5757

Dental Journal
(Majalah Kedokteran Gigi)

2020 June; 53(2): 57–61

Research Report

Effects of alkalisation and volume fraction reinforcement 
of Bombyx mori silk fibre on the flexural strength of dental 
composite resins

Dyah Anindya Widyasrini and Siti Sunarintyas
Department of Dental Biomaterial,
Faculty of Dentistry, Universitas Gadjah Mada
Yogyakarta – Indonesia

ABSTRACT
Background: Composite resins are widely used in dentistry to restore dental caries. Recently, short fibre-reinforced composite 
(FRC) resins have been widely used for high-stress areas, especially in posterior teeth. Bombyx mori silk fibre is under research to 
reinforce dental composite resin as it has good mechanical properties. Purpose: This study aims to obtain the effects of alkalisation 
and silk fibre volume fraction on the flexural strength of FRC. Methods: Bombyx mori silk fibres were obtained from Perhutani, Pati, 
Indonesia. Samples were divided into two alkalisation groups (4% and 8%). Alkalisation of the silk fibres was conducted through the 
scouring process in NaOH, hydrolysis (30% H2SO4) and drying. Silk fibres were then reinforced in a resin matrix. The samples were 
subdivided based on the fibre volume fraction reinforcements, which were 0%, 5%, 10% and 15%. Each group of samples consisted of 
three specimens (n = 3). Flexural strength was measured using a universal testing machine. Data were analysed by two-way ANOVA 
(p < 0.05) and post-hoc least significant difference test (p < 0.05). Results: The results showed the flexural strength (MPa) means 
of the 4% alkalisation group were 169.31 ± 54.28 (0%), 76.08 ± 43.69 (5%), 107.86 ± 40.61 (10%) and 101.99 ± 10.61 (15%). The 
flexural strength (MPa) means of the 8% alkalisation group were 169.31 ± 54.28 (0%), 82.62 ± 22.41 (5%), 111.07 ± 32.89 (10%) 
and 153.23 ± 23.80 (15%). Statistical analysis by ANOVA indicated that the fibre volume fraction affected the flexural strength of 
composite resins. Conclusion: It can be concluded that the volume fraction of silk fibre increases the flexural strength of composite 
resins, although the strength is not as high as a composite resin without fibres. However, the alkalisation percentage did not affect 
the flexural strength of composite resins, and there was no interaction between alkalisation percentage and fibre volume fraction with 
the flexural strength of composite resins.

Keywords: alkalisation; composite resins; flexural strength; silk fibre; volume fraction

Correspondence: Siti Sunarintyas, Dental Biomaterial Department, Faculty of Dentistry, Universitas Gadjah Mada, Sekip Utara 
Yogyakarta 55281 Indonesia, E-mail: sunarintyassiti@ugm.ac.id

INTRODUCTION

Oral and dental health are inseparable parts of overall body 
health. To date, caries pose a major problem in dental 
health throughout the world and cause significant tooth 
decay. Dental restorative materials are needed to prevent or 
repair tooth decay.1 Composite resins are the most preferred 
restorative material due to their good biocompatibility, 
aesthetic properties, affordable costs and mechanical 
bonding to the tooth structure.2 However, there are some 
problems concerning composite resin restorations, such as 

inadequate mechanical properties, high water absorption, 
shrinkage after polymerisation and poor wear resistance 
when used.3,4

Recently, short fibre-reinforced composite (FRC) has 
been introduced as a restorative material of composite 
resins for bearing high-stress areas, especially in molars. 
The results of laboratory mechanical tests show that there 
are substantial improvements in load-bearing capacity, 
flexural strength and fracture toughness in composite resins 
that are reinforced with short e-glass fibre fillers compared 
to conventional fillers.5

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
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58 Widyasrini and Sunarintyas/Dent. J. (Majalah Kedokteran Gigi) 2020 June; 53(2): 57–61

The availability of synthetic dental FRC resin for 
restorations in Indonesia is still limited and more expensive 
than regular composite resin because it must be imported 
from another country. As an alternative to using synthetic 
fibres to reinforce composite resin as a restorative material, 
silk fibre, taken from the Bombyx mori silkworm cocoon, 
is used. Bombyx mori silk fibre is one of the strongest 
natural fibres.6 Previous studies have shown that the silk 
fibre of the Bombyx mori silkworm cocoon has a higher 
tensile strength than glass fibres or other organic synthetic 
fibres and has good resilience and elasticity.7 Widely 
used in biomedical applications, Bombyx mori silk fibres 
have shown not only good mechanical properties but also 
excellent biocompatibility and low immunogenicity.6 
Another study shows that up to 100 µg/ml of extract 
from the silkworm cocoon of Cricula triphenestrata is not 
cytotoxic to gingival fibroblast cells.8 

A study conducted by Fransiska et al.9 shows that an 
increase in the Bombyx mori silk fibre volume fraction in 
composite resins increased water absorption and decreased 
flexural strength. The study found that a small gap was 
allegedly due to weak interfacial bonds between the resin 
matrix and the Bombyx mori fibre. This induced the water to 
penetrate easily, reducing flexural strength. Sericin, which 
was still attached to the surface of the Bombyx mori fibre, 
was ostensibly the cause of the bad bond between the resin 
matrix and the fibre.9 In addition, sericin has been shown to 
induce allergic and immunological reactions, so it must be 
removed before use in biological applications.10 Sericin can 
dissolve in water and can be removed by a thermochemical 
process known as degumming.11 During the degumming 
process, sericin is hydrolysed, and amide bonds with long 
protein molecules are broken into smaller fractions, then 
dispersed and dissolved in solutions containing alkali, soap 
or synthetic detergents.12 In order to overcome the damage 
that occurs during the degumming process, it is necessary to 
research the effects of alkalisation, which aims to remove 
sericin and impurities in the flexural strength of composite 
resins. This study aims to reveal the effects of alkalisation 
and the addition of a volume fraction of Bombyx mori silk 
fibre on the flexural strength of composite resins as dental 
filling material.

MATERIALS AND METHODS

Bombyx mori silk fibres were obtained from Perhutani, 
Pati, Central Java, Indonesia; the silk fibres had been reeled 
and spun from the Bombyx mori silkworm cocoon. UDMA 
was obtained from Esstech Inc. (Essington, Pennsylvania). 
BisGMA, TEGDMA, champorquinone (CQ) and CEMA 
were obtained from Sigma-Aldrich Chemical (Darmstadt, 
Germany). NaOH, CH3COOH and other chemicals used 
at analysis levels were obtained from Sigma-Aldrich 
Chemical (Darmstadt, Germany).

Bombyx mori silk fibres were alkalised based on the 
method developed by Mohammed and Dauda,13 with 

modifications. Bombyx mori silk fibres were alkalised by 
cutting silk fibres to 2 mm long using stainless steel scissors 
and grouping them into two groups based on the alkalisation 
percentage. Afterwards, the scouring process was performed 
by soaking the silk fibres in 250 ml of NaOH solution in 
a beaker glass at 65ºC for three hours on a hotplate stirrer. 
The concentrations of NaOH solution used were 4% and 
8%. The silk fibres were rinsed with distilled water, then 
neutralised with 500 ml of 2% CH3COOH solution in a 
beaker glass for two hours at 65ºC on a hotplate stirrer. 
The fibres were then rinsed using distilled water until the 
litmus paper showed a neutral pH. The fibres were left to 
dry at room temperature.13 Drying was continued until it 
reached a constant fibre weight.

The results of the 4% and 8% silk fibre alkalisation 
were mixed with a composite resin matrix mixture until 
they were homogeneous, according to Sunarintyas et al.14 
(BisGMA 67%, TEGDMA 30%, UDMA 1%, CQ 1%, 
CEMA 1%). The results of each percentage of silk fibre 
alkalisation were then subdivided into four groups based 
on the silk fibre volume fraction. The volume fractions 
of the silk fibres used were 0%, 5%, 10% and 15%.9 The 
samples of the silk FRC for flexural strength tests were 
made according to ISO 4049 (2009). Three (n = 3) samples 
were made for each volume, so there were eight groups of 
samples. Afterwards, the composite was put into a mould 
measuring 25 mm x 2 mm x 2 mm until it was fully loaded. 
The composite surface was covered with a glass slide, and 
the top of the sample was illuminated using a light-curing 
unit perpendicular to the sample from a distance of 2 
mm. The tip diameter of the light-curing unit was 8 mm, 
while the sample length was 25 mm. The illumination was 
divided into three parts, each of which was illuminated 
for 20 seconds; non-illuminated parts were covered with 
aluminium foil. After the illumination was complete, the 
sample was removed from the mould.

Flexural strength was tested with a three-point bending 
test using a universal testing machine (Tokyo Testing 
Machine, Japan), according to ISO 4049.15 The test was 
performed by putting the sample on a supporting board 
with a support distance of 20 mm (L), then the sample 
was loaded in the middle until it broke. Afterwards, the 
monitor screen displayed a number (F), which was the 
maximum pressure that the sample received. Furthermore, 
the measurement data obtained were entered into the 
following equation:15

σ = (3F.L) / 2 b.h2

Where:
σ = flexural/transverse strength (N/mm2 or Mpa)
F = maximum load (N)
L = distance between the two supports
b = width of the sample (mm)
h = thickness of the sample (mm)

Normality (Shapiro–Wilk) and homogeneity (Levene’s 
test) tests were performed on the data obtained from the 
results of the flexural strength test. Furthermore, to test 

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.v53.i2.p57–61

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59Widyasrini and Sunarintyas/Dent. J. (Majalah Kedokteran Gigi) 2020 June; 53(2): 57–61

the hypothesis, a two-way ANOVA test was performed 
to reveal the effects of alkalisation and the addition of the 
volume fraction of Bombyx mori silk fibre on the flexural 
strength of composite resins with a significance level of 
p < 0.05. Furthermore, the data were analysed using the 
post-hoc least significant difference (LSD) test to see the 
average difference between each group.

RESULTS

Figure 1 presents the results of the research into the effects 
of alkalisation and volume fraction of Bombyx mori silk 
fibre on the flexural strength of composite resins. Figure 
1 shows that the lowest flexural strength was seen in 
composite resins with a 5% silk fibre volume fraction, and 
the highest value was in composite resins without fibre 
additions (0% silk fibre volume fraction) in both the 4% 
and 8% alkalisation groups. In composite resins with the 
addition of silk fibre, there was an increase in the flexural 

strength value along with the addition of the fibre volume 
fraction in the two alkalisation groups. 

The results of the two-way ANOVA test indicated the 
effects of adding fibre volume fraction on flexural strength 
(p = 0.007), but the percentage of fibre alkalisation did 
not significantly affect the flexural strength of silk fibre 
composite resins (p = 0.344). Based on the statistical 
analysis, there was no interaction between the percentage 
of alkalisation and fibre volume fraction and the flexural 
strength of composite resins (p = 0.626). The results of 
observations with a scanning electron microscope (Figure 
2) showed a small gap between the fibre and the matrix in 
the 8% alkalisation group specimen. Furthermore, the data 
obtained were tested post-hoc using the LSD test Table 
1). The post-hoc LSD test results indicated that there were 
significant differences between the flexural strength values   
of the composite resins with 0% and 5% volume fractions in 
both alkalisation groups. Meanwhile, the flexural strength 
values of composite resins with 0%, 10% and 15% fibre 
volume fractions were not significantly different.

 

 

 

0

50

100

150

200

250

0% 5% 10% 15%

Fl
ex

ur
al

 s
tr

en
gt

h 
(M

Pa
)

Fiber volumetric fraction

4% Alkalisation

8% Alkalisation

Figure 1. Mean and standard deviation of flexural strength of 
silk fibre composite resins.

 

Figure 2. The results of an SEM photograph on a silk 
fibre composite resin in 8% alkalisation with a 
magnification of 500x. There are small gaps between 
the fibre and the matrix (white arrow).

Table 1. Summary of LSD test of fibre volume fraction of 4% alkalisation group on the flexural strength of silk fibre composite 
resin

Volume fibre fraction 0% 5% 10% 15%

0% 93.23000* 61.45333 67.32000

5% 31.77667 25.91000

10% 5.86667

15%
*= Significantly different (p <0.05)

Table 2. Summary of LSD test of fibre volume fraction of 8% alkalisation on the flexural strength of silk fibre composite resin

Volume fibre fraction 0% 5% 10% 15%

0% 86.69333* 58.24000 16.07333

5% 28.45333 70.62000*

10% 42.16667

15%
*= Significantly different (p <0.05)

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.v53.i2.p57–61

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60 Widyasrini and Sunarintyas/Dent. J. (Majalah Kedokteran Gigi) 2020 June; 53(2): 57–61

DISCUSSION

The results of the research indicated that the greatest 
flexural strength in the two alkalisation groups was in the 
0% volume fraction treatment, while the lowest flexural 
strength was shown in the 5% silk fibre volume fraction. 
This may be due to the absence of fibre additions (0% 
volume fraction), causing no gaps to form in the matrix 
(homogeneous matrix without fibre additives). In composite 
resins with the addition of fibres, especially fibres that 
are not perfectly clean, there is a gap between the matrix 
and fibres, which happens because there is still a layer of 
sericin and other impurities that have not been completely 
removed from the silk fibres through the alkalisation 
process. The presence of a sericin layer can prevent physical 
contact or chemical attachment between the fibres and the 
matrix, reducing the mechanical properties of the silk fibre 
composite resins.16 The small gap between the fibres and 
the matrix shown in Figure 2 might be due to imperfect 
adhesion due to sericin remaining in the fibres. Fibre-
matrix attachment is another important factor affecting 
the mechanical properties of short-FRC. The gap formed 
between the fibre and the matrix is like a cavity without 
reinforcement, reducing the composite’s overall strength. 
Poor interfacial attachment between the silk fibre and 
polymer matrix dominates other factors that might influence 
the decrease in mechanical strength.16 This shows that a 
better sericin cleaning process is needed so that the sericin 
does not interfere with the fibre’s attachment to the matrix. 
In addition, a coupling agent can be added to improve the 
interfacial attachment between silk fibres and the matrix. 
The addition of coupling agents to composites made from 
natural fibres can improve mechanical properties by up to 
61% because they can increase the bond between organic 
and inorganic materials.17 With the addition of a coupling 
agent, it is expected that the load transfer to the fibre will 
be more effective, increasing mechanical strengths, one of 
which is flexural strength.

In the 8% alkalisation group, the flexural strength 
increased from the 5% to the 15% volume fraction. 
Meanwhile, in the 4% alkalisation group, the flexural 
strength increased from the 5% to the 10% volume fraction 
but slightly decreased in the 15% volume fraction. The 
increased value in the flexural strength of the composite 
resins might be due to the addition of silk fibre as a 
reinforcement material. Bombyx mori silk fibre is a natural 
fibre that has good mechanical strength. Silk fibre has 
high tensile strength, good flexibility and resistance to 
compression strength, making it suitable to be used as 
a composite material to bear the load.4 The mechanical 
strength of Bombyx mori silk fibre is equal to e-glass fibre 
and is greater than that of other synthetic fibres, including 
Kevlar.18 The mechanical strength of Bombyx mori silk 
fibre is obtained from the β-sheet structure, which is 
formed by a repeated sequence of the amino acids glycine, 
alanine and serine (G-A-G-A-G-S) in the crystalline phase 
of fibroin.10 The addition of a volume fraction of silk 

fibres increases the amount of silk fibre in the composite 
composition, thereby increasing the mechanical strength 
of the composite resins.

The results of the two-way ANOVA indicated the 
effects of fibre volume fraction on flexural strength (p 
= 0.007). The effectiveness of fibre reinforcement is 
affected by the amount of fibre in the composite resin. An 
increase in fibre content increases mechanical strength.19 
This is consistent with the results of this research; the 
flexural strength of composite resins generally increased 
in line with the addition of silk fibre in composite resins. 
However, statistically, the difference in the percentage of 
fibre alkalisation indicated that there was no significant 
effect on the flexural strength of the composite resin (p 
= 0.344). This might be due to the degumming procedure 
using alkalisation being poorly performed so that the 
results of the two alkalisation percentages did not show 
any differences. In the degumming process with alkali, the 
non-covalent fibroin bond in a silk fibre is modified, making 
the fibre swell. The swelling effect of the fibre is due to 
the difference in osmotic pressure arising between the fibre 
and the solution, forming protein salts. Furthermore, sericin 
degrades into sericin peptides or hydrolysed sericin.12,20 

The degumming process of silk fibres using NaOH is 
widely used, but this process results in strong irritation to 
the fibroin content of silk fibre.12 Degumming using alkali 
may result in a damaged structure of the silk fibres, poor 
stretch quality and lack of shine.21 Therefore, it is necessary 
to use a more optimal and safer degumming procedure when 
removing sericin to maintain the physical and mechanical 
properties of fibroin. In addition, proper degumming 
procedures are needed to increase fibre roughness, thus 
increasing attachment strength. This is consistent to Ho et 
al.’s16 statement on the interaction between the fibre and 
matrix being supported by the existence of the mechanical 
interlocking obtained from fibre surface roughness, 
providing weak adhesion.

Based on the results of the post-hoc test, it can be seen 
that there was an increased value in the flexural strength 
of composite resin with 5%, 10% and 15% fibre volume 
fractions in the 8% alkalisation group. These results indicate 
that fibre has the potential to increase the mechanical 
strength of composite resins, although the results are not 
as good as the composite resins with a 0% fibre volume 
fraction. Also, the results of the post-hoc LSD test indicated 
that the flexural strength of composite resins with 0%, 10% 
and 15% fibre volume fractions did not differ significantly 
(Tables 1 and 2), especially in the 8% alkalisation group. 
This indicates that degumming using 8% NaOH has better 
cleaning potential than using 4% NaOH, although it was 
not perfect. In addition, according to ISO 404915 restorative 
material is deemed to have met the initial requirements if 
the flexural strength of the test sample is more than 80 MPa. 
All samples in the 8% alkalisation group had an average 
flexural strength greater than 80 MPa.

Based on the results of the research, it can be concluded 
that the fibre volume fraction increases the flexural strength 

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.v53.i2.p57–61

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61Widyasrini and Sunarintyas/Dent. J. (Majalah Kedokteran Gigi) 2020 June; 53(2): 57–61

of composite resins, although they are not as strong as the 
composite resin without fibres. Silk fibre has the potential 
to increase the mechanical strength of composite resins; 
however, the optimum volume fraction of silk fibre to 
be added in the composite resins still needs to be found. 
Meanwhile, the percentage of silk fibre alkalisation does 
not affect the flexural strength of composite resins

ACKNOWLEDGEMENT

This research was financially supported by the Faculty of 
Dentistry, Universitas Gadjah Mada, under contract number 
4310/UN1/FKG1/Set.KG1/PT/2019.

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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.v53.i2.p57–61

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v53.i2.p57-61