119119

Dental Journal
(Majalah Kedokteran Gigi)
2021 September; 54(3): 119–123

Original article

Evaluation of osteogenic properties after application of 
hydroxyapatite-based shells of Portunus pelagicus

Michael Josef Kridanto Kamadjaja, Alya Nisrina Sajidah Gatia, Agtadilla Novitananda, Lintang Maudina, Harry Laksono, Agus Dahlan, Bambang 
Agustono Satmoko Tumali and Muhammad Dimas Aditya Ari
Department of Prosthodontics, Faculty of Dental Medicine, Universitas Airlangga, Surabaya, Indonesia 

ABSTRACT
Background: After tooth extraction, the socket leaves a defect on the alveolar bone. The administration of shell crab-derived 
hydroxyapatite maintains bone dimensions that are important for achieving successful prosthodontic treatment. Purpose: The aim of the 
study was to determine the osteogenic properties, such as the number of osteoclasts, osteoblasts and osteocytes, after the application of 
hydroxyapatite-based shell crab in the post-extraction sockets of Wistar rats. Methods: There were two groups: the control group (K) 
and the treatment group (T). Wistar rats were randomly divided into control and treatment groups. After tooth extraction, hydroxyapatite 
gel derived from Portunus pelagicus shells was applied to the tooth sockets of Wistar rats. Observations and calculations of osteoclasts, 
osteoblasts and osteocytes were carried out on the 14th and 28th days under a light microscope with 400 times magnification. Statistical 
analysis was performed using one-way ANOVA. Results: There was a significant difference (p<0.05) between the K14 and P14 groups, 
K28 and P28 groups, K14 and K28 groups, and P14 and P28 groups. The results indicated that there were significant differences 
between groups of variables. Conclusion: The application of shell crab-derived hydroxyapatite (Portunus pelagicus) was able to 
decrease the number of osteoclasts and increase the number of osteoblasts and osteocytes.

Keywords: hydroxyapatite; Portunus pelagicus; osteoblasts; osteoclasts; osteocytes

Correspondence: Michael Josef Kridanto Kamadjaja, Department of Prosthodontics, Faculty of Dental Medicine, Universitas Airlangga. 
Jl. Mayjen Prof. Dr. Moestopo 47, Surabaya 60132 Indonesia. Email: michael-j-k-k@fkg.unair.ac.id. 

INTRODUCTION

Tooth extraction is the process of removing the tooth 
from the alveolar bone when teeth are unable to withstand 
further treatment.1 The post-extraction socket healing 
process leaves an alveolar defect. Along with the growth 
of bone in post-extraction sockets, there is also a process 
of resorption on the alveolar ridge.2 There is a decrease 
in the buccolingual dimensions, as well as a decrease in 
the apicoronal dimensions of the alveolar ridge, as is often 
found after tooth extraction.3 Reduction of the alveolar 
ridge can interfere with prosthodontic treatment. Resorption 
can lead to a loss of aesthetic and function, which can be 
harmful when paired with dental implants, especially in 
the anterior maxilla.4

Bone resorption after tooth extraction would cause 
difficulties for implant placement. This can be overcome 
by preserving the socket. There are several methods that 

can be used to minimise the occurrence of bone resorption. 
Among them is the use of demineralised freeze-dried bone 
allograft (DFDBA), Bioglass and hydroxyapatite (HA), 
which has been used in the form of both a resorbable and 
non-resorbable membrane.5 

Calcium phosphate bioceramics, such as HA, are 
popular materials for bone reconstruction.6 HA bioceramic 
materials form up to 70% of bone structure. HA can be  
produced synthetically from chemical reagents or can be 
synthesised from natural resources through hydrothermal 
transformation and the high-temperature calcination of 
bones.7 Raw HA biomaterials are easily available and are 
abundant in Indonesia. Among the abundant raw materials is 
shell crab, which is one of Indonesia’s export commodities. 
Indonesia exports 604,215–625,000 tons of crab without 
shells per year.8 Flower crabs (Portunus pelagicus) has been 
a mainstay of Indonesia’s export commodities to various 
countries around the world.8 Crab shells contain calcium 

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 https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i3.p119–123

mailto:michael-j-k-k@fkg.unair.ac.id
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120 Kamadjaja et al./Dent. J. (Majalah Kedokteran Gigi) 2021 September; 54(3): 119–123

carbonate (CaCO3), which can be processed further into 
HA [CA5(PO4)3(OH)]. HA’s structure is identical to that of 
human bone, which renders it a potential source of synthetic 
bone for bone grafts. In the field of dentistry, bone grafts 
are used to increase the alveolar ridge height, remodel the 
jawbone, transfer tissue free of microvascular problems 
and re-establish the alveolar crest.8

HA has osteoconductive properties and can stimulate 
mesenchymal cells to proliferate and differentiate in the 
bone regeneration process. Porous HA forms a strong 
bond between the bones, accelerating the process of 
vascularisation. The porosity of the bone graft increases 
the osteoconductive properties and the colonisation of 
osteoblasts, facilitates the penetration of osteoblast cells and 
provides a medium for osteoblasts to attach to.9 Osteoblasts 
and osteocytes secrete osteoprotegerin (OPG), which acts 
as a binder for the RANKL receptor and decreases the 
differentiation of osteoclasts.10 OPG has been shown to 
function as an inhibiting factor for osteoclastogenesis in 
vivo and in vitro.11 This study aimed to determine the effect 
of HA crab shell on the number of osteoclasts, osteoblasts 
and osteocytes in the tooth sockets of Wistar rats. 

MATERIALS AND METHODS

This study was approved by the Institutional Health 
Research Ethical Clearance Commission with certificate 
number 177/HRECC.FODM/VII/2018. An HA powder 
was made from crab shell by soaking the shell in water 
(ratio 3:20) for 15 minutes. The powder was immersed 
in chlorine and dissolved in water (10 ml of chlorine was 
used for 20 litres of water). It was soaked for 5 minutes. 
The calcination process was carried out by heating the 
material in a furnace at an initial temperature of ± 50°C, 
which slowly increased by 5°C/minute until the temperature 
reached 1000°C. It was maintained at this temperature for 
two hours. The HA powder was made into a gel by adding 
carrageenan powder and water with a ratio of 6:3:2, then 
mixed and heated slowly at 70°C for 10 minutes to form 
a gel compound.

The experimental subjects were 36 Wistar rats divided 
into four subgroups. Each group consisted of nine Wistar 
rats: control group at 14 days (K14), control group at 28 
days (K28), treatment group at 14 days (P14) and treatment 
group at 28 days (P28). The rats were sedated with 10% 
ether. Each had its mandibula left incisor extracted using 
sterile forceps. For the treatment groups, HA gel was 
applied to the sockets, which were then sutured with silk 
thread 3/0. Meanwhile, the sockets of the control groups 
were sutured without the application of HA gel.

All the Wistar rats were sacrificed on the 14th and 
28th days. Rats were euthanised using ketamine at a lethal 
dose (66–88 mg/kg of body weight). The mandible was 
cut and immersed in a 10% formaldehyde solution for 
at least 24 hours. Decalcification was performed using 
ethylenediaminetetraacetic acid. The tissue then underwent 
dehydration and was stored at 60°C for some time before 
being submerged in liquid paraffin. The paraffin blocks 
containing tissue were then cut using a microtome machine 
(3–4µm). 

The slices of tissue were then inserted into a water 
bath (30–40°C). The tissue pieces were carefully attached 
to a glass object and 1–2 drops of albumin were added to 
the tops of the tissue pieces. After that, the glass object 
was heated with a hot plate at a temperature of 30–40°C. 
Haematoxylin and eosin staining was then used to measure 
the number of osteoclasts, osteoblasts and osteocytes. This 
observation was carried out under a light microscope with 
400 times magnification. Statistical analysis was performed 
using one-way ANOVA with a p value of <0.05. 

RESULTS

The measurements of the osteoblasts, osteoclasts and 
osteocytes on the 14th and 28th days from all groups can be 
seen in Figure 1. Histological imaging of the osteoblasts, 
osteoclasts and osteocytes can be seen in Figures 2, 3 and 4. 
The data was analysed using the Kolmogorov-Smirnov test 
and Levene’s test, and the results showed that the data were 
normally distributed (p>0.05) and homogenous (p>0.05).

0

2

4

6

8

10

12

14

16

18

Control 14 day Treatment 14 day Control 28 day Treatment 28 day

M
ea

n

Osteoclasts Osteoblasts Osteocytes

 

Number of cells

Figure 1. Diagram of the mean number of osteoclasts, osteoblasts and osteocytes from the control and treatment groups.

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 https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i3.p119–123

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121Kamadjaja et al./Dent. J. (Majalah Kedokteran Gigi) 2021 September; 54(3): 119–123

 

 

A B

C D

Figure 2. A histological view of the osteoclasts on the 14th (A) and 28th (B) days of the control group and the 14th (C) and 28th (D) 
days of the treatment group.

 A B 

C D 

Figure 3. A histological view of the osteoblasts on the 14th (A) and 28th (B) days of the control group and the 14th (C) and 28th (D) 
days of the treatment group.

 

 
 

A B 

C D 

 Figure 4. A histological view of the osteocytes on the 14th (A) and 28th (B) days of the control group and the 14th (C) and 28th (D)
days of the treatment group.

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 https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i3.p119–123

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122 Kamadjaja et al./Dent. J. (Majalah Kedokteran Gigi) 2021 September; 54(3): 119–123

After the homogeneity test was carried out, a significance 
test was conducted using the one-way ANOVA test. The 
results showed that there were significant differences 
between groups of variables (p<0.05). A post hoc Tukey 
test was also conducted to determine the significance of 
the number of osteoclasts, osteoblasts and osteocytes in 
each study group. The significant differences between each 
group can be seen in Table 1.

DISCUSSION

Tooth extraction is the most common procedure in the field 
of dentistry. The response to the body’s normal healing 
process after tooth extraction often causes significant bone 
resorption.12 After tooth extraction, the alveolar bone is 
gradually absorbed by the body. Then, a remodelling process 
occurs, which results in a decrease in the dimensions of the 
alveolar bone. The vertical plane decreases and tends to be 
more palatal than its original position.13

The bone remodelling process consists of several 
phases, beginning with the activation phase. The activation 
phase involves the recruitment and activation of osteoclast 
monocyte-macrophage precursors from the circulation, 
resulting in the interaction of osteoclast precursor cells and 
osteoblasts. Then, during the resorption phase, osteoclasts 
begin to dissolve the mineral matrix and decompose the 
osteoid matrix.12 The resorption phase is dominated by 
osteoclasts. Next comes the recovery phase, in which the 
transition from bone resorption to bone formation occurs. 
Bone absorbed in the resorption phase contains various 
mononuclear cells, including monocytes, osteocytes 
released from the bone matrix and preosteoblasts, which 
function to begin the process of new bone formation. In the 
formation phase, osteoblast cells are released on the surface 
to begin bone formation.13 The process is completed by the 
mineralisation phase, which begins 30 days after osteoid 
deposition.14 

To maximise bone regeneration after tooth extraction 
and minimise the occurrence of bone resorption, the socket 
is filled with bone graft material. When filling the socket, 
actions that could cause trauma to the bone should be 
avoided, thereby reducing the occurrence of buccal, lingual 
and ridge alveolar resorption.12

Calcium phosphate bioceramics, such as HA, are 
popular materials for bone reconstruction. Bioceramic 
HA material forms up to 70% of the bone structure. HA 

is effectively used to replace part or all of the bone tissue. 
It can be used as a bone filling material. HA can produce 
a physicochemical interaction between ceramics and bone 
tissue, thus encouraging the binding and growth of new 
tissue.15

The HA in this study was made from crab shell, which 
was first made into a HA powder using a furnace, then 
converted into a crab shell-based HA gel. The crab shell-
based HA gel used in this study contained 87.11% HA.

The results showed a significant difference in the number 
of osteoclasts on the 14th and 28th days. This was because, 
on the 14th day, the resorption phase was dominated by 
osteoclasts. Osteoclasts need 2–4 weeks for the remodelling 
cycle to complete bone resorption. Meanwhile, on the 28th 
day, there was a decrease in the number of osteoclasts due 
to the commencement of the initial stage of the recovery 
phase. It was found that the number of osteoclasts on day 
14 was higher than the number of osteoclasts on day 28 
in both the control groups and the treatment groups. The 
results also showed that there was a decrease in the number 
of osteoclasts in the treatment group when compared with 
the number of osteoclasts in the control group on the 14th 
and 28th days. This indicates that the administration of crab 
shell-based HA can reduce the number of osteoclasts in 
sockets after extraction. 

The number of osteoblasts in P14 and P28 was higher 
than the number of osteoblasts in K14 and K28. No 
significant differences were found between P14 and P28. 
This is because, on the 28th day, an insignificant number 
of osteoblasts were formed due to the continuation of 
osteoblast cells in the maturation phase forming osteocytes 
for apoptosis.16

Figure 1 also shows that there were significant 
differences between K14 and P14 and K28 and P28. This 
is because HA gel can trigger osteocytes to differentiate, so 
there is an increase in the number of osteocytes. However, 
the differences were only significant between the K14 
and P14; the differences between K28 and P28 were not 
significant. This was due to osteocyte apoptosis occurring 
after a period of 10 to 14 days. Osteocyte apoptosis plays 
a key role in activating the bone remodelling mechanism.17 
Although the P28 showed the highest number of osteocytes, 
maximum cell growth actually occurred before the 28th 
day. Thus, the number of osteocytes did not increase 
much between days 14 and 28. This is because crab 
shell-based HA has osteoconductive and osteoinductive 
properties, facilitating the growth of new bone tissue in 
the gap between mineral particles in HA. Adding crab 
shell-based HA particles can significantly reduce the 
number of osteoclasts. The formation of an apatite layer 
on the surface of a biomaterial has the ability to bind living 
bones. The potential for the osteoinductive properties of HA 
has been confirmed in previous studies. Furthermore, the 
administration of HA is found to deposit a higher number 
of collagen fibres around the HA particles.18

HA can bind to bone tissue and provide a specific 
biological response that can stimulate osteoblast cells to form 

Table 1. This data represents the p value between each group 
of all-day treatment. All groups showed significant 
differences (p<0.05)

K14 K28 P14 P28
K14 0.044 0.000 0.000
K28 0.024 0.000
P14 0.024
P28

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 https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i3.p119–123

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123Kamadjaja et al./Dent. J. (Majalah Kedokteran Gigi) 2021 September; 54(3): 119–123

new bone tissue and help the bone regeneration process.18 
Combined with osteoconduction, it can increase osteoblast 
attachment. The activation of osteoblasts and osteocytes 
can produce OPG.19 OPG is one of the main factors in 
regulating osteoclast differentiation. OPG is found to inhibit 
the spontaneous induction of bone absorption.20 OPG is a 
feed receptor for RANKL and competes with RANK to bind 
RANKL. As a result, OPG can be an effective inhibitor for 
osteoclast cell maturation and osteoclast cell activation. 
When the bone resorption phase by osteoclasts is complete, 
the resorbed bone cavity contains various mononuclear 
cells, including monocytes, osteocytes released from the 
bone matrix and preosteoblasts, which function to initiate 
new bone formation. In conclusion, the administration of 
HA-based shell crab to Wistar rats after tooth extraction can 
reduce the number of osteoclasts and increase the number 
of osteoblasts and osteocytes.

REFERENCES

 1.  Pedersen GW. Buku ajar praktis bedah mulut. 4th ed. Jakarta: EGC; 
2013. p. 36. 

 2.  Alani AFI. Multiple techniques have been proposed to preserve 
alveolar bone after tooth loss. Ann Med Health Sci Res. 2018; 8(1): 
65–8. 

 3.  Hansson S, Halldin A. Alveolar ridge resorption after tooth 
extraction: a consequence of a fundamental principle of bone 
physiology. J Dent Biomech. 2012; 3: 1–8. 

 4.  van Heerden P. Treatment concepts for socket grafting. Int Dent – 
African Ed. 2012; 2(1): 70–4. 

 5.  Kim Y-K, Yun P-Y, Um I-W, Lee H-J, Yi Y-J, Bae J-H, Lee J. Alveolar 
ridge preservation of an extraction socket using autogenous tooth 
bone graft material for implant site development: prospective case 
series. J Adv Prosthodont. 2014; 6(6): 521–7. 

 6.  Ari MDA, Yuliati A, Rahayu RP, Saraswati D. The differences 
scaffold composition in pore size and hydrophobicity properties 
as bone regeneration biomaterial. J Int Dent Med Res. 2018; 11(1): 
318–22. 

 7.  Komur B, Altun E, Aydogdu MO, Bilgiç D, Gokce H, Ekren N, 
Salman S, Inan AT, Oktar FN, Gunduz O. Hydroxyapatite synthesis 
from fish bones: Atlantic salmon (Salmon salar). Acta Phys Pol A. 
2017; 131(3): 400–2. 

 8.  Raya I, Mayasari E, Yahya A, Syahrul M, Latunra AI. Shynthesis 
and characterizations of calcium hydroxyapatite derived from 
crabs shells (Portunus pelagicus) and its potency in safeguard                                   
against to dental demineralizations. Int J Biomater. 2015; 2015: 
469176. 

 9.  Ardhiyanto HB. Stimulasi osteoblas oleh hidroksiapatit sebagai 
material bone graft pada proses penyembuhan tulang. Stomatognatic 
(J K G Unej). 2012; 9(3): 162–4. 

10.  Smith SY, Varela A, Samadfam R. Bone Toxicology. New York: 
Spinger; 2017. p. 27–93. 

11.  Jana S, Shah R, Thomas R, Kumar ABT, Mehta DS. Techniques 
for preservation of post-extraction alveolar bone loss: A literature 
review. J Adv Med Med Res. 2021; 33(10): 33–42. 

12.  Udeabor S, Halwani M, Alqahtani S, Alshaiki S, Alqahtani A, 
Alqahtani S. Effects of altitude and relative hypoxia on post-
extraction socket wound healing: A clinical pilot study. Int J Trop 
Dis Heal. 2017; 25(3): 1–7. 

13.  Pagni G, Pellegrini G, Giannobile W V., Rasperini G. Postextraction 
alveolar ridge preservation: biological basis and treatments. Int J 
Dent. 2012; 2012: 1–13. 

14.  Fogelman I, Gnanasegaran G, Van der Wall H. Radionuclide and 
hybrid bone imaging. Heidelberg: Springer; 2012. p. 44–6. 

15.  Anchana devi C, Perumal P. Synthesis & application of hydroxyapatite 
bioceramics from different marine sources. J Res Environ Earth Sci. 
2016; 2(11): 7–15. 

16.  Bellido T. Osteocyte-driven bone remodeling. Calcif Tissue Int. 
2014; 94(1): 25–34. 

17.  Ca rdoso L , Her ma n BC, Verborgt O, Laud ier D, Majeska 
RJ, Schaff ler MB. Osteocyte apoptosis controls activation of 
intracortical resorption in response to bone fatigue. J bone Miner 
Res. 2009; 24(4): 597–605. 

18.  Sotto-Maior BS, Senna PM, Aarestrup BJ V, Ribeiro RA, Assis 
NM de SP, Cury AADB. Effect of bovine hydroxyapatite on early                   
stages of bone formation. Rev Odonto Ciência. 2011; 26(3): 198–
292. 

19.  Supangat D, Cahyaningrum SE. Synthesis and characterization of 
crab shell hydroxyapatite (Scylla serrata) by wet application method. 
UNESA J Chem. 2017; 6(3): 143–9. 

20.  Bonucci E, Ballanti P. Osteoporosis-bone remodeling and animal 
models. Toxicol Pathol. 2014; 42(6): 957–69.

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 https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i3.p119–123

https://e-journal.unair.ac.id/MKG/index
http://dx.doi.org/10.20473/j.djmkg.v54.i3.p119-123