Vol 51 No 3 Jul - Sep 2018_pus.indd


114114

The effect of various concentrations of HA-TCP derived from 
cockle shell synthesis on scaffold porosity

Reyhan Alvaryan Ferdynanto, Priska Evita Setia Dharmayanti, Putu Tahlia Krisna Dewi, and Widyasri Prananingrum
Department of Dental Materials,
Faculty of Dentistry, Universitas Hang Tuah, Surabaya - Indonesia

ABSTRACT

Background: Porosity is an important property that must be possessed by scaffold due to its role in new bone growth. Hydroxyapatite 
is a scaffold material with a composition resembling that of bone that can be synthesized from cockle shell (Anadara granosa). 
Purpose: This research aimed to determine the effects of various HA-TCP concentrations (wt%) derived from cockle shell synthesis 
on scaffold porosity. Methods: HA-TCP was synthesized from cockle shells using a hydrothermal method at 200o C with a 12-hour 
sintering process period. An XRD test was subsequently carried out to determine the composition of hydroxyapatite (HA) and tricalcium 
phosphate (TCP) compounds. Eighteen scaffold samples (n=6) were then produced using a freeze dry method and divided into three 
groups, namely; Group 1 (K1) treated with 5% HA-TCP, Group 2 (K2) treated with 25% HA-TCP and Group 3 (K3) treated with 
50% HA-TCP. Thereafter, a scaffold porosity test was conducted using liquid displacement method. Scaffold porosity was observed by 
means of an SEM image. A One-Way ANOVA test  was subsequently performed, followed by an LSD Post-Hoc test (p <0.05). Results: 
The results of the XRD test showed that the percentage of HA was 51.5%, while TCP was 16.8%. The porosity of the scaffolds was 
within the range of 67.24% - 80.17%. The highest porosity was found in Group 1, while the lowest occurred in Group 3. There were 
significant differences in all groups. Conclusion: The concentration of HA-TCP derived from the synthesis of cockle shells affects the 
porosity of scaffold. The lower the concentration of HA-TCP, the higher the scaffold porosity.

Keywords: HA-TCP concentration; gelatin; porosity; scaffold; cockle shells

Correspondence: Widyasri Prananingrum, Department of Dental Materials, Faculty of Dentistry, Universitas Hang Tuah, Jl. Arif 
Rahman Hakim No. 150, Surabaya 60111, Indonesia. E-mail: widyasri.prananingrum@hangtuah.ac.id

Dental Journal
(Majalah Kedokteran Gigi)
2018 September; 51(3): 114–118

Research Report

INTRODUCTION

Repairing bone damage remains a problem for medical 
personnel since the bone healing process often proves 
ineffective, culminating in the need for a material to 
promote it. One method commonly used to restore the 
function of lost or damaged bone tissue is the application 
of bone graft1, a biomaterial used to fill damaged bone 
cavities which disappears when new bone cell growth 
has occurred.2 In general, there are three properties that a 
bone graft requires in order to form new bones, namely: 
osteoconductivity, osteoinductivity and osteogenetic.3 
However, bone graft has been widely used in dentistry to 
overcome the problem of bone resorption by regenerating 
lost or severely damaged bones.

Bone grafts can be grouped into four types: autographs, 
allographs, xenographs and alloplasts. The most commonly 
used are xenografts, bone grafts from different species 
that possess osteoconductive properties and demonstrate 
high levels of biocompatibility. 4 Hydroxyapatite 
(Ca10(PO4)6(OH)2) is the main inorganic component in 
bones and teeth generally used as a bone graft due to its 
excellent biocompatibility, osteoconductivity in relation 
to the chemical and biological affinity to bone tissue.5,6 
Synthetic hydroxyapatite currently constitutes an expensive 
imported product, costing approximately one million rupiah 
per gram. Although hydroxyapatite can be synthesized 
from readily available natural ingredients, these have yet 
to be utilized.7 Moreover, hydroxyapatite unfortunately 
demonstrates certain weaknesses, including fragility and 
poor absorbency.8

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i3.p114–118

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115 Ferdynanto, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 Sept; 51(3): 114–118

Tricalcium phosphate is a compound possessing 
physical and chemical properties similar to the mineral 
structure of human bones and teeth.9 Tricalcium phosphate 
has bioactive, biocompatible and osteoconductive 
properties, while being readily absorbed. The combination 
of hydroxyapatite and tricalcium phosphate produced 
is assumed to possess higher quality and more stable 
compounds.10 The manufacture of HA-TCP combination 
compounds with a 12-hour sintering period produces a 
high tricalcium phosphate compound in which the longer 
the sintering time, the higher the production of tricalcium 
phosphate compounds.11

One of the natural ingredients possessing a high 
calcium content is cockle shell with a calcium carbonate 
level of 98%.12 Cockles constitute one of the marine food 
commodities with a high commercial value that are favored 
by consumers in Indonesia and throughout Asia. The high 
consumption of cockles will, consequently, produce large 
quantities of shells as waste. The use of accumulated cockle 
shell waste can enhance waste management in reducing 
pollution and improving environmental aesthetics.13 This 
research, therefore, focused on converting cockle shell 
waste into HA-TCP bone graft.

HA-TCP bone graft derived from cockle shells is 
formed into a scaffold enabling it to accelerate the process 
of biomineralization in the bone. An important property 
that must be possessed by scaffold is porosity. The porous   
characteristics of scaffold are very important to the process 
of new bone growth. Scaffold represents a site to which 
growth cells can attach and develop to form new bone 
tissue. Scaffold with high porosity, optimal pore size 
and pore interconnectivity plays a very important role 
in the growth of bone cells.14 Hence, the hydroxyapatite 
present in porous scaffold is assumed to demonstrate more 
effective osteoconductivity and greater absorbability than 
dense scaffold. Effective pore size for bone cell growth 
is approximately 40-100μm.15 The porosity of scaffold 
effectively employed as a bone graft is between 30% 
and 90%.16 Consequently, there is a great demand for the 
development of porous scaffold synthesis.

Research conducted by Narbat (2006) using HA 
scaffold at concentrations of 30%, 40% and 50% showed 
that the highest porosity was found in scaffolds with an 
HA concentration of 30%. However, HA has difficulty 
in absorbing.17 As a result, this research was conducted 
to synthesize HA-TCP from cockle shells (Anadara 
granosa). Theoretically, TCP will be more easily degraded 
and absorbed by the body, leading to the expectation of 
more rapid new bone formation.18 However, it has yet to 
be confirmed whether variations in the  concentrations of 
HA-TCP synthesis derived from cockle shells can affect 
scaffold porosity.

In this research, porous HA-TCP scaffold was produced 
with HA-TCP concentrations of 5%, 25% and 50% 
combined with gelatin, a biodegradable, biocompatible and 
soluble protein-based material..19 Gelatin contains many 

protein bonds in aginine-glycine-apartic acid (RGD) which 
can increase cell attachment and cell growth.20 The addition 
of gelatin to scaffold with hydroxyapatite combination was 
intended to increase bone-forming cell differentiation and 
improve the mechanical properties of the scaffold.21 Thus, 
this research aimed to determine the effects of HA-TCP 
concentration variations (wt%) derived from cockle shells 
synthesis on scaffold porosity.

MATERIALS AND METHODS

This research constituted an experimental laboratory 
study with a posttest-only group design and was conducted 
in two stages, namely, a sampling process stage and a 
sample testing stage. The raw material used consisted 
of cockle shells (Anadara granosa) extracted from waste 
present on the coast at Probolinggo. The cockle shells were 
pulverized and converted to HA-TCP by a hydrothermal 
method at 200°C with a 12-hour sintering period, including 
calcination, sintering, PA methanol rinsing and drying 
processes.

HA-TCP compounds were obtained from cockle shells 
which had been cleaned and  ground to form a smooth 
texture. The filtered powder was then calcined at 100° for 
three hours in an oven furnace (Naberterm, Germany). 
As part of the hydrothermal process, the hydroxyapatite 
powder was mixed with Ammonium Dihydrogen Phosphate 
(Daishin, Japan) and heated at 200°C in an oven furnace 
(Naberterm, Germany) with a sintering time of 12 hours. 
After completion of this process, the powder was rinsed 
with distilled water until the pH reached ±7, and was also 
rinsed with methanol PA (Emsure, Germany). The powder 
was then heated to a temperature of 50° for four hours and 
at 900°C for a further three hours. Before manufacture of 
the scaffold, HA-TCP powder had been filtered with a 200-
mesh filter to produce a powder size of <74 μm. Scaffold 
was subsequently produced by mixing HA-TCP with 10% 
gelatin (Sigma, Germany) (wt%) (1:1). In this research, 
three varieties of HA-TCP concentration (wt%) were used, 
namely 5% HA-TCP (K1), 25% HA-TCP (K2) and 50% 
HA-TCP (K3). The results of the mixing process were 
then deposited in a 6mm-diameter mold  10mm in height, 
frozen at a temperature of -80° C for five hours and freeze 
dried for 30 hours.

An XRD test was conducted using an Xpert-Pro 
PANalytical at an angle of 2θ= 5°- 60° to identify the 
crystallization phase and content of the material using 
X-ray electromagnetic radiation. The XRD test results were 
then presented in the form of spectrum charts and tables. 
The spectrum diffraction pattern of the XRD test results 
provides information about the angle of diffraction in the 
atomic material (2θ) on the horizontal axis and the intensity 
result on the vertical axis. An identification phase was then 
performed by comparing the hydroxyapatite diffraction 
pattern with data from International Center for Diffraction 
Data (ICDD).

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i3.p114–118

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Porosity is the volume of empty space contained 
in a sample tested using a liquid displacement method 
determined by the percentage of liquid absorbed by scaffold 
after being immersed in ethanol. Materials used in this test 
comprised HA-TCP scaffold derived from cockle shell 
synthesis and 96% absolute ethanol (Merck, Germany). 
The tools employed consisted of analytical scales, tweezers 
and vernier calipers (Krisbow, Indonesia). This research 
also used 18 cylindrical 6x10mm-sized (n=6) samples. A 
porosity test was subsequently carried out to determine 
the volume of empty space in each sample. A porosity test 
measured the volume of the samples, weighing their dry 
weight before soaking them in 96% absolute ethanol for 
48 hours. The samples were weighed to determine the wet 
mass of the specimens. The porosity of the samples was 
then calculated using the following equation:22

x 100 Porosity (%) = 
  mb - mk 

ρliquid x Vb 

Note:
mb = wet mass of specimen (gram)
mk = dry mass of specimen (gram)
Vb = volume of specimen (cm

3)ρliquid = density of water (1 gr/cm3)

SEM was conducted with an electron microscope 
at 1000x magnification in order to identify pores in the 
samples. Pore   size observed through an electron microscope 
lens was displayed on a computer screen using the SEM 
imaging device. A photo was taken of the selected part 
of each sample  at the desired magnification and the pore 
size was measured. The scaffold pore was represented by 
black and its size measured using a scale line found in the 
SEM image.

Statistical analysis was performed on the porosity data 
using SPSS one-way ANOVA with a significance level of 
95% (0.05), followed by an LSD Post-Hoc test.

RESULTS

The XRD results of HA-TCP powder in Figure 1 
illustrated a diffractogram with high peaks indicating 
changes in the crystallization phase of the samples at 
each calcination temperature. The diffraction pattern of 
hydroxyapatite formation in the XRD results was shown 

 
Figure 1 XRD spectrum graph.  of HA-TCP derived from cockle shell synthesis.

*p<0.05 

Figure 2.  Percentages of porosity in 5% HA-TCP scaffold 
(K1), 25% HA-TCP scaffold (K2), and 50% HA-TCP 
scaffold (K3).

Table 1. Chemical compounds contained in HA-TCP powder 
derived from cockle shell synthesis.

PercentageName of compounds
(%)

Chemical 
formulas

Ca16.8Tri-Calcium Phosphate (TCP) 3(PO4)2
Ca51.5Hydroxyapatite  (HA) 5(PO4)3(OH)
CaCO20.8Aragonite  (CaCO3) 3
Ca(OH)3.0Calcium Hydroxide 2
CaO7.9Calcium Oxide
CaCO-Calcite 3

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i3.p114–118

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117 Ferdynanto, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 Sept; 51(3): 114–118

at 2θ : 32°, and the formation of tricalcium phosphate at 
2θ : 28°.

The XRD results in Table 1 showed that the levels 
of hydroxyapatite (HA) and tricalcium phosphate (TCP) 
produced were relatively high. Other compounds produced 
from blood clams (Anadara granosa) included: aragonite, 
calcium oxide and calcium hydroxide.

As shown in Figure 2, the percentages of porosity 
were high in all groups. The statistical test results showed 
significant differences between Group 1 and Group 2 (p = 
0.037), Group 2 and Group 3 (p = 0.000), and Group 3 and 
Group 1 (p = 0.000). The percentage of porosity in the 5% 
HA-TCP group was 80.17%, 77.51% in the 25% HA-TCP 
group, and 67.24% in the 50% HA-TCP group.

Based on the SEM image in Figure 3, there were 
interconnected scaffold pores. In Figure 4, the pore size was 
small, while in Figure 5, the pore size varied. In general, the 
pore size in all groups varied and was unequally distributed. 
The average diameter of the 5% HA-TCP scaffold pore size 
was 75.99 μm, 25% HA-TCP scaffold was 45.08 μm and 
50% HA-TCP scaffold was 90.31 μm.

DISCUSSION

An X-ray diffractometer (XRD) machine is essential 
not only to evaluate crystalline structures, crystallization 
phase and crystallinity degree, but also to determine types 
of elements or compounds contained in a material. The 
output of an XRD machine is a diffractogram with a high 
peak indicating the crystallization phase of a sample.23 
In this research, the  XRD machine results relating to 
cockle shell synthesis confirmed the presence of HA 
compounds (51.5%), TCP (16.8%), and others such as 
calcium carbonate in the form of aragonite. This is due to 
the decomposition of hydroxyapatite during combustion 
as a result of imperfections in the reactants. Since natural 
material was used in this study, it proved difficult to achieve 
a high level of purity in the material.24

The results of this research indicated that the porosity of 
the samples varied. The highest porosity was demonstrated 
by Group 1 that had been treated with 5% HA-TCP scaffold, 
while the lowest occurred in Group 3 which had been 
treated with 50% HA-TCP scaffold. This signified that 
the porosity of HA-TCP scaffold samples decreased as the 
concentration of HA-TCP scaffold powder increased. The 
statistical test results also revealed significant differences 
between groups. In other words, the concentration of HA-
TCP powder in the manufacture of scaffold affects the level 
of scaffold porosity. The higher the concentration of HA-
TCP powder administered, the lower the level of porosity.5 
This occurs because the formation of a salt bridge and 
cross-linking due to the hydroxyapatite reaction absorbed 
on the material matrix fills the gap between the particles 
in the material.25 

The porosity of the scaffold is also known to be 
affected by porogen (porous-forming material/gelatin) 
concentration and the sintering process. The porogen 
concentration is directly proportional to the porosity of 
a scaffold. The higher the concentration of porogen used 
in making scaffold, the higher the porosity produced.26 
In this research, the same concentration of porogen, 10% 
gelatin, was used in all groups. As a result, the effect of 

Pa 1 = 69.90 μm Pa 2 = 82.08 μm 

Pa R1 

Pa R2 

Pa 1 Pa 2 

Figure 3. SEM image indicating porosity of 5% HA-TCP 
scaffold at 1000x magnification.

Pa 1 = 49.14 μm 

Pa 2 = 41.02 μm 

Pa 1 

Pa 2 

Pa R2 

Pa R2 

Figure 4. SEM image indicating porosity of 25% HA-TCP 
scaffold at 1000x magnification.

Pa 2 = 88.68 μm 

Pa 1 = 91.93 μm 

Pa 1 

Pa 2 

Pa R2 

Pa R1 

Figure 5. SEM image indicating porosity of 50% HA-TCP 
scaffold at 1000x magnification.

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i3.p114–118

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118Ferdynanto, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 Sept; 51(3): 114–118

the porogen factor on scaffold porosity was not detected. 
However, the porosity produced in this research was quite 
high. An effective level of porosity for bone cell growth 
is one of approximately 70%.27 Thus, the manufacture of 
scaffold with 5% and 25% HA-TCP can produce porosity 
supportive of bone growth.

In addition, SEM images (Figures 3, 4 and 5) showed 
that pores of varying sizes in HA-TCP scaffolds were 
connected to one another and spread unevenly in all groups. 
The research findings reported here indicate that pore size 
is not directly proportional to porosity. Rather, a large 
number of small pores can increase porosity. The pore 
size of scaffold pores can be influenced by temperature 
and the freezing time required during the freeze-drying 
method. The lower the freezing temperature, the faster 
the ice crystal dendrite formed resulting in pores on the 
scaffold. The faster the freezing time, the larger the size 
of the pores formed.28 Since variations in the freeze-drying 
method were not employed during this research, they did 
not affect scaffold porosity which has greater influence 
on bone formation compared to pore size. The number of 
endothelial cells, osteoblasts and bone mass is proportional 
to an increase in scaffold porosity. 

In conclusion, this research indicated that the smaller 
the concentration of HA-TCP powder (wt%), the higher 
the porosity of the scaffold. The highest porosity occurs 
in scaffold with 5% HA-TCP (80.17%), proving that the 
concentration of HA-TCP powder derived from cockle shell 
synthesis affects the porosity of the HA-TCP scaffold.

ACKNOWLEDGEMENT

This research was supported by the 2018 Funding 
Student Creativity Program (PKM) of the Directorate 
of Student Affairs, Directorate General of Learning and 
Student Affairs, Ministry of Research, Technology and 
Higher Education of the Republic of Indonesia.

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Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i3.p114–118

http://dx.doi.org/10.20473/j.djmkg.v51.i3.p114-118
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