JURNAL FARMASI SAINS DAN KOMUNITAS, November 2021, 102-111 Vol. 18 No. 2
p-ISSN 1693-5683; e-ISSN 2527-7146
doi: https://doi.org/10.24071/jpsc.002525

*Corresponding author: Aan Edison
Email: Aanedison@gmail.com

INHIBITORY ACTIVITY OF SNAIL (Achatina fulica (Lam.) Bowdich) MUCUS
ON GROWTH OF MAMMARY CANCER IN RAT INDUCED WITH DMBA

(7,12-DIMETHYLBENZ(α)ANTHRACENE)

Aan Edison1*), Phebe Hendra2, B. Boy Rahardjo Sidharta1, Sri Herwiyanti3, Christy Jacub1

1Biology Study Program, Faculty of Biotechnology Universitas Atma Jaya Yogyakarta
2Pharmacy Study Program, Faculty of Pharmacy Universitas Sanata Dharma Yogyakarta

3Department of Histology and Cell Biology, Faculty of Medicine Universitas Gadjah Mada
Yogyakarta

Received April 14, 2020; Accepted March 2, 2021

ABSTRACT
Back to nature as a medication concept has been accepted widely because it has fewer side

effects than modern medicines. Researches on natural products as anticancer agent therapies are in
progress. This present research was conducted to determine that the inhibitory activity of snail
(Achatina fulica (Lam.) Bowdich) mucus inhibits the growth rate of mammary cancer in Sprague-
Dawley rats. Five groups of female rats, with four individuals each, were induced with 7,12-
dimethylbenz(α)anthracene (DMBA) for five weeks. Snail mucus was applied every seven days to
the treated rats with three different dosages (15, 20, and 25 mg/kg BW). Observations were done
on diameters and growth rate of the mammary cancer lump developed at the end of week 8, 10, 12,
14, and 16. Histopathological examination was carried out at the end of the 16th week. Inhibitory
activity results showed a row of average diameter of the cancerous lumps on rats with the
following details. The results obtained from the application of snail mucus at dosage of 15, 20,
and 25 mg/kg BW were at 0.40, 0.60, and 0.09 cm respectively along with average growth rate of
cancerous lumps at 1.50, 0.75, and 0.25. The histopathology results of the snail mucus treatment
at dosage of 15, 20, and 25 mg/kg BW showed normal tissue depiction and similarly normal
histopathological form indicated by the presence of their sub-clinic components. The results
showed that a snail mucus dose of 25 mg/kg BW was able to perform inhibitory activity on
growing mammary cancer in rats induced by DMBA.

Keywords: Achatina fulica; snail mucus; DMBA; mammary cancer; lump tissue

INTRODUCTION
Global Cancer Observatory data show

that every three minutes on every continent
in the world, there are cancer cases that
present lethal impact like what occurs in
breast cancer cases. Breast cancer
contributed 24.2% of the highest number of
cancer cases, followed by cervical cancer
(uteri) of 12.1% (Globocon, 2018).
According to the most recent report from
Indonesia in 2013 until 2018, the highest
number of events in breast cancer was 42.1

per 100,000 populations with an average
death rate of 17 per 100,000 populations.

Cancer treatment has been running in
Indonesia since 1920. Now, the world cancer
day is celebrated every 4th of February.
Cancer treatment depends on the level of
complexity of the growing cancer cells of
which are usually treated with surgery,
radiation and chemotherapy chemicals, and
immunotherapy (Globocon, 2018). In
Indonesia, there are at least 170 to 190 types
of cancer cases out of one hundred thousand

https://doi.org/10.24071/jpsc.002525
mailto:Aanedison@gmail.com


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Inhibitory Activity of Snail Achatina fulica (Lam.)… 103

patients, so there must be a proper diagnosis
of cancer. Mammary breast cancer is one of
the most discussed topics in Indonesia cancer
study. It is caused by carcinogenesis process
that improves cell abnormalities (Patrick,
2013).

Future research is attracted to the
substance 7,12-dimethylbenz(α)anthracene
(DMBA) as a cancer carcinogenic substance
(Wongso & Iswahyudi, 2013). 7,12-
dimethylbenz(α)anthracene also known as
DMBA belongs to the polycyclic aromatic
hydrocarbon group (Pitot & Dragan, 1996).
DMBA metabolites are the main components
of the free form of dihydrodiol. They are
potent mutagens in normal mammalian cells
(Pitot & Dragan, 1996). Snail mucus
(Achatina fulica) is used as an anti-cancer
treatment which causes healthy tissue
stratum to remain healthy but cancerous cells
to be inhibited (Matusiewicz et al., 2018).

Snails (Achatina fulica (Lam.)
Bowdich)—snails or by other names Giant
African land snail—were found in Bali in
1822 in the remote areas of Bali, Nusa
Penida, and Nusa Lembongan (Hoffman et
al., 2014; Vermeulen & Whitten, 1998). The
results of the study by Matusiewicz et al.
(2018) show that the protein fraction
extracted from snails provides a chemo
preventive healing effect on cancer cells.
Anticancer inhibitory activity of protein
fraction through the induction of apoptosis is
performed by inhibiting the expression of
enzyme topoisomerase (Ekobon et al., 2016).
This expression prevents protein
topoisomerase initiated by DMBA from
inhibiting the formation of cancer cells DNA
(Wongso & Iswahyudi, 2013).

Mucus is a natural material from the
secretory snails (Achatina fulica) with thick
concentration in the form of amino acids
such as glutamic acid, aspartate, glycine,
alanine, and histidine. Clear yellow mucus
with 99% moisture contains 4 mg/cm3
protein. Acharan sulfate is also found in
snails (Achatina fulica), which is a part of
glycosaminoglycan that has a main recurrent
disaccharide structure Alpha-DN-
acetylglucosaminyl and 2-O-sulfoalpha-L-

iduronic acid as a potential cytotoxic agent
(Islam & Linhart, 2003). This study aims to
determine the inhibitory activity of snail
mucus on the growth of mammary cancer in
rats induced with DMBA. Observations were
done on diameters and growth of the
mammary cancer lumps developed at the end
of week 8, 10, 12, 14, and 16.

METHODS
Snail mucus (Achatina fulica) was

obtained from snail breeders in Djengkol
Hamlet, Sragen, Central Java, Indonesia.
Materials needed for chemical carcinogenic
test induction were 7,12-
dimethylbenz(α)anthracene (Sigma Aldrich)
substances. The histopathological method
was hematoxylin and eosin of 1% staining.
Test animals were laboratory rats (Rattus
norvegicus), non-pregnant females Sprague-
Dawley and aged 40 days with weight of 60
grams (rat was obtained from veterinary of
Gadjah Mada University, Yogyakarta). This
study has obtained ethical clearance from the
Ethical Clearance Committee of the Health
Research Bioethics Committee, Duta
Wacana Christian University with Number
EC/960/C.16/FK/2019.

Snail (Achatina fulica) mucus preparation
Snail Achatina fulica mucus was

freshly harvested from six kilograms of
living snails during the four weeks of the
study. Mucus was removed from the snail
body by suppressing suppressors' stimulation
at the snail shell hole. Mucus would come
out about ± 1 to 2 ml when suppressed,
which was then collected (Sudjono et al.,
2012). Snail mucus was then stored at
temperature of 15oC and avoided from the
sunlight.

Determination of test animal groups
The rats that were tested had to be

adapted or acclimatized for seven days
before the study (Besselsen, 2004). The
number of groups used in this study is based
on the following formula for animal test.
Twenty-four female Sprague-Dawley rats
weighing 50 g were divided into 6 groups



Jurnal Farmasi Sains dan Komunitas, 2021, 18(2), 102-111

Aan Edison et al.104

namely control group with DMBA
(control DMBA induction), control group
with snail mucus treatment (control group),
DMBA induced with mucus dose of 15
mg/kg BW (dose I), DMBA induced with
mucus dose of 20 mg/kg BW (dose II),
DMBA induced with mucus dose of 25
mg/kg BW (dose III), and normal rats (with
no control group). Sprague-Dawley rats were
randomly divided into 6 experimental groups
with the code number of rats’ each mammary
gland as samples for the treatment test
observations.

Preparation of DMBA carcinogen (7,12-
dimethylbenz(α)anthracene)

Carcinogenic DMBA was orally
administered to the animal models of cancer.
DMBA solution is made of a DMBA powder
solution containing 7,12-
dimethylbenz(α)anthracene (DMBA) with
corn oil as a solvent. The test dose
calculation used a dose unit of 20 mg/kg
using a sample of the highest rat BW of 200
grams, and the maximum volume of the
application in rats was 1.0 mL (Zhao et al.,
2011). The frequency of DMBA induction
with injection dose in units of 20 mg/kg BW
with an interval of 48 hours and frequency of
twice a week was ten times induction for five
weeks. Carcinogenic substances were given
orally (intra-gastric) by tracing the direction
on the edge of the palate toward the
esophagus (Sigma, 2018).

Dose determination of the amount of
mucus (Achatina fulica)

Determination of the dosage of snail
mucus is to reveal the inhibitory effect on
cancer growth in rats induced by DMBA as
cancer inducers (Sigma, 2018). Snail mucus
was given in three different doses of 15, 20,
and 25 mg/kg BW. The treatment dose was
based on variations of calculating the dose of
the treatment with mucus snail according to
the concentration of the preliminary study
and literature finding for toxicity test before
treatment (Jacub et al., 2019).

Concentration in mg/ml was obtained by
defining out the preset amount of dose in

mg/Kg BW. While determining the dose is
calculated from the maximum concentration
from the highest rat weight which is 200
grams divided with the maximum volume of
administration of 2.0 mL (Zhao et al., 2011;
Meiyanto et al., 2007; Hendra, 2001). Snail
mucus was given orally after DMBA
induction as the post-initiation in test animals.
The treatment dose was carried out at 24-
hour intervals immediately after macroscopic
tumor examination due to DMBA induction.
The dose was given twice at 24-hour
intervals until the end of the trial period for
the treatment dose.

Mammary cancerous observation
(Palpation)

Palpation protocol in test animals was
done by calculating the diameter (± 50 mm
ratio) while observing the parts of the
mammary gland below the protruding part of
the enlarged organ. Sometimes other parts
besides the mammary duct will develop
cancer in animals. Palpation aimed to
determine the growth rate and diameter of
cancer in rats that had been induced with
DMBA as a carcinogenic part of cancerous
tissue. The average cancerous lumps were
obtained in centimeter unit. Mammary gland
was obtained in the last observation week
(Besselsen, 2004).

Excision procedure–histopathological
procedure

Histopathological tissue observation was
performed in Sprague-Dawley rats by
removing their organs in the form of
mammary glands and ovaries (Nurung et al.,
2016). In mamma tissue, two parts of the
tissue were made by placing them on a slide
(deparaffinized) for histopathological
examination using Hematoxilyn Eosin
staining which caused the color of the
granulation tissue of capillary endothelial
cells to turn brown. The cut was excised ± 50
mm off skin with a tissue as deep as fascia
including 0.3 to 0.55 cm of mammary gland.
The mamma tissue was examined by
stereological histology on the cellular part
(Meiyanto et al., 2007).



Jurnal Farmasi Sains dan Komunitas, 2021, 18(2), 102-111

Inhibitory Activity of Snail Achatina fulica (Lam.)… 105

Statistical analysis
Analysis was initially processed using

SPSS. It was then continued using Kruskal-
Wallis nonparametric to determine the real
differences of the growth and diameter of
cancers among groups with a 95%
confidence level. Mann-Withney Test was
the next procedure to obtain the mean among
groups (Gasperz, 1991). Histopathological
aspect was analyzed descriptively to find out
the comparison between component layers
on the cellular level and stereology.

RESULTS AND DISCUSSION
This study was purely experimental

research to find out the potential components
of snail mucus against carcinogenesis on
laboratory animals by administering a
carcinogenic chemical substance of 7,12-
dimethylbenz(α)anthracene in Sprague-
Dawley female rats. The results were
evaluated based on the growth rate and
diameter of cancer in each rat, as well as
histopathological analysis of the mammary
organs. The treatment was carried out at the
end of the 10th, 12th, 14th, and 16th week.
Figure 1 shows increasing cancer rates at the

end of the eighth week until the end of the
16th week (0 to 8 cancer lumps). This is
related to the length of DMBA induction as a
cause of cancer events due to mutations in
somatic cells in normal rats that will become
cancer cells. According to Hendra's (2001)
study, induction of DMBA (7,12-
dimethylbenz(α)anthracene) and TPA was
performed 12 times for 12 weeks. Cancer
induction with DMBA carcinogens would be
a stimulating factor for the growth of lumps
over time with an average lump growth of ±
20 mm.

The growth results showed the diameter
(cm) of the lump in cancer induction
experiments with DMBA carcinogen
compounds in female mice (Hennings et al.,
1990). The carcinogenesis of DMBA
substances is defined as the induction or
increase of neoplasia in cells. Genotoxic
compounds in DMBA substances
(commonly formed during carcinogenesis)
interact with genetic macromolecules (DNA)
from carcinogen adducts. DMBA activates
the kinase enzyme that influences the
proliferation and differentiation of cancer
cells (Pitot & Dragan, 1996).

Figure 1. The number and diameter of cancerous lumps induced by DMBA in each rat.

The data of rats developing mammary
cancer due to DMBA induction can be
observed in the bar chart above (Figure 1).
The results show that the first lump in the
mammary organ channel of the rat due to the
induction of DMBA cancer could already be
obtained in the seventh week until the middle

of the eighth week. This result is based on
the study research from Wongso and
Iswahyudi (2013) who reported that lumps
caused by cancer first appeared in rats
induced with DMBA carcinogenic
substances in the eighth week until the end of
the 13th week.



Jurnal Farmasi Sains dan Komunitas, 2021, 18(2), 102-111

Aan Edison et al.106

Table 1. Average growth and diameters (cm) of rat cancerous lumps in positive control group and experimental group

Treatment
The average growth of cancerous

lumps ± SD
Average diameter (cm) of
cancerous lumps ± SD

End of the week-16 End of the week -16
Group (+) DMBA 2.00 ± 0.82 3.09 ± 0.51
Control group 0 ± 0 0 ± 0
Snail mucus 15 mg/kg BW in 7 days +
DMBA

1.50 ± 1.00 0.40 ± 0.22

Snail mucus 20 mg/kg BW in 7 days +
DMBA

0.75 ± 0.96 0.60 ± 0.95

Snail mucus 25 mg/kg BW in 7 days +
DMBA

0.25 ± 0.50 0.09 ± 0.18

Kruskal Wallis Statistic Result P=0.058 P=0.016
Note.
SD: Standard Deviation
Control group: No treatment and no dosage
Significant differences (P < 0.05)

Based on the results, it shows the growth
of cancerous lumps in the snail mucus
treatment group at doses of 20 and 25 mg/kg
BW in the 16th week of observation. At the
end of the 16th observation week, the average
growth of mammary cancer in the DMBA
positive control group compared with the
snail mucus treatment group showed
differences. Those differences regarding the
growth rate and diameter of the lump were
caused by snail mucus treatment. These
results indicated that the three treatment
doses had the potency to inhibit the activity
of the cancer cells in the rats’ mammary
glands.

The results obtained in the end of the 8th,
10th, 12th, 14th, and 16th week of observation
on average DMBA lump diameter were 0,
0.86, 1.34, 1.47, and 1.55 cm (Figure 1). The
results among doses of 15, 20, and 25 mg/kg
BW at the end of the 16th week showed the
average lump growth of 0.40, 0.60, and 0.09
cm (Table 1). The treatment with snail
mucus at a dose of 25 mg/kg BW presented
the best potential to inhibit the diameter of
mammary tumors in Sprague-Dawley female
rats.

Statistical results of the Kruskal-Wallis
analysis (Table 1) inform that the variation

between the doses of 15, 20, and 25 mg/kg
BW for the positive and negative group has a
significant difference with each P-value of
<0.05. The result of the Kruskal-Wallis
statistical analysis is obtained at 0.016,
meaning that they are significantly different
(Gasperz, 1991). In the result of the Mann
Whitney statistical test, it is found that the
snail mucus treatment group at doses of 15,
20, and 25 mg/kg BW has a significantly
different diameter of the cancerous lump
compared to the positive group with P-value
below significant standards (p<0.05).

Statistically, the Mann-Whitney
statistical analysis has obtained a value of
0.018, meaning that it shows a significant
difference (p<0.05) (Gasperz, 1991). The
mean diameter of the lump due to cancer
between the control and snail mucus
treatment group with three dose variations in
the 16th week showed a significant difference.
At a dose of 25 mg/kg BW, the growth rate
of lumps due to cancer was significantly
different in the positive control group. This
result can be interpreted that snail mucus
treatment with three administered dose ranks
can inhibit the average diameter and growth
rate of the lump due to cancer in each group
of rats.



Jurnal Farmasi Sains dan Komunitas, 2021, 18(2), 102-111

Inhibitory Activity of Snail Achatina fulica (Lam.)… 107

Figure 2. Macroscopic appearance in positive control group for cancer due to the induction of DMBA (palpation
observing the parts of the mammary gland).

Note.
Thickening of an irregular shape resembling cancer around seeds skin (AE); there is a lump layer (Mammary Maligna)
(M); normal mammary layer (MN); the area of the normal mammary gland organ (Pt); mammary gland organ cancer
(MGO); normal mammary gland supporting mammary tissue stratum (ON1).

The changing macroscopic palpation in
the rat’s body show that most cancerous
growths are found in DMBA induced
mammary organs (Figure 2). The mammary
gland organ position is under the protruding

part of the enlarged part (Hadek, 1965). The
shape of the rat's mammary organ can be seen
at the bottom of the rat's body. Part of the skin
that protrudes out is called mammary gland
(Pt).

Pt

AE

M

MGO MGO

ON1

Pt

ON1

MN



Jurnal Farmasi Sains dan Komunitas, 2021, 18(2), 102-111

Aan Edison et al.108

Figure 3. Histopathological picture of cancer in mammary gland due to DMBA induction (hematoxylin and
eosinstaining).

Note.
Irregular epithelial thickening (AE); maligna (M); bleeding (P); mammary gland organs (MGO) at three
magnifications of 4, 10, 40X.

In terms of microscopic histology, some
damaged structures can be found (Figure 3)
namely the surface of gaps between the
epithelial cells making up the faint acini layer.
No duct layer is found in the histology picture
because the membrane cell has been separated
from the layer of the acini (Hadek, 1965).
There is a coarse core chromatin accompanied
with a bleeding of intestinal constituent parts
of the tunica intima caused by carcinogens
(Hadek, 1965; Husain et al., 2015). The
initiation of a DMBA carcinogenic substance
is defined as an event that occurs after
administration of a chemical, physical or
biological compound which can directly or
indirectly change the structure of the genetic
component of the cell (genotoxic).

The histopathological examination in
DMBA induction group rats has revealed that
the MGO mammary gland group has a
thickening of the layer with irregular cell
shape of the rat’s mammary ducts (Figure 3).
Besides the results of histopathology, there are
early signs of growth and development
towards cancer (malignant) in the form of
hyperplasia. The histopathological picture
depicts that DMBA initiates cancer in the duct

and mammary glands of rats (Figure 3) (Nansi
et al., 2015; Constantinou et al., 2003; Hadek,
1965).

Histopathological picture of the mammary
group of rats (ON1), appearing on normal
mammary gland (Figure 4) is a component of
the lactic duct (D) coated with epithelium
arranged by connective tissue (4x
magnification) (Nansi et al., 2015). The
presence of an acini (As) component in a thin
layer of tissue stratum without cancerous
growth shows a normal histological picture.
One to two layers of column epithelial cells
appear around the part of the lactating duct
(Husain et al., 2015).

The results of the analysis of other
histopathological groups show that there is no
cancer in groups treated with snail mucus for
each dose. The results of histopathology, when
compared with the histopathology of normal
mammary organ channels, show similarity in
cell shape marked by the presence of the
components making up the cell layer (Figure 4)
(Meiyanto et al., 2007). The third dose of snail
mucus of 25 mg/kg BW treatment does not
show the occurrence of cancer lump in
descript results on rat’s mammary.

MGO

(P)

4 X

MGO

(M)

10 X

(M)

MGO
o

40 X

(AE)

(AE)



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Inhibitory Activity of Snail Achatina fulica (Lam.)… 109

Figure 4. Histopathological features in normal group rats (hematoxylin and eosin staining).
Note.
The main component in the mammary organ Asinus (As); Duct (D); (ON1) normal group mammary gland organs
three magnifications 4, 10, 40X.

Histopathological group analysis results
show a description of mammary organ
channels in the ovaries and mammary glands
(three-dose) in a descriptive comparison to
groups with abnormal tissue stratum
(Meiyanto et al., 2007; Hadek, 1965). From
the results of the histopathological test, it is
revealed that snail mucus has the potential
inhibitory activity on cancer giving cytotoxic
effects on an animal cell. Empirically
concluding, snail mucus is potential for use as
cancer inhibition in female Sprague-Dawley
rats.

Snail mucus at a dosage of 25 mg/kg BW
may contain flavonoids in the mucus bioactive
components (Constantinou et al., 2003; Jacub
et al., 2019) or other flavonoids such as
phenoxodiol, genistein, and tamoxifen.
According to research findings by
Constantinou et al. (2003), component
flavonoids can inhibit protein synthesis by
deactivating topoisomerase from eukaryotic
initiation which then causes phosphorylation
in topoisomerase II, so that it fails to initiate
mRNA translation in the tumor cell cycle.
Some flavone derivatives can suppress tumor
cell growth by inhibiting various types of
metabolic enzymes one of which is
Topoisomerase II which is needed for DNA
replication and allows the separation of
chromosomes. The ability to inhibit protein

synthesis has been found in rat and human
cells (Hendra,2011; Constantinou et al., 2003).

Snail mucus is a secretory natural material
from snails with a yellowish color containing
4 mg/cm3 of protein and various amino acids
(Ekobon et al., 2016). Extract science data
from some literature, state that Snail mucus
contains phenoxodiol flavonoid derivatives,
glycoprotein, mytimacin-AF,
glycosaminoglycan, and achasin which are
effective in inhibiting breast cancer cells
(Constantinou et al., 2003; Ekobon et al.,
2016). Recent research from Poland shows
that tissue extracted from Helix aspersa snails
has a chemo preventive healing effect on
colon cancer cells (Matusiewicz et al., 2018).

CONCLUSION
It can be concluded that snail mucus has

an inhibitory effect on the growth and
diameter of mammary cancer in female
Sprague-Dawley rats induced by 7,12-
dimethylbenz(α)anthracene (DMBA). Snail
mucus at a dose of 25 mg/kg BW for 7
consecutive days can potentially inhibit the
growth and diameter of cancer in rats induced
by DMBA. Histopathological picture of the
mammary organ channel shows that there are
different histological features between groups
receiving snail mucus treatment with three
variations of doses and the positive control
group induced with 7,12-

(D)

(ON1) (ON1)

(As)

(D)

(ON1)

40 X10 X4 X



Jurnal Farmasi Sains dan Komunitas, 2021, 18(2), 102-111

Aan Edison et al.110

dimethylbenz(α)anthracene (DMBA) cancer in
rats’ mammary.

Suggestion for further research includes
the need for fractionation, isolation, and
purification of specific bioactive compounds
of snail mucus treatment samples. Research
can be continued using different and more
specific objects like human cell cultures
through preliminary cytotoxic applications in
the cancer cell.

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