Vol 51 No 4 Okt-Des 2018.indd


179

A study of cytotoxicity and proliferation of Cosmos caudatus 
Kunth leaf extract in human gingival fibroblast culture

Zhafira Nur Shabrina, Ni Putu Mira Sumarta, and Coen Pramono
Department of Oral and Maxillofacial Surgery
Faculty of Dental Medicine, Universitas Airlangga 
Surabaya – Indonesia 

ABSTRACT

Background: Post-extraction dental sockets clinically resolve within a period of 3-4 weeks. However, complete healing and bundling 
of gingival fibers may require several months. Medication is therefore required to accelerate the healing process. Cosmos caudatus 
(C. caudatus), a local plant with antioxidant properties and high calcium content, has the potential to promote wound healing while 
also reportedly capable of strengthening bone. Previous studies have demonstrated the effectiveness of C. caudatus as an alternative 
treatment for post-menopausal osteoporosis by investigating the dynamic and cellular parameters of bone histomorphometry. Purpose: 
The study aimed to examine the citotoxicity and proliferation of human gingival fibroblast cells culture after the application of C. 
caudatus extract. Methods: Cultures of human gingival fibroblast cells with 5x104 cell density were divided into two groups and placed 
in a 30-well culture dish. The control group contained human gingival fibroblast cell culture without extract, while the experimental 
group consisted of human gingival fibroblast cells culture with extract. The concentrations of extract were 1200 μg/ml, 600 μg/ml, 
300 μg/ml, 150 μg/ml, and 75 μg/ml. A toxicity test was conducted and the optimum concentration evaluated using an MTT assay, 
while fibroblast numbers on were calculated days 1 and 2 by means of a hemocytometer. Research data was analyzed using a one-way 
ANOVA test. Results: No toxicity was found. The optimum concentration was 600 μg/ml and fibroblast proliferation was significantly 
higher in the experimental group compared to the control group, p=0.002 (P<0.05). Conclusion: C. caudatus leaf extract is non-toxic 
and increases the proliferation of human gingival fibroblast culture at an optimum concentration of 600 μg/ml.

Keywords: Cosmos caudatus leaf extract; human gingival fibroblasts culture; wound healing

Correspondence: Ni Putu Mira Sumarta, Department of Oral and Maxillofacial Surgery, Faculty of Dental Medicine, 
Universitas Airlangga. Jl. Mayjend. Prof. Dr. Moestopo 47 60132, Surabaya, Indonesia. E-mail: niputu.mira@fkg.unair.ac.id; 
zhafiranurshabrina@yahoo.com

Dental Journal
(Majalah Kedokteran Gigi)
2018 December; 51(4): 179–184

INTRODUCTION

A wound is considered healed if tissue has regenerated 
to its original anatomic structure, function and within a 
reasonable period. Most wounds result from minor injuries, 
but some do not heal fully in a timely fashion. Several local 
and systemic factors can impede wound repair by disrupting 
the process of balance improvement, resulting in chronic 
wounds failing to healing.1

Fibroblasts, cells in the connective tissue that affect 
the wound healing process, enter the wound area three 
days after extraction and became dominant after 6-7 days.2 
Fibroblasts will experience certain changes to the phenotype 

and become myofibroblasts that serve to retract the 
wound. Fibroblasts produce extracellular matrix, collagen 
primer and fibronectin which promote cell migration and 
proliferation. Fibroblasts derived from the undifferentiated 
mesenchymal cells produce mucopolysaccharides, amino 
acid glycine and proline, a basic ingredient of collagen 
fibers, that binds wound edges. However, in cases of 
significant bone damage, the natural repair processes 
within the body cannot restore its function or promote 
clinical improvement.3

Cosmos caudatus (C. caudatus), known as kenikir in 
Indonesia, had been used in eastern regions of the country 
to reduce high blood pressure. As well as acting as an anti-

Research Report

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.i4.p179–184

mailto:zhafiranurshabrina@yahoo.com
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180Shabrina, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 December; 51(4): 179–184

hypertensive, it possesses anti-diabetic, anti-inflammatory, 
bone protective, anti-microbial and anti-fungal properties.4 
The polyphenol content of C. caudatus is high, as is the 
level of vitamin E, vitamin C, folic acid, β-carotene and 
polyphenols in the C. caudatus lycopene.5 C. caudatus also 
promotes oral health, especially as an antibacterial, as it 
contains polyphenol derivates such as flavones, flavonols, 
flavonones, catechins and isoflavones. The catechin 
derivate has antioxidant and anti-inflammatory properties. 
Other substances contained in C. caudatus include 
phytochemical flavonoids. Previous studies have shown 
flavonoids to have anti-inflammatory and antioxidant 
properties, the capacity to accelerate tissue regeneration 
and to act as a natural antioxidant that enhances the wound 
healing process.6 Another study stated that C. caudatus 
leaves contain terpenoids (essential oils), alkaloids and 
saponin.7 C. caudatus was studied in this experiment 
because it is readily available, widely consumed and used 
in the manufacture of drugs to enhance the process of post-
extraction healing.

Tooth extraction socket healing occurs through a 
secondary healing process that involves the formation of 
granulated tissue and subsequent covering by epithelium. C. 
caudatus leaf properties have proved capable of balancing 
the production of reactive oxygen species (ROS) and 
promoting cell growth, such as fibroblasts.8

This research was conducted as a preliminary 
study of the development of drugs applied to promote 
fibroblast proliferation. It followed the successive stages 
of drug development, namely: in vitro examination, 
experimentation on live subjects (in vivo), clinical trials 
and a market launch.9 The initial step of this study prior 
to analyzing the proliferation of human gingival fibroblast 
(HGF) culture was that of conducting a citotoxicity assay/
study.10 

The study aimed to quantify the citotoxicity and 
proliferation of human gingival fibroblast cell culture 
after the application of C. caudatus extract. C. caudatus 
leaf properties were able to balance the production of 
ROS and promote cell growth such as fibroblast so 
that tooth extraction socket healing occurred through a 
secondary healing process that increased the proliferation 
of granulated tissue and the epithelium.

MATERIALS AND METHODS

This was an experimental laboratory study using a 
post-test control group design. The experiment involved C. 
caudatus leaf extract application to primary cell cultures of 
human gingival fibroblasts.

Preliminary cytotoxicity and optimum concentration 
tests were conducted using a colorimetric assay that 
measured the reduction of yellow 3-(4.5-dimethythiazol-
2-yl) -2.5-diphenyl tetrazolium bromide (MTT) assay by 
mitochondrial succinate dehydrogenase. Five concentrations 
of extract, consisting of 1200 μg/ml, 600 μg/ml, 300 μg/ml, 

150 μg/ml, and 75 μg/ml based on the IC50, were tested. 
The optimum concentration for cell growth was found to 
be approximately 504.840 μg/ml.11 

The MTT results did not demonstrate toxicity after 
24 hours with an ELISA reader used to calculate cells 
spectrophotometrically with a wavelength of 620-650 nm 
based on formazan crystal absorbance values. 

Extract concentrations of 600 μg/ml were selected 
because, at this concentration, viable cell numbers of 
HGF were optimal with no bias in spectrophotometric 
absorbance. These concentrations correspond to the 
proliferation of fibroblasts compared to ones below 600 μg/
ml because lower extract concentrations will not provide 
maximum results.

Two groups, a control group and an experiment group 
each containing five samples placed in 30-well culture disk, 
were used in this study, together with a monolayer HGF 
culture of 5x104 cell density. A control group was HGF-
cultured without extract application, while the experiment 
group was HGF-cultured with the application of 600 μg/ml 
extract. C. caudatus leaf extract was applied by means of 
a 1 ml pipette with the fibroblast numbers being counted 
after 24 hours and 48 hours.

Fibroblast cell counts were conducted using a 
hemocytometer after trypan blue staining. Cells were taken 
at the ratio 1:1 and resuspended with trypan blue stain and 
observed under a light microscope at 100x magnification. 
Cells were considered viable if they were single, clear and 
round. An overlap between two or more cells was counted as 
two cells. Non-viable cells were defined as those absorbing 
the color of trypan blue. The measurement results of the 
observations were added together and calculation values   
obtained for the subjects of research using the formula:12

Number of cells =
(A+B+C+D)

4
x x 2 x sample dilution 

Note: Count the number of cells – both viable (unstained) and non-
viable (stained) in each of the four corner quadrants (A, B, C and D).

Data were then analised statistically using one-way 
ANOVA. A p-value less than 0.05 was considered 
statistically significant. 

RESULTS

All concentrations increased the number of fibroblasts. 
There were differences in formazan crystal formation 
between each concentration. This was due to the difference 
in the number of living cells in each extract concentration 
as presented in Figure 1. The optimum concentration was 
600 μg/ml which produced a high level of HGF proliferation 
as shown in Table 1. Extract concentrations of 1200 μg/
ml produced a false positive result due to the dark color as 
shown in Figure 1A.

The proliferation of HGF culture in both the control 
group and experiment group at 600 μg/ml extract 
applications showed a higher density under light microscope 

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.i4.p179–184

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181 Shabrina, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 December; 51(4): 179–184 

examination in the experiment group on both the first and 
second days, as shown in Figures 2 and 3. 

The number of fibroblast in experiment groups were 
higher compared to control groups. Anova statistical 

analysis showed that there were significant differences 
in average fibroblast numbers between groups, p=0.002 
(p<0.05) as presented in Table 2.

Table 1. Toxicity test results of C. caudatus leaf extract

No.
Control well 
with medium

Control well 
with HGF

Well HGF + 
1200 μg/ml 

extract

Well HGF 
+ 600 μg/ml 

extract

Well HGF 
+ 300 μg/ml 

extract

Well HGF 
+ 150 μg/ml 

extract

Well HGF 
+ 75 μg/ml 

extract

0.7240.7860.8941.0711.4170.660.0561

0.7250.7890.8741.0371.4130.6410.0572

0.7260.7680.8471.0581.3910.6670.0563

0.7280.7680.8561.0681.4130.6610.0564

0.7250.7690.8581.0711.4140.650.0575

0.7260.7710.8571.0691.4060.6620.0576

4.3544.6415.1866.3748.4543.9410.339Total

0.7260.7740.8641.0621.4090.657Mean 0.057

111119135168225.3Total living cell %

Figure 1. Figure fibroblasts after application of C. caudatus extracts for 24 hours under light microscope at 10x magnification. (A) 
Concentration of 1200 μg/ml. (B) Concentration of 600 μg/ml. (C) Concentration of 300 μg/ml. (D) Concentration of 150 
μg/ml. (E) Concentration of 75μg/ml.

Figure 2. Microscopic picture of fibroblasts on the first day (40x magnification). (A) Control fibroblasts on the first day. (B) Treatment 
of fibroblast cells.

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.i4.p179–184

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182Shabrina, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 December; 51(4): 179–184

DISCUSSION

This was an experimental in vitro study with an 
application of C. caudatus leaf extract on HGF cell culture. 
The study was carried out following a drug development 
sequence which comprised of in vitro examination, animal 
experiments (in vivo), clinical trials and preparation for 
marketing.9 Cell culture was obtained from human gingival 
cells because these could be cultured into primary cell line 
culture demonstrating a similar pattern of behavior to in 
vivo reactions compared to cell lines.13 Cell lines have been 
used for decades to produce culture, resulting in stronger 
cells often genetically and phenotypically different from 
their original networks which underwent morphological 
changes. Unlike cell lines, primary cells are isolated directly 
from the network, have a limited lifespan and expansion 
capacity. On the positive side, primary cells demonstrate 
normal cell morphology and retain many important 
observable markers and functions, and the data obtained 
from primary cells is more relevant for interpretation and 
can be generalized into an in vivo setting.14

This finding was in line with that produced by the 
research conducted by Wong et al15 indicating that primary 
cells are more sensitive to drugs than cell lines and tend 
to survive at higher concentrations and proliferation. 
In contrast, the lifespan of primary cells was shorter at 
16-24 hours after the administering of drugs at lower 
concentrations. The administering of 20 μM (6 μg/ml) 
cisplatin to primary cells resulted in a viability range 
of 64.0% cells, while the cell line with 33 μM (6.6 μg/
ml) cisplatin concentration produced a viability level of 
71.6% cells.15

Extract concentrations were set at 1200 μg/ml, 600 μg/
ml, 300 μg/ml, 150 μg/ml and 75 μg/ml. Dose reduction was 
based on a geometric series of measurements to evaluate 
the dose-cell response relationship to the exposure of the 
extract.11 All concentrations of C. caudatus extract were 
non-toxic as shown in Table 1. The concentration of 600 
μg/ml was selected because it showed the highest number 
of proliferated living cells. Moreover, the absorbance value 
of formazan crystals at a concentration of 600 μg/ml could 
be read spectrophotometrically without bias caused by the 
extremely dark color. This concentration was suitable for 
fibroblast cell proliferation compared to those below 600 
μg/ml because, according to the dose-response relationship, 
weaker extract concentrations will produce a lower number 
of living fibroblasts or will fail to produce optimum results. 
The concentration of 1200 μg/ml was rejected because it was 
found that significantly elevated proliferation rates would 
induce dense cell growth resulting in greater competition for 
nutrients in the media. As a result, the cells did not mature 
rapidly and experienced high mortality rates culminating 
in a false negative result. The possibility of such a result 
occurring also existed because the concentrated color 
of dense cells caused the spectrophotometric reading to 
indicate a higher level of absorbance. 

Fibroblast proliferation was significantly higher in the 
experiment group compared to that in the control group, p 
= 0.002 (p <0.05). This was due to the active ingredients in 
C. caudatus leaf extract containing catechins, polyphenols, 
flavonoids, vitamins C and E and saponins.9 Schuck et al16, 
citing Weisburg et al (2004), stated that catechins do not 
induce oxidative stress in normal human cells originating in 
the oral cavity because catechins in extracts can reduce ROS 

Table 2. Statistical analysis results of fibroblast numbers

Control and 
experiment group

Standard deviationAverage
Kolmogorov-

Smirnov
AnovaLevenne

0.29,082.9582,000K1

0.0020.782
0.28,366.6088,000P1

0.27,905.6995,000K2

0.26,519.20106,000P2

Figure 3. Microscopic picture of fibroblasts on the second day (40x magnification). (A) Control fibroblasts on the second day. (B) 
Treatment of fibroblast cells.

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.i4.p179–184

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183 Shabrina, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 December; 51(4): 179–184 

levels in normal cells, while causing intracellular oxidative 
stress in cancer cells. This indicates that the cathechin 
effect on normal and cancer cells worked in different 
biochemical pathways that induce normal cell proliferation. 

Polyphenol content promotes both anti-microbial and anti-
fungal activities that play a role in maintaining the growth 
of cell cultures. The catechins present in polyphenols 
can reduce ROS levels in normal cells, while flavonoids 
stimulate fibroblast synthesis and are able to balance the 
production of ROS with antioxidant capacity that promotes 
fibroblast growth.8

Other ingredients found in C. caudatus include 
high levels of vitamin C and E. Flavonoids increase the 
effectiveness of vitamin C conducive to the formation 
of fibroblasts.14 Ascorbic acid, also known as vitamin 
C, is necessary for normal responses to physiological 
stressors and its requirement increases during injury 
or stress. Studies have shown that physiological stress 
produces excessive ROS leading to vitamin C playing the 
role of activating intracellular signaling which regulates 
fibroblast proliferation.17

Terpenoids or essential oils, as well as polyphenol, 
promote antibacterial and antifungal activity. Fibroblasts 
are able to proliferate effectively because of the eugenol 
content of essential oils that damage the cell walls of 
bacteria causing damage to the cells themselves for example 
those of gram-positive bacteria, especially Streptococcus 
aureus. Phenolic compounds present in essential oils cause 
protein denaturation and bacterial cell death.8

Saponins, active substances that act as anti-microbes, 
increase cell membrane permeability and have antioxidant 
propoerties.18 Saponins can stimulate the formation of a cell-
extracellular matrix by stimulating fibronectin synthesis 
in fibroblasts capable of promoting the wound healing 
process.19 The saponin content stimulating transforming 
growth factor-beta 1 (TGF-β1) can affect fibroblast growth 
factor (FGF) in fibroblast cells thereby promoting the 
formation of collagen fibers. When FGF is stimulated by 
TGF-β1 fibroblast proliferation will be increased.20

Alkaloids represent one of the other active components 
in C. caudatus leaves with toxic properties that significantly 
affect physiological activity. Most alkaloids that have 
been isolated from plants are crystalline solids with a 
certain melting point.21 The toxic content of alkaloids in C. 
caudatus leaf extract was at small levels, caused no effect 
on cell culture and does not increase ROS but induced 
oxidative stress in normal cells. In this study, cell death 
occurred but there were also fibroblast proliferation that 
did not effect the results.22

The wound healing process is evident from several 
indicators, including an increase in the number of 
fibroblasts that will stimulate the collagen forming 
extra-cellular matrices. The proliferation of fibroblasts 
promoted by transforming growth factor-β (TGF-β) will 
increase collagen and fibronectin synthesis and promote 
extracellular matrix deposition.20

In the next stage, there is a decrease in endothelial cell 
proliferation and the number of fibroblast cells, but fibroblasts 
become more progressive in synthesizing collagen and 
fibronectin involving changes in the composition of extra-
cellular matrix (ECM).19 The ECM provides a sub-layer 
for cell attachment and effectively regulates cell growth, 
movement and differentiation propagated by growth factors 
and cytokines namely platelet-derived growth factor, FGF, 
TGF-β and interleukin-1, interleukin-4, immunoglobulin-g 
produced by leukocytes and lymphocytes during collagen 
synthesis. Remodeling will commence after an extracellular 
matrix is formed.20

An inherent weakness of this study was the fact that 
dense fibroblasts in the culture plate can perish because of 
an over-proliferation of their cells. Further research needs 
to be undertaken by reducing the number of cells to less 
than 5x104. Further study will be conducted to develop a 
herbal drug which promotes post-extraction tooth socket 
healing. It can be concluded that C. caudatus leaf extract is 
non-toxic to human gingival fibroblast culture resulting in 
a significant increase in fibroblast numbers. The optimum 
concentration of C. caudatus leaf extract to increase 
fibroblast proliferation is 600 μg/ml.

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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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