213213

Research Report

Dental Journal
(Majalah Kedokteran Gigi)
2015 December; 48(4): 213–216

Application of chitosan scaffolds on vascular endothelial growth 
factor and fibroblast growth factor 2 expressions in tissue 
engineering principles

Ariyati Retno Pratiwi,1 Anita Yuliati,2 Istiati Soepribadi,3 and Maretaningtias Dwi Ariani4
1Master Program in Dental Health Science
2Department of Dental Material 
3Department of Oral Pathology and Maxillofacial
4Department of Prosthodontics
Faculty of Dental Medicine, Universitas Airlangga
Surabaya-Indonesia

abstract

Background: Tissue engineering has given satisfactory results as biological tissue substitutes to restore, replace, or regenerate 
tissues that have a defect. Chitosan is an organic biomaterial often used in the biomedical field. Chitosan has biocompatible, antifungal, 
and antibacterial properties. Chitosan is osteoconductive, suitable for bone regeneration applications. Bone defect healing begins with 
inflammatory phase as a response to the presence of vascular injury, so new vascularization is required. Vascular endothelial growth 
factor (VEGF) and basic fibroblast growth factor-2 (FGF2) are indicators of the beginning of bone regeneration process, playing 
an important role in angiogenesis. Purpose: This research was aimed to determine the effects of chitosan scaffold application on the 
expressions of VEGF and FGF2 in tissue engineering principles. Method: Chitosan was dissolved in CH3COOH and NaOH to form 
a gel. Chitosan gel was then printed in mould to freeze dry for 24 hours. Those rats with defected bones were divided into two groups. 
Group 1 was the control group which defected bones were not administrated with chitosan scaffolds. Group 2 was the treatment group 
which defected bones were administrated with chitosan scaffolds. Those rats were sacrificed on day 14. Tissue preparations were 
made, and then immunohistochemical staining was conducted. Finally, a statistical analysis was conducted using Kruskal Wallis test. 
Result: There was no significant difference in the expressions of VEGF and FGF2 between the control group and the treatment group 
(p>0.05). Conclusion: Chitosan scaffolds do not affect the expressions of VEGF and FGF2 during bone regeneration process on day 
14 in tissue engineering principles

Keywords: chitosan; VEGF; FGF2; tissue engineering

Correspondence: Ariyati Retno Pratiwi, c/o: Peserta Program S2 Ilmu Kesehatan Gigi, Fakultas Kedokteran Gigi Universitas Airlangga. 
Jl. Mayjend. Prof. Dr. Moestopo no. 47 Surabaya 60132, Indonesia. e-mail: ariyatiretnop@gmail.com

introduction

Tissue engineering is an application of the principles 
and methods of engineering used to restore, maintain, or 
improve tissue function. The principles of tissue engineering 
are conducted by providing appropriate materials to 
trigger the cells in order to regenerate or combine the 
performance of the cells in the body by using scaffold to 
trigger the growth of new tissue. Tissue engineering has 
given satisfactory results as biological tissue substitutes to 

restore, replace, or regenerate tissue suffering from defects.1 
Cells, scaffold, and growth stimulating signals are generally 
called as tissue engineering triad, a major component of 
tissue engineering. 

Scaffold is an important material in tissue engineering. 
Scaffold is a very porous artificial extracellular matrix 
used for cell accommodation, cell growth, and tissue 
regeneration.2 Scaffold must meet some requirements, such 
as has interconnecting pores appropriate to support tissue 
integration and vascularity. It made from materials that have 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v48.i4.p213-216

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214 Pratiwi, et al/Dent. J. (Majalah Kedokteran Gigi) 2015 December; 48(4): 213–216

certain properties, such as biodegradation or bioresorption. 
As a result, the tissue will eventually be replaced with 
scaffolds, which have a surface suitable for supporting cell 
attachment, cell differentiation, and cell proliferation, as 
well as have good mechanical properties, easily made into 
a variety of shape and size.3 

Organic biomaterials are often used in the biomedical 
field, especially chitosan application. Chitosan has 
biocompatibility, antifungi, and antibacteria properties.4 
Chitosan also is osteoconductive, so it is suitable for 
hard tissue regeneration application, but the mechanical 
properties and biological activities need to be improved.5 
The biological properties of chitosan that very influential 
in the process of wound healing are biodegradability, 
biocompatibility, and antimicrobial activity. The high 
biodegradation rates can trigger chitosan to be increasingly 
inadequate in accelerating wound healing. Biodegradability 
of chitosan also affects its biocompatibility because hight 
degradation will increase amino sugar accumulation and 
inflammatory response.6

Bone healing process is a series of molecular and cellular 
process as well as tissue transformation, from resorption to 
hard and soft tissue formation. Bone defect healing process 
begins with inflammatory phase, which is vascular response 
to injury, requiring new vascularization. Vascularization 
plays an important role in osteogenesis during the bone 
healing process.7-9 Increased formation of blood vessels 
in the area indicates that wound epithelialization process 
occurs faster.10 

Bone regeneration can be affected by vascular 
endothelial growth factor (VeGF) directly or indirectly. 
VeGF plays an important role in the formation of new 
blood vessels serving to mobilize and recruit endothelial 
progenitor cell (ePC), a well as to differentiate and 
proliferate endothelial cells.8 VeGF induces angiogenic 
process through endothelial cells. Bone-forming precursor 
cells migrate through the bloodstream to the callus that will 
differentiate into osteoblasts.9 VeGF affects osteogenesis 
from day 14 to day 21 after the defect occurred. 

In addition to VeGF, basic fibroblast growth factor 
2 (FGF2) plays an important role in the process of 
vascularization. VeGF and FGF2 can also stimulate 
fibroblasts to migrate to the defect and trigger collagen 
synthesis. FGF2 expression occurs in the early phase of 
bone healing process to form osteoblasts.11 FGF2 also plays 
a role in mitogenesis of mesenchymal cells, proliferating 
and differentiating into progenitor cells. Progenitor cells 
will differentiate into osteoblasts as bone formation 
cells.13

This research was aimed to determine the effects 
of chitosan scaffold application on VeGF and FGF2 
expressions in tissue engineering principles. 

materials and method

This research was a laboratory experimental research 
with post control group design. Animals used were male 
rats (Rattus norvegicus) aged 3 months old and weighed 250 
grams. Materials used in this research were chitosan with 
deacetylation 81% (Sigma 93646, USA), a solution of acetic 
acid (CH3COOH) and NaOH (Merck, Germany), VeGF 
polyclonal antibody (BIOSSUSA), and FGF2 polyclonal 
antibody (BIOSSUSA). Tools used in this research were a 
glass beaker, connicle tube, freezer (Royal Chest Freezer 
BD 195, China), spatula glass, scales (Pioneer, USA), 
magnetic stirrer (HANNA, USA), and freeze-dryer (Heto 
FD3, eN 87 164, Japan).

Chitosan scaffold was synthesized by dissolving chitosan 
powder into a solution of acetic acid (CH3COOH 0.5M) and 
sodium hydroxide (NaOH 0.1M), and then centrifuged at a 
speed of 9000 rpm for 10 minutes. Supernatant in the form 
of chitosan gel was inserted into the mold. The mold already 
containing chitosan gel was frozen at a temperature of -20° 
C using deep freezer for 2 hours, and then freeze-drying was 
conducted for 24 hours to form a porous three-dimensional 
structure, known as scaffold.

Research procedure was performed into several phases. 
Those six rats were divided into two groups. Group 1 
was the control group, while group 2 was the treatment 
group. Those rats were acclimatized for one week. The 
manufacture of bone defects was performed in both groups 
by drilling the rats’ femoral and dextral areas. During the 
making of bone defects, irrigation was made using Ringer 
solution. In the   defect area of the control group, placebo 
scaffold was applied to each defect using tweezers and 
escavator, and then sutured with 3/0 non-absorbable black-
silk thread on muscles. In the   defect area of the treatment 
group, chitosan scaffold was applied to each defect using 
tweezers and escavator, and then sutured with 3/0 non-
absorbable black-silk thread on muscles. 

 On the 14th day after the closure of the defect, those rats 
were anesthetized using 10% ether as asphyxiation, and then 
sacrificed. The defected tissues of those rats were cut. The 
pieces of the tissues were fixed with 10% formalin for two 
days. They were decalcified using eDTA in order to soften 
the tissues to facilitate the process of cutting. The tissues 
were cut to a thickness of 0.3 mm. Dehydration process 
was carried out using alcohol. Those pieces of the tissues 
were put in xylol solution three times. Paraffin infiltration 
was conducted by melting solid paraffin. embedding tissue 
was performed by pouring paraffin into molding devices. 
The tissues were taken using tweezers, and then implanted 
into the mold, which had been filled by paraffin. The mold, 
which had been filled by paraffin and tissue, was cooled to 
form paraffin blocks. Those rats that had been sacrificed 
were then buried properly.

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v48.i4.p213-216

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v48.i4.p213-216


215215Pratiwi, et al/Dent. J. (Majalah Kedokteran Gigi) 2015 December; 48(4): 213–216

Immunohistochemical preparations were performed by 
cutting the paraffin block using a rotary microtome. The 
pieces placed in the glass object was then deparaffinized 
using xylol solution. The preparations were dripped with 
normal serum evenly on a glass object, and then put in a 
preparation box (humidity chamber) with tissue paper, 
etched with PBS to keep the moisture. The preparations 
were put in an incubator at a temperature of 37º C for 45 
minutes. The tissues were dripped with primary antibody 
against inducible nitric oxyde synthase (iNOS) enzyme, 
and incubated at 4° C for one night. The tissues then were 
dripped with secondary antibody (biotinylation), and 
incubated at 37º C for 35 minutes. The administration 
of chromogen was performed by dripping a solution of 
3,3’- diaminobenzidine (DAB), then incubated at 37° C 
for 35 minutes. Counter stain was conducted by dripping 
hematoxylin shed evenly, then left for 15 seconds and 
washed with running water. Dehydration was carried out 
with alcohol solution 70%, 80%, 90%, and 100%. Clearing 
with xylol (I, II, and III) and closing the preparat (mounting) 
then were carried out immediately using the cover glass.

expressions of VeGF and FGF2 in each sample were 
assessed semiquantitatively using the modification of 
Remmele method. Remmele scale index (immuno reactive 
score/IRS) is the result of multiplying immunereactive 
cells percentage score to color intensity score on the 
immunoreactive cells. Data then were obtained from the 
average value of the IRS in each sample observed in five 
different fields of view at 400x magnification. The whole 
of this examination was performed using light microscope 
(Nikon N600L) equipped with a 300 megapixel DS Fi2 
digital camera and image processing software (Nikkon 
Image System).

results

The VeGF and FGF2 distribution were show in  
Figure 1. The average of VeGF and FGF2 expression in the 
control and treatment groups were shown in Figure 2. Based 
on the results of the statistical Kruskal Wallis test, p value 
obtained was less than 0.05, which means that there was 
no significant difference in VeGF and FGF2 expressions 
between the control group and the treatment group.

discussion

Tissue engineering involves cells as a building block, 
scaffold as a template, and growth factor as a biochemical 
signal that indicates there has been a growth of tissue. The 
primary function of scaffold is as cell support, an artificial 
extracellular matrix. It is not only providing sufficient 
mechanical environment of cells, but also causing cell 
attachment, proliferation, differentiation, and metabolism 
signals.4 Selection of biomaterials for scaffold design 
is essential to cell growth and proliferation in three-
dimensional matrix.

Chitosan is a natural polysaccharide which is similar 
to glycosaminoglycans and has a good interaction with 
cell membrane.6 Natural polysaccharides can stimulate 
the activity of growth factors, which can maintain cell 
phenotype in particular morphology and play an important 
role as scaffold component of soft tissue and hard tissue.7

Chitosan-containing N-acetyl-D-glucosamine can bind 
to receptors that recognize macrophages. Macrophages 
produce VeGF directly to stimulate endothelial cell 
proliferation.9 Chitosan may provide more amino groups 

8 

 

 

 

       

       
  

Figure 1. VEGF expressions on the control group (a) and the treatment group; (b)  FGF2 expressions 
on the control group; (c) and the treatment group; (d) VEGF and FGF2 expressions were 
evenly distributed in the control and treatment groups.  

 
 

 

Figure 2. The average of VEGF and FGF2 expression. 

 

  

A

8 

 

 

 

       

       
  

Figure 1. VEGF expressions on the control group (a) and the treatment group; (b)  FGF2 expressions 
on the control group; (c) and the treatment group; (d) VEGF and FGF2 expressions were 
evenly distributed in the control and treatment groups.  

 
 

 

Figure 2. The average of VEGF and FGF2 expression. 

 

  

B

8 

 

 

 

       

       
  

Figure 1. VEGF expressions on the control group (a) and the treatment group; (b)  FGF2 expressions 
on the control group; (c) and the treatment group; (d) VEGF and FGF2 expressions were 
evenly distributed in the control and treatment groups.  

 
 

 

Figure 2. The average of VEGF and FGF2 expression. 

 

  
C

8 

 

 

 

       

       
  

Figure 1. VEGF expressions on the control group (a) and the treatment group; (b)  FGF2 expressions 
on the control group; (c) and the treatment group; (d) VEGF and FGF2 expressions were 
evenly distributed in the control and treatment groups.  

 
 

 

Figure 2. The average of VEGF and FGF2 expression. 

 

  
D

Figure 1. VeGF expressions on the control group (a) and the treatment group; (b) FGF2 expressions on the control group; (c) and 
the treatment group; (d) VeGF and FGF2 expressions were evenly distributed in the control and treatment groups. 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v48.i4.p213-216

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v48.i4.p213-216


216 Pratiwi, et al/Dent. J. (Majalah Kedokteran Gigi) 2015 December; 48(4): 213–216

for the attachment and proliferation of endothelial cells 
because of the affinity between cations of the ammonium 
group of chitosan and the anion surface of the endothelial 
cell membrane.13

In this research, chitosan with a degree of deacetylation 
of 81% was used. Deacetylation degree can increase 
the attachment and stimulate fibroblast proliferation. 
Deacetylation degree of chitosan can also indicate free 
amine groups presented in the structure of chitosan. Cationic 
amine chitosan group provides a suitable environment for 
cell attachment. Cell attachment, is not only influenced 
by acetylation degree, but also by molecular weight 
and porosities. Chitosan, furthermore, can increase the 
proliferation of fibroblasts indirectly through the formation 
of poly-electrolyte complex with serum as heparin.13

The results of this research showed that there was no 
significant difference in VeGF expressions between the 
treatment group and the control group on day 14 during 
the process of bone regeneration. Chitosan could stimulate 
inflammatory cells and growth factors in the early phase 
of wound healing process. This is supported by a research 
conducted by Inan and Saraydin indicating that the 
expression of VeGF in post-administration of chitosan 
will decline on day 14.14 Chitosan could also stimulate 
the formation of granulation tissue. At the same time, 
chitosan could stimulate both fibroblasts to proliferate and 
extracellular matrix formation. 

This study also showed that there was no significant 
difference in FGF2 expressions between the treatment 
group and the control group on day 14 during the process 
of bone regeneration. The number of FGF2 expressions on 
the 14th day is lower than on the 3rd day.14 This condition 
is possible because fibroblasts have produced collagen 
fiber on the 14th day. Consequently, fibroblasts will grow 
into inactive fibroblasts, known as fibrocyte. In this study, 
however, chitosan scaffold on the 14th day could still 
interact with the endothelial cells and fibroblasts although 
not optimal. Finally, it may be concluded that chitosan 

scaffold cannot affect VeGF and FGF2 expressions on 
the 14th day during bone regeneration process in tissue 
engineering principles.

references

 1. Karp JM, Langer R. Development and therapeutic applications of 
advanced biomaterials. Curr Opin Biotechnol 2007; 18(5): 454-9.

 2. Chan BP, Leong KW. Scaffolding in tissue engineering: general 
approaches and tissue-specific considerations. eur Spine J 2008; 
17(Suppl 4): 467–9.

 3. Sachlos e, Czernuszka JT. Making tissue engineering scafollds work. 
Review: The application of solid free form fabrication technology 
to the production of tissue engineering scaffolds. euro Cell Mater 
2003; 5: 29-39.

 4. Shin JA, Choi JY, Kim ST, Kim CS, Lee YK, Cho KS, Chai JK, Kim 
CK, Choi SH. The effect of hydroxyapatite-chitosan membrane on 
bone regeneration in rat calvarial defects. J Korean Acad Periodontal 
2009; 39: 213-4.

 5. Isikli C, Hasirci V, Hasirci N. Development of porous chitosan-
gelatin/hydroxiapatite composite scaffold for hard tissue engineering 
application. J Tissue eng Reg Med 2012; 6(2): 135-43. 

 6. Aranaz I, Mengibar M, Harris R, Panos I, Miralles B, Acosta N, 
Galed G, Heras A. Functional characterization of chitin and chitosan. 
Current Chemical Biology 2009; 3: 203-30.

 7. Hankenson KD, Dishowitz M, Gray C, Schenker M. Angiogenesis 
in bone regeneration. Injury 2011; 42(6): 556-61.

 8. Saran U, Piperni SG, Chatterjee S. Role of angiogenesis in bone 
repair. Arch Biochem and Biophys 2014; 561: 109-17. 

 9. Stegen S, Gastel NV, Carmeliet G. Bringing new life to damaged 
bone: T he impor t a nce of a ngiogenesis i n bone repa i r a nd 
regeneration. Bone 2014; 70: 19-25.

 10. Mackay D, Miller A. Nutritional support for wound healing. Altern 
Med Rev 2003; 8(4): 359-77.

 11. Dimitriou R, Tsiridis e, Giannoudis PV. Current concept of 
molecular aspects of bone healing. Injury 2005; 36(12): 1392-404.

 12. Arvidson K, Abdallah BM, Applegate LA, Baldini N, Cenni e, 
Gomez-Barrena e, Granchi D, Kassem M, Konttinen YT, Mustafa 
K, Pioletti DP, Sillat T, Finne-Wistrand A. Bone regeneration and 
stem cells. J Cell Mol Med 2011; 15(4): 718-46.

13. Ma L, Gao C, Mao Z, Zhou J, Shen J, Hu X, Han C. Collagen/
chitosan porous scaffold with improved biostability for skin tissue 
engineering. Biomaterials 2003; 24(26): 4833-41.

14. Deniz I, Serpil S. Investigation of the wound healing effects of 
chitosan on FGFR3 and VEGF ımmunlocalization in experimentally 
diabetic rats. Int J Biomed Mat Research 2013; 1: 1-8.

8 

 

 

 

       

       
  

Figure 1. VEGF expressions on the control group (a) and the treatment group; (b)  FGF2 expressions 
on the control group; (c) and the treatment group; (d) VEGF and FGF2 expressions were 
evenly distributed in the control and treatment groups.  

 
 

 

Figure 2. The average of VEGF and FGF2 expression. 

 

  

Figure 2. The average of VeGF and FGF2 expression.

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v48.i4.p213-216

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v48.i4.p213-216