Vol 51 No 4 Okt-Des 2018.indd


158158

Variations of gelatin percentages in HA-TCP scaffolds as the result 
of 6- and 12-hour sintering processes of blood cockle(Anadara 
granosa) shells against porosity

Desak Putu Sudarmi Ari, Firda Dean Yonatasya, Gita Saftiarini, and Widyasri Prananingrum 
Department of Dentistry Material and Technology Sciences
Faculty of Dentistry, Universitas Hang Tuah
Surabaya – Indonesia

ABSTRACT

Background: Porous scaffold is one type of biomaterial primarily employed as a bone substitute material which demonstrates 
superior osteoconductive and osteointegrative properties than solid scaffold since it can stimulate and accelerate the growth of new 
tissue. For the purposes of this study, porous scaffold was produced using hydroxyapatite-tricalcium phosphate (HA-TCP) powder 
derived from a synthesis of blood cockle (Anadara granosa) shells and gelatin. Purpose: The aim of this study was to reveal the effects 
of the percentage of gelatin in HA-TCP scaffolds derived from 6- and 12-hours sintering processes involving blood cockle shells on 
porosity. Methods: HA-TCP powder was derived from a synthesis of Anadara granosa shells using a hydrothermal method at 200oC 
with sintering periods of 6 and 12 hours. A XRD test was subsequently conducted to reveal the compositions of HA-TCP powder. The 
24 scaffold samples (n=6) employed were manufactured using a freeze dry method before being divided into four groups, namely; 
Group 1 using 25% HA-TCP powder (a six-hour sintering process) combined with 20% gelatin, Group 2 using 25% HA-TCP powder 
(a six-hour sintering process) combined with 10% gelatin, Group 3 using 25% HA-TCP powder (a twelve-hour sintering process) 
combined with 20% gelatin; and Group 4 using 25% HA-TCP powder (a twelve-hour sintering process) combined with 10% gelatin. 
A scaffold porosity test was subsequently carried out using a liquid displacement method. A one-way ANOVA test was performed 
using SPSS, followed by a Post-Hoc LSD (p<0.05). Results: The statistical results for scaffold porosity were within the range of 67.21 
-77.51%. The highest porosity was found in Group 3, while the lowest was in Group 4. Significant differences were also present in all 
groups. Conclusion: Variations in the percentage of gelatin can affect the porosity of HA-TCP scaffolds derived from 6-and 12 hours 
sintrering processes blood cockle shells. The smaller the percentage of gelatin, the higher the porosity.

Keywords: Anadara granosa shell; HA-TCP; percentage of gelatin; porosity; scaffold

Correspondence: Widyasri Prananingrum, Department of Dentistry Material and Technology Sciences, Faculty of Dentistry, Universitas 
Hang Tuah. Jl. Arif Rahman Hakim no. 150 Surabaya, Indonesia. E-mail: widyasri.prananingrum@hangtuah.ac.id

INTRODUCTION

Bone substitute material serves to assist reconstruction, 
stabilize the structure and bonding of bone and stimulate 
osteogenesis and healing processes within bone defects.1 
Bone substitute material must, therefore, be biocompatible, 
non-toxic, non-cariogenic and non-allergenic, while 
possessing a biological mechanism that is osteoconductive, 
osteoinductive and osteogenic.2 In general, there are four 
types of bone substitute material (bone graft), namely; 
autograft, allograft, xenograft and alloplast. Autograft is a 

substitute for bone material taken from the patient’s body, 
while allograft is derived from that of another human 
being. Contrastingly, xenograft is extracted from the 
body of an animal or a different species, while alloplast 
is composed of synthetic material.3 Hydroxyapatite (HA), 
with the chemical formula Ca10 (PO4)6 (OH)2, is an 
inorganic compound capable of binding to bone4 which 
can be produced synthetically from blood cockle (Anadara 
granosa) shells.

Indonesia is one of the countries producting significant 
amounts of seafood, one example being blood cockle. 

Dental Journal
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Research Report

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
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According to data released by the Directorate General of 
Capture Fisheries in 2011, shellfish production in Indonesia 
during the previous year reached 34,929 tons of which the 
volume of blood cockle production amounted to 34,482 
tons.5 Until recently, blood cockles had been harvested only 
for their meat, the consumption of which results in high 
levels of unutilized shell waste. As a result, hydroxyapatite 
derived from the synthesis of blood cockle shell waste is 
used to produce scaffold.

Scaffold applied to tissue engineering requires open 
porosity construction and adequate pore size to support cell 
nutrient transport, cell proliferation and migration resulting 
from tissue vascularization.6 A porous surface also serves to 
facilitate mechanical interlocking between the scaffolds and 
surrounding tissue to improve the mechanical stability of 
the implant. In addition, the network structure of the pores 
assists in guiding and promoting new tissue formation.7 To 
promote ideal scaffold production the addition of supporting 
materials is required, one of which is gelatin.

Gelatin is a collagen-rich polypeptide bond derived 
from the hydrolysis of bone and animal skin. It is non-toxic, 
biocompatible, biodegradable and nonimmunogenetic in 
character, rendering it useful as a coating for implants, 
wound dressings and scaffold in cell culture. Therefore, 
as a natural polymer, gelatin can be used as a scaffold 
for tissue engineering.8,9 A mixture of 10% gelatin and 
80% nanoparticles cockle shells bone graft is effective 
in increasing the number of osteoblast cells in the bone 
healing process. 10% gelatin produces a high viscosity 
liquid with significant potential for tissue engineering.10,11 

On the other hand, scaffold containing 20% gelatin shows 
a strong expansive character and induces biological 
responses such as cell attachment, cell proliferation and 
effective cell spread.12 Gelatin plays an important role in 
making scaffold because of its ability to cross-link and 
modify other materials that can significantly change their 
mechanical properties to become stronger and porous.13 The 
addition of gelatin in the manufacture of scaffold is also 
intended to increase adhesion, migration and mineralization 
of osteoblast cells that play an important role in bone 
formation process.14 The pore structures in each sample of 
macroporus scaffold will differ.

Furthermore, variations in sintering period will also 
affect the composition and structure of the HA powder 
produced, while also causing differences in crystallinity. 
The longer the sintering period, the greater the crystallinity 
produced which affects the regularity of HA atom 
arrangement.15 In this research, porous HA scaffold was 
derived from the synthesis of blood cockle shells and 25% 
HA and 10% or 20% gelatin after 6- and 12-hour periods 
of hydrothermal circulation. Hence, this study aimed 
to determine the effect of adding variations of gelatin 
percentage on the porosity of hydroxyapatite-tricalcium 
phosphate (HA-TCP) scaffold as a result of blood cockle 
shells synthesis with hydrothermal sintering of 6- and 12-
hour duration.

MATERIALS AND METHODS

The sample manufacture stage includes producing 
scaffold from the synthesis of blood cockle shells. HA 
was obtained by processing blood cockle shells which 
involved boiling them for 30 minutes before cleaning and 
drying. The shells were subsequently pounded to form a 
powder which was filtered through a 100-mesh sieve. The 
powder was calcined at 100°C for three hours to produce 
calcium carbonate (CaCO3) powder, 10 grams of which 
were then dissolved in distilled water to produce 1M 
CaCO3. Thereafter, 1M of CaCO3 was mixed with 0.6M of 
NH4H2PO4 obtained from 6.9 grams of NH4H2PO4 which 
was dissolved in 100 ml of distilled water. By means of a 
hydrothermal method at 200oC for 6 hours for P1 and 12 
hours for P2, CaCO3 powder was further processed and 
rinsed using distilled water to obtain pH ± 7. Thereafter, 
final rinsing was performed using methanol PA after which 
it was warmed at 50oC for 4 hours before being subjected 
to the final sintering process at 900oC for 3 hours until 
HA powder was produced. Scaffold was then produced 
by mixing up to 25% (wt%) HA powder with 10% or 20% 
(wt%) gelatin and putting it into 360 μl (6–10 mm) well 
plates. The scaffold material was subsequently frozen at 
-80o C for 5 hours before being freeze dried for 30 hours.

A x-ray diffraction (XRD) test was carried out to 
determine the crystal system, lattice parameter, crystallinity 
degree and substance type contained in each sample. X-rays 
were directed at the sample inducing the XRD detector to 
rotate according to the range of diffraction angles employed. 
A diffractogram graph depicting the relationship between 
the intensity and diffraction angle was created, before being 
presented on the computer screen. The diffractogram graph 
was subsequently interpreted using Software Match which 
provided information about the crystal structure contained 
in the sample in the form of percentage results.

A porosity test was carried out to determine the 
percentage volume of void space contained in the samples. 
In this research, the samples were divided into 4 groups (n 
= 6) according to differences in the ratio between HA and 
gelatin. 96% absolute ethanol was subsequently used as a 
liquid to determine the wet mass value. Moreover, a digital 
balance was also used to quantify the mass of objects. A 
porosity test was carried out using the liquid displacement 
method which involved soaking the samples in 96% 
absolute ethanol for 48 hours before wet mass measurement 
was carried out.16 The percentage porosity of each sample 
was then quanitified after the object mass measurement 
results of the wet mass of the samples had been obtained 
by means of the following equation (Figure 1).

A scanning electron microscope (SEM) test was 
performed to identify the microstructure of the samples 
with the results being observed through a photo. A sample 
preparation had previously been produced for observation 
using the SEM imaging device. Coated scaffold samples 
were then cut on the side to be studied and observed through 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
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160Ari, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 December; 51(4): 158–163

an electron microscope and displayed on a computer screen. 
An interpretation was subsequently conducted by searching 
for a field of view, selecting pores randomly and measuring 
them with the SEM imaging device at 1000x magnification. 
A statistical test analysis was carried out using one-way 
ANOVA, followed by LSD Post-Hoc test (p<0.05).

RESULTS

XRD was performed to determine the lattice 
parameters, crystallinity degree and substances contained 
in a sample. 

The results of an XRD test on HA-TCP powder 
derived from the synthesis of blood cockle shells with a 
6-hour sintering period produced a diffractogram with 
sharp peaks, the highest being in the range of 30°-40°, as 
well as high intensity. This signifies the sample having 

undergone perfect crystallinity. Moreover, this diffraction 
pattern also indicated that the predominant content of the 
sample was HA.

The results of an XRD test on HA-TCP powder derived 
from the synthesis of blood cockle shells during a 12-hour 
sintering period produced a diffractogram similar to that 
of a 6-hour sintering period with sharp peaks, the highest 
being in the range of 30°-40° as well as elevated intensity. 
The similarity between the XRD results of the two samples 
indicated that HA was the main content of HA-TCP powder 
derived from the synthesis of blood cockle shells.

Table 1 shows that HA-TCP powder derived from the 
synthesis of blood cockle shells with a 6-hour sintering 
period had the most dominant HA level of 54.5% and a TCP 
level of 9.1%. The table above also indicates that HA level 
in the group with a 12-hour sintering period was less than in 
the group with a 6-hour sintering period. However, the TCP 
level in the group subject to a 12-hour sintering period was 
double that of the group subject to one of 6 hours.

Table 2 shows that K4-generated scaffold had the 
highest percentage of porosity compared to the other 
three sample groups. Furthermore, the porosity test results 
revealed that the group using 25% HA-TCP combined with 
10% gelatin and a 6-hour sintering period demonstrated a 
higher average percentage porosity than the group using 
25% HA-TCP combined with 20% gelatin and a 6-hour 
sintering period. Similarly, the group using 25% HA-TCP 
combined with 10% gelatin and a 12-hour sintering period 
had a higher average percentage of porosity than the group 
using 25% HA-TCP combined with 20% gelatin and a 12-
hour sintering period.

x 100 Porosity (%) = x 
  mb - mk 
ρliquid x Vb 

Figure 1. Porosity test equation.16

Note: 

mb = wet mass of sample (gram)

mk = dry mass of sample (gram)

Vb = volume of test object s(cm
3)

ρliquid = density of liquid

Table 1.  List of chemical compounds contained in scaffold based on XRD test on HA-TCP powder derived from the synthesis of 
blood cockle shells sintering times lasting 6 and 12 hours.

Sintering Period (hours) Percentage (%)Chemical FormulaCompounds

CaHA 5(PO4)3 6 54.5(OH)

CaTCP 3(PO4)2 6 9.1

CaHA 5(PO4)3 12 51.5(OH)
CaTCP 3(PO4)2 12 16.8

Table 2. The porosity of the HA-TCP scaffold with variations in the percentage of gelatin and the results of the comparative test 
between groups

pMean ± SDScaffold sample codesGroups
25% HA-TCP combined with 20% gelatin (with a 6-hoursK1
sintering period) 67.65 ± 0.872

0.000*

25% HA-TCP with 10% gelatin (with aK2
6-hours sintering period) 72.98 ± 2.250

25% HA-TCP with 20% gelatin (with aK3
12-hours sintering period) 67.21 ± 1.977

K4 25% HA-TCP with 10% gelatin (with a 
12-hours sintering periiod)

77.51 ± 2.858

Note: * p<0.05 (significantly different)

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
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161 Ari, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 December; 51(4): 158–163

From Table 3 it can be seen that the results of the Post 
Hoc LSD test showed significant differences between each 
study group, except between K1 and K3 both of which 
showed a significance level of more than 0.05.

A SEM test at 1000x magnification was then conducted 
on pores derived from the randomly selected sample to be 
measured digitally through the computer. In all the samples 
tested, the scaffold pore size varied within the range of 
41.02 μm to 73.63 μm.

Figure 3. XRD graph of HA-TCP powder derived from the 
synthesis of blood cockle shells with a sintering period 
lasting 12 hours.

Table 3. Results of the Post Hoc LSD test 

K4K3K2Groups K1
0.000*0.7220.000*K1

K2 0.001*0.000*
K3 0.000*

*p < 0.05 (significantly different) 

 

  

A B 

C 

Figure 4.  SEM results in scaffold porosity at 1000x magnification. (A) 25% HA combined with 10% gelatin after a 12-hours sintering 
period; (B) 25% HA combined with 20% gelatin after a 12-hours sintering period; (C) 25% HA combined with 10% gelatin 
after a 6-hour sintering period.

Figure 2. XRD graph of HA-TCP powder derived from the 
synthesis of blood cockle shells with a sintering period 
lasting 6 hours. 

Subsequently, a one-way ANOVA test with a 
significance level of 95% (0.05) was performed, followed 
by an LSD Post-Hoc test. The one-way ANOVA test 
showed significant differences between groups, where the 
value was one of p<0.05. 

In Table 2, the results for significance between groups 
were 0 with a p value of less than 0.05 (0 <0.05). It 
indicates that there was a significant difference in the mean 
percentage of porosity between all groups. Therefore, an 
LSD Post Hoc test was then performed.

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
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Figure 4 shows that pores od various sizes were 
interconnected in all groups. The porosity of HA-TCP 
scaffold combined with 10% gelatin and a 12-hour sintering 
period formed pores with an average diameter of between 
41.02-49.14 μm. Meanwhile, the porosity of HA-TCP 
scaffold combined with 20% gelatin and a 12-hour sintering 
time formed pores with an average diameter of between 
72.14 μm -73.63 μm. In addition, the porosity of HA-TCP 
scaffold combined with 10% gelatin and a 6-hour sintering 
period formed pores with an average diameter of between 
41.76 μm - 64.87 μm. 

DISCUSSION

In XRD characterization, the main property of a 
material observed using x-ray waves is crystallinity. The 
longer the processing time, the greater the semicrystalline 
nature of the calcium phosphate phase. This is because 
the more protracted the duration of calcium phosphate 
formation, the more the particles will combine with others 
to form agglomerates. This situation causes changes in 
the crystalline properties of calcium phosphate and also 
widens the XRD diffractogram. In other words, the longer 
the duration of calcium phosphate formation, the greater the 
crystallite size because particles will combine with others 
(agglomeration).17 The HA-TCP samples with a 6-hours 
sintering period had the highest peak at 2θ = in the range 
31˚-32˚ (Figure 2). Meanwhile, the HA-TCP samples with 
a 12-hours sintering period had the highest peak at 2θ = in 
the range 31˚-32˚ (Figure 3). 

The majority of peaks identified from HA-TCP samples 
subject to varying sintering duration (6 and 12 hours) 
were the same, thereby signifying the presence of HA. 
This proves that, during the synthesis process, the HA 
composition is dominant. Although the HA level at the 
end of the 6-hours sintering period was higher than the HA 
level at the end of the 12-hours sintering period, the TCP 
level at the end of the 6-hours sintering period was less than 
the TCP level at the end of the 12-hours sintering period. 
This is due to the hydrothermal method. The highest peak 
of HA level was at the end of the 6-hour sintering period. 
At the end of the 12-hours sintering period, the HA level 
decreased while the TCP level increased. The HA level at 
the end of the 12-hours sintering period decreased since 
HA has a peak point after which HA will decrease and be 
converted to TCP with the result that the TCP percentage 
increases, while the HA percentage decreases.18 

Porosity, the ratio of void space volume to the mass 
volume of a solid material, can be measured using the 
ratio between dry mass, wet mass and sample volume. 
There was a significant difference between porosity in 
HA-TCP scaffold combined with 25% gelatin (6-hours 
sintering) and that in HA-TCP scaffold combined with 
10% gelatin (6-hours sintering). Moreover, there was also 
a significant difference between the porosity of HA-TCP 
scaffold combined with 25% gelatin (12-hours sintering) 

and that in HA-TCP scaffold combined with 10% gelatin 
(12-hours sintering). 

The results of this research indicate that the composition 
of HA-TCP scaffold compounds is influenced by 
variations in the percentage of gelatin which is a natural 
polymer employed as a scaffold in tissue engineering. The 
combination of HA-TCP and gelatin will form covalent 
bonds between Ca2+ ions and R-COO- ions derived from 
gelatin molecules. This crosslinking will then cause a 
reduction in the distance between HA-TCP-gelatin fibers.19 

The greater the percentage of gelatin formed the more 
numerous the bonds resulting in a shorter distance between 
the fibers and reduced porosity.

The freeze dry method applied during the manufacture 
of scaffolds removed liquid from the scaffolds20 with the 
result that rough structure patterns formed. This is because 
the HA-TCP particle powder used in this research was 
less than 74 μm in size, while the largest pore diameter 
was derived from HA-TCP scaffold combined with 20% 
gelatin. The largest pore diameter of ± 70 μm was found 
in the group using HA-TCP scaffold combined with 20% 
gelatin. Meanwhile, the smallest pore diameter of ± 40 μm 
was in the group using HA-TCP scaffold combined with 
10% gelatin. Therefore, it is assumed that the addition of 
20% gelatin can generate ± 70 μm pore diameter that is 
open and interconnected.

Finally, it can be concluded that the addition of various 
percentages of gelatin can affect the porosity of HA-TCP 
scaffolds as a result of the synthesis of blood cockle shells 
after a 6- or 12-hours sintering period. The lower the 
percentage of gelatin, the higher the porosity of the scaffold. 
The highest porosity is found in HA-TCP scaffold with the 
addition of 10% gelatin.

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Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
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http://e-journal.unair.ac.id/index.php/MKG
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