https://doi.org/10.52973/rcfcv-e34423
Received: 28/03/2024 Accepted: 27/07/2024 Published: 27/10/2024
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Revista Científica, FCV-LUZ / Vol. XXXIV, rcfcv-e34423
ABSTRACT
Peptic ulcer disease poses a critical health risk, leading to considerable
morbidity and mortality. It arises from an imbalance between aggressive
factors that damage the stomach’s mucosal lining and protective
components that safeguard it. Traditional plant–based remedies have
gained traction as potential alternatives to conventional drugs. This
experiment aimed to assess the anti–ulcer action of the crude extract
of Paeonia mascula through two in vivo tests using male Wistar rats.
The preventive test involved inducing acute gastric lesions, while the
therapeutic test involved treating the lesions with crude extract and
in vitro quantifying stomach parameters such as gastric volume, pH,
total acidity, pepsin activity, and ulcer index. The results illustrated a
noteworthy reduction in ulcer index in preventive and healing tests.
These ndings suggest that the extract has an anti–ulcerogenic effect
by suppressing acid secretion and reducing gastric injuries.
Key words: Antiulcer; crude extract; Paeonia mascula; preventive;
curative
RESUMEN
La afección por úlcera péptica representa un riesgo sanitario crítico,
que provoca un sufrimiento y una mortalidad considerables. Surge
de un desequilibrio entre las variables de fuerza que dañan el
revestimiento mucoso del estómago y los componentes protectores
que lo aseguran. Las curas convencionales a base de plantas han
cobrado fuerza como opciones potenciales a los fármacos ordinarios.
Este experimento pretendía evaluar la acción antiulcerosa del extracto
crudo de Paeonia mascula con dos pruebas in vivo utilizando ratas
Wistar macho. La prueba preventiva consistió en inducir lesiones
gástricas agudas, mientras que la prueba terapéutica consistió en
tratar la lesión con extracto crudo y cuanticar in vitro parámetros
estomacales como el volumen gástrico, el pH, la acidez total, la
actividad de la pepsina y el índice de úlcera. Los resultados ilustraron
una notable reducción del índice de úlcera en las pruebas preventivas
y curativas. Estos descubrimientos recomiendan que el extracto
tiene un impacto antiulcerogénico al sofocar la secreción corrosiva
y disminuir las lesiones estomacales.
Palabras clave: Antiulceroso; extracto crudo; Paeonia mascula;
preventivo; curativo
Assessment of antiulcer activity in crude extract of Paeonia mascula
subsp. atlantica (Coss.) Greuter & Burdet
Actividad antiulcerosa en extracto crudo de Paeonia mascula
subsp. atlantica (Coss.) Greuter & Burdet
Wafa Nouioua
1
* , Soane Gaamoune
2
1
Ferhat Abbas University Setif 1, Faculty of Natural and Life Sciences, Department of Plant Ecology and Biology,
Laboratory of phytotherapy applied to chronic diseases. Setif, Algeria.
2
National Institute of Agriculture Research. Setif, Algeria.
*Corresponding Author: nouioua.wafa@yahoo.fr
Antiulcer activity in crude extract of Paeonia mascula / Nouioua and Gaamoune ___________________________________________________
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INTRODUCTION
Peptic ulcer disease is a group of ulcerative disorders in areas of
the upper gastrointestinal tract exposed to acid–pepsin secretions,
affecting 10% of the world population [1, 2]. Ulcers that affect the
gastrointestinal system are usually aggravated by an imbalance
between destructive and defensive factors in the stomach [3].
The major protective factors include adequate blood ow and the
secretion of prostaglandins, mucus, and bicarbonate by resident
mucosal cells. Aggressive agents include increased secretion of
hydrochloric acid and pepsin, inadequate dietary habits, consumption
of nonsteroidal anti–inflammatory drugs and alcohol, stressful
conditions, and infection by Helicobacter pylori [4].
The treatment of gastric ulcers includes antacids, muscarinic
antagonists, histamine receptor antagonists, and proton pump
inhibitors. However, long–term use of these drugs can cause side
effects on human health, including hypersensitivity, arrhythmia,
hematopoietic disorders, impotence, and gynecomastia [5]. This
underscores the need for alternative means of control. Currently,
plants and plant–based products appear promising in the renewed
search for better ulcer treatment. Some medicinal plants have been
reported to possess anti–ulcer properties based on studies using
experimental animal models [6].
In this study, we aim to scientifically validate the anti–ulcer
properties of the methanol extract of Paeonia mascula. Peptic ulcer
disease is a prevalent gastrointestinal disorder characterised by
mucosal disintegration and ulcer formation. Our goal is to enhance
the body of knowledge advocating for the use of natural products in
treating peptic ulcers by investigating the anti–ulcer effects of the
methanol extract of Paeonia mascula.
MATERIALS AND METHODS
Plant material
Aerial parts of Paeonia algeriensis Chabert = Paeonia mascula
subsp. atlantica (Coss.) Greuter & Burdet were harvested from Kefrida
Forest at 36°34'14" N, 5°17'24" E, and dried in the shade for later use.
Methanol extraction
The method of Motamed and Naghibi [7] was employed. Briey, 10 g
of powdered areal parts were macerated in 100 mL of 80% methanol for
24 h at laboratory temperature. The resulting solution was evaporated
under a vacuum until dry. The extract was stored at -18 until use.
Animals
Experiments were conducted using adult male Wistar albino
rats (Rattus norvegicus) (180–240 g). The animals were housed in
standard metal cages (33 Wistar albino rats in total, with 15 for testing
preventive effects and 18 for testing curative effects), kept at ambient
temperature (20–25°C), and illuminated on a 12:12 h dark/light cycle.
They were provided with standard food pellets and tap water until
the night before the test or sacrice.
Preventive effects of crude extract against acute gastric lesions
For the determination of anti–ulcerative activity, fteen male Wistar
rats were divided into three groups:
•
The first group was orally administered 2.5 mL of water
(control).
•
The second group was orally administered 2.5 mL of a
suspension containing 200 mg of the extract.
•
The third group was orally administered 80 mg·kg
-1
of
Omeprazole 30 min before gastric ulcer induction.
The gastric mucosal lesions leading to an acute gastric ulcer
were induced by the oral administration of 1.5 mL of a 150 mM HCl/
ethanol (40:60, v/v) solution [8]. The animals were sacriced under
anaesthesia 60 min after the HCl/ethanol administration. Stomachs
were removed, opened along the greater curvature, rinsed with
physiological saline solution, and stretched on polystyrene boards. The
degree of gastric mucosal damage was evaluated from digital pictures
using a computerised image analysis system (Digimizer version
4.0.0.0). The percentage of the total lesion area (hemorrhagic sites)
to the total surface area of the stomach, excluding the forestomach,
was dened as the ulcer index.
Curative effects of crude extract against acute gastric lesions
Male Wistar rats weighing about 180–220 g were divided into three
groups of at least six rats each. Ulcers were induced in all rats by oral
gavage of 1 mL of absolute ethanol. The experimental groups were
then treated as follows:
• Group I was the control, treated with 1 mL of water only.
• Group II was treated with 200 mg·kg
-1
of crude extract.
• Group III was treated with 30 mg·kg
-1
of Omeprazole for each
of 8 successive days [9].
On the 9
th
day, all animals were sacriced under anaesthesia. The
stomachs were dissected out and opened along the greater curvature.
The stomachs were gently rinsed with water to remove the gastric
contents and blood clots for subsequent ulcer scoring.
Calculation of ulcer index and percentage ulcer inhibition
The ulcer index has been calculated by adding the total number of
ulcers per stomach and the total severity of ulcers per stomach [10].
The score for the ulcer was made as follows:
0: normal–coloured stomach.
0.5: red coloration.
1: spot ulcers.
1.5: hemorrhagic streak.
2: ulcers.
3: perforation
The mean ulcer score for each animal was expressed as an ulcer
index. The percentage of ulcer inhibition was determined as follows:
(%)
()
Inhibition of UlcerIndex
Control mean index
Control mean indexTestmeanindex
=
-
Collection of gastric juice
The stomach was excised carefully by keeping the oesophagus closed
and opened along the greater curvature, and the luminal content was
removed. The samples were collected and centrifuged (Sigma 3–30K,
Germany) at 1000 G for 10 min. The volume of the supernatant was
TABLE I
Preventive eect of Paeonia mascula, crude extract
Ulcer Index Inhibition (%)
Omeprazole 0.15 ± 0.02 83.80 ± 7.20
Crude extract 200 mg·Kg
-1
0.15 ± 0.05 70.25 ± 14.24
Control 0.66 ± 0.27 –
A
B
C
FIGURE 1. A: Gastric lesion observed in crude extract treated
group induced by HCl – Ethanol. B: Gastric lesion observed
in standard group induced by HCl–Ethanol. C: Gastric lesion
observed in control group induced by HCl–Ethanol
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expressed as mL·100 g
-1
of body weight, and the centrifuged samples
were decanted and analysed for gastric volume, pH, and total acidity [11].
Estimation of total acidity
It was measured by the method of Hawk et al. [12]. Briefly, 1 mL
of the supernatant liquid was pipetted out and diluted to 10 mL with
distilled water. The pH of this solution was noted with the help of a pH
meter. The solution was titrated against 0.01N sodium hydroxide using a
phenolphthalein reagent as an indicator. The endpoint was titrated when
the solution turned orange–pink. The volume of NaOH was noted, which
corresponds to total acidity. Acidity was expressed as a formula [13]:
.
Acidity
Volume of NaOH Normality mEq
01
100��
1
=
-
Estimation of pepsin activity:
Aliquots of 20 μL of the gastric contents were incubated with 500μL
of albumin solution (5 mg·mL
-1
, 0.06 N hydrochloric acid) at 37°C for
10 min. The reaction was stopped with 200 μL of 10% trichloroacetic
acid, and the samples were centrifuged (Sigma 3–30K, Germany) at
1500 G for 20 min. The supernatant was alkalinized with 2.5 mL of 0.55
M sodium carbonate, and 400 μL of 0.1 N Folin reagent was added to
the tubes, which were then incubated for 30 min at room temperature.
The absorbance (spectrophotometer UV visible VWR) of the sample
was determined at 660 nm. A standard curve of tyrosine was used for
the determination of the concentration of pepsin. The pepsin content
of the gastric uid was expressed as μg of tyrosine·mL
-1
(Eq. tyr) [14].
Statistical analysis
The values are expressed as the mean ± SEM for six rats in each
group. All the data were analysed statistically by the t–test of the
student, followed by the Fisher test. The difference was considered
signicant at P<0.05.
RESULTS AND DISCUSSION
Preventive effect
The anti–ulcerative preventive effect of crude extract of Paeonia
mascula is shown in TABLE I below
with a percentage inhibition of 75.30 ± 17.64% in comparison to the
standard drug (80 mg·kg
-1
), which provided 83.80 ± 7.20% protection.
Oxidative stress and mucosal inammation are the main factors
associated with the pathogenesis of the hydrochloric acid (HCl) and
ethanol (EtOH)–induced gastric ulcer model [15, 16], a commonly
used in vivo model that induces gastric mucosal erosion, bleeding,
Results showed that rats pre–treated with omeprazole or crude
extract before being given HCl/ethanol solution had signicantly
reduced areas of gastric ulcer formation compared with the ulcer
control group (FIG. 1).
Pre–treated animals with crude extract (200 mg·kg
-1
) signicantly
reduced the formation of ulcers induced by the HCl/ethanol mixture,
TABLE II
Curative eect of Paeonia mascula, crude extract
Treatment
Dose (mg·kg
-1
)
p.o
Volume of gastric
juice (ml·100 g
-1
)
pH
Total acidity
(meq·L
-1
)
Ulcer index
Inhibition
(%)
Pepsin (µg·ml
-1
)
Eq.tyr
Control 10 ml·kg
-1
0 1.84 ± 0.14 2.80 ± 0.14 70.16 ± 0.30 9.00 ± 1.22 – 67.96 ± 1.71
Standard omeprazole 50 1.25 ± 0.05 5.24 ± 0.25 22.5 ± 7.5 4.83 ± 0.20 48.77 ± 5.85 11.15 ± 2.90
Crude extract 200 1.24 ± 1.12 4.50 ± 1.20 24.22 ± 1.12 4.12 ± 0.89 50.11 ± 3.22 9.54 ± 4.14
Antiulcer activity in crude extract of Paeonia mascula / Nouioua and Gaamoune ___________________________________________________
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perforation, and other damage [17, 18]. Driven by oxidative stress,
the nuclear factor κB (NF–κB) pathway is regulated to amplify the
inammatory response by increasing the release of pro–inammatory
cytokines, including tumor necrosis factor–α (TNF–α) and interleukin–6
(IL–6), and the expression of the downstream inammatory mediators
cyclooxygenase–2 (COX–2) and inducible nitric oxide synthase (iNOS)
[19]. These agents break the mucosal barrier, provoke an increase
in gastric mucosal permeability to H+ and Na+ ions, reduce the
transmucosal potential difference, and induce the formation of
erosions and ulcers [20]. The crude extract of Paeonia mascula was
effective in signicantly reducing the ulcer index and also increased
the mucus content. This model demonstrates the cytoprotective
effect of Paeonia mascula extract.
Curative effect
The results of the potential curative action against experimentally
induced ulcers caused by the administration of HCl–Ethanol are
demonstrated in TABLE II.
Oral administration of the crude extract (200 mg·kg
-1
) for 8 d
signicantly (P<0.05) reduced the ulcer index in ethanol–induced
experimental ulcers in rats, with a percentage of 50.11 ± 3.22%; this
result was better than the standard drug, which was 48.77 ± 5.85%.
These results demonstrate that the crude extract of Paeonia
mascula signicantly reduced ethanol–induced ulcers. The extract
at a dose of 200 mg·kg-1 signicantly decreased the ulcer index,
pepsin activity, and total acidity when compared to their respective
controls, which indicates the healing of the induced ulcer.
The anti–ulcer activity shown by the crude extract of Paeonia
mascula in ethanol–induced ulcers suggests that the extract has a
cytoprotective effect, meaning that it protects the gastric mucosa
through mechanisms other than inhibiting gastric acid secretion.
[21]. Such mechanisms include inhibition of leukotrienes [22],
pepsinogen [23], and substance P [24], free radical scavenging [25],
increasing gastric mucosal blood ow [26], increasing the protective
glycoprotein content and thereby strengthening the gastric mucosa,
and prevention of oxidation of the mucosal xanthine dehydrogenase.
CONCLUSION
The results of this research show a potential curative effect of the
crude extract of Paeonia mascula.
The methanol extract of Paeonia mascula appears to have a
signicant anti–ulcer effect, prominently inhibiting acid secretion
and the formation of stomach lesions. These ndings suggest that the
phytoconstituents in the extract may protect against ethanol/HCl
-
and
absolute ethanol–induced gastric mucosal damage by inhibiting gastric
acid, pepsin, histamine, and free radicals while promoting mucus
secretion. Additionally, the scavenging of reactive oxygen species
(ROS) by polyphenols is considered an important mechanism in the
healing of gastric ulcers. These multifaceted properties indicate the
extract’s potential in developing future medications. However, further
research is crucial to investigate the extract’s toxicity and chemical
composition, which are essential for its safe and effective utilization.
Conict of interests
The authors declare that they have no conicting interests.
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