106

Dental Journal
(Majalah Kedokteran Gigi)

2017 June; 50(2): 106–110

Research Report

The Effect of a combination of 12% spirulina and 20% chitosan 
on macrophage, PMN, and lymphocyte cell expressions in post 
extraction wound

Nike Hendrijantini, Rostiny, Mefina Kuntjoro, Kevin Young, Bunga Shafira, and Yunita Pratiwi 

Department of Prosthodontics
Faculty of Dental Medicine, Universitas Airlangga
Surabaya- Indonesia

abstract

Background: Tooth extraction is the ultimate treatment option for defective teeth followed by the need for dentures. Inflammation 
is one phase of the healing process that should be minimized in order to preserve alveolar bone for denture support. Macrophage, 
PMN and lymphocyte cells are indicators of acute inflammation. Spirulina and chitosan are natural compounds with the potential to be 
anti-inflammatory agents. Purpose: This study aimed to determine macrophage, PMN and lymphocyte cells of animal models treated 
with a combination of 12% spirulina and 20% chitosan on the 1st, 2nd and 3rd post-extraction day. Methods: Animal models were 
randomly divided into control (K) and treatment (P) groups. Each group was further divided into three subgroups (KI, KII, KIII and PI, 
PII, PIII). The post-extraction sockets of the control group animals were then filled with CMC Na 3%. Meanwhile, the post-extraction 
sockets of the treatment group members were filled with a combination of 12% spirulina and 20% chitosan. Subsequently, the number 
of PMN, macrophage and lymphocyte cells was analyzed by means of HE analysis on the 1st, 2 nd  and 3 rd   days. Statistical analysis 
was then performed using a T-test. Results: There was a decrease in PMN cells and an increase in macrophage and lymphocyte cells 
on Days 1, 2 and 3.  Conclusion: It can be concluded that a combination of 12% spirulina and 20% chitosan can not only decrease 
PMN cells, but can also increase macrophage and lymphocyte cells on day 1, 2 and 3 after tooth extraction.

Keywords: spirulina; chitosan; inflammation; PMN; macrophage; lymphocyte

Correspondence: Nike Hendrijantini, Department of Prosthodontics, Faculty of Dental Medicine, Universitas Airlangga. Jl. Mayjend. 
Prof. Dr. Moestopo no. 47 Surabaya 60132, Indonesia. Email: nike-h@fkg.unair.ac.id

introduction

Tooth loss is one of dental health problem. Its prevalence 
in Indonesia, according to RISKESDAS data in 2013, was 
14.51% within the 45-54 years age group, 25.02% in the 55-
64 years age group, and 43.79% in the >65 years age group.1 
Tooth loss can occur due to extraction which can increase 
injury to dental tissues resulting in an acute inflammatory 
reaction as well as inflammatory cell infiltration, such 
as polymorphonuclear (PMN), macrophages, and 
lymphocytes.2 Clinical inflammatory reaction is usually 
indicated by edema, redness, and pain.3 The inflammatory 
phase commonly lasts from the point of injury to Day 6 
after its occurrence.4 Thus, in order to maintain the alveolar 

bone while promoting prosthetic restoration, biomaterial 
is required to eliminate the inflammatory process and 
accelerate the post-extraction healing process.

Recently, the use of natural materials in accelerating 
the wound healing process has been widely studied since 
they are safer than synthetic materials. One of the natural 
ingredients that have many benefits for the wound healing 
process is spirulina - a greenish-green algae containing 
C-phycocyanin, B-carotenoids, vitamin E, zinc, and other 
components useful to the human body. C-phycocianin 
is even considered to have an anti-inflammatory and 
antioxidant components.5,6

Another natural ingredient in the healing process that is 
commonly studied is chitosan, a polymer of deacetylated 

 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.v50.i2.p106–110

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v50.i2.p106-110


107107Hendrijantini, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 June; 50(2): 106–110

chitin. Chitin is a copolymer of N-acetyl-d-glucosamine 
and D-glucosamine bound by ß- (1-4) glycosidic bonds. 
Chitin and chitosan can both be found in aquatic and 
terrestrial organisms. Chitosan can currently be obtained 
via the food industry through the processing of waste 
derived from shrimps, lobsters, crabs, and squids.7 
Chitosan is widely used as one of ingredients for drug 
delivery systems, wound healing processes, and orthopedic 
implants, while also being tknown to increase the activities 
of immune cells, inflammatory cells and angioendothelial 
cells. Chitosan oligosaccharides have anti-inflammatory 
properties since chitosan can inhibit the production of tumor 
necrotizing factor-α (TNF-α) in inflammation stimulated 
by lipopolysaccharide (LPS).6 Other studies have also 
shown that chitosan can reduce the inflammation associated 
with allergic responses by inhibiting the secretion of 
interleukin-8 (IL-8) and TNF-α.7

Some cases in the field of prosthodontics, such as 
immediate denture and ovate pontik installation, also 
require a more rapid wound healing process. Consequently, 
a shorter treatment that can lead to optimal results for patient 
comfort is necessary. Considerable previous research into 
the effects of spirulina and chitosan induction on collagen, 
osteoblast, and osteoclast cells in animal models has been 
conducted. The results of past investigations have shown 
that a combination of 12% spirulina and 20% chitosan can 
not only increase collagen and osteoblast expressions, but 
can also decrease osteoclast expression. As a result, it can be 
said that spirulina and chitosan has the potential to promote 
the bone healing process.8 The effects of spirulina and 
chitosan in this regard have actually already been studied, 
unlike the effects of a combination of spirulina and chitosan 
on inflammatory cells. Therefore, this research aimed to 
reveal the effects of a combination of 12% spirulina and 
20% chitosan on PMN, macrophage and lymphocyte cells 
in animal models on day 1, 2 and 3 after extraction.

  materials and methodS

  This investigation reported here constituted laboratory- 
based  experimental  research  incorporating  a  post  test- 
only control group design and using male Cavia cobaya 
specimens (n = 42) weighing 300-350 grams and aged 3-3.5 
months. The research passed an ethical test performed by 
the Faculty of Dental Medicine, Universitas Airlangga (no. 
110/KKEPK.FKG/VII/2016).

 The animal specimens were subsequently divided into 
two groups, namely; control and treatment. The control (K) 
and treatment (P) groups were each sub-divided into three 
sub-groups referred to as KI, KII, KIII, PI, PII, and PIII. 
The roman numerals I, II and III represent day 1, 2, and 3 
after the specimens had been terminated.

Thereafter, the mandibular incisors of the members of 
all groups were extracted under ketamine anastesi (Ketalar, 
PT Pfizer, Jakarta, Indonesia) at a dose of 40 mg/kgBW. 
After the extraction, the sockets of the KI, KII, and KIII 
control groups were filled with 3% sodium-carboxymethyl 
cellulose natrium (CMC Na). Meanwhile, the sockets of 
the treatment groups, PI, PII, and PIII, were filled with 
a combination of 3% CMC Na, 12% spirulina and 20% 
chitosan using a 0.1 cc syringe. The sockets were stitched 
with 3/0-size silk threat. After the treatment, these animals 
were returned to their cages. On the first day, members of 
the KI and PI groups were decapitated, a process repeated 
for the KII and PII groups on day 2, as well as the KIII and 
PIII groups on day 3. Mandible samples were then taken 
and fixed.

At that point, the mandibles were with 2.5% nitric acid 
for 2 days. Thereafter, the sagittal incisive socket area of the 
specimens was cut and soaked in a 10% buffered formalin 
for 24 hours. Mixed preparations were then performed by 
using eosin haematoxylin (HE) before PMN, macrophages, 
and lymphocytes on one-third of the sockets’ area were 
observed using a light microscope (Nikon H600L®, Tokyo, 
Japan) at a magnification of 400x. The data obtained was 
then analyzed by means of a Saphiro Wilk test to analyze 
the data distribution, followed by an Independent t-test to 
identify the differences between the groups.

results

The results of the observation of PMN, macrophage, 
and lymphocyte cells in the control and treatment groups 
can be seen in Table 1. Moreover, the results of HE staining 
in both groups are contained in Figure 1. The results of 
HE staining illustrate that PMN possessed a large cell 
picture, a nucleus featuring lobes (2-5 lobes), chromatin 
in a condensed nucleus and visible organelle in cytoplasm. 
They also depicted macrophages as having a large cell 
image and generally kidney-shaped, erratically located 
cell nuclei. Furthermore, the cytoplasm cells were solid 
and appeared to be composed of a pink and purple granule, 

Table 1. Mean and standard deviation of PMN, macrophage, and lymphocyte expressions

No Groups n PMN Macrophages Lymphocytes

1 KI 7 41.85±5.87 1.43±0.53 3.00±0.82

2 PI 7 32.00±3.26 5.57±1.51 12.00±2.00

3 KII 7 35.29±2.81 2.00±1.15 8.28±2.28

4 PII 7 11.71±1.60 19.71±1.98 21.43±2.37

5 KIII 7 20.57±3.69 15.57±1.72 19.14±2.41

6 PIII 7 15.14±2.41 20.57±2.70 22.43±3.31

 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.v50.i2.p106–110

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v50.i2.p106-110


108 Hendrijantini, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 June; 50(2): 106–110

whereas the lymphocytes had a circular or spherical nucleus 
cell with dark blue chromatin and a surrounding thin, light 
blue cytoplasm.

Subsequently, before a t-test analysis was performed, 
normality test, Saphiro Wilk test was conducted. Results of 
the Saphiro Wilk test showed that all data were normally 
distributed because p value was more than 0.05. Independent 
t-test then was carried out. Results of the independent t-test 
indicated that the p values of PMN cells between KI and 
PI groups, between KII and PIII groups, and between KIII 
and PIII groups were 0.020, 0.000, and 0.007, respectively. 
The results of the independent t-test also showed that the p 
values of macrophages between KI and PI groups, between 
KII and PII groups, and between KIII and PIII groups were 
0.000, 0.000, and 0.001, sequentially. Meanwhile, the p 
values of lymphocytes between KI and PI groups, between 
KII and PII groups, and between KIII and PIII groups were 
0.000, 0.000, and 0.055, respectively. Almost all of the 
independent t-test results in the control groups compared 
with the treatment groups indicated significant increase 
macrophages and lymphocytes differences (p<0.05), except 
between group PMN significant decrease (p>0.05). Thus, it 
can be said that no significant difference existed between 
the two groups.

discussion

The presence of PMN cells is very important as an 
indicator of the wound healing process since PMN cells 
are the first to appear in the acute inflammatory phase.9 
PMN cells are cellular defenses that play an active role 
in the process of bacterial destruction through endothelial 

adherens, chemotaxis and phagocytosis. Furthermore, PMN 
cells are able to move actively, and in a short period of time 
can collect in large numbers in the wound area. PMN cells 
have a lifespan of 1-3 days in connective tissue.10

Another cell that plays a role in the inflammatory process 
is the macrophage cell which carries out several functions in 
the wound healing process, such as producing collagenase 
and elastase enzymes, generating cytokines, facilitating 
phagocytosis and angiogenesis processes, as well as 
stimulating granulation tissue formation in the proliferative 
phase.11 Macrophage cells in the inflammatory process can 
be distinguished by the origin of the tissue macrophage 
resident and monocytes undergoing differentiation.12 
Monocytes in the blood vessels will be transported toward 
inflammatory tissues due to chemotaxis resulting from 
the response to chemoattractant. Chemoattractant consists 
partly of kemokin, a protein (8-14 kDa) that regulates cell 
travel through interaction with a 7-transmembrane subset 
G-protein pair receptor.13

Similarly, lymphocyte cells play a role in the 
inflammatory process. Lymphocytes result in both immune-
mediated inflammation caused by infectious agents and 
non-immune inflammation. T and B lymphocytes migrate 
to the inflammatory area and direct neutrophils and other 
leukocytes.14 In the remodeling process, when the wound 
has been closed and the local infection has subsided, the 
leukocyte subtance most often found in the injured tissue 
is that of T cell which acts as an adaptive immune response 
cell.6

Results of the research on day 1 revealed that the 
presence of PMN cells in the control group was higher than 
in the treatment group. This occurred because phycocyanin 
and b-carotene contained in spirulina can decrease the 

12 
 

  

  

  

Figure 1.  Inflammatory cells in the tooth extraction sockets of Cavia cobaya animals in group KI 
(A), group PI (B), group KII (C), group PII (D), group KIII (E), and group PIII (F). (blue 
arrows: PMN, yellow arrows: macrophage cells, green arrows: lymphocytes). 

 
12 

 

  

  

  

Figure 1.  Inflammatory cells in the tooth extraction sockets of Cavia cobaya animals in group KI 
(A), group PI (B), group KII (C), group PII (D), group KIII (E), and group PIII (F). (blue 
arrows: PMN, yellow arrows: macrophage cells, green arrows: lymphocytes). 

 

12 
 

  

  

  

Figure 1.  Inflammatory cells in the tooth extraction sockets of Cavia cobaya animals in group KI 
(A), group PI (B), group KII (C), group PII (D), group KIII (E), and group PIII (F). (blue 
arrows: PMN, yellow arrows: macrophage cells, green arrows: lymphocytes). 

 

12 
 

  

  

  

Figure 1.  Inflammatory cells in the tooth extraction sockets of Cavia cobaya animals in group KI 
(A), group PI (B), group KII (C), group PII (D), group KIII (E), and group PIII (F). (blue 
arrows: PMN, yellow arrows: macrophage cells, green arrows: lymphocytes). 

 

BA C

ED F

Figure 1.  Inflammatory cells in the tooth extraction sockets of Cavia cobaya animals in Group KI (A), Group PI (B), Group KII (C), 
Group PII (D), Group KIII (E), and Group PIII (F). (blue arrows: PMN, yellow arrows: macrophage cells, green arrows: 
lymphocytes).

 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.v50.i2.p106–110

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109109Hendrijantini, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 June; 50(2): 106–110

production of proinflammatory cytokines, TNF-α and IL-
1b. b-carotene in spirulina also has an anti-inflammatory 
effect through resistance to the production of nitric oxide 
and prostaglandin E2. Furthermore, b-carotene also 
inhibits the expression of INOS, COX2, TNFα and IL1b. 
Suppression of inflammatory mediators is due to NF-κB 
inhibition that restricts the nuclear translocation of subunits 
NF-κB p65.15

As a result, anti-inflammatory activity of spirulina can 
decrease the number of PMNs in the lesion site. TNF-α 
and IL-1b can also facilitate the movement of PMN cells to 
the site of the lesion and spur the production of endothelial 
adherens.16 It is intended that PMN cells easily pass through 
the gap between endothelial cells in capillary blood vessels 
to eliminate bacteria, so the reduction of proinflammatory 
cytokines can, in turn, lead to a decrease in the production 
of PMN cells.16

In addition, on the first day after dental extraction, the 
average number of PMN cells in Group KI was the highest 
compared with the other control groups (K II and K III) 
and the treatment groups on the other days (P II and P III) 
because PMN cells had already been active and assembled 
at a large number of lesion sites very rapidly, i.e. within 
hours.17 PMN cells are highly reactive to chemotactic 
products in the form of proteins produced by bacteria.16

Moreoever, the results of calculating macrophage cells 
on day 1 indicated that the treatment group (P I) had a 
higher number of such cells than the control group (K I). 
This may occur because the inflammatory cells that appear 
immediately post-incision are not only neutrophils, but also 
monocytes moving into the inflammatory area. However, 
the number of monocytes migrating to the wound area is not 
as high as that of neutrophils.18 The combination of 12% 
spirulina and 20% chitosan also contains more synthetic 
C-phycocyanin components which execute a greater 
immunomodulatory function than when applied alone.19

Furthermore, the results of the independent t-test 
showed there to be a significant difference in the presence 
of lymphocytes between the K1 and P1 groups on the first 
post-extraction day. This may occur because phycocyanin 
pigments contained in spirulina may act as an anti-
inflammatory by inhibiting proinflammatory cytokines, 
namely; TNF-α and IL-1b.15 Chitosan also plays a role in 
increasing lymphocyte cells. A previous piece of research 
using mice orally induced with chitosan finds that the latter 
can stimulate the release of IL-10, IL-4, and TGF-b mRNA 
expressions in gastric mucosa, CD3 + T lymphocytes in 
the spleen, as well as natural killer cells (NK) in intestinal 
intraepithelial lymphocytes.20

In addition, the number of PMN cells in Group PII, 
based on the results of the second day’s observation, was 
lower than that in Group KII. The decrease in PMN cells 
on the second day was higher than on the first day due to 
the homeostasis process where the number of PMN cells 
produced in the bone marrow must be balanced with that 
having clearance which had already worked on the system 
within the body. The number of PMN cells produced 

in the bone marrow can reach a post-injury maximum 
within 24-48 hours. On the other hand, the process of 
PMN cell clearance can reach its peak 48 hours after the 
occurrence of the lesion. The number of PMN cells will 
then decrease as the chronic inflammatory phase is entered. 
Clearance can also occur when the PMN cells extravatase 
into the peripheral tissues. A previous investigation into 
mice revealed that PMN cells can migrate back from 
peripheral tissue into the bloodstream through a process 
known as reverse transmigration.16 This suggests that the 
extravasation of PMN cells does not necessarily lead to the 
clearance of tissue. The clearance process reaches its peak 
on the second day. Consequently, the anti-inflammatory 
effect of the combination of 12% spirulina and 20% 
chitosan will reduce the number of PMN cells on the second 
day to a greater extent than on the first day.16

The number of lymphocytes in Group PII, based on the 
results of the second day of observation, was higher than that 
in Group KII. This difference is due to spirulina being able 
to increase the number of lymphocytes. Previous research 
has even shown spirulina to have an immune modulatory 
effect on lymphocytes by significantly increasing IFN-.2 
production.21 The increased number of lymphocyte cells 
in the treatment group is also due to chitosan that exhibits 
biocompatible and biodegradable properties. The latter allow 
chitosan to be broken down into micromolecules so that they 
are easily absorbed by the body without causing toxicity, 
thereby enabling it to be used as an analgesic, anti-tumor, 
anti-microbial, anti-oxidant, and wound healing agent.22 
Chitosan also contains a N-acetyl-D-glucosamine unit, 
polysaccharide similar to glucan, which accelerates cytokine 
production in order to stimulate repair of affected tissue.23

The results of the third day’s observation found that the 
number of PMN cells in Group PIII was lower than that in 
Group KIII. The number of PMN cells on day 3 was lower 
than that on Day 2. This happened because the number of 
PMN cells will usually decrease between day 3 and 7.18.24 
This reduction is essential to preventing further damage to 
healthy body tissue. The body responds to a reduction in 
the production of PMN cells in order not to damage other 
tissues because PMN cells issue anti-microbial products 
that can damage healthy tissue of the body.

The number of macrophages in Group PIII, based on the 
results of the third day’s observation, was still higher than 
that in Group KIII. Nevertheless, there was no significant 
difference in the post-extraction number of macrophages 
between the treatment groups on day 2 and day 3. This may 
be due to the inflammatory process beginning to enter the 
resolution phase during which a reduction of chemokine by 
the mechanism of proteolysis and chemokine sequestration 
occurs.25 Macrophages, as a result, begin to dominate the 
wound area from day 3 to day 7 after extraction.

The number of lymphocyte cells in the treatment 
group, based on the results of the third day’s observation, 
appeared to increase compared with that of the control 
group. However, based on the results of the independent 
t-test, there was no significant difference in the number 

 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.v50.i2.p106–110

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v50.i2.p106-110


110 Hendrijantini, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 June; 50(2): 106–110

of lymphocyte cells between the control group and the 
treatment group on day 3. During the chronic inflammatory 
process, the presence of lymphocyte can usually reach a 
peak between day 5 and day 10.15 Thus, 12% spirulina and 
20% chitosan are expected to act as anti-inflammatories. 
This insignificant difference between the control group 
and the treatment group is due to the chronic inflammatory 
process having begun to subside and entering the maturation 
process which leads to regeneration.

The phycocyanin and b-carotene substances contained 
in spirulina can be considered to be anti-inflammatory 
antioxidants that can accelerate the wound healing process. 
Phycyocyanin, according to previous in vitro and in 
vivo research using rat-fed animals, can inhibit TNF-α 
inflammatory cytokine secretion and act as an antioxidant.26 
This strongly suggests that the anti-inflammatory activity 
of spirulina may cause TNF-α and IL-1b secretions to 
decrease.27 Similarly, the antioxidants in b-carotene 
contained in spirulina can improve the wound healing 
process.6 Chitin and chitosan are biopolymers that offer 
many benefits, including; a high level of biocompatibility, 
low toxicity, increased antibacterial activity and accelerated 
wound healing.28 Chitosan can also stimulate PMN cells to 
chemotaxyize the wound area due to the presence of IL-1, 
TNF-α, and bacterial products.29

In other words, spirulina and chitosan exert a synergistic 
effect when combined since chitosan plays a role in drug 
delivery, while spirulina has a therapeutic effect. Spirulina 
and chitosan can also interact intermolecularly to increase 
mechanical resistance. Both of these materials can even 
work together to provide more effective benefits than if 
applied alone. 

In addition, a high degree of chitosan acetylation will 
improve the hydrophobic properties of chitosan. The 
hydrophilic component is capable of diffusing through the 
chitosan polymer into the outer medium to be absorbed 
by the body.22 Finally, based on the above discussion, it 
can be concluded that 12% spirulina and 20% chitosan 
combination can not only decrease PMN expression, 
but also increase macrophages and lymphocytes in cavia 
cobaya animals on the first, second and third days after 
extraction.

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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.v50.i2.p106–110

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v50.i2.p106-110