Gastroprotective potential and mechanisms of action of <i>Hedera nepalensis</i>

Shahzad, Naeem; Anjum, Irfan; Ahsan, Haseeb; Alamgeer,; Syed, Shahzad Khurrum; Mushtaq, Muhammad Naveed

doi:10.1590/s2175-97902023e20493

Abstract

Hedera nepalensis (H. nepalensis) , belonging to the family Araliaceae, is a medicinal plant traditionally used to treat stomach problems. The current study investigated the gastroprotective potential and the mechanism of action of H. nepalensis in diclofenac-and ethanol-induced ulcer models. Anti-oxidant and lipid peroxidation inhibitory prospects of H. nepalensis were checked out by free radical scavenging assay and UV spectrophotometer respectively. Effect of H. nepalensis on the pH, gastric total acidity of gastric juice and protective effects of H. nepalensis against ulcer models have been examined. Histopathological studies have been carried out. The aqueous methanol extract of H. nepalensis (100 µg/mL) showed anti-oxidant (83.55%) and lipid peroxidation inhibitory (70.88%) potential at 1000 µg/mL; the extract had no buffer potential. The extract (400 mg/kg) significantly (81.12% and 63.46%) showed gastroprotective effect in diclofenac and ethanol-induced rat ulcer models respectively. Histopathological studies confirmed the biochemical findings. FTIR analysis showed the presence of carboxylic acid, alkanes, conjugated alkanes, aldehydes and alkyl-aryl ethers. Gallic acid, M-coumaric acid and quercetin were found by HPLC analysis. H. nepalensis exhibited significant protection against diclofenac and ethanol induced gastric damage by anti-oxidant and lipid peroxidation suppression effects suggesting potential broad utility in treatment of diseases characterized with gastric damage.

Keywords:
Antioxidant; Diclofenac; Ethanol; Gastroprotective; Hedera nepalensis.

INTRODUCTION

Gastric ulcer has become the leading source of hospitalization of patients in modern world. Every year, 4 million peoples worldwide suffer from peptic ulcer disease ( Chung, Shelat, 2017Chung KT, Shelat VG. Perforated peptic ulcer - an update. World J Gastrointest Surg. 2017;9(1):1-12. doi: 10.4240/wjgs.v9.i1.1. PMID: 28138363; PMCID: PMC5237817.
https://doi.org/10.4240/wjgs.v9.i1.1... ). Ulcers form when there is an inequity between protective and aggressive factors in the stomach. These factors include acid and mucus secretions, blood flow, prostaglandins, Helicobacter pylori infection and cell regeneration in stomach. Some exogenous factors, such as smocking, non-steroidal anti-inflammatory drugs, alcohol and stress may lead to development of gastric ulcer ( Klein et al., 2010Klein LC, Gandolfi RB, Santin JR, Lemos M, Cechinel Filho V, de Andrade SF. Antiulcerogenic activity of extract, fractions, and some compounds obtained from Polygala cyparissias St. Hillaire & Moquin (Polygalaceae). Naunyn Schmiedbergs Arch Pharmacol. 2010;381(2):121-126. ).

Antacids, H₂ receptor blockers and proton pump inhibitors are being used to treat ulcer. High cost and development of unwanted effects such as impotence, arrhythmia, hypersensitivity and gynecomastia demand more effective and less toxic agents to treat ulcer ( Ramis et al., 2012Ramis IB, Moraes EPd, Fernandes MS, Mendoza-Sassi R, Rodrigues O, Juliano CRV, et al. Evaluation of diagnostic methods for the detection of helicobacter pylori in gastric biopsy specimens of dyspeptic patients. Braz J Microbiol. 2012;43(3):903-908. ). Nowadays medicinal plants and various phytochemicals derived from plants have been used to treat a number of diseases. Even in the developed countries, most of the population relies on use of traditional medicinal plants to treat their illness ( Luna et al., 2005Luna JS, Dos Santos A, De Lima M, De Omena M, De Mendonça F, Bieber L, et al. A study of the larvicidal and molluscicidal activities of some medicinal plants from northeast Brazil. J Ethnopharmacol. 2005;97(2):199-206. ).

Hedera nepalensis belonging to the family Araliaceae, is a medicinal plant found in Japan, Afghanistan, West Asia and the Himalayas ( Jafri et al., 2017Jafri L, Saleem S, Ullah N, Mirza B. In vitro assessment of antioxidant potential and determination of polyphenolic compounds of Hedera nepalensis K. Koch. Arab J Chem. 2017;10(Suppl 2):S3699-S3706. ). Traditionally, H. nepalensis is used to treat diabetes, ulcer, abscesses, cancer and as a diaphoretic and cathartic agent ( Ahmad, Javed, 2007Ahmad SS, Javed S. Exploring the economic value of underutilized plant species in Ayubia National Park. Pak J Bot. 2007;39(5):1435-1442. ; Qureshi et al., 2007Qureshi RA, Ghufran MA, Gilani SA, Sultana K, Ashraf M. Ethnobotanical studies of selected medicinal plants of Sudhan Gali and Ganga Chotti Hills, District Bagh, Azad Kashmir. Pak J Bot. 2007;39(7):2275-2283. ). Flavonoids, tannins, steroids, terpenoids and glycosides have been found in H. nepalensis ( Kanwal et al., 2011Kanwal S, Ullah N, Haq I, Afzal I, Mirza B. Antioxidant, antitumor activities and phytochemical investigation of Hedera nepalensis K. Koch, an important medicinal plant from Pakistan. Pak J Bot. 2011;43:85-89. ). Decoction from plant is effective against lice. The juice prepared from leaves of this plant is used as a blood purifier and to treat diabetes ( Akhtar et al., 2013Akhtar N, Rashid A, Murad W, Bergmeier EJ. Diversity and use of ethno-medicinal plants in the region of Swat, North Pakistan. J Ethnobiol Ethnomed. 2013;9:25. ).

The present study was aimed to investigate the gastro-protective activity of Hedera nepalensis in diclofenac-and ethanol-induced gastric ulcer rats. The acidity, pH, ulcer score and histopathological studies have been performed to evaluate the gastroprotective potential of aqueous methanol extract of H. nepalensis (AMEHN). The phenolic contents, anti-oxidant and lipid peroxidation inhibitory potential of plant have also been determined. Moreover, FTIR was utilized to assess the functional groups present in the aqueous methanol extract of whole plant.

MATERIAL AND METHODS

Animals

Albino rats of either sex (7-8 weeks old, 150-200 g) were used. Animals were housed in the animal house at the Faculty of Pharmacy, Lahore College of Pharmaceutical Sciences. The temperature was kept at 22±2 ˚C. The animals were exposed to a 12-hour dark/light cycle for one week. Animals were fed chaos and water as needed. The animals were handled in accordance with National Research Council guidelines (UOS/ORIC/1478).

Collection and extraction of H. nepalensis

The aerial parts of the plant were collected from Sawat Khyber Pakhtunkhwa (35° 22’ 42” North, 72° 10’ 47” East), Pakistan in August and September 2017. The plant was identified and authenticated by Dr. Zaheer-ud-Din Khan, Department of Botany, Government College University Lahore (Ref. #: GC. Herb. Bot. 3469). The aerial parts of the plant were shade dried and crushed into powder. The aqueous methanol extract was prepared by cold maceration. A dark greenish mass was obtained with percentage yield of 13.48%.

Phytochemical testing

AMEHN was analyzed for the detection of alkaloids, saponins, flavonoids, steroids, tannins, resins, anthraquinones, glycosides and phenols ( Odeja et al., 2015Odeja O, Obi G, Ogwuche CE, Elemike EE, Oderinlo Y. Retracted Article: Phytochemical Screening, Antioxidant and Antimicrobial activities of Senna occidentalis (L.) leaves Extract. Clin Phytosci. 2015;1(6):1-6. ).

Buffer potential estimation

Buffer potential of AMEHN was determined to know the change in pH by adding 1 and 2 mL of 0.1 N HCl and NaOH. The pH of 1 mL of extract (100 mg/mL) was determined alone and with addition of 0.1 N HCl/ NaOH ( Adefisayo et al. , 2017Adefisayo MA, Akomolafe RO, Akinsomisoye SO, Alabi QK, Ogundipe OL, Omole JG, et al. Gastro-protective effect of methanol extract of Vernonia amygdalina (del.) leaf on aspirin-induced gastric ulcer in Wistar rats.” Toxicol Rep. 2017;4:625-633. ).

Antioxidant activity

Ascorbic acid, quercetin and AMEHN (10 mg each) were weighed and dissolved separately in methanol (10 mL). The resultant solution (1000 µg/mL) was obtained. The above stock solutions (1 mg/mL) were undergone serial dilution so that lower concentrations viz. 20, 40, 60, 80, 100 µg/mL were obtained. By using DPPH free radical, quenching effect of plant extract and standards was determined. 2.22 mg of DPPH was dissolved in methanol (100 mL) to prepare fresh 0.1 mM solution of DPPH ( Awan et al. , 2020Awan AF, MS Akhtar, I Anjum, Mushtaq MN, Fatima A, Khan MUR, et al. Hepatoprotective effect of Ziziphus oxyphylla Edgew in paracetamol-induced hepatotoxic rat model. Pak J Pharm Sci. 2020;33(5):2449-2454. ). 3 mL of extract and standard solutions at different concentrations were mixed in 1 mL of methanol solution of DPPH. The solution was kept at 25^o C for 30 minutes and analyzed on UV spectrophotometer at =517 nm (Harlalka et al. , 2007). The standards used were quercetin and ascorbic acid. Radical scavenging activity was evaluated by following expression:

% Oxidant inhibition = (\frac{Ac - As}{Ac}) x 100

Whereas,

Ac denotes absorbance of DPPH without AMEHN i.e., control and

As denotes absorbance of DPPH with AMEHN i.e., sample

Lipid peroxidation inhibition evaluation of AMEHN

TBARS assay was performed to assess lipid peroxidation inhibition activity of the extract. Egg homogenate (lipid rich medium) was used in this analysis. AMEHN (0.1 mL) and quercetin (2 mg/mL), as well as 0.5 mL of 10% v/v egg homogenate, were placed in a test tube and diluted to a final volume of 1 mL with water. To induce lipid peroxidation in each solution, 0.5 mL of 0.07 M ferrous sulphate solution was added and incubated for 30 minutes. The following chemicals were dissolved in 1.5 mL of 20% ascorbic acid, whose pH was adjusted to 3.5 with NaOH, 1.5 mL of 0.8 percent w/v TBA in 1.1 percent SDS, and 0.5 mL of 20% TCA. The resulting mixture was vortexed and warmed for 60 minutes at 95 ˚C. Entire methodology is recapped in the same way but without incubation of TBA for each sample. After cooling the solution, butanol (5 mL) was included in it and then centrifuged for 10 minutes (395x g). Absorbance was measured at 532 nm of organic layer ( Jahantighi et al. , 2016Jahantighi A, G Kiani, TT Moghaddam and S Ghahari. In vitro antibacterial activity of selected medicinal plants traditionally used in Iran against plant and human pathogenic bacteria. Jordan J Bio Sci. 2016;9(3):221-226. ). Lipid peroxidation percentage was calculated as follows;

% anti - lipid peroxidation = [1 - (\frac{E}{C})] \times 100

Whereas,

C denotes absorbance of control

E denotes absorbance of sample (Abs 532_+TBA - Abs 532_-TBA)

Study design for diclofenac induced gastric ulcer

The rats were divided into 5 groups (n=5). Group I (Normal control) was administered vehicle; 1% carboxymethyl cellulose (CMC) (10 mL/kg) orally. Group II (Disease control) was treated with single dose of diclofenac sodium (100 mg/kg) dissolved in 1% CMC. Group III (Standard drug) received three doses at 12hr interval of omeprazole (20 mg/kg) dissolved in 1% CMC. Group IV and V (AMEHN treated) received three doses of AMEHN (200 and 400 mg/kg respectively) at 12 hours interval. Diclofenac sodium was administered after one hour of last dose of AMEHN and omeprazole ( Kang et al. , 2014Kang J-W, Yun N, Han H-J, Kim J-Y, Kim J-Y, Lee S-M. Protective effect of flos lonicerae against experimental gastric ulcers in rats: mechanisms of antioxidant and anti-inflammatory action. Evid Based Complementary Altern Med . 2014;596920. doi: 10.1155/2014/596920
https://doi.org/10.1155/2014/596920... ).

Study design for ethanol induced gastric ulcer

Same protocols (as for diclofenac) were followed for ethanol induced gastric ulcer model. However, dose for 80% ethanol was 5 mL/kg. Rats were anesthetized with chloroform after 12hrs interval of last dose ( Liu et al. , 2001Liu X, Zakaria M, Islam M, Radhakrishnan R, Ismail A, Chen H, et al. Anti-inflammatory and anti-ulcer activity of Calligonum comosum in rats. Fitotherapia. 2001;72(5):487-491. ).

The rats were provided with regular diet and monitored to find the signs of ulcer. Their stomachs were dissected out. Gastric contents after dissection were collected and the stomachs were rinsed with normal saline, afterwards macroscopic examination i.e., ulcer score, ulcer index, percent protection, pH determination, total acidity estimation and histopathological examination were carried out.

Ulcer Scoring, ulcer Index and percentage protection

To determine the induction of ulcers, the stomach was isolated, washed, and inspected with a magnifying glass. Normal colored stomach (0), red coloration (0.5), spot ulcer (1), hemorrhagic streak (1.5), deep ulcers (2), perforation (3).

The Ulcer index (UI) was computed using the following formula:

UI = (Un + Us + Up) \times 10^{- 1}

Whereas; Un = average number of ulcers per animal, Us = average number of severity of scores, Up = percentage of animals with ulcers.

And percentage protection has been calculated by;

% Protection = (C - T / C) X 100

Whereas; C = ulcer index in control group, T = ulcer index in treated group ( Sattar et al ., 2019Sattar A, Abdo A, Mushtaq MN, Anjum I, Anjum A. Evaluation of Gastro-protective activity of Myristica fragrans on Ethanol-induced ulcer in albino rats. An Acad Bras Ciênc. 2019;91(2):e20181044. https://doi.org/10.1590/0001-3765201920181044 .
https://doi.org/10.1590/0001-37652019201... ).

Determination of gastric total acidity and pH

The gastric juice was obtained from stomach of rat; pH of gastric juice was then checked with the help of pH litmus paper. For the determination of gastric total acidity, gastric juice was diluted with 1 ml of distilled water, 2-3 drops of phenolphthalein were added in the mixture as an indicator and titrated against 0.01N NaOH until pink colour. The total acidity (meq/L/100 g) was calculated by given formula ( Lee, Kallal, Feldman, 1996Lee M, Kallal S, Feldman M. Omeprazole prevents indomethacin-induced gastric ulcers in rabbits. Aliment Pharmacol Ther. 1996;10(4):571-576. ; Abebaw, Mishra, Gelayee, 2017Abebaw M, Mishra B, Gelayee DA. Evaluation of anti-ulcer activity of the leaf extract of Osyris quadripartita Decne. (Santalaceae) in rats. J Exp Pharmacol. 2017;9:1-11. );

Total aciditiy = \frac{V (NaOH) \times N \times 100 mEq / L}{0.1}

Whereas;

V; volume of NaOH used N; normality of NaOH

Histopathological Studies

For histopathological studies, little partitions of stomach from each exploratory gathering were fixed in 10% formalin and submerged in paraffin. Areas of 5 µ were taken with a standard microtome and stained with hematoxylin and eosin. The areas were inspected for presence of degenerative and necrotic elements ( Sattar et al. , 2019Sattar A, Abdo A, Mushtaq MN, Anjum I, Anjum A. Evaluation of Gastro-protective activity of Myristica fragrans on Ethanol-induced ulcer in albino rats. An Acad Bras Ciênc. 2019;91(2):e20181044. https://doi.org/10.1590/0001-3765201920181044 .
https://doi.org/10.1590/0001-37652019201... ).

Fourier-transform infrared spectroscopy (FTIR) analysis

AMEHN was analyzed spectroscopically for the determination of functional groups. 1 mg sample along with 2.5 mg KBr was grounded. Grounded powder was filled in micro cup of 2 mm internal diameter and loaded onto FTIR set at temperature 26^o C ± 1^o C. The sample was scanned in infrared range of 4000-400 cm. The spectrum obtained was compared with reference chart for identification of functional groups ( Chandra, 2019Chandra S. Fourier transform infrared (Ft-Ir) spectroscopic analysis of Nicotiana plumbaginifolia (Solanaceae). J Med Plants Studies. 2019;7(1):82-85. ).

High performance liquid chromatography (HPLC) analysis

50 mg of AMEHN, 16 mL of distilled water, 24 mL methanol were mixed. 10 mL of 6 M HCl was added in above solution. Solution was kept in oven for 2 hours at 95^oC to obtain aglycons of flavanol glycosides. Samples were then centrifuged for ten minutes (395x g). Upper layers of samples were sonicated and filtered S 0.45 µm sized filter of cellulose acetate. Then the samples were injected into HPLC as described previously ( Tokuşoğlu, Ünal, Yildirimk, 2003Tokuşoğlu Ö, Ünal M, Yildirim Z. HPLC-UV and GC-MS characterization of the flavonol aglycons quercetin, kaempferol, and myricetin in tomato pastes and other tomato-based products. Acta Chromatogr. 2003;13(13):196-207. ).

RESULTS

Phytochemical Screening

Phytochemical screening of aqueous methanol extract of H. nepalensis showed the presence of alkaloids, flavonoids, phenols, resins, saponins and tannins as shown in Table I .

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TABLE I
Phytochemical screening of aqueous methanol extract of H. nepalensis

Buffer potential

AMEHN did not show any variation in pH by addition of 0.1N NaOH and 0.1N HCl solutions. Thus, it might be assumed that AMEHN did not have buffer capacity (as shown in Table II ).

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TABLE II
Buffer potential of aqueous methanol extract of H. nepalensis

Antioxidant activity

AMEHN exhibited antioxidant activity that was concentration dependent. The extract at concentration 100 µg/mL had remarkable free radical scavenging ability (83.55%). Quercetin and ascorbic acid free radical scavenging activity was (95.59%) and (98.23%) respectively as shown in Table III .

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TABLE III
Antioxidant potential of H. nepalensis

Lipid peroxidation inhibition

Lipid peroxidation inhibitory action of AMEHN was analyzed and compared to reference inhibitors quercetin ( Table IV ). Inhibitory action of AMEHN, was decreased to 0.00 at lower concentration (62.5 µg/mL) however, quercetin showed 63.99 ± 0.05% inhibition at lowest concentration of 62.5 µg/mL. Notwithstanding, AMEHN exhibited better anti-lipid peroxidation activity at higher conc. as shown in Table IV .

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TABLE IV
Inhibition of lipid peroxidation by AMEHN

Effects of AMEHN on gastric ulcer induced by diclofenac

Mucosal damage by diclofenac represented as severity score and ulcerative lesions were decreased to a large extent by AMEHN. The Disease control group had significantly increased gastric ulcer score (11.40±1.12) compared to control group. The number of lesions decreased (0.60±0.03) at 200 mg/kg dose likewise number of ulcerative lesions decreased (0.40±0.05) at 400 mg/kg dose. Severity score was decreased to (1.40±0.40, 0.60±0.10) at 200 and 400 mg/kg doses respectively in comparison to disease control (11.40±1.12). Ulcer index was decreased to a remarkable extent at 200 mg/kg (2.2) and 400 mg/kg (2.16). The ulcer protection was observed to be 80.77% and 81.12% at respective doses in comparison to disease control and standard drug treatment group (82.17%) ( Table V ).

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TABLE V
Effects of AMEHN on gastric ulcer induced by diclofenac

Effect of AMEHN on pH and total acidity of gastric juice

The Disease control group had significantly increased gastric total acidity (73.42±0.81) compared to control group (24.01±0.23). AMEHN (400 mg/kg) increased the pH of gastric juice (5.36±0.07) as compared to Disease control (1.54±0.11). The gastric total acidity was decreased (34.54±1.80) by AMEHN (400 mg/kg) as compared to standard drug treatment (35.39±0.96) ( Table VI ).

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TABLE VI
Effect of AMEHN on pH and total acidity in diclofenac induced ulcer model

Histopathological studies

Histopathological studies have been carried out of gastric damage induced by diclofenac. It has been found that the gastric mucosa and superficial epithelium in disease group was completely eroded. In standard drug treated group, superficial epithelium remained intact. AMEHN (400 mg/kg) showed gastric protection similar to standard drug treated group of rats however, mild damage in gastric mucosa and superficial epithelium was observed in AMEHN (200 mg/kg) pretreated rats as shown in Figure 1 .

FIGURE 1
Histopathological studies of stomachs from normal control (A), disease control (B), standard drug treated (C), aqueous methanol extract of H. nepalensis (200 and 400 mg/kg) treated group of rats (D) and (E) respectively in diclofenac induced gastric ulcer model. (A) arrow show intact epithelium, (B) arrow showing superficial epithelium was sloughed, necrosis of gastric glands had occurred, (C) mild erosion (arrow), restoration of epithelium by standard drug, (D) less necrosis in gastric glands and restoration of their normal shape (arrow) (E) arrow indicating very less erosion of superficial epithelium by H. nepalensis (400 mg/kg). (Light microscope magnification X100; hematoxylin and eosin staining) 215x279mm (300 x 300 DPI).

Effects of AMEHN on gastric ulcer induced by ethanol

Mucosal damage by ethanol represented as severity score and ulcerative lesions are decreased to a large extent by AMEHN. The Disease control group had significantly increased gastric ulcer score (12.80±1.63) compared to control group. The number of lesions decreased (0.60±0.20) at 200 mg/kg dose likewise number of ulcerative lesions decreased (0.80±0.17) at 400 mg/ kg dose. Severity score decreased up to (2.00±0.38, 1.20±0.58) at 200 and 400 mg/kg doses respectively in comparison to disease control (12.80±1.63). Ulcer index was decreased to a remarkable extent at 200 mg/kg (4.26) and 400 mg/kg (6.20) doses. Percentage ulcer protection was observed to be 63.46% and 46.83% at respective doses in comparison to disease control and standard drug treatment group (63.64%) ( Table VII ).

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TABLE VII
Effect of AMEHN on gastric mucosal damage induced by ethanol

Effects of AMEHN on pH and total acidity of gastric juice in ethanol induced ulcer

The Disease control group had significantly increased gastric total acidity (74.65±1.15) compared to control group (24.01±0.23). AMEHN (400 mg/kg) increased the pH of gastric juice (5.52±0.07) as compared to disease control (1.42±0.11). The gastric total acidity was decreased (35.76±1.37) by AMEHN (400 mg/kg) as compared to standard drug treatment omeprazole (34.92±0.80) ( Table VIII ).

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TABLE VIII
Effects of AMEHN on pH and total acidity in ethanol induced ulcer

Histopathological assessment

Histopathological results showed that gastric mucosa and superficial epithelium were damaged by ethanol. In case of omeprazole pretreated rats, superficial epithelium and gastric mucosa observed to be intact. AMEHN (400 mg/kg) showed similar protection as was seen in omeprazole pretreated group ( Figure 2 ).

FIGURE 2
Histopathological studies of stomachs from normal control (A), disease control (B), standard drug treated (C), aqueous methanol extract of H. nepalensis (200 and 400 mg/kg) treated group of rats (D) and (E) respectively in ethanol induced gastric ulcer model. (A) arrow shows intact epithelium, (B) damage to superficial epithelium, hemorrhage in lamina propria, (C) area of restoration of epithelium by standard drug, (D) less necrosis (arrow) in gastric glands (E) intact epithelium with no necrotic gastric glands by H. nepalensis (400 mg/kg). (Light microscope magnification X100; hematoxylin and eosin staining) 215x279 mm (300 x 300 DPI).

FTIR analysis of H. nepalensis

AMEHN was analyzed spectroscopically for determination of functional groups. Aqueous methanol extract of H. nepalensis FTIR spectra was compared with standard chart. It was found that functional groups like carboxylic acid, alkanes, conjugated alkenes, aldehydes and alkyl-aryl ethers were present in AMEHN ( Table IX ; Figure 3 ).

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TABLE IX
FTIR analysis of AMEHN

FIGURE 3
FTIR spectra of aqueous methanol extract of Hedera nepalensis.

Phenolic content estimation

The extract was analyzed with HPLC which confirmed the presence of phenols like quercetin, gallic acid and M-coumaric acid in 0.78 ppm, 5.24 ppm 3.52 ppm concentrations respectively ( Table X ; Figure 4 ).

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TABLE X
HPLC analysis of AMEHN

FIGURE 4
HPLC chromatogram of aqueous methanol extract of Hedera nepalensis.

DISCUSSION

Plants have become an important part of alternative medicines worldwide. A number of traditional medicinal plants have been used to protect gastric mucosa from ulcer causing agents. In this study, H. nepalensis was evaluated for its gastroprotective activity against diclofenac and ethanol induced ulcer. The phenolic contents, anti-oxidant and lipid peroxidation inhibitory potential of plant have been determined. FTIR and HPLC analysis has also been carried out.

Phytochemical evaluation of H. nepalensis showed the presence of alkaloids, flavonoids, gums, saponins, phenols, tannins while anthraquinones, glycosides and steroids were absent as shown in Table I . Phytomedicines comprising of anti-oxidants such as flavonoids, tannins and polyphenols have better ability to decrease disease hazards and have healing effects ( Jennings et al ., 2012Jennings A, Welch AA, Fairweather-Tait SJ, Kay C, Minihane A-M, Chowienczyk P, et al. Higher anthocyanin intake is associated with lower arterial stiffness and central blood pressure in women. Am J Clin Nutr. 2012;96(4):781-788. ; Muthusamy et al ., 2008Muthusamy V, Anand S, Sangeetha K, Sujatha S, Arun B, Lakshmi B. Tannins present in Cichorium intybus enhance glucose uptake and inhibit adipogenesis in 3T3-L1 adipocytes through PTP1B inhibition. Chem Biol Interact. 2008;174(1):69-78. ). Phenols show anti-oxidant ability and scavenge ROS and free radicals from the body showing cytoprotective effect in physiological systems ( Scalbert et al ., 2005Scalbert A, Manach C, Morand C, Rémésy C, Jiménez L. Dietary polyphenols and the prevention of diseases. Cri Rev Sci Nutri. 2005;45(4):287-306. ). Flavonoids, due to hydroxyl group in main skeleton, also present free radical scavenging potential ( Heinonen, Lehtonen, Hopia, 1998Heinonen IM, Lehtonen PJ, Hopia AI. Antioxidant activity of berry and fruit wines and liquors. J Agric Food Chem. 1998;46(1):25-31. ).

The aqueous methanol extract of H. nepalensis (AMEHN) was studied for its buffer potential by addition of NaOH (0.1N) and HCl (0.1N). AMEHN did not show any buffer capacity and thus having no ability to neutralize acidity of stomach as shown in Table II .

AMEHN was studied for its lipid peroxidation inhibitory and antioxidant potentials. TBARS test was used to evaluate AMEHN in vitro anti-lipid peroxidation potential. MDA reacts with TBA to give a red chromogen. It was further analyzed spectrophotometrically ( Tiong et al ., 2013Tiong SH, Looi CY, Hazni H, Arya A, Paydar M, Wong WF, et al. Antidiabetic and antioxidant properties of alkaloids from Catharanthus roseus (L.) G. Don. Molecules. 2013;18(8):9770-9784. ). AMEHN inhibited the formation of MDA. In vitro examination for anti-oxidant activity of test extract was performed by DPPH assay. Antioxidant activity was exhibited by the plant extract ( Table III and IV ) as reported earlier ( Jafri et al., 2017Jafri L, Saleem S, Ullah N, Mirza B. In vitro assessment of antioxidant potential and determination of polyphenolic compounds of Hedera nepalensis K. Koch. Arab J Chem. 2017;10(Suppl 2):S3699-S3706. ; Kanwal et al., 2011Kanwal S, Ullah N, Haq I, Afzal I, Mirza B. Antioxidant, antitumor activities and phytochemical investigation of Hedera nepalensis K. Koch, an important medicinal plant from Pakistan. Pak J Bot. 2011;43:85-89. ; Hashmi et al ., 2018Hashmi WJ, Ismail H, Mehmood F, Mirza B. Neuroprotective, antidiabetic and antioxidant effect of Hedera nepalensis and lupeol against STZ+ AlCl 3 induced rats model. DARU. 2018;26(2):179-190. ). Results showed that AMEHN has significant antioxidant and anti-lipid peroxidation effects. Medicinal plants showing gastro protective effect showed lipid peroxidation inhibitory potential previously ( Ismail et al. , 2012Ismail IF, Golbabapour S, Hassandarvish P, Hajrezaie M, Abdul Majid N, Kadir FA, et al. Gastroprotective activity of Polygonum chinense aqueous leaf extract on ethanol-induced hemorrhagic mucosal lesions in rats. Evid Based Complementary Altern Med. 2012;404012. doi: 10.1155/2012/404012.
https://doi.org/10.1155/2012/404012... ).

The gastroprotective activity of AMEHN was assessed by using diclofenac and ethanol induced ulcer model in rats. NSAIDs are hazard factors of gastric ulcer. Cyclooxygenase inhibitors decrease the mucus secretion, bicarbonate discharge, stifles the combination of prostaglandins, initiation of neutrophils, decrease mucosal blood flow, disturb the mucosal boundary, lipid per oxidation with subsequent development of ulcer ( Wallace, 2008Wallace JL. Prostaglandins, NSAIDs, and gastric mucosal protection: why doesn’t the stomach digest itself? Physiol Rev. 2008;88(4):1547-1565. ). Ethanol is a well-known necrotic agent and induces ulcer by disrupting the mucosal membrane. The parameters like number of lesions, severity score and ulcer index have been increased by oral administration of diclofenac sodium and ethanol in diseased control groups ( El-Hady, El Awdan, Ibrahim, 2013El-Hady FKA, El Awdan SA, Ibrahim AM. Anti-ulcerative potential of Egyptian propolis against oxidative gastric injury induced by indomethacin in rats. Adv J Med Plant Res. 2013;3(2):35-42. ).

In present study, diclofenac sodium and ethanol considerably decreased pH (from 5.38 to 1.54 and 1.42 respectively) as shown in Table VI and VIII . Diclofenac and ethanol have significantly enhanced the total acidity of gastric contents in disease control groups ( Table VI and VIII ). Increase in volume of gastric contents is due to over production of HCl ( Pratt, 1992Pratt D. Natural antioxidants from plant material. ACS Publications. 1992. Chapter 5; 54-7. DOI: 10.1021/bk-1992-0507.ch005
https://doi.org/10.1021/bk-1992-0507.ch0... ). AMEHN produced gastroprotective effects in pretreated rats against diclofenac and ethanol induced ulcer as shown by decrease in number of lesions, severity score and ulcer index ( Table V and VII ). Findings of present work are in line with previous studies ( De Barros et al ., 2008De Barros MP, Lemos M, Maistro EL, Leite MF, Sousa JPB, Bastos JK, et al. Evaluation of antiulcer activity of the main phenolic acids found in brazilian green propolis. J Ethnopharmacol. 2008;120(3):372-377. ; Kim et al ., 2006Kim S-H, Jun C-D, Suk K, Choi B-J, Lim H, Park S, et al. Gallic acid inhibits histamine release and pro-inflammatory cytokine production in mast cells. Toxicol Sci. 2006;91(1):123-131. ; Sumbul et al ., 2011Sumbul S, Ahmad MA, Mohd A, Mohd A. Role of phenolic compounds in peptic ulcer: An overview. J Pharm BioALLied Sci. 2011;3(3):361-367. ). Ethanol causes necrotic lesions of the gastric mucosa by lipid peroxidation, free radical production and increased intracellular oxidative stress ( Sannomiya et al. , 2005Sannomiya M, Fonseca VB, Da Silva MA, Rocha LRM, Santos LC dos, Hiruma-Lima CA, et al. Flavonoids and antiulcerogenic activity from Byrsonima crassa leaves extracts. J Ethnopharmacol. 2005;97(1):1-6, 2005. ). Thus, it can be considered that AMEHN has phytochemicals which show anti-oxidant potential to modify the deleterious effects of ethanol ( Table VI and VIII ). However, further studies on molecular level are required to confirm this mechanism.

Gastric mucosa is protected by prostaglandins synthesized from arachidonic acid whose production is interrupted by ulcerative agents ( Yamamoto et al ., 1992Yamamoto K, Kakegawa H, Ueda H, Mutsumoto H, Sudo T, Miki T, et al. Gastric cytoprotective anti-ulcerogenic actions of hydroxychalcones in rats. Planta Med. 1992;58(5):389-393. ). NSAIDs reduce prostaglandins synthesis from phospholipids leading to gastric mucosal damage. The protective effect of AMEHN in diclofenac induced gastric ulcer model might show its involvement in prostaglandins synthesis. Histopathological studies of also confirmed that AMEHN has gastroprotective effects similar as of omeprazole treated group of rats as shown in Figure 1 and 2 .

FTIR analysis of the extract has shown that it contains a variety of natural chemicals like alkyl aryl ether, aldehyde, conjugated alkenes, alkanes, carboxylic acid and others. HPLC analysis also showed presence of phenols like gallic acid, M-coumaric acid and quercetin. M-coumaric and quercetin have good ability to inhibit H+/K+-ATPase pump ( De Barros et al ., 2008De Barros MP, Lemos M, Maistro EL, Leite MF, Sousa JPB, Bastos JK, et al. Evaluation of antiulcer activity of the main phenolic acids found in brazilian green propolis. J Ethnopharmacol. 2008;120(3):372-377. ). Gallic acid also inhibits vasoconstriction and protein precipitation which lead to ulcer ( Sumbul et al ., 2011Sumbul S, Ahmad MA, Mohd A, Mohd A. Role of phenolic compounds in peptic ulcer: An overview. J Pharm BioALLied Sci. 2011;3(3):361-367. ). Quercetin is a natural flavonoid which has anti-ulcer activity. It has anti-lipid per oxidant and antioxidant properties. Its antiulcer activity is due to inhibition of ROS, reduced acid production and down regulation of H+/K+ ATPase pump. Quercetin also secures mucosa by elevated mucosal prostaglandin contents ( Martin et al ., 1998Martin M, La-Casa C, Alarcon-de-La-Lastra C, Cabeza J, Villegas I, Motilva V. Anti-oxidant mechanisms involved in gastroprotective effects of quercetin. Z Naturforsch C J Biosci. 1998;53(1-2):82-88. ).

CONCLUSION

The findings of this study suggested that Hedera nepalensis has gastroprotective activity in diclofenac and ethanol induced gastric ulcer, which might be attributed to anti-oxidant and lipid peroxidation inhibitory effect of plant. Such potential might be due to presence of anti-oxidant and phenolic contents in the extract. Thus, Hedera nepalensis might be useful to prevent gastritis and gastric ulcer.

REFERENCES

Abebaw M, Mishra B, Gelayee DA. Evaluation of anti-ulcer activity of the leaf extract of Osyris quadripartita Decne. (Santalaceae) in rats. J Exp Pharmacol. 2017;9:1-11.
Adefisayo MA, Akomolafe RO, Akinsomisoye SO, Alabi QK, Ogundipe OL, Omole JG, et al. Gastro-protective effect of methanol extract of Vernonia amygdalina (del.) leaf on aspirin-induced gastric ulcer in Wistar rats.” Toxicol Rep. 2017;4:625-633.
Ahmad SS, Javed S. Exploring the economic value of underutilized plant species in Ayubia National Park. Pak J Bot. 2007;39(5):1435-1442.
Akhtar N, Rashid A, Murad W, Bergmeier EJ. Diversity and use of ethno-medicinal plants in the region of Swat, North Pakistan. J Ethnobiol Ethnomed. 2013;9:25.
Awan AF, MS Akhtar, I Anjum, Mushtaq MN, Fatima A, Khan MUR, et al. Hepatoprotective effect of Ziziphus oxyphylla Edgew in paracetamol-induced hepatotoxic rat model. Pak J Pharm Sci. 2020;33(5):2449-2454.
Chandra S. Fourier transform infrared (Ft-Ir) spectroscopic analysis of Nicotiana plumbaginifolia (Solanaceae). J Med Plants Studies. 2019;7(1):82-85.
Chung KT, Shelat VG. Perforated peptic ulcer - an update. World J Gastrointest Surg. 2017;9(1):1-12. doi: 10.4240/wjgs.v9.i1.1. PMID: 28138363; PMCID: PMC5237817.
» https://doi.org/10.4240/wjgs.v9.i1.1
De Barros MP, Lemos M, Maistro EL, Leite MF, Sousa JPB, Bastos JK, et al. Evaluation of antiulcer activity of the main phenolic acids found in brazilian green propolis. J Ethnopharmacol. 2008;120(3):372-377.
El-Hady FKA, El Awdan SA, Ibrahim AM. Anti-ulcerative potential of Egyptian propolis against oxidative gastric injury induced by indomethacin in rats. Adv J Med Plant Res. 2013;3(2):35-42.
Hashmi WJ, Ismail H, Mehmood F, Mirza B. Neuroprotective, antidiabetic and antioxidant effect of Hedera nepalensis and lupeol against STZ+ AlCl 3 induced rats model. DARU. 2018;26(2):179-190.
Heinonen IM, Lehtonen PJ, Hopia AI. Antioxidant activity of berry and fruit wines and liquors. J Agric Food Chem. 1998;46(1):25-31.
Ismail IF, Golbabapour S, Hassandarvish P, Hajrezaie M, Abdul Majid N, Kadir FA, et al. Gastroprotective activity of Polygonum chinense aqueous leaf extract on ethanol-induced hemorrhagic mucosal lesions in rats. Evid Based Complementary Altern Med. 2012;404012. doi: 10.1155/2012/404012.
» https://doi.org/10.1155/2012/404012
Jahantighi A, G Kiani, TT Moghaddam and S Ghahari. In vitro antibacterial activity of selected medicinal plants traditionally used in Iran against plant and human pathogenic bacteria. Jordan J Bio Sci. 2016;9(3):221-226.
Jafri L, Saleem S, Ullah N, Mirza B. In vitro assessment of antioxidant potential and determination of polyphenolic compounds of Hedera nepalensis K. Koch. Arab J Chem. 2017;10(Suppl 2):S3699-S3706.
Jennings A, Welch AA, Fairweather-Tait SJ, Kay C, Minihane A-M, Chowienczyk P, et al. Higher anthocyanin intake is associated with lower arterial stiffness and central blood pressure in women. Am J Clin Nutr. 2012;96(4):781-788.
Kang J-W, Yun N, Han H-J, Kim J-Y, Kim J-Y, Lee S-M. Protective effect of flos lonicerae against experimental gastric ulcers in rats: mechanisms of antioxidant and anti-inflammatory action. Evid Based Complementary Altern Med . 2014;596920. doi: 10.1155/2014/596920
» https://doi.org/10.1155/2014/596920
Kanwal S, Ullah N, Haq I, Afzal I, Mirza B. Antioxidant, antitumor activities and phytochemical investigation of Hedera nepalensis K. Koch, an important medicinal plant from Pakistan. Pak J Bot. 2011;43:85-89.
Kim S-H, Jun C-D, Suk K, Choi B-J, Lim H, Park S, et al. Gallic acid inhibits histamine release and pro-inflammatory cytokine production in mast cells. Toxicol Sci. 2006;91(1):123-131.
Klein LC, Gandolfi RB, Santin JR, Lemos M, Cechinel Filho V, de Andrade SF. Antiulcerogenic activity of extract, fractions, and some compounds obtained from Polygala cyparissias St. Hillaire & Moquin (Polygalaceae). Naunyn Schmiedbergs Arch Pharmacol. 2010;381(2):121-126.
Lee M, Kallal S, Feldman M. Omeprazole prevents indomethacin-induced gastric ulcers in rabbits. Aliment Pharmacol Ther. 1996;10(4):571-576.
Liu X, Zakaria M, Islam M, Radhakrishnan R, Ismail A, Chen H, et al. Anti-inflammatory and anti-ulcer activity of Calligonum comosum in rats. Fitotherapia. 2001;72(5):487-491.
Luna JS, Dos Santos A, De Lima M, De Omena M, De Mendonça F, Bieber L, et al. A study of the larvicidal and molluscicidal activities of some medicinal plants from northeast Brazil. J Ethnopharmacol. 2005;97(2):199-206.
Martin M, La-Casa C, Alarcon-de-La-Lastra C, Cabeza J, Villegas I, Motilva V. Anti-oxidant mechanisms involved in gastroprotective effects of quercetin. Z Naturforsch C J Biosci. 1998;53(1-2):82-88.
Muthusamy V, Anand S, Sangeetha K, Sujatha S, Arun B, Lakshmi B. Tannins present in Cichorium intybus enhance glucose uptake and inhibit adipogenesis in 3T3-L1 adipocytes through PTP1B inhibition. Chem Biol Interact. 2008;174(1):69-78.
Sannomiya M, Fonseca VB, Da Silva MA, Rocha LRM, Santos LC dos, Hiruma-Lima CA, et al. Flavonoids and antiulcerogenic activity from Byrsonima crassa leaves extracts. J Ethnopharmacol. 2005;97(1):1-6, 2005.
Odeja O, Obi G, Ogwuche CE, Elemike EE, Oderinlo Y. Retracted Article: Phytochemical Screening, Antioxidant and Antimicrobial activities of Senna occidentalis (L.) leaves Extract. Clin Phytosci. 2015;1(6):1-6.
Pratt D. Natural antioxidants from plant material. ACS Publications. 1992. Chapter 5; 54-7. DOI: 10.1021/bk-1992-0507.ch005
» https://doi.org/10.1021/bk-1992-0507.ch005
Qureshi RA, Ghufran MA, Gilani SA, Sultana K, Ashraf M. Ethnobotanical studies of selected medicinal plants of Sudhan Gali and Ganga Chotti Hills, District Bagh, Azad Kashmir. Pak J Bot. 2007;39(7):2275-2283.
Ramis IB, Moraes EPd, Fernandes MS, Mendoza-Sassi R, Rodrigues O, Juliano CRV, et al. Evaluation of diagnostic methods for the detection of helicobacter pylori in gastric biopsy specimens of dyspeptic patients. Braz J Microbiol. 2012;43(3):903-908.
Sattar A, Abdo A, Mushtaq MN, Anjum I, Anjum A. Evaluation of Gastro-protective activity of Myristica fragrans on Ethanol-induced ulcer in albino rats. An Acad Bras Ciênc. 2019;91(2):e20181044. https://doi.org/10.1590/0001-3765201920181044 .
» https://doi.org/10.1590/0001-3765201920181044
Scalbert A, Manach C, Morand C, Rémésy C, Jiménez L. Dietary polyphenols and the prevention of diseases. Cri Rev Sci Nutri. 2005;45(4):287-306.
Sumbul S, Ahmad MA, Mohd A, Mohd A. Role of phenolic compounds in peptic ulcer: An overview. J Pharm BioALLied Sci. 2011;3(3):361-367.
Tiong SH, Looi CY, Hazni H, Arya A, Paydar M, Wong WF, et al. Antidiabetic and antioxidant properties of alkaloids from Catharanthus roseus (L.) G. Don. Molecules. 2013;18(8):9770-9784.
Tokuşoğlu Ö, Ünal M, Yildirim Z. HPLC-UV and GC-MS characterization of the flavonol aglycons quercetin, kaempferol, and myricetin in tomato pastes and other tomato-based products. Acta Chromatogr. 2003;13(13):196-207.
Wallace JL. Prostaglandins, NSAIDs, and gastric mucosal protection: why doesn’t the stomach digest itself? Physiol Rev. 2008;88(4):1547-1565.
Yamamoto K, Kakegawa H, Ueda H, Mutsumoto H, Sudo T, Miki T, et al. Gastric cytoprotective anti-ulcerogenic actions of hydroxychalcones in rats. Planta Med. 1992;58(5):389-393.

Publication Dates

Publication in this collection
19 June 2023
Date of issue
2023

History

Received
12 July 2020
Accepted
21 June 2022

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Abebaw M, Mishra B, Gelayee DA. Evaluation of anti-ulcer activity of the leaf extract of Osyris quadripartita Decne. (Santalaceae) in rats. J Exp Pharmacol. 2017;9:1-11.

[2] Adefisayo MA, Akomolafe RO, Akinsomisoye SO, Alabi QK, Ogundipe OL, Omole JG, et al. Gastro-protective effect of methanol extract of Vernonia amygdalina (del.) leaf on aspirin-induced gastric ulcer in Wistar rats.” Toxicol Rep. 2017;4:625-633.

[3] Ahmad SS, Javed S. Exploring the economic value of underutilized plant species in Ayubia National Park. Pak J Bot. 2007;39(5):1435-1442.

[4] Akhtar N, Rashid A, Murad W, Bergmeier EJ. Diversity and use of ethno-medicinal plants in the region of Swat, North Pakistan. J Ethnobiol Ethnomed. 2013;9:25.

[5] Awan AF, MS Akhtar, I Anjum, Mushtaq MN, Fatima A, Khan MUR, et al. Hepatoprotective effect of Ziziphus oxyphylla Edgew in paracetamol-induced hepatotoxic rat model. Pak J Pharm Sci. 2020;33(5):2449-2454.

[6] Chandra S. Fourier transform infrared (Ft-Ir) spectroscopic analysis of Nicotiana plumbaginifolia (Solanaceae). J Med Plants Studies. 2019;7(1):82-85.

[7] Chung KT, Shelat VG. Perforated peptic ulcer - an update. World J Gastrointest Surg. 2017;9(1):1-12. doi: 10.4240/wjgs.v9.i1.1. PMID: 28138363; PMCID: PMC5237817.
» https://doi.org/10.4240/wjgs.v9.i1.1

[8] De Barros MP, Lemos M, Maistro EL, Leite MF, Sousa JPB, Bastos JK, et al. Evaluation of antiulcer activity of the main phenolic acids found in brazilian green propolis. J Ethnopharmacol. 2008;120(3):372-377.

[9] El-Hady FKA, El Awdan SA, Ibrahim AM. Anti-ulcerative potential of Egyptian propolis against oxidative gastric injury induced by indomethacin in rats. Adv J Med Plant Res. 2013;3(2):35-42.

[10] Hashmi WJ, Ismail H, Mehmood F, Mirza B. Neuroprotective, antidiabetic and antioxidant effect of Hedera nepalensis and lupeol against STZ+ AlCl 3 induced rats model. DARU. 2018;26(2):179-190.

[11] Heinonen IM, Lehtonen PJ, Hopia AI. Antioxidant activity of berry and fruit wines and liquors. J Agric Food Chem. 1998;46(1):25-31.

[12] Ismail IF, Golbabapour S, Hassandarvish P, Hajrezaie M, Abdul Majid N, Kadir FA, et al. Gastroprotective activity of Polygonum chinense aqueous leaf extract on ethanol-induced hemorrhagic mucosal lesions in rats. Evid Based Complementary Altern Med. 2012;404012. doi: 10.1155/2012/404012.
» https://doi.org/10.1155/2012/404012

[13] Jahantighi A, G Kiani, TT Moghaddam and S Ghahari. In vitro antibacterial activity of selected medicinal plants traditionally used in Iran against plant and human pathogenic bacteria. Jordan J Bio Sci. 2016;9(3):221-226.

[14] Jafri L, Saleem S, Ullah N, Mirza B. In vitro assessment of antioxidant potential and determination of polyphenolic compounds of Hedera nepalensis K. Koch. Arab J Chem. 2017;10(Suppl 2):S3699-S3706.

[15] Jennings A, Welch AA, Fairweather-Tait SJ, Kay C, Minihane A-M, Chowienczyk P, et al. Higher anthocyanin intake is associated with lower arterial stiffness and central blood pressure in women. Am J Clin Nutr. 2012;96(4):781-788.

[16] Kang J-W, Yun N, Han H-J, Kim J-Y, Kim J-Y, Lee S-M. Protective effect of flos lonicerae against experimental gastric ulcers in rats: mechanisms of antioxidant and anti-inflammatory action. Evid Based Complementary Altern Med . 2014;596920. doi: 10.1155/2014/596920
» https://doi.org/10.1155/2014/596920

[17] Kanwal S, Ullah N, Haq I, Afzal I, Mirza B. Antioxidant, antitumor activities and phytochemical investigation of Hedera nepalensis K. Koch, an important medicinal plant from Pakistan. Pak J Bot. 2011;43:85-89.

[18] Kim S-H, Jun C-D, Suk K, Choi B-J, Lim H, Park S, et al. Gallic acid inhibits histamine release and pro-inflammatory cytokine production in mast cells. Toxicol Sci. 2006;91(1):123-131.

[19] Klein LC, Gandolfi RB, Santin JR, Lemos M, Cechinel Filho V, de Andrade SF. Antiulcerogenic activity of extract, fractions, and some compounds obtained from Polygala cyparissias St. Hillaire & Moquin (Polygalaceae). Naunyn Schmiedbergs Arch Pharmacol. 2010;381(2):121-126.

[20] Lee M, Kallal S, Feldman M. Omeprazole prevents indomethacin-induced gastric ulcers in rabbits. Aliment Pharmacol Ther. 1996;10(4):571-576.

[21] Liu X, Zakaria M, Islam M, Radhakrishnan R, Ismail A, Chen H, et al. Anti-inflammatory and anti-ulcer activity of Calligonum comosum in rats. Fitotherapia. 2001;72(5):487-491.

[22] Luna JS, Dos Santos A, De Lima M, De Omena M, De Mendonça F, Bieber L, et al. A study of the larvicidal and molluscicidal activities of some medicinal plants from northeast Brazil. J Ethnopharmacol. 2005;97(2):199-206.

[23] Martin M, La-Casa C, Alarcon-de-La-Lastra C, Cabeza J, Villegas I, Motilva V. Anti-oxidant mechanisms involved in gastroprotective effects of quercetin. Z Naturforsch C J Biosci. 1998;53(1-2):82-88.

[24] Muthusamy V, Anand S, Sangeetha K, Sujatha S, Arun B, Lakshmi B. Tannins present in Cichorium intybus enhance glucose uptake and inhibit adipogenesis in 3T3-L1 adipocytes through PTP1B inhibition. Chem Biol Interact. 2008;174(1):69-78.

[25] Sannomiya M, Fonseca VB, Da Silva MA, Rocha LRM, Santos LC dos, Hiruma-Lima CA, et al. Flavonoids and antiulcerogenic activity from Byrsonima crassa leaves extracts. J Ethnopharmacol. 2005;97(1):1-6, 2005.

[26] Odeja O, Obi G, Ogwuche CE, Elemike EE, Oderinlo Y. Retracted Article: Phytochemical Screening, Antioxidant and Antimicrobial activities of Senna occidentalis (L.) leaves Extract. Clin Phytosci. 2015;1(6):1-6.

[27] Pratt D. Natural antioxidants from plant material. ACS Publications. 1992. Chapter 5; 54-7. DOI: 10.1021/bk-1992-0507.ch005
» https://doi.org/10.1021/bk-1992-0507.ch005

[28] Qureshi RA, Ghufran MA, Gilani SA, Sultana K, Ashraf M. Ethnobotanical studies of selected medicinal plants of Sudhan Gali and Ganga Chotti Hills, District Bagh, Azad Kashmir. Pak J Bot. 2007;39(7):2275-2283.

[29] Ramis IB, Moraes EPd, Fernandes MS, Mendoza-Sassi R, Rodrigues O, Juliano CRV, et al. Evaluation of diagnostic methods for the detection of helicobacter pylori in gastric biopsy specimens of dyspeptic patients. Braz J Microbiol. 2012;43(3):903-908.

[30] Sattar A, Abdo A, Mushtaq MN, Anjum I, Anjum A. Evaluation of Gastro-protective activity of Myristica fragrans on Ethanol-induced ulcer in albino rats. An Acad Bras Ciênc. 2019;91(2):e20181044. https://doi.org/10.1590/0001-3765201920181044 .
» https://doi.org/10.1590/0001-3765201920181044

[31] Scalbert A, Manach C, Morand C, Rémésy C, Jiménez L. Dietary polyphenols and the prevention of diseases. Cri Rev Sci Nutri. 2005;45(4):287-306.

[32] Sumbul S, Ahmad MA, Mohd A, Mohd A. Role of phenolic compounds in peptic ulcer: An overview. J Pharm BioALLied Sci. 2011;3(3):361-367.

[33] Tiong SH, Looi CY, Hazni H, Arya A, Paydar M, Wong WF, et al. Antidiabetic and antioxidant properties of alkaloids from Catharanthus roseus (L.) G. Don. Molecules. 2013;18(8):9770-9784.

[34] Tokuşoğlu Ö, Ünal M, Yildirim Z. HPLC-UV and GC-MS characterization of the flavonol aglycons quercetin, kaempferol, and myricetin in tomato pastes and other tomato-based products. Acta Chromatogr. 2003;13(13):196-207.

[35] Wallace JL. Prostaglandins, NSAIDs, and gastric mucosal protection: why doesn’t the stomach digest itself? Physiol Rev. 2008;88(4):1547-1565.

[36] Yamamoto K, Kakegawa H, Ueda H, Mutsumoto H, Sudo T, Miki T, et al. Gastric cytoprotective anti-ulcerogenic actions of hydroxychalcones in rats. Planta Med. 1992;58(5):389-393.

Phytochemicals	Test	Observations	Inferences
Alkaloids	Mayer’s test	Formation of ppt.	+
Anthraquinones	Ammonia test	No pink, violet or red color in ammonical phase	-
Flavonoids	Magnesium test	A red or intense red coloration	+
Glycosides	Fehling test	No red precipitates	-
Phenols	Ferric chloride test	Green/dirty green color	+
Resins	Acetone test	Green color solution	+
Saponins	Foam test	Foam observed	+
Steroids	Salkowshi test	No reddish-brown cooler observed	-
Tannins	FeCl₃ test	Blue black/blue green ppt.	+

Solution concentration	pH
1 mL extract	5.51±0.34
1 mL 0.1 N HCl	1.58±0.21
1 mL extract + 1 mL HCl	2.49±0.11
1 mL extract + 2 mL HCl	1.97±0.18
1 mL 0.1 N NaOH	12.70±0.92
1 mL extract + 1 mL NaOH	11.02±0.17
1 mL extract + 1 mL NaOH	12.03±0.51

Solution concentration (µg/mL)	Antioxidant potential
Solution concentration (µg/mL)	Quercetin	Ascorbic acid	AMEHN
20	81.71±0.77	94.15±0.17	31.07±0.536
40	84.28±0.50	96.04±0.36	65.76±0.183
60	88.81±0.41	96.35±0.31	80.07±0.30
80	92.62±0.59	96.73±0.33	82.34±0.43
100	95.59±0.42	98.23±0.27	83.55±0.28

Concentrations (µg/mL)	% Inhibition of lipid peroxidation
Concentrations (µg/mL)	Quercetin	AMEHN
62.5	63.99±0.05	0.00
125	68.56±0.28	37.77±0.44
250	70.80±0.16	61.81±0.09
500	73.93±0.07	68.07±0.31
1000	74.38±0.19	70.88±0.45

Treatment	Severity score	No. of lesions	Ulcer index	Percentage protection (%)
Normal control	0	0	0	-
Disease control	11.40±1.12	3.00±0.32	11.44	-
Standard drug (20 mg/kg)	0.40±0.15***	0.20±0.02***	2.04***	82.17***
AMEHN (200 mg/kg)	1.40±0.40***	0.60±0.03***	2.20***	80.77***
AMEHN (400 mg/kg)	0.60±0.10***	0.40±0.05***	2.16***	81.12***

Brasil

Brasil

Gastroprotective potential and mechanisms of action of Hedera nepalensis

Abstract

INTRODUCTION

MATERIAL AND METHODS

Animals

Collection and extraction of H. nepalensis

Phytochemical testing

Buffer potential estimation

Antioxidant activity

Lipid peroxidation inhibition evaluation of AMEHN

Study design for diclofenac induced gastric ulcer

Study design for ethanol induced gastric ulcer

Ulcer Scoring, ulcer Index and percentage protection

Determination of gastric total acidity and pH

Histopathological Studies

Fourier-transform infrared spectroscopy (FTIR) analysis

High performance liquid chromatography (HPLC) analysis

RESULTS

Phytochemical Screening

Buffer potential

Antioxidant activity

Lipid peroxidation inhibition

Effects of AMEHN on gastric ulcer induced by diclofenac

Effect of AMEHN on pH and total acidity of gastric juice

Histopathological studies

Effects of AMEHN on gastric ulcer induced by ethanol

Effects of AMEHN on pH and total acidity of gastric juice in ethanol induced ulcer

Histopathological assessment

FTIR analysis of H. nepalensis

Phenolic content estimation

DISCUSSION

CONCLUSION

REFERENCES

Publication Dates

History

Treatment groups	pH	Total Acidity (mEq/L/100 g)
Normal control	5.38±0.12	24.01±0.23
Disease control	1.54±0.11	73.42±0.81
Standard drug (20 mg/kg)	5.52±0.09***	35.39±0.96***
AMEHN (200 mg/kg)	4.78±0.06***	46.20±1.10***
AMEHN (400 mg/kg)	5.36±0.07***	34.54±1.80***

Treatments	Severity score	No. of lesions	Ulcer index	Percentage protection (%)
Normal control	0	0	0	-
Disease control	12.80±1.63	3.80±0.38	11.66	-
Standard drug treatment	1.80±0.50***	0.60±0.20***	4.24	63.64
AMEHN (200 mg/kg)	2.00±0.38***	0.60±0.20***	4.26***	63.46***
AMEHN (400 mg/kg)	1.20±0.58***	0.80±0.17***	6.20***	46.83***

Sr. no.	Peak value	Transmittance	Bond	Functional group
1	803.87	77.51	Unknown	-
2	1020.06	51.81	Unknown	-
3	1272.55	67.32	C-O stretching	Alkyl aryl ether
4	1389.02	69.55	C-H bending	Aldehyde
5	1598.00	69.75	C=C stretching	Conjugated alkenes
6	2920.05	73.82	C-H stretching	Alkanes
7	3280.01	69.04	OH stretching	Carboxylic acid

Peak no.	Retention time	Compound name	Quantity (ppm)
1	1.55	Unknown	-
2	2.44	Ethanol	-
3	2.82	Quercetin	0.78 ppm
4	3.26	Unknown	-
5	3.70	Unknown	-
6	5.05	Gallic acid	5.24 ppm
7	5.93	Unknown	-
8	8.23	Unknown	-
9	10.99	Unknown	-
10	13.94	Unknown	-
11	17.17	Unknown	-
12	18.42	Unknown	-
13	20.02	M-cumeric acid	5.52 ppm
14	23.85	Unknown	-
15	30.39	Unknown	-
16	32.29	Unknown
17	34.43	Unknown	-