178

Dental Journal
(Majalah Kedokteran Gigi)
2023 September; 56(3): 178–183

Original article

Toxicity test of Stenochlaena palustris extract based on kidney 
histopathology examination

Maharani Laillyza Apriasari1, Tiara Intan Permata Sari2, I Wayan Arya Krishnawan Firdaus2
1Department of Oral Medicine, Faculty of Dentistry, Universitas Lambung Mangkurat, Banjarmasin, Indonesia
2Department of Oral Biology, Faculty of Dentistry, Universitas Lambung Mangkurat, Banjarmasin, Indonesia

ABSTRACT
Background: Kalimantan’s people consume Stenochlaena palustris leaf extract as food and for traditional medicine. The bioactive 
components of Stenochlaena palustris leaf extract are flavonoids, alkaloids, saponins, and tannins. An in vitro study shows that the 
leaf extract has no toxic effect, so it can be used as an alternative drug in oral health, such as in mouthwashes or topical ulcer drugs. 
Purpose: This study aims to analyze the toxic effects of Stenochlaena palustris leaf extract based on the bleeding and lesions resulting 
from necrosis in kidney by using histopathology examination. Methods: The Stenochlaena palustris leaves were extracted using 95% 
ethanol and then given to male Wistar strain (Rattus norvegicus) with a 2,000, 2,500, and 3,000 mg/kg/body weight two times a day 
for fourteen days. The kidneys were collected and subjected to histopathology examination. Results: There are higher bleeding and 
necrosis lesion rates in the 2,500 and 3,000 mg/kg/body weight of Stenochlaena palustris leaves extract group compared to the control 
and 2,000 mg/kg/body weight of Stenochlaena palustris leaves extract group (p<0.05). Conclusion: Stenochlaena palustris leaf extract 
showed no toxic effect at doses of 2,000 mg/kg/body weight.

Keywords: antioxidant; bleeding; necrosis; Stenochlaena palustris leaves; toxicity test; medicine
Article history: Received 1 December 2022; Revised 20 January 2023; Accepted 9 February 2023; Published 1 September 2023

Correspondence: Maharani Laillyza Apriasari, Department of Oral Medicine, Faculty of Dentistry, Universitas Lambung Mangkurat. 
Jl. Veteran 128B, Banjarmasin, Indonesia Email: maharaniroxy@gmail.com

INTRODUCTION

South Kalimantan has various types of ferns that are 
potentially medicinal plants. Based on empirical data, 
Stenochlaena palustris is eaten as a vegetable and used 
as a breast milk enhancer and alternative medicine to 
cure anemia and allergies and relieve fever.1 The public 
demand for herbal ingredients is increasing because of 
science and technology’s rapid development and progress, 
which is encouraging the development of naturally derived 
alternative medicines. In addition, these natural ingredients 
are more affordable and easier to obtain compared to 
drugs made with chemicals and are considered to have 
minimal side effects.2 Stenochlaena palustris leaves 
contain various secondary metabolites. Based on the 
results of phytochemical screening by Debnath et al.,3 the 
ethanolic extract of Stenochlaena palustris leaves contains 
flavonoids, saponins, alkaloids, steroids, and tannins. 
Flavonoids have a content of 503.56 mg QE/g. Alkaloids, 

saponins, steroids, tannins, and total phenol were 11.56%, 
8.06%, 3.43%, 23 mg GAE/g, and 51.69 ± 1.28 mg GAE/g, 
respectively. Tannins are antioxidants that accelerate the 
epithelialization process. Steroids and saponins are anti-
inflammatory and antiseptic.3–5

There have been several studies on the extract of 
Stenochlaena palustris leaves. One tested the toxicity of 
BHK-21 fibroblast cells and concluded that 10%, 20%, 
and 30% concentrations of the Stenochlaena palustris leaf 
extract were toxic to BHK-21 fibroblasts. In comparison, 
the concentrations of 40%, 50%, 60%, 70%, 80%, and 90% 
were proven to be non-toxic to BHK-21 fibroblast cells.  
This study concluded that the extract of Stenochlaena 
palustris leaves could increase cell viability because 
it contains flavonoids with non-enzymatic antioxidant 
functions that inhibit cell damage caused by reactive oxygen 
species (ROS).6

Therefore, antioxidants in Stenochlaena palustris 
leaves have the potential to heal wounds because of their 

Copyright © 2023 Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 158/E/KPT/2021. 
Open access under CC-BY-SA license. Available at https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v56.i3.p178–183

mailto:maharaniroxy@gmail.com
https://e-journal.unair.ac.id/MKG/index
https://doi.org/10.20473/j.djmkg.v56.i3.p178-183


179Apriasari et al. Dent. J. (Majalah Kedokteran Gigi) 2023 September; 56(3): 178–183

granular tissue formation ability, fibroblast proliferation, 
and collagen fiber production.7 Research has not found the 
toxicity or side effects of Stenochlaena palustris herbal 
products used as medicine to heal wounds. It has been 
widely used in the community. Several factors, including 
the accuracy of the dose, timeliness, and method of use, 
must be considered when taking natural treatments, such 
as Stenochlaena palustris leaves, as a drug to heal wounds. 
Therefore, it is necessary to carry out further testing to 
protect the user community from potentially detrimental 
effects and to ensure the safety of its use.8 Hazard data is 
obtained using a toxicity test that detects the poisonous 
effect of a substance on a biological system and receives 
specific dose-response data from the test preparation. 
The test detects the presence of toxins in a substance and 
determines the toxin’s target organ and its sensitivity after 
the acute administration of the compound for 14 days. 
This toxicity test’s parameters include clinical symptoms, 
subject death, and organ histopathology.9

The kidneys often receive the unwanted effects of drugs. 
Suppose the content of the extract that enters the body 
exceeds normal conditions. In that case, it will decrease the 
kidneys’ ability to concentrate xenobiotic substances in the 
cells, resulting in the accumulation of toxic substances that 
cause damage to the kidneys.10 The relatively high blood 
flow to the kidneys exposes them to substances carried in 
the circulatory system, so toxic substances can quickly 
damage the kidney, causing changes in structure and 
function. Damage to the nephrons can occur in the tubules, 
renal corpuscles, and capillaries. The conditions of toxicity 
commonly found in the kidneys include cell necrosis, 
cell degeneration, and bleeding.11 Furthermore, the study 
analyzes the toxic effects of three different Stenochlaena 
palustris leaf extracts (2,000, 2,500, and 3,000 mg/kg/body 
weight) based on the bleeding and necrosis found in kidney 
tissue using a histopathology examination.

MATERIALS AND METHODS

The test used 16 male Wistar rats (Rattus novergicus) aged 
8–12 weeks, with body weights between 200–250 g, and all 
in good health. The Wistar rats usually ate 20% of their total 

body weight, so in a laboratory adaptation, they were fed 40 
g once daily for one week. Boiled water was given in 500 
ml bottles. The subjects were grouped by simple random 
sampling and divided into four groups, each consisting 
of four rats. The protocol of this study was approved by 
the ethical committee of the Faculty of Dentistry, the 
Universitas Lambung Mangkurat, with registration number 
016/KEPKG-FKGULM/EC/III/2022. 

Greenish mature leaves (12 kg) of Stenochlaena 
palustris were taken in the Anjir Barito Kuala Region. The 
leaves were washed, cut into small pieces, and dried in an 
oven at 40°C for four hours. After, the leaves were crushed 
in a blender and macerated with 95% ethanol for 72 hours.12 
Upon finishing, the solution was filtered with WH40 filter 
paper until a clear brownish liquid was obtained. In the next 
stage, a vacum rotary evaporator evaporated the solvent 
for four to six hours. It was then heated with a water bath 
to get a brownish liquid residue.  Ethanol-free was tested 
with potassium dichromate (K2Cr2O7) on 3 ml of ethanol. 
The extract was then stored in a 10°C refrigerator to 
prevent oxidation. The doses of the extract were prepared 
by diluting the extract with distilled water.1

The toxicity test was performed by giving the 
Stenochlaena palustris per-oral to the subject with a 
gastric probe two times a day for 14 days. The subjects 
were divided into four groups listed in Table 1. At the end 
of the day’s treatment, the subjects were fasted and given 
only water for 8–12 hours.

On the 15th day, the subjects were sacrificed by giving 
intraperitoneal injection using 0.5 ml of ketamine.13 The 
kidneys were collected, cleaned, wrapped in a white cloth, 
and buried at a depth of ± 50 cm.14 The kidneys were then 
washed with NaCl and soaked with 10% BNF solution for 
tissue fixation and process for further processing.

The bleeding and necrosis lesions were analyzed using 
histopathology with hematoxylin–eosin (HE) staining. The 
bleeding lesions were characterized by red blood cells 
migrating from the vasculature into the tissue between the 
proximal tubular spaces. In contrast, the necrosis lesions 
were characterized by changes in shape and cell nucleus 
(darker nucleus), indicating the presence of pyknosis. The 
bleeding and necrosis lesions on kidney cells were counted 
and scored as listed in Table 2.15

Table 1. The distribution of subjects in the toxicity test

Group Dose

Control 1 ml of distilled water

P1
2000 mg/kg/body weight Stenochlaena 
palustris extract (1 ml)

P2
2500 mg/kg/body weight Stenochlaena 
palustris extract (1 ml)

P3
3000 mg/kg/body weight Stenochlaena 
palustris extract (1 ml)

Table 2. Bleeding and necrosis lesion scoring

Bleeding Appearance Score

No bleeding lesion 0

Mild bleeding (<25% area) 1
Moderate bleeding (25–50% area) 2
Severe bleeding (>50% area) 3

Necrosis Lesion

No necrosis lesion 0
Mild necrosis (<25% area) 1
Moderate necrosis (25–50% area) 2
Severe necrosis (>50% area) 3

Copyright © 2023 Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 158/E/KPT/2021. 
Open access under CC-BY-SA license. Available at https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v56.i3.p178–183

https://e-journal.unair.ac.id/MKG/index
https://doi.org/10.20473/j.djmkg.v56.i3.p178-183


180 Apriasari et al. Dent. J. (Majalah Kedokteran Gigi) 2023 September; 56(3): 178–183

RESULTS

The histopathology analysis of the bleeding lesion was 
characterized by red blood cells migrating from the 
vasculature into the tissue between the proximal tubular 
spaces (black arrow) (Figure 1). The kidney tissue showed 
mild intratubular bleeding (< 25% area) in groups that were 
given Stenochlaena palustris extract with 2,500 and 3,000 
mg/kg/body weight (Figure 1C–D). The type of bleeding 
lesion was petechial, measuring 1–2 mm. There were no 

histopathological changes in bleeding in control and 2,000 
mg/kg/body weight Stenochlaena palustris extract groups 
(Figure 1A–B).

The 2,500 and 3,000 mg/kg/body weight Stenochlaena 
palustris extract groups showed higher bleeding lesions 
than the control and 2,000 mg/kg/body weight Stenochlaena 
palustris extract (p<0.05). There is no significant 
difference in bleeding lesions in the control and 2,000 
mg/kg/body-weight Stenochlaena palustris extract groups                  
(p>0.05). 

Figure 1. The histopathology of a bleeding lesion in the kidney tissue. (A) control; (B) 2,000 mg/kg/body weight Stenochlaena palustris 
extract; (C) 2,500 mg/kg/body weight Stenochlaena palustris extract; and (D) 3,000 mg/kg/body weight Stenochlaena 
palustris extract. Magnification 400x, hematoxylin–eosin staining.

  

 

Figure 2. The histopathology of a necrosis lesion in the kidney tissue. (A) control; (B) 2,000 mg/kg/body weight Stenochlaena palustris
extract; (C) 2,500 mg/kg/body weight Stenochlaena palustris extract; and (D) 3,000 mg/kg/body weight Stenochlaena 
palustris extract. Magnification 400x, hematoxylin–eosin staining.

Copyright © 2023 Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 158/E/KPT/2021.
Open access under CC-BY-SA license. Available at https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v56.i3.p178–183

https://e-journal.unair.ac.id/MKG/index
https://doi.org/10.20473/j.djmkg.v56.i3.p178-183


181Apriasari et al. Dent. J. (Majalah Kedokteran Gigi) 2023 September; 56(3): 178–183

The necrosis lesion in histopathology analysis is 
characterized by the changes in shape and cell nucleus 
(darker nucleus) indicating the presence of pyknosis (black 
arrow) (Figure 2). The kidney showed mild necrosis (<25% 
area) in groups with 2,500 and 3,000 mg/kg/body weight 
Stenochlaena palustris extract (p<0.05) (Figure 2C–D). 
No necrosis lesion was observed in the control and 2,000 
mg/kg/body-weight Stenochlaena palustris extract groups 
(Figure 2A–B).

DISCUSSION

The histopathological changes in the kidneys are usually 
caused by substances that enter the bloodstream and 
that are toxic to the body. Inappropriate use of natural 
ingredients can potentially cause organ damage, such as 
the kidney. This is because the kidney is an organ that 
often accumulates unwanted effects from the use of drugs 
taken orally.10,11 Based on the results of statistical tests on 
the histopathological appearance of bleeding, it was found 
that the 2,000 mg/kg/body weight group had no significant 
difference from the control. In the treatment group at 
a dose of 2,500 mg/kg/body weight and the treatment 
group at a dose of 3,000 mg/kg/body weight, there was a 
significant difference with the control group, suggesting 
the treatment was potentially toxic to the kidneys of                                                                              
Wistar rats.

In the control group that was given distilled water, there 
was no histopathological appearance of bleeding. This 
indicates that the administration of distilled water is safe 
for the kidney of rats. According to research by Maliangkay 
et al.,16 distilled water does not have the potential to have a 
toxic effect because it is not an irritant. The administration 
of a dose of 2,000 mg/kg/body weight of Stenochlaena 
palustris leaf extract did not cause any signs of bleeding. In 
the P1 group who were given the 2,000 mg/kg/body weight 
Stenochlaena palustris extract, no bleeding was seen. This 
is in line with the research by Alsawaf et al.17 who found 
that the use of flavonoids at the right dose will not cause 
toxic effects on the kidneys of Wistar rats. Sudira et al.18 
stated that the presence of flavonoids strengthens blood 
vessels and inhibits lipid peroxidation through peroxidase 
activation of hemoglobin in anticipation of damage caused 
by free radicals. Flavonoids can prevent hemolysis of red 
blood cells caused by free radicals.19 

The treatment group at a dose of 2,500 mg/kg/body 
weight and the treatment group at a dose of 3,000 mg/kg/
body weight had a significant difference from the control 
group. In both groups, there was a histopathological 
appearance of mild bleeding <25%. According to research 
by Rafe et al.,19 tubular bleeding that resulted from toxic 
effects occurred in the treatment group that consumed a 
high dose of the extract. Saponin is one of the secondary 
metabolites that affect the occurrence of bleeding with 
the use of Stenochlaena palustris leaf extract. Saponins 
are membranolytic which causes disintegration of the 

capillary endothelial layer, causing bleeding in the rats’ 
kidneys. Saponins injure the lipid bilayer of the protein 
membrane of red blood cells, resulting in an inflammatory 
response.18 The two stages of inflammation are the vascular 
stage and the late stage. The vascular stage is associated 
with vasodilation and increased capillary permeability 
where blood substances leave the plasma. The late stage 
occurs when leukocytes infiltrate the inflamed tissue. 
This causes the release of various mediators such as 
histamine, prostaglandins, and leukotrienes which are 
produced from plasma. Prostaglandins have a vasodilating 
effect, relax smooth muscles, and increase capillary 
permeability. Histamine plays a role in the earliest 
changes, causing vasodilation in arterioles which is 
preceded by initial vasoconstriction and increased capillary                                                                         
permeability. This causes changes in the distribution of red 
blood cells, such as in slow blood flow when red blood 
cells clump and are consequently pushed to the edge. 
White blood cells stick to the walls of blood vessels with 
slower blood flow. Changes in permeability that occur 
cause blood to come out of the blood vessels and collect 
in the tissues.20,21 

The results of statistical tests on the histopathological 
appearance of necrosis showed that the treatment group 
at a dose of 2,000 mg/kg/body weight had no significant 
difference from the control group. In the treatment group 
at a dose of 2,500 mg/kg/body weight and the treatment 
group at a dose of 3,000 mg/kg/body weight, there was a 
significant difference with the control group. According 
to research, Makiyah et al.,15 if the treatment group had 
a significant difference from the control group, the group 
was potentially toxic to the kidneys based on necrosis. In 
the microscopic observation of the control group that was 
only given distilled water, there is no histopathological 
change in necrosis because water is not an irritant, so it is 
not potentially toxic to organs.

The P1 group, which was given a dose of 2,000 mg/
kg/body weight of Stenochlaena palustris leaf extract, did 
not show any histopathological appearance of necrosis. 
The right dose of flavonoids has antioxidant potential to 
inhibit oxidation reactions by neutralizing free radicals 
and preventing cell damage. This is due to the content 
of secondary metabolites possessed by the extracts of 
the Stenochlaena palustris leaves, such as flavonoids 
and phenolics, which have the ability to inhibit free 
radicals and oxidative reactions.22 As antioxidants, the 
direct mechanism of action for flavonoids is to stabilize 
free radicals by complementing their lack of electrons 
and inhibiting the chain reactions that form the cell-
damaging free radicals. The indirect mechanism of action 
of antioxidants is the inhibition of the enzymes involved 
in the production of free radicals by neutralizing and 
suppressing the formation of ROS so that their number 
decreases and the activity of superoxide dismutase (SOD) 
enzymes increases. Antioxidants can modulate free radical 
reactions by reducing lipid hyper peroxides and hydrogen 
peroxide (H2O2), thereby preventing the occurrence of 

Copyright © 2023 Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 158/E/KPT/2021. 
Open access under CC-BY-SA license. Available at https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v56.i3.p178–183

https://e-journal.unair.ac.id/MKG/index
https://doi.org/10.20473/j.djmkg.v56.i3.p178-183


182 Apriasari et al. Dent. J. (Majalah Kedokteran Gigi) 2023 September; 56(3): 178–183

lipid peroxidation. SOD plays a role in catalyzing the 
dismutation reaction of superoxide anion free radicals 
(O-) into hydrogen peroxide and oxygen, thereby turning 
them into products that are more stable and harmless                                  
to cells.23

In the treatment group, a dose of 2,500 mg/kg/body 
weight and a dose of 3,000 mg/kg/body weight showed 
a histopathological appearance of necrosis. The results of 
statistical tests stated that the treatment group at a dose of 
2,500 mg/kg/body weight and the treatment group at a dose 
of 3,000 mg/kg/body weight had significant differences 
from the control group so that both treatment groups were 
potentially toxic to the kidneys of rats. Tubular epithelial 
cell necrosis is caused by excessive intake of secondary 
metabolites contained in the extract that are nephrotoxic. 
Flavonoids is one of the potentially toxic contents in 
Stenochlaena palustris leaf extract. Flavonoids in high 
concentrations can be pro-oxidants. Quercetin is one of the 
compounds that can be prooxidant among these flavonoid 
compounds.24

When there are too many free radicals, the endogenous 
antioxidants will deplete their rate of use compared to 
their rate of regeneration. An imbalance between pro-
oxidants and antioxidants in the body will result in an 
increased rate of free radical formation, resulting in an 
increase in oxidative stress that causes lipid peroxidation, 
oxidized DNA, and misfolded proteins. This results in the 
accumulation of covalent bonds in the tubular membrane 
with free radicals, resulting in damage to the renal tubules. 
Pro-oxidants cause oxidative stress and mitochondrial 
dysfunction. Mitochondrial dysfunction is a condition 
characterized by impaired mitochondrial biogenesis, altered 
membrane potential, reduced number of mitochondria, and 
altered protein oxidative activity due to the accumulation of 
ROS in cells and tissues. Mitochondrial dysfunction causes 
hydropic degeneration due to impaired active transport. 
The disturbed osmosis process causes water to enter the 
cell so that the cell swells with the vacuole, and the cell 
nucleus enlarges. Cells undergoing hydropic degeneration 
and that are continuously exposed to toxic compounds will 
become necrotic.25–27

It can be concluded that there was no toxic effect 
on the administration of 2,000 mg/kg/body weight dose 
of Stenochlaena palustris leaf extract to the kidney of 
Wistar rats based on the histopathological appearance 
of bleeding and necrosis. There was a toxic effect on 
the administration of the Stenochlaena palustris leaves 
extract at a dose of 2,500 mg/kg/body weight and a dose 
of 3,000 mg/kg/body weight on the kidney of Wistar rats 
based on the histopathological appearance of bleeding                                                       
and necrosis.

ACKNOWLEDGEMENT

The authors thank to Faculty of Dentistry, Universitas 
Lambung Mangkurat that have supported the research.

REFERENCES

 1.  Syamsul ES, Hakim YY, Nurhasnawati H. Penetapan kadar 
flavonoid ekstrak daun kelakai (Stenochlaena palustris (Burm. F.) 
Bedd.) dengan metode spektrofotometri UV-VIS. J Ris Kefarmasian 
Indones. 2019; 1(1): 11–20. 

 2.  Firdaus IWAK, Dewi N, Fuady RI, Apriasari ML. Antibacterial 
effect of kelakai leaf extract (Stenochlaena palustris (Burm) Bedd.) 
for inhibiting Enterococcus faecalis. ODONTO  Dent J. 2022; 9(1): 
110–8. 

 3.  Debnath SL, Kundu P, Ahad MF, Saha L, Biswas NN, Sadhu SK. 
Investigation of phytochemical and pharmacological assessment 
of ethanol extract of Stenochlaena palustris- an edible fern of 
Sundarbans. J Med Plants Stud. 2021; 9(3): 226–32. 

 4.  Chear NJ-Y, Khaw K-Y, Murugaiyah V, Lai C-S. Cholinesterase 
inhibitory activity and chemical constituents of Stenochlaena 
palustris fronds at two different stages of maturity. J Food Drug 
Anal. 2016; 24(2): 358–66. 

 5.  Awang-Kanak F, Abu Bakar MF. Traditional vegetable salad (ulam) 
of Borneo as source of functional food. Food Res. 2019; 4(1): 
1–12. 

 6.  Panche AN, Diwan AD, Chandra SR. Flavonoids: an overview. J 
Nutr Sci. 2016; 5: e47. 

 7.  Ahmed OM, Mohamed T, Moustafa H, Hamdy H, Ahmed RR, 
Aboud E. Quercetin and low level laser therapy promote wound 
healing process in diabetic rats via structural reorganization and 
modulatory effects on inflammation and oxidative stress. Biomed 
Pharmacother. 2018; 101: 58–73. 

 8.  Arundina I, Tantiana, Diyatri I, Surboyo MDC, Adityasari R. Acute 
toxicity test of liquid smoke of rice hull (Oryza sativa) on mice (Mus 
Musculus). J Int Dent Med Res. 2020; 13(1): 91–6. 

 9.  Badan Pengawas Obat Dan Makanan Republik Indonesia. Peraturan 
Kepala Badan Pengawas Obat Dan Makanan Republik Indonesia 
Nomor 7 Tahun 2014 Tentang Pedoman Uji Toksisitas Nonklinik 
Secara In Vivo. 2014. p. 3–4.Available from: https://peraturanpedia.
id /perat u ra n-bada n-pengawas- obat- da n-ma ka na n-nomor-7-                  
tahun-2014/.

10.  Meles DK, Wurlina W, Mustofa I, Zakaria S, Basori A, Hariadi M, 
Safitri E, Cempaka Putri DKS, Suwasanti N. Toxicity, stability and 
renal histopathology of alkaloid of jarong (Achyranthes aspera Linn.) 
(Caryophyllales: Amaranthaceae) leaf on mice. Philipp J Vet Med. 
2018; 55(Special Issue): 35–42. 

11.  Sudjarwo, Widiastuti H, Primaharinastiti P, Prihatiningtyas S. 
Toxicity test from Gloriosa Superba L leaves extract in rats (Rattus 
Novegicus). Int J Pharm Pharm Sci. 2014; 6(5): 183–7. 

12.  Setyorini D, Firdaus IWAK, Oktiani BW. Comparison of inhibitory 
activity of kelakai leaves extract with Ciprof loxacin against 
Aggregatibacter actinomycetemcomitans ATCC® 6514TM. Dentino 
J Kedokt Gigi. 2019; 4(2): 199–204. 

13.  Silverman J, Suckow MA, Murthy S. The IACUC Handbook. 3rd ed. 
St Louis: CRC Press Taylor & Francis Group; 2014. p. 377–416. 

14.  Fajriani N, Carabelly AN, Apriasari ML. The effect of toman fish 
extract (Channa Micropeltes) onneutrophilin diabetes mellitus 
wound healing. In vivo study in the back of male Wistar mice (Ratus 
Novergicus). Dentino J Kedokt Gigi. 2018; 3(1): 15–21. 

15.  Makiyah A, Tresnayanti S. Uji toksisitas akut yang diukur dengan 
penentuan LD50 ekstrak etanol umbi iles-iles (Amorphophallus 
variabilis Bl.) pada tikus putih strain Wistar. Maj Kedokt Bandung. 
2017; 49(3): 145–55. 

16.  Maliangkay HP, Rumondor R, Walean M. Uji efektivitas antidiabtes 
ekstrak etanol kulit buah manggis (Garcinia mangostana L) pada 
tikus putih (Rattus novergicus) yang diinduksi aloksan. Chem Prog. 
2018; 11(1): 15–21. 

17.  A lsawa f S, A l nua i m i F, A fza l S, T homas R M, Chela k kot 
AL, Ramadan WS, Hodeify R, Matar R, Merheb M, Siddiqui 
SS, Va zhappilly CG. Pla nt f lavonoids on oxidative st ress-
mediated kidney inflammation. Biology (Basel). 2022; 11(12):                                         
1717. 

18.  Sudira W, Merdana M, Winaya IBO, Parnayasa IK. Histopathological 
changes in white rat’s kidney given ant nest extract induced 
paracetamol toxic dose. Bul Vet Udayana. 2019; 11(2): 136–46. 

Copyright © 2023 Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 158/E/KPT/2021. 
Open access under CC-BY-SA license. Available at https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v56.i3.p178–183

https://peraturanpedia
https://e-journal.unair.ac.id/MKG/index
https://doi.org/10.20473/j.djmkg.v56.i3.p178-183


183Apriasari et al. Dent. J. (Majalah Kedokteran Gigi) 2023 September; 56(3): 178–183

19.  Rafe MASR, Gaina CD, Ndaong NA. Gambaran histopatologi ginjal 
tikus putih (Rattus norvegicus) jantan yang diberi infusa pare lokal 
pulau Timor. J Vet Nusant. 2019; 3(1): 61–73. 

20.  Rezkita F, Wibawa KGP, Nugraha AP. Curcumin loaded chitosan 
nanoparticle for accelerating the post extraction wound healing in 
diabetes mellitus patient: a review. Res J Pharm Technol. 2020; 13(2): 
1039–42. 

21.  Narmada IB, Laksono V, Nugraha AP, Ernawati DS, Winias S, 
Prahasanti C, Dinaryanti A, Susilowati H, Hendrianto E, Ihsan IS, 
Rantam FA. Regeneration of salivary gland defects of diabetic Wistar 
rats post human dental pulp stem cells intraglandular transplantation 
on acinar cell vacuolization and interleukin-10 serum level. Pesqui 
Bras Odontopediatria Clin Integr. 2019; 19(1): 1–10. 

22.  Jeane M, Asih IARA, Bogoriani NW. Asupan glikosida flavonoid 
terong belanda (Solanum betaceum Cav.) terhadap aktivitas 
superoksida dismutase dan kadar malondialdehid tikus Wistar yang 
diberi aktivitas fisik maksimal. J Media Sains. 2018; 2(1): 32–6. 

23.  Shafira N, Ayu PR, Susianti. Potensi Bit merah (Beta vulgaris L.) 
sebagai nefroprotektor dari kerusakan ginjal akibat radikal bebas. 
MEDULA Med Prof J Univ Lampung. 2019; 9(2): 322–7. 

24.  Lazuardi M, Suharjono S, Chien C-H, He J-L, Lee C-W, Peng 
C-K, Sukmanadi M, Sugihartuti R, Maslachah L. Toxicity test of 
flavonoid compounds from the leaves of Dendrophthoe pentandra 
(L.) Miq. using in vitro culture cell models. Vet World. 2022; 15(12): 
2896–902. 

25.  Purnamasari P, Purnawati RD, Susilaningsih N. Pengaruh ekstrak 
daun sukun dan madu terhadap gambaran mikroskopik ginjal tikus 
Wistar yang diinduksi dietilnitrosamin. Diponegoro Med J. 2018; 
7(2): 1391–405. 

26.  Ardiaria M. Disfungsi mitokondria dan stress oksidatif. JNH (Journal 
Nutr Heal. 2019; 7(3): 50–5. 

27.  Budi HS, Kriswandini IL, Iswara AD. Antioxidant activity test 
on ambonese banana stem sap (Musa parasidiaca var. sapientum).               
Dent J. 2015; 48(4): 188–92.

Copyright © 2023 Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 158/E/KPT/2021. 
Open access under CC-BY-SA license. Available at https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v56.i3.p178–183

https://e-journal.unair.ac.id/MKG/index
https://doi.org/10.20473/j.djmkg.v56.i3.p178-183