Iraqi J Pharm Sci, Vol.30(2) 2021 Antioxidant activity of Echinops polyceras DOI: https://doi.org/10.31351/vol30iss2pp261-268 261 Antioxidant Activity of Total phenols and Flavonoids extracted from Echinops polyceras roots grown in Syria Issa Al-Assaf*,1 and Mays Khazem* * Department of Pharmacognosy in Faculty of Pharmacy, Damascus University, Damascus, Syria Abstract Free radicals are products of normal cellular metabolism, they are unstable, short-lived, and highly reactive and the excessive production of them may cause numerous degenerative diseases like cancer. Antioxidants such as polyphenols have a protective role against free radicals. Echinops polyceras Boiss. (Asteraceae) is one of Echinops genus species that spread in Syria, Lebanon, and Palestine. Phytochemicals found in this species roots have been extracted with gradient polarity solvents, and primary screening of the secondary metabolites was established. Then, the phenolic compounds content was determined with Folin-Ciocalteu reagent and flavonoids content with aluminum chloride reagent. The free radicals scavenging activity was evaluated for all extracts with DPPH• in a 96-well microplate. The selectivity study indicates that ascorbic acid and reducing sugars didn't exist in the extracts. The identification tests showed the presence of polyphenols like flavonoids and coumarins. The methanolic extract of the E.polyceras roots was the most effective scavengers of free radicals (84% in 30 min) with phenolic compounds content 575.5 mg GAE/g DE and flavonoids content 130 mg QE/ g DE, and the chloroform extract was the least effective as free radical scavenging (45% in 30 min) as the phenolic compounds content was 222.5 mg GAE/g DE and flavonoids content 57.5mg QE/ g DE. In conclusion, the phenolic compounds and flavonoids from Echinops polyceras Boiss. are effective in free radicals scavenging and protecting from diseases caused by oxidative stress. Keywords: Antioxidants, Polyphenols, Flavonoids, Free Radicals, and Echinops polyceras Boiss دراسةُ الفعاليّة الُمضادة لألكسدة لعديدات الفينول والفالفونوئيدات الُمستخلَصة من جذور نبات Echinops polyceras النامي في سورية *ميس خازم و 1،عيسى العّساف* كليّة الصيدلة، جامعة دمشق، دمشق، سورية في قسم العقاقير * الخالصة فرط تُعدّ الجذور الُحّرة نواتج طبيعّية لعمليات االستقالب، وتتميّز أنها غير ثابتٍة وذات عمٍر قصير وُمتفاعلة بشدّة، ويُمكن أن يُسبب Echinopsإنتاجها أمراضاً تنكسيّة مثل السرطان. تتميّز ُمضادات األكسدة مثل عديدات الفينول بدورها الوقائّي ضد الجذور الُحّرة. يُعدّ نوع polyceras Boiss. أحد أنواع جنسEchinops .استُخلصت الُمكّونات الفعّالة الموجودة في جذور هذا الذي ينتشر في سورية ولبنان وفلسطين -لفينولّي )باستخدام كاشف فولينالنوع باستخدام ُمحاّلٍت ُمتدّرجة القطبّية، وقد تّم بعد ذلك إجراء تحّرٍ أولّي عن الُمستقلبات الثانوّية. تّم تحديد الُمحتوى ا استخدام كاشف سيكالتو( والفالفونوئيدّي )باستخدام كاشف كلوريد األلمنيوم(، ومن ثّم تقييم الفعاليّة الكاسحة للجذور الُحّرة للخالصات المدروسة ب DPPH• ن كّلٍ من حمض األسكوربيك والسكريات حفرة. أظهرت نتائج دراسة االنتقائّية خلو الخالصات م 96وذلك باستخدام طبٍق للزرع ذو الكحولّي الُمختزلة، كما أظهرت تفاعالت نتائج الكشوفات األوليّة وجود عديدات الفينول مثل الفالفونوئيدات والكومارينات. وقد أبدى الُمستخلص 130والفالفونوئيدّي mg GAE/g DE 575.5دقيقة( حيث بلغ الُمحتوى الفينولّي 30خالل %84أفضل نشاط في كسح الجذور الُحّرة وبتقدير ) mg QE/ g DE( حيث بلغ الُمحتوى الفينولّي 30خالل %45، وكانت أدنى فعالية ُمضادة لألكسدة لُمستخلص الكلوروفورم )222.5دقيقة mg GAE/g DE 57.5والفالفونوئيدّيmg QE/ g DEفالفونوئيدات تمتلك فعّالّية في كسح . يُمكن تلخيص ما سبق بأن الُمركبات الفينوليّة وخاصةً ال .الجذور الُحّرة وبالتالي الوقاية من األمراض الناتجة عن الشدة التأكسديّة Boiss Echinops polycerasعديدات الفينول، الفالفونوئيدات، الجذور الُحّرة وُمضادات األكسدة، الكلمات المفتاحيّة: Introduction Free radicals are products of normal cellular metabolism, they are atoms or molecules which contain one or more unpaired electrons in a valency shell. The odd number of electron(s) of a free radical makes it unstable, short-lived and highly reactive (1). The excessive production of free radicals is considered to be an important cause of oxidative damage in biomolecules, such as proteins, lipids, and DNA, this damage leads to numerous degenerative diseases (2), such as cancer, atherosclerosis, gastric ulcer, and other conditions (3). Antioxidants are molecules that can prevent or delay the oxidation of substrate, these compounds have a high affinity for free radicals and scavenge them to protect our health (4). Polyphenols are strong antioxidants that have a protective role against oxidative stress caused by excess free radicals (5). The mechanism of the protective action of phenolic compounds in plants relies on the antioxidant activity that scavenges free radicals, protection of lipid peroxidation, and the chelation of toxic metals (6). 1Corresponding author E-mail: issa.alassaf.92@gmail.com Received: 18/ 5/2021 Accepted:11 / 7 /2021 Published Online First: 2021-12-12 Iraqi Journal of Pharmaceutical Science https://doi.org/10.31351/vol30iss2pp261-268 Iraqi J Pharm Sci, Vol.30(2) 2021 Antioxidant activity of Echinops polyceras 262 Flavonoids are a large subgroup of the family of phenolic compounds, and because of the presence of multiple hydroxyl groups in their structure flavonoids have reducing properties (7). Echinops (Asteraceae) is a genus that includes 120 species of perennials, annuals, and biennials plants. These species are found in Eastern and Southern Europe, Tropical and North Africa, and Asia (8). Echinops polyceras Boiss. is a perennial herb, 40-60 cm, sometimes with very fine and short whitish glandular hairs in the lower part. Basal leaves congested, oblong-lanceolate, pinnatipartite into short lobes armed with short yellow spines. Heads generally abundantly, with about 4.5-5 cm in diameter (not including cornigerous bracts). Partial involucre of non-cornigerous headlets about 2 cm, pale green. Corolla is white to pale bluish, anthers are greyish-violet, and the flowering time is June – July (9). This species spread in Syria, Lebanon, and Palestine (10). The aim of this study was to evaluate the phytochemicals and the free radicals scavenging activity of Echinops polyceras Boiss root since no previous studies have distinguished the chemical constituents and the biological effects of this plant. Materials and Methods Chemicals Gallic acid (was purchased from AVONCHEM), Quercetin (from Sigma-Aldrich), 2,2-diphenyl-1-picrylhydrazyl DPPH (from TCI), distilled water, absolute ethanol (from Merck), absolute methanol (from sigma-Aldrich), ethyl acetate (from SHAM LAB), chloroform (from Merck), glacial acetic acid (from BDH), hydrochloric acid (from Himedia), sulfuric acid (from Himedia), folin ciocalteu (from Sigma- Aldrich), sodium carbonate (from Scharlau), aluminum chloride (from Scharlau), potassium acetate (from Merck), ascorbic acid (from Panreac Quimica SLU), magnesium metal turnings (from Chem-Lab), ferric chloride (from Panreac), potassium iodide (from Eurolab), bismuth nitrate (from Himedia) and mercuric chloride (from Himedia), picric acid (from Panreac eu), iodine crystals (from Honeywell), 3,5-dinitrobenzoic acid (from Titan biotech), gelatin. Apparatus 96-well microplate reader (BioTek), rotary evaporator. Plant material The whole plant of flowering Echinops polyceras Boiss. was collected from Ma'aret Sednaya (Rif-Dimashq, Syria) in July 2019, and authenticated by Dr. Imad Alkadi (Department of Plant Biology, Damascus University, Syria). The Roots were separated from the rest of the plant parts, then dried in shade and powdered. Extraction of the plant roots: Dried and powdered roots of Echinops polyceras Boiss. (20 g) were extracted with 200 ml of each of gradient polarity solvents: Distilled water, Ethanol 50%, absolute Methanol, Methanol + Ethyl Acetate (1:1), and chloroform, at room temperature with shaking for seven days. The five extracts were evaporated separately by a rotary evaporator, and the extraction yield was calculated by the equation: Yield% = (weight of evaporated extract/ weight of roots powder) ×100 Phytochemical identification Echinops polyceras roots extract was assessed for the existence of flavonoids, coumarins, tannins, anthraquinones, alkaloids, saponins and cardiac glycosides. Test for flavonoids lavonoids were identified by UV (366 nm) fluorescence after the addition of 1 ml of 5% aluminum chloride in ethanol (11).  Magnesium metal (0.5 g) was added to 5 ml of ethanolic extract then 1 ml of concentrated HCl was added. A pink or red coloration that disappears on standing for 3 minutes indicates the presence of flavons (Shinoda test). Test for coumarins Ethanolic extract (5 ml) was evaporated, and the residue was dissolved in 2 ml of hot distilled water, then few drops of this solution were put on a filter paper and the fluorescence under UV light was examined. An intense blue fluorescence indicates the presence of coumarins. Test for tannins  Ferric chloride test: Ethanolic extract (1 ml) was added into a test tube then 2 to 3 drops of 10% of ferric chloride (FeCl3) solution were added, and observed for a dark green (hydrolysable tannins) or dark blue (condensed tannins) coloration (12).  Gelatin test: Tested extract (1 ml) was placed in a test tube, then 2 drops of 1 % gelatin solution with 10% sodium chloride were added. A white precipitate formation indicates the presence of tannins (13). Test for anthraquinones:  Borntrager test: E. polyceras roots powder (1 g) was extracted with 10 ml of chloroform for 10 minutes and filtered, then 2 ml of ammonia were added. The formation of red color in the aqueous layer indicates the presence of free anthraquinones (12).  Modified Borntrager test Boil 1g of the plant material with 2ml of dilute sulphuric acid, 2ml of 5% aqueous ferric chloride solution for 5 minutes and continue the reaction as Borntrager test. The formation of red Iraqi J Pharm Sci, Vol.30(2) 2021 Antioxidant activity of Echinops polyceras 263 color in the aqueous layer indicates the presence of anthraquinone glycosides (13). Test for alkaloids Ethanolic extract (20 ml) was evaporated, and the dry residue dissolved in 5 ml of HCl (2N) and filtered. Then, few drops of Mayer, Dragendroff, Wagner and Hager reagents were added. The formation of white, orange, reddish-brown and yellow precipitates respectively indicate the presence of alkaloids (12, 13). Test for saponins To 0.5 g of the aqueous extract, 20 ml of hot water were added into a test tube, the tube was shaken vigorously. The formation of a stable foam indicates the presence of saponins (12). Test for cardiac glycosides  Keller killiani test: To 2 ml of the ethanolic extract, 1 ml of glacial acetic acid was added with one drop of 5% FeCl3 and 1 ml concentrated H2SO4. The formation of reddish-brown color at the junction of the two liquid layers, and the bluish-green color at the upper layer indicate the presence of cardiac glycosides (14).  Kedde’s test: Evaporate the chloroform extract of the roots, then add one drop of 90% alcohol and 2 drops of the reagent (2% 3,5-dinitro benzoic acid in 90% alcohol), an alkaline solution (20% sodium hydroxide solution) was added. Purple color is produced in the case of the presence of β- unsaturated-o lactones (13). Determination of total phenolic content (TPC) Total phenolic content was determined by a micro colorimetric method described by Ainsworth & Gillespie (15): 200 mg of each extract were dissolved with 2 ml of methanol 95% (vol/vol). 100 µL of each sample were transferred to 2 ml microtubes and were mixed with 200 µL of 10% (vol/vol) Folin–Ciocalteu reagent, the mixture was vortexed thoroughly. Then 800 µL of Na2CO3 (700 mM) was added into each tube, and the assay tubes were incubated at room temperature for two hours. 200 µL of samples, standard (gallic acid), and blank (200 µL of 10% (vol/vol) Folin–Ciocalteu reagent with 800 µL of 700 mM Na2CO3) were transferred to a clear 96-well microplate, and the absorbance of each well was read at 765 nm in triplicate. Gallic acid calibration curve The calibration curve was established with nine dilutions of gallic acid standard at concentrations of (12, 24, 36, 48, 60, 84, 96, 108, 120) mg/L. Then the absorbance was read at 765 nm using the microplate reader. TPC of the extracts: Total phenolic content was calculated as gallic acid equivalents (GAE) in 1 g of dried extract (DE) using the regression equation between Gallic acid standard concentrations and absorption at 765 nm. Specificity The specificity of Folin–Ciocalteu method was checked by detection of the presence of some reducing compounds like reducing sugars and ascorbic acid.  Detection of reducing sugars using Fehling's test: 1 ml of the ethanol extract was diluted with 1ml of water in a test tube, then 20 drops of boiling Fehling’s solution (A and B) was added. The formation of a precipitate red-brick in the bottom of the tube indicates the presence of reducing sugars (12).  Detection of Ascorbic acid using a spectrophotometric method: - Determination of λmax of ascorbic acid (16) Ascorbic acid (0.1 g) was dissolved with distilled water in a volumetric flask (100 ml), then 1 ml of this solution was transferred into another 100 ml volumetric flask with the addition of 10 ml of 0.1 N of hydrochloric acid, distilled water was used to complete the rest volume to 100 ml. The λmax was determined by a spectrophotometric scan between 200-300 nm. - Scanning of extract solution Aqueous extract (1 g) was also dissolved with distilled water in a volumetric flask (100 ml), then 1 ml of the solution was transferred into another 100 ml volumetric flask with 10 ml of 0.1 N of hydrochloric acid, then distilled water was used to complete the rest volume to 100 ml. The absorbance was detected at the λmax of ascorbic acid. Determination of total flavonoids content (TFC) Flavonoids content was determined according to chang et al. protocol (17): 200 mg of each extract were mixed with 1.5 mL of 95% ethanol, 100 µL of 10% AlCl3 (w/v) solution, and 100 µL of 1 mol/L potassium acetate solution were added, and the assay tubes were incubated at room temperature for 30 min. 200 µL of samples, standard (Quercetin) and blank (100 µL of 10% AlCl3 (w/v) with 100 µL of 1 mol/L potassium acetate) were transferred to a clear 96-well microplate and read the absorbance of each well at 420 nm in triplicate. Quercetin calibration curve The calibration curve was established with seven dilutions of quercetin standard at concentrations of (6, 12, 24, 30, 36, 48, 60) mg/L. Then the absorbance was read at 420 nm using the microplate reader. TFC of the extracts Total Flavonoids content was calculated as quercetin equivalents (QE) in 1 g of dried extract (DE) using the regression equation between quercetin standard concentrations and absorption at 420 nm. Evaluation of free radicals scavenging activity (RSA) Iraqi J Pharm Sci, Vol.30(2) 2021 Antioxidant activity of Echinops polyceras 264 The DPPH• radical scavenging activity was evaluated according to Cheung et al. method (18) with some modification by Choi et al. Briefly, 160 µL of 0.2 mM DPPH• in methanol were mixed with 40 µL of the extracts or standards (ascorbic acid, gallic acid, and quercetin) in a 96-well microplate. The mixtures were left to stand at room temperature, and the absorbance at 520 nm was measured against methanol as a blank after 10 and 30 min. Free radicals scavenging activity (RSA) was determined by the equation: RSA% = 100 × 𝐀𝟎−𝐀𝐬 𝐀𝟎 Where: A0: absorption of DPPH• solution As: absorption of DPPH• solution after 10 and 30 min of the sample addition. Results Extraction yield The extraction yield% of the extracts is shown in Table (1). Aqueous extract showed the highest yield (10.5%) followed by hydroethanolic 50%, methanol, methanol: ethyl acetate (1:1), and chloroform extracts with yields of 7, 4, 2.75, and 1%, respectively. Table 1. Extraction yield Extracts Yield% DH2O 10.5 EtOH 50 7 MeOH 4 MeOH+EtOAc 2.75 CHCl3 1 Phytochemical identification The results of the identification tests are shown in Table (2). Table 2 . Phytochemical identification of E. polyceras roots Flavonoids Aluminum chloride + Shinoda test + Coumarins fluorescence + Tannins Ferric chloride test + Gelatin test - Anthraquinones Borntrager test - Modified Borntrager - Alkaloids Mayer - Dragendroff - Wagner - Hager - Saponins Foam test + Cardiac glycosides Keller killiani test - Kedde’s test - Gallic acid calibration curve Gallic acid concentrations and their absorbances are shown in Table (3). Also, the linearity and the regression equation are shown in Figure (1). Table 3. Gallic acid concentrations and their absorbances Figure 1. Gallic acid calibration curve TPC of the extracts Total phenolics content in the extracts was presented in Table (4). The methanolic extract showed the highest content of phenolic compounds (575.5 mg GAE/g DE), followed by MeOH: EtOAc (1:1), EtOH 50%, distilled H2O, and CHCl3 extracts, respectively. The TPC results are shown in Figure (2). Concentration (mg/L) Ā 765 0 0 12 0.174 24 0.317 26 0.428 48 0.595 60 0.721 84 1.011 96 1.13 108 1.223 120 1.378 Iraqi J Pharm Sci, Vol.30(2) 2021 Antioxidant activity of Echinops polyceras 265 Table 4.TPC, TFC and RSA% of the standards and the extracts. Samples TPC±SD (GAE/ g DE) TFC±SD (QE/ g DE) RSA% Time for RSA≥ 90% 10 min 30 min Ascorbic Acid - - 91.21 93.85 < 10 min Gallic Acid - - 83.52 87.54 > 30 min Quercetin - - 85.71 89.59 > 30 min DH2O 403.5 ±0.335 103 ±0.541 76.61 82.65 > 30 min EtOH 50 486 ±0.335 119 ±0.207 77.39 81.55 > 30 min MeOH 575.5 ±0.358 130 ±0.435 78.96 84.07 > 30 min MeOH+EtOAc 521.5 ±0.503 123 ±0.281 73.47 83.28 > 30 min CHCl3 222.5 ±0.276 57.5 ±0.405 35.16 45.27 > 30 min Figure 2. TPC in 1 g of the dried extracts All results of TPC are presented as the mean of three replicates ± SD (p < 0.05) Specificity  Detection of reducing sugars: The result of Fehling's test indicates the absence of reducing sugars because the red-brick precipitate does not exist.  Detection of Ascorbic acid using a spectrophotometric method: - Determination of λmax of ascorbic acid: Ascorbic acid solution showed the maximum absorbance at 240 nm, according to Figure (3). Figure 3. The scanning of ascorbic acid solution Scanning of extract solution The scanning of the extract solution is shown in Figure (4), it indicates that the extract of E. polyceras roots is free of ascorbic acid. Figure 4. The scanning of roots extract solution. Quercetin calibration curve The concentrations of quercetin and their absorbances are shown in Table (5). Also, the linearity and the regression equation are shown in Figure (5). Iraqi J Pharm Sci, Vol.30(2) 2021 Antioxidant activity of Echinops polyceras 266 Table 5. Quercetin concentrations and their absorbances Figure 5. Quercetin calibration curve TFC of the extracts Flavonoids content in the extracts is also presented in Table (4). As the methanolic extract showed the highest phenolic amount, it contained the highest flavonoid content (38.9 mg QE/ g DE), followed by MeOH: EtOAc (1:1), EtOH 50%, distilled H2O and CHCl3 extracts, respectively. The TFC results are shown in Figure (6). Figure 6. TFC in 1 g of the dried extracts All results of TFC are presented as the mean of three replicates ± SD (p < 0.05) RSA of the extracts DPPH• assay revealed that the methanolic extract was the most effective in free radicals scavenging after 30 min (≈ 84.1 %), compared with the other extracts: MeOH: EtOAc (1:1), DH2O, EtOH 50%, and CHCl3, they scavenge 83.28, 82.65, 81.55, and 45.27 % of DPPH• radical, respectively. The scavenging activities after 10 and 30 min for the standards: [ascorbic acid (AA), gallic acid (GA) and quercetin (Q)] and the studied extracts are shown in Figure (7). The DPPH• scavenging activities after 10 and 30 min, total phenolic, and flavonoid contents of the extracts is shown in Table (4). Figure 7.RSA% of standards and studied extracts after 10 and 30 min Statistical analysis All experiments were accomplished in triplicate. The results were expressed as the mean± standard deviation (SD). One-way analysis of variance (ANOVA) was carried out to identify significant differences between experimental groups, using Microsoft excel 2019. Differences were considered significant (p < 0.05). Correlation ratio was calculated between: - Total phenolic content and flavonoids content of the roots extracts, it was ≈ 98%. - Free radical scavenging activity and total phenolic content, it was ≈ 82% - Free radical scavenging activity and flavonoids content, it was ≈ 89% Discussion Neither the chemical composition nor the biological effects of Echinops polyceras Boiss. have been studied previously. In this study, a primary chemical screening has been established, the polyphenols and flavonoids contents have been determined and the free radicals scavenging activity has been evaluated for five different extracts of this plant. The results of extraction yield of E. polyceras Boiss. roots (H2O> EtOH 50%> MeOH 100% > MeOH+ EtOAc (1:1) > CHCl3) -which descended according to the polarity of the solvent- may refer to the polarity of the extracted compunds, or the presence of the secondary metabolites as glycosides more than free aglycons because the solvents have a crucial role in the type of the secondary metabolites found in the extracts (19). The phytochemical screening revealed the existence of polyphenols as an important component in the Concentration (mg/L) Ā 420 0 0 6 0.058 12 0.109 24 0.196 30 0.235 36 0.285 48 0.363 60 0.456 Iraqi J Pharm Sci, Vol.30(2) 2021 Antioxidant activity of Echinops polyceras 267 extract, especially flavonoids and coumarins, because of that the content of total phenols and flavonoids were determined. Ascorbic acid and reducing sugars are reducing compounds that may interfere with the antioxidant activity of the phenolic compounds in the extracts (20), so, they were identified in the specificity tests, which indicates the absence of ascorbic acid and the reducing sugars. The methanolic extract of E. polyceras roots showed the highest content of total phenols (575.5 GAE/ g DE) and flavonoids (194.5 QE/ g DE), while the chloroform extract showed the lowest contents 222.5 GAE/ g DE and 94 QE/ g DE respectively. Based on these results, the examined extracts have significant antioxidant and free radicals scavenging effects, the most effective extract among them was the methanolic extract (84% in 30 minutes), while the chloroform extract was the less effective (45% in 30 minutes), this may be explained by the content of phenols and flavonoids in the extracts. According to the correlation ratio, the free radicals scavenging activity is correlated to the phenolic content and flavonoids content with correlation ratio 82% and 89%, respectively, these results indicate that the phenolic compounds especially flavonoids are effectively contributed to the scavenging activity. Also, we noticed that there is a high correlation between phenolic compounds and flavonoids (98%), this may indicate that the majority of phenols in the studied extracts are flavonoids and these compounds were responsible for most of the activity. The phenolic content may contribute directly to the antioxidant activity (21). Studied extracts scavenging activities of free radicals were close to the scavenging activities of gallic acid and quercetin standards, this may be explained by the obvious content of phenolic compounds especially flavonoids. Depending on the positive result of Shinoda test, the extract of roots contains flavone type of flavonoids, the structure-activity relationship study of these compounds indicates that the hydroxyl groups, the 3,4-catechol structure in the B-ring, the 2-3 double bond, and 4-oxo function are key factors for the antioxidant activity of the flavonoids (22). The aqueous extract which can use as an infusion in traditional medicine (23) showed a good effect in scavenging free radicals (≈83 in 30 minutes). All the results of this study showed that E. polyceras roots can be a valuable source of polyphenols such as flavonoids, which have a crucial role as antioxidants and free radicals scavengers, this can predict the ability to use this species in the treatment of oxidative stress illnesses. This plant needs more studies about the safety, the toxicological effects and the determination of the therapeutic dose. Conclusion The study was concluded that our study is the first report about Echinops polyceras Bois. roots, where primary identification tests of secondary metabolites were established, and the phenolic compounds and flavonoids contents were determined in different extracts, using micro methods in a 96-well microplate. Also, the scavenging activity of free radicals was evaluated using the DPPH• radical. Our in vitro results were good enough to make this species a good source of effective antioxidants which can be used to prevent oxidative stress illnesses. The in vivo and the safety studies should be fulfilled. Acknowledgments The authors would like to thank the staff of the department of pharmacognosy in the Faculty of pharmacy Damascus University and the staff of the Leishmania Center of Epidemiological and Biological Studies, Damascus University, especially, prof. Chadi Soukkarieh and Dr. Hassan Alkhouri for providing research facilities. References 1. Phaniendra A, Jestadi DB, Periyasamy L. Free radicals: properties, sources, targets, and their implication in various diseases. Indian J Clin Biochem. 2015 Jan;30 (1):11-26. 2. Supasuteekul C, Nonthitipong W, Tadtong S, Likhitwitayawuid K, Tengamnuay P, Sritularak B. Antioxidant, DNA damage protective, neuroprotective, and α-glucosidase inhibitory activities of a flavonoid glycoside from leaves of Garcinia gracilis. Rev. bras. farmacogn. 2016 Jun;26(3):312-320. 3. Shon MY, Kim TH, Sung NJ. Antioxidants and free radical scavenging activity of Phellinus baumii (Phellinus of Hymenochaetaceae) extracts. Food Chem. 2003 Sep;82(4):593-7. 4. Ramos‐Tovar E, Muriel P. Free radicals, antioxidants, nuclear factor‐E2‐related factor‐2 and liver damage. J Appl Toxicol. 2020 Jan;40(1):151-68. 5. Tsao R. Chemistry and biochemistry of dietary polyphenols. Nutrients. 2010 Dec;2(12):1231- 46. 6. Kalinowska M, Gryko K, Wróblewska AM, Jabłońska-Trypuć A, Karpowicz D. Phenolic content, chemical composition and anti-/pro- oxidant activity of Gold Milenium and Papierowka apple peel extracts. Sci Rep. 2020 Sep;10(1):1-5. 7. Vicente O, Boscaiu M. Flavonoids: Antioxidant compounds for plant defence... and for a healthy human diet. Not Bot Horti Agrobo. 2018 Jan;46(1):14-21. 8. Khadim EJ, Abdulrasool AA, Awad ZJ. Phytochemical investigation of alkaloids in the Iraqi Echinops heterophyllus (Compositae). Iraqi J Pharm Sci. 2014;23:26-34. Iraqi J Pharm Sci, Vol.30(2) 2021 Antioxidant activity of Echinops polyceras 268 9. Feinbrun-Dothan N. Flora Palaestina/3. Ericaceae to compositae/by Naomi Feinbrun- Dothan Text Text. Israel Academy of Sciences and Human.; 1978. 10. Mouterde P. Nouvelle flore du Liban et de la Syrie. 11. Sabatier S, Amiot MJ, Tacchini M, Aubert S. Identification of flavonoids in sunflower honey. J. Food Sci. 1992 May;57(3):773-4. 12. Zohra SF, Meriem B, Samira S, Muneer MA. Phytochemical screening and identification of some compounds from mallow. J Nat Prod Plant Resour. 2012;2(4):512-6. 13. De S, Dey YN, Ghosh AK. Phytochemical investigation and chromatographic evaluation of the different extracts of tuber of Amorphaphallus paeoniifolius (Araceae). Int J Pharm Biol Res. 2010;1(5):150-7. 14. Bhatt S, Dhyani S. Preliminary phytochemical screening of Ailanthus excelsa Roxb. Int J Curr Pharm Res. 2012;4(1):87-9. 15. Ainsworth EA, Gillespie KM. Estimation of total phenolic content and other oxidation substrates in plant tissues using Folin–Ciocalteu reagent. Nat Protoc. 2007 Apr;2(4):875-7. 16. Davey MW, Montagu MV, Inze D, Sanmartin M, Kanellis A, Smirnoff N, Benzie IJ, Strain JJ, Favell D, Fletcher J. Plant L‐ascorbic acid: chemistry, function, metabolism, bioavailability and effects of processing. J Sci Food Agric. 2000 May;80(7):825-60. 17. Mammen D, Daniel M. A critical evaluation on the reliability of two aluminum chloride chelation methods for quantification of flavonoids. Food Chem. 2012 Dec;135(3):1365-8. 18. Choi Y, Jeong HS, Lee J. Antioxidant activity of methanolic extracts from some grains consumed in Korea. Food Chem. 2007 Jan;103(1):130-8. 19. Azwanida NN. A Review on the Extraction Methods Use in Medicinal Plants, Principle, Strength and Limitation. Med Aromat Plants. 2015; 4: 196. 20. Sánchez-Rangel JC, Benavides J, Heredia JB, Cisneros-Zevallos L, Jacobo-Velázquez DA. The Folin–Ciocalteu assay revisited: improvement of its specificity for total phenolic content determination. Anal. Methods. 2013;5(21):5990-9. 21. Rammohan A, Bhaskar BV, Camilo Jr A, Gunasekar D, Gu W, Zyryanov GV. In silico, in vitro antioxidant and density functional theory based structure activity relationship studies of plant polyphenolics as prominent natural antioxidants. Arab J Chem. 2020 Feb;13(2):3690-701. 22. Heim KE, Tagliaferro AR, Bobilya DJ. Flavonoid antioxidants: chemistry, metabolism and structure-activity relationships. J Nutr Biochem. 2002 Oct;13(10):572-84. 23. Alachkar A, Jaddouh A, Elsheikh MS, Bilia AR, Vincieri FF. Traditional medicine in Syria: folk medicine in Aleppo governorate. Nat. Prod. Commun. 2011 Jan;6(1). Baghdad Iraqi Journal Pharmaceutical Sciences by bijps is licensed under a Creative Commons Attribution 4.0 International License. Copyrights© 2015 College of Pharmacy - University of Baghdad. http://bijps.uobaghdad.edu.iq/index.php/bijps.com http://creativecommons.org/licenses/by/4.0/ http://creativecommons.org/licenses/by/4.0/ http://creativecommons.org/licenses/by/4.0/