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 September; 50(3): 138–143

19.  Ridwan E. Etika pemanfaatan hewan percobaan dalam penelitian 
kesehatan. J Indones Med Assos. 2013; 63(3): 112–6. 

20.  Sari RP, Wahjuningsih E, Soeweondo IK. Modulation of FGF2 after 
topical application of Stichopus hermanii gel on traumatic ulcer in 
Wistar rats. Dent J (Maj Ked Gigi). 2014; 47(3): 126–9. 

21.  Sihombing I, Wangko S, Kalangi SJR. Peran estrogen pada 
remodeling tulang. J Biomedik. 2012; 4(3): S18-28. 

22.  Bronner F, Farach-Carson MC, Rubin JE. Bone resorption. London: 
Springer; 2005. p. 17. 

23.  Sultani M, Stringer AM, Bowen JM, Gibson RJ. Anti-inflammatory 
cytokines: important immunoregulatory factors contributing to 
chemotherapy-induced gastrointestinal mucositis. Chemother Res 
Pract. 2012; 2012: 490804. 

24.  Sfeir C, Ho L, Doll BA, Azari K, Hollinger JO. Fracture repair. In: 
Lieberman JR, Friedlaender GE, editors. Bone regeneration and 
repair : biology and clinical applications. Totowa: Humana Press; 
2005. p. 21–30. 

25.  Mao T, Kamakshi V. Bone grafts and bone substitutes. Int J Pharm 
Pharm Sci. 2014; 6(2): 88–91. 

26.  Mescher AL. Histologi dasar Junqueira: teks & atlas. 12th ed. 
Jakarta: EGC; 2012. p. 118-128. 

27.  Bharatham H, Zakaria MZAB, Perimal EK, Yusof LM, Hamid M. 
Mineral and physiochemical evaluation of Cockle shell (Anadara 
granosa) and other selected Molluscan shell as potential biomaterials. 
Sains Malaysiana. 2014; 43(7): 1023–9. 

28.  Suhendi A, Nurca hya nti, Muhtadi, Sutr isna EM. A ktivitas 
antihiperurisemia ekstrak air jinten hitam (Coleus ambonicus Lour) 
pada mencit jantan galur balb-c dan standardisasinya. Majalah 
Farmasi Indonesia. 2011; 22(2): 77–84. 

29.  Hazmi AJA, Zuki ABZ, Noordin MM, Jalila A, Norimah Y. Mineral 
composition of the cockle (Anadara granosa) shells of West Coast 
of Peninsular Malaysia and it’s potential as biomaterial for use in 
bone repair. J Anim Vet Adv. 2007; 6(5): 591–4. 

30.  Warastuti Y, Abbas B. Sintesis dan karakterisasi pasta injectable 
bone substitute iradiasi berbasis hidroksiapatit. J Ilmiah Aplikasi 
Isotop dan Radiasi. 2011; 7(2): 73–95. 

31.  Asakura T, Koyanagi R, Nishiyama N, Kuboyama N, Kiba H, Abiko 
Y. Bone regeneration on the epicondyle of the femur supported by 
silk fibroin-based scaffold: a model system for dental surgery. J 
Insect Biotechnol Sericology. 2011; 80: 25–30. 

32.  I nda hya n i DE. Minya k i ka n L emur u (Sa rdinella longicep) 
menurunkan apoptosis osteoblas pada tulang alveolaris tikus wistar 
(Fish oil of Lemuru (Sardinella longicep) reduced the osteoblast 
apoptosis in wistar rat alveolar bone). Dent J (Maj Ked Gigi). 2013; 
46(4): 185–8. 

33.  Asami A, Nakamura M, Takeuchi M, Nakayama A, Nakamura H, 
Yoshida T, Nagasawa S, Hiraoka BY, Ito M, Udagawa N, Miyazawa 
H. Effects of heat treatment of hydroxyapatite on osteoblast 
differentiation. J Hard Tissue Biol. 2008; 17(2): 37–46. 

34.  Teti A. Mechanisms of osteoclast-dependent bone formation. 
Bonekey Rep. 2013; 2: 1–6. 

35.  Sari RP, Hermanto E, Divilia D, Candra I, Kuncoro W, Liswanti T. 
Effects of Anadara granosa shell combined with Sardinella longiceps 
oil on oesteoblast proliferation in bone defect healing process. Dent 
J (Maj Ked Gigi). 2016; 49(1): 27–31. 

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.v50.i3.p138-143

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v50.i3.p138-143