210

Dental Journal
(Majalah Kedokteran Gigi)
2021 December; 54(4): 210–215

Original article

Effectiveness of capsaicin nanoparticle gel of Capsicum 
frutescens L. on oral squamous cell carcinoma in Rattus 
norvegicus

Fitri Aniowati1, Cantika Nadrotan Naim1, Nova Dwi Anggraeni2 and Pratiwi Nur Widyaningsih3
1Student of Dentistry, Faculty of Medicine, Jenderal Soedirman University, Purwokerto, Indonesia
2Student of Pharmacy, Faculty of Health Sciences, Jenderal Soedirman University, Purwokerto, Indonesia
3Departement of Dentistry, Faculty of Medicine, Jenderal Soedirman University, Purwokerto, Indonesia

ABSTRACT
Background: Oral squamous cell carcinoma (OSCC) is an oral cancer with a low life expectancy, less than five years after diagnosis. 
The drug therapy often used for OSCC patients is cisplatin, but it is considered to cause tumour persistence, drug resistance, and high 
toxicity. Therefore, it is important to test the development of alternative drugs from natural ingredients. One potential ingredient is green 
chilli pepper (Capsicum frutescens L.). It contains capsaicin that functions as an anticancer agent by suppressing BCa tumorigenesis 
so that proliferation is inhibited, as well as increasing and preventing p53 antibody mutations that play a role in cancer cell apoptosis. 
Purpose: This study aimed to compare effectiveness using capsaicin nanoparticle gel from green chilli pepper extract levels of 1% 
and 3.3% to reduce OSCC nodules. Methods: This study used 20 Rattus norvegicus that were randomly divided into five groups; 
C- (rat without treatment), C+ (rat induced to 7,12-Dimethylbenz(a)anthracene (DMBA)), E1 (DMBA exposed and given cisplatin, 
E2 (rat induced to DMBA and capsaicin extract nanoparticle gel with a concentration of 1%), and E3 (rat induced to DMBA and 
capsaicin extract nanoparticle gel with a concentration of 3.3%). The data were analysed statistically with the one-way ANOVA and 
least significance difference (LSD) test. Results: The comparison of mean nodule volume between C+ (5.834 ± 2.77 mm3) with E1 
(1.75 ± 0.37 mm3), E2 (1.747 ± 0.36 mm3), and E3 (1.812 ± 0.11 mm3) had a significant difference (p = 0.00, p ≤ 0.05). Conclusion: 
Capsaicin nanoparticle gel with green chilli pepper extract at levels of 1% (E2) reduces OSCC nodules by more than gel with green 
chilli pepper extract at 3.3% (E3) concentration.

Keywords: anticancer; capsaicin; OSCC

Correspondence: Fitri Aniowati, Student of Dentistry, Faculty of Medicine, Jenderal Soedirman University. Jl. Dr. Gumbreg No.1, 
Mersi Purwokerto 53112, Indonesia. Email: fitrianiowati12@gmail.com

INTRODUCTION

Cancer is one of the leading causes of death in the world. 
The prevalence of cancer in Indonesia has increased from 
1.4% in 2013 to 1.8% in 2018.1 Of the different types of 
oral cancer, 95% is oral squamous cell carcinoma (OSCC). 
OSCC is an oral cancer with a low life expectancy, less than 
5 years after diagnosis.2 OSCC occurs due to a multitude 
of factors such as smoking, betel chewing, and alcohol 
consumption.3

The drug therapy often used for OSCC patients is 
cisplatin, but cisplatin is considered to cause tumour 
persistence, drug resistance, and high toxicity.4 It is 

important to test the development of alternative drugs 
from natural ingredients, such as fruits and plants, to create 
anticancer benefits of price and applications that are more 
affordable for OSCC patients. One such potential ingredient 
is green chilli pepper (Capsicum frutescens L.) because it 
contains anticancer, high-antioxidant, pain-reliever, and 
anti-inflammatory benefits. These benefits are mainly due 
to the content of capsaicin. Capsaicin (8-methyl-N-vanillyl-
6-noneamide) is an alkaloid compound that is responsible 
for the spicy taste of green chilli peppers.4 Green chilli 
pepper (Capsicum frutescens L.) has the highest capsaicin 
content of all the chilli varieties at 2.11%. Capsaicin 
functions as an anticancer agent by suppressing BCa 

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 https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i4.p210–215

mailto:fitrianiowati12@gmail.com
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211Aniowati et al./Dent. J. (Majalah Kedokteran Gigi) 2021 December; 54(4): 210–215

tumorigenesis so that proliferation is inhibited, as well as 
increasing and preventing p53 antibody mutations that play 
a role in cancer cell apoptosis.6,7

Green chilli pepper (Capsicum frutescens L.) will be 
applied using a nanoparticle gel on the object of research, 
Wistar rats (Rattus norvegicus). Wistar rats were chosen 
as research material because they have an anatomy similar 
to humans.8 Nanoparticle gel preparations were selected 
because the particles are small, making it easier to reach 
the target. In addition, the use of nanoparticles will achieve 
higher bioavailability than oral preparations and is accepted 
by patients because it is practical, safe, and painless.9

With the low life expectancy of OSCC patients, 
drugs treatment such as cetuximab and cisplatin has high 
resistance and toxicity. Utilization of natural resources as 
the latest treatment developments is needed to overcome 
this problem. This study aimed to compare the effectiveness 
of using capsaicin nanoparticle gel from green chilli pepper 
extract at levels of 1% and 3.3% to reduce OSCC nodules. 
The hope is that the presence of green chilli pepper extract 
nanoparticles will inhibit the growth rate of OSCC with 
the right concentration of nanoparticle gel and facilitate 
the curing of OSCC. 

MATERIALS AND METHODS

The research was performed in an experimental laboratory 
using the method of randomized post-test only control group 
design for four months at Jenderal Soedirman University. 
The research had ethical clearance agreement number 125/
KEPK/VII/2021 and applied strict health protocols. 

Wistar rats aged two months with an initial body 
weight of 150–200 grams were the test animals obtained 
from the Gadjah Mada University, Medical Faculty 
Research Laboratory. The rats were divided into five 
groups. Capsicum frustescens was obtained from Kemutug 
Kidul, Baturraden, Banyumas, with 22 grams of urea 
fertilization in the plantation and got determination tests in 
the Environmental Laboratory of the Faculty of Biology, 
Jenderal Soedirman University.10

Capsaicin extraction was performed using 96% ethanol 
solvent, at a stirring speed of 200 rpm, a temperature of 
50ºC, and 4 hours by maceration method. The extract 
evaporated to form a thicker extract and filtrate. The sample, 
formed as Capsicum frustescens powder, was dissolved 
in a single solvent of n-hexane and methanol.11 Then, 5 
grams of the Capsicum frustescens powder was dissolved 

in 100 ml of methanol, with 10 ml taken for isolation. 
The solution had 10 ml of distilled water and n-hexane 
added to form a fraction containing purer capsaicin. After 
shaking the solution, the fraction that formed was placed in 
a vial. It was then placed in a desiccator for 24 hours in the 
refrigerator until crystals formed that proved it contained 
purer capsaicin. 11

The nanoparticles were prepared in 100-gram extract 
concentrations of 3.3% and 1%. The concentration used was 
based on research that stated that the capsaicin content of 
333 µg/mL has a significant effect and the highest cytotoxic 
activity on the OSCC cell line.12 Materials were all weighed 
according to the calculation. The gel was prepared by 
mixing 0.5 grams of a gelling agent (Carbopol) with heated 
water that was then allowed to form and expand the gel 
mass.13 Then 0.3 grams of methylparaben was dissolved 
in 15 grams of propylene glycol, and 1 gram of sodium 
metabisulfite was added. This was stirring until it was 
homogeneous. The solution was placed on a Carbopol 
base and homogenized. Extracts of 1 gram and 3 grams 
were mixed into the resultant base and homogenized. 
The remaining water was added to this base and again 
homogenized.14 The manufacture of nanoparticles was 
carried out by stirring on a magnetic stirrer for 4 hours.

Carcinogen induction in rats used a formula of 96 mg 
7,12-Dimethylbenz(a)anthracene (DMBA) dissolved in 24 
mL corn oil, vortexed for ± 15 minutes until homogeneous. 
Carcinogen induction was performed two times a week for 
two weeks by the right buccal mucosa injection route. The 
induction dose given was 20 mg/kg of a rat’s weight.15 Rats 
were anaesthetized using ketamine intramuscularly at a 
dose of 0.2 mL/200 gr of a rat’s weight and observed by 
the method of palpation of the buccal mucosa four times 
a week for two weeks. Rats were diagnosed with cancer if 
there were palpable nodules on the buccal mucosa.16 After 
observation and rats were diagnosed with cancer, treatment 
commenced and was carried out once a day for seven days. 
Each test group of Wistar rats received a marker, and the 
rats were acclimatized for one week. The rats then received 
an induced DMBA solution by injection of the right buccal 
mucosa. The rats were sampled using the method random 
sampling. They were divided into five treatment groups, 
and the treatments were carried out once a day for seven 
days (Table 1).

The Wistar rats were weighed after being divided into 
the five groups. Weighing occurred three times: after the 
acclimatization process, before DMBA was induced, and 
before treatment. These weights were recorded to help 

Table 1. Experiment group

Experiment group Treatment
Control – (C -) Rat without treatment
Control + (C+) Rat induced to DMBA
Experimental control 1 (E1) Rat induced to DMBA and cisplatin
Experimental control 2 (E2) Rat induced to DMBA and capsaicin extract nanoparticle gel with a concentration of 1%
Experimental control 3 (E3) Rat induced to DMBA and capsaicin extract nanoparticle gel with a concentration of 3.3%

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 https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i4.p210–215

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212 Aniowati et al./Dent. J. (Majalah Kedokteran Gigi) 2021 December; 54(4): 210–215

track the symptoms of cancer.16 A surgical procedure 
was performed on each rat three months after it was 
diagnosed with cancer. The rat was given a capsaicin extract 
nanoparticle gel using the cervical dislocation method. The 
rat’s head was cut off to observe the tumour tissue, then 
stained using toluidine blue, cleaned using saline, and stored 
in a sample pot containing 10% neutral buffered formalin 
(NBF). The variables obtained were nodule volume, length 
and width. The volume of the nodules was calculated by the 
formula (p x l2), and the length and width were measured 
in millimetres using callipers.17 The analysis used in this 
research are the normality and homogeneity tests, the one-
way ANOVA test, and post-hoc LSD. The ANOVA test and 
post-hoc LSD are completed if the results reach p ≤ 0.05. 

RESULTS

The rats’ weight results in Table 2 showed that there was a 
considerable weight loss before the inducement of DMBA 
and before treatment (p ≤ 0.05) in 3 weeks, with a difference 
in body weight between the two periods of 27.23 g (Table 
3). Cancer patients can experience the condition cachexia, 
and one of the symptoms of this is weight loss. 

Observation of OSCC nodules was carried out for two 
weeks after DMBA induction through palpation of the 
buccal mucosa four times a week. The results of clinical 
observations showed the formation of OSCC nodules on 
the right buccal of the rats in the form of nodules that 
extended to the outer cheek. The round nodules felt rubbery 
and contained tissue. They appeared purplish-red to black 
and were of exophytic, endophytic, or ulcerative types. 
The extension was on the extraoral, to the infraorbital, to 
the buccal anterior. Group 1 (C-) had no buccal nodules. 
Group 2 (C+) had exophytic-typical nodules with the 
largest volume, but some rats also had ulcerative-type 
lesions. Lesions in this group appeared to contain tissue in 
some parts that were necrotic and purplish-red in colour, 
spreading to the infraorbital and buccal areas of the front. 
Clinically, OSCC had degraded the tissue to the extent it 

Table 2. Weight change comparison

Weight measurement time n
Mean weight

(gr) ± SD

Weight before acclimatization 20 200.29 ± 24.3

Weight before DMBA induction 20 214.05 ± 24.7

Weight before treatment 20 186.81 ± 40.6

Table 3. Comparison of weight change between groups

Weight measurement time Mean difference P

Weight before acclimatization vs Weight before DMBA induction -13.762 0.174

Weight before acclimatization vs Weight before treatment 13.476 0.513

Weight before DMBA induction vs Weight before acclimatization 13.762 0.174

Weight before DMBA induction vs Weight before treatment 27.238 0.012*

Weight before treatment vs Weight before acclimatization -13.476 0.513

Weight before treatment vs Weight before DMBA induction -27.238 0.012*
*ANOVA, significant difference (p ≤ 0.05)

 

A B C D E

 Figure 1. Intergroup rat head morphology; A. Negative control group (C-); B. Positive control group (C+); C. The cisplatin treatment
group (E1); D. 1% nanoparticle gel treatment group (E2); E. 3.3% nanoparticle gel treatment group (E3)

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 https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i4.p210–215

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213Aniowati et al./Dent. J. (Majalah Kedokteran Gigi) 2021 December; 54(4): 210–215

could be seen externally on the rat’s head. Group 3 (E1) 
had exophytic nodules with volumes that were not as large 
as the other group and felt supple and filled with tissue, but 
externally there was no sign of redness. A difference in 
size and texture could be felt on both sides of the buccal. 
Group 4 (E2) had an exophytic type of nodule, almost the 
same nodule volume as Group 3, felt supple, and external 
inspection showed no redness on the outer buccal skin of 
the rats. Group 5 (E3) had an exophytic type of nodule, 
with a larger nodule volume than the other two treatment 
groups. External inspection revealed a reddish colour 
on the buccal outer skin of the rats, which indicates the 
progression of OSCC to almost the external structure of 
the rat (Figure 1).

Another indicator in determining the development of 
cancer cells is the measurement of nodule volume. The 
volume of the nodule was calculated by the formula (p x l2), 
and the length and width were measured in millimetres using 
callipers. The measurement of nodule volume occurred in 
all groups. A one-way ANOVA test performed on the 
nodule volume data of the five groups showed a significant 
difference in nodule volume between the five groups during 
the two-week observation (p ≤ 0.05). This difference 
indicates the effect of DMBA administration in inducing 
OSCC (C+) and the effect of capsaicin nanoparticle gel 
administration (in treatment groups E2 and E3).

The LSD post hoc test that compared between groups 
showed that the positive control group (C+) and the 
treatment groups (groups E1, E2, and E3) had a significant 
difference (p ≤ 0.05). Comparison between treatment groups 
(groups E1, E2, and E3) showed no significantly difference, 

but clinically there was a difference mean nodule volume in 
the measurement results (Table 4). Comparison indicated 
the difference in the volume of nodules between the groups 
that were not given any treatment (C+), with the groups 
treated with cisplatin (E1) and capsaicin nanoparticle gel 
separately (groups E2 and E3) (Table 5).

DISCUSSION

Patients with OSCC have several manifestations in the 
development of cancer cells, two of which are weight 
loss and the formation of OSCC nodules. There was 
considerable weight loss in the rats used in this study, before 
DMBA was induced and before treatment. This shows 
that weight loss is one of the symptoms of pain in cancer 
patients. Generally, cancer patients experience a decrease 
in their quality of life, and major weight loss is one of the 
most prominent signs of this reduction.18 Inducing DMBA 
in rats to cause breast cancer showed a decrease in body 
weight in rats, especially in the DMBA-induced group who 
died in the middle of the study. In addition to the weight 
loss of rats, this group also showed symptoms in the form 
of decreased appetite, then reduced movement, until their 
death.19 There was a substantial difference in body weight 
after the inducement of DMBA between the control group 
and the treatment group. This is because cachexia, a cancer-
induced weight loss condition, is initiated by cachectin, a 
tumour necrosis factor that breaks down fat and reduces 
fat-storing enzymes. In addition, a decrease in the rats’ feed 
intake could be a factor in their weight loss. This decrease 

Table 4. Comparison of mean volume of nodules

Groups n Mean volume nodule ± SD Sig.

Negative control 4 0 0.000*

Positive control 4 5.834 ± 2.77 0.000*

Cisplatin 4 1.75 ± 0.37 0.000*

1% capsaicin nanoparticle gel 4 1.747 ± 0.36 0.000*

3.3% capsaicin nanoparticle gel 4 1.812 ± 0.11 0.000*
*ANOVA significant difference (p ≤ 0.05)

Table 5. Comparison of mean volume of nodules each group

Groups
Negative 
control

Positive 
control

Cisplatin
1% capsaicin 

nanoparticle gel
3.3% capsaicin 
nanoparticle gel

Negative control

Positive control 0.000*

Cisplatin 0.097 0.001*

1% capsaicin nanoparticle gel 0.098 0.001* 0.998

3.3% capsaicin nanoparticle gel 0.087 0.001* 0.951 0.949
*post hoc LSD, a significant difference (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 https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i4.p210–215

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214 Aniowati et al./Dent. J. (Majalah Kedokteran Gigi) 2021 December; 54(4): 210–215

could be due to difficulty in accessing food due to lumps in 
the rats’ buccals.20 The mechanism of action of capsaicin 
on cachexia is not fully understood, but some literature 
states that the relationship between giving capsaicin to 
patients with cachexia affects the amount of food intake. 
Capsaicin is thought to increase food intake by induced 
vagal afferent signalling, which results in weight gain and 
decreased metabolism.21,22

The OSCC nodule formation that extends extra-orally 
looks purplish-red to blackish and reaches the infraorbital 
to the anterior buccal area. This supports the description of 
cancerous lesions that OSCC can be exophytic, endophytic 
or ulcerative. Lesions can also spread to several parts of 
the oral cavity and tend to be more common in areas with 
non-keratinized mucosa because it has a thinner barrier 
than other mucosa.23

Measurement of nodule volume is one indicator to 
detect the progression and spread of cancer. Changes in the 
size of cancer tissue indicate the development of cancer. 
This study measured the administration of the extract to 
cancer and noted whether a change occurred in the nodule 
volume.17 In general, cancer develops constantly, and the 
nodule volume increases gradually from day to day. This 
characteristic shows that the measurement of nodule volume 
can be an indicator of cancer development.17 Development 
of nodule volume also supports differences in post-DMBA 
induction in rats. Observations were made post-induction by 
palpation of the buccal mucosa. Nodules with an average 
size of 1.9 mm3 that developed after two weeks of induction 
were found in the DMBA-induced group, and no nodules 
were found in the control group. The results of the nodule 
volume measurement also showed a notable difference 
between the control group and the treatment group (p ≤ 
0.05). This difference indicates that the nodule volume in 
the treatment group was smaller than the positive control 
group. Comparison between the three treatment groups 
showed no major difference, but in the mean volume 
of nodules, there were differences in numbers between 
groups. There were differences of 0.01 between groups 
E1 and E2, and 0.1 between groups E2 and E3. Groups 
E1 and E2 had no real difference in their nodule volume 
measurements, indicating there is potential for a study to 
be developed on 1% capsaicin nanoparticle gel, used in E2, 
due to its anticancer effect, which was comparable with the 
standard OSCC treatment with cisplatin used in E1. The 
comparison between groups E2 and E3, namely the 1% and 
3.3% capsaicin nanoparticle gel treatment groups, showed 
that the 1% group had better results. This better result in the 
1% group is because the use of capsaicin at a dose of 3% 
can cause saturation of the capsaicin concentration, and so 
the absorption power of rats is not optimal.24 Previous in 
vivo studies state that capsaicin has mutagenic potential, 
depending on the dosage and the treatment period, which 
is why lower doses were non-mutagenic when given 
for several days. The 1% concentrate showed the same 
anticancer mechanism as in previous studies, with action 
induced G0/G1 phase cell arrest, inhibited tumour growth 

and promoted apoptosis.25,26 Therefore, administering 
anticancer agents to a nodule can slow the progression and 
development of cancer.17

Generally, normal cells have apoptotic ability with 
different triggers. Cancer cells form due to DNA damage 
that means cell division and replication cannot be controlled 
also do not have regulation in apoptosis. However, in 
preventing uncontrolled replication that causes cancer, the 
body naturally has tumour suppressor genes, one of which 
is the p53 gene in the p53 protein. The concentration of p53 
protein in normal cells is low, and if the cell is damaged 
by DNA causing uncontrolled replication, activation of 
p53 protein is required to prevent further cell division. 
The p53 protein can inhibit the G1 phase in cell division. 
The inhibited G1 phase can provide an opportunity for 
cells to repair DNA or carry out apoptosis to suppress the 
further development of cancer cells.27 Capsaicin is thought 
to be able to phosphorylate p53 to inhibit the growth of 
existing tumours. The cytotoxic effect appears by giving 
various doses of capsaicin from the extraction of Capsicum 
annuum L. var. angulosum against human squamous cell 
carcinoma and human submandibular gland carcinoma. 
The administration of capsaicin can activate p53 protein 
that will increase apoptosis in cancer cells.28

DMBA induction could lead to serious differences 
in body weight between the groups and the growth of 
cancerous nodules on the buccal mucosa. Administration 
of the capsaicin nanoparticle gel with 1% and 3.3% 
concentrations, along with cisplatin, can suppress the 
growth of cancer cells when viewed from the morphology 
of the nodules and the measurement of the nodule volumes 
between groups. Nevertheless, capsaicin nanoparticle gel 
from green chilli pepper extract at levels of 1% reduces 
OSCC nodule more than 3.3% concentration.

We suggest further research using the same green chilli 
pepper (Capsicum frutescens L.) or another variety of chilli 
pepper. We also suggest that future research use various 
concentrations and testing using histopathology and other 
apoptosis cell activities.

ACKNOWLEDGEMENTS

The author is grateful to Unsoed Medical Pharmacy 
Laboratory for technical support for this research and the 
lecturers for input and revisions to the article. There were 
no conflicts of interest while conducting the research and 
write up.

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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 https://e-journal.unair.ac.id/MKG/index
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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 https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i4.p210–215

https://e-journal.unair.ac.id/MKG/index
http://dx.doi.org/10.20473/j.djmkg.v54.i4.p210-215