- *Corresponding Author:
- L. Arrar
Laboratory of Applied Biochemistry, Faculty of Nature and Life Sciences, Algeria
E-mail: [email protected]
|Date of Submission||26 June 2017|
|Date of Revision||22 March 2018|
|Date of Acceptance||21 September 2018|
|Indian J Pharm Sci 2018;80(6):1021-1028|
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This study involved investigation of the antioxidant and antibacterial activities of Algerian Fraxinus excelsior extracts. Antioxidant activity was evaluated using spectrophotometric and electrochemical techniques. Phytochemical screening revealed the presence of alkaloids, tannins, polyphenols, flavonoids, sterols/triterpenes, and coumarins. The total polyphenol contents in the extracts were in the order of ethyl acetate>methanol>butanol>chloroform>aqueous>petroleum ether, while flavonoid contents were in the order of, ethyl acetate>chloroform>methanol>butanol>aqueous>petroleum ether. In the 2,2’-diphenyl-1-picrylhydrazyl test, ethyl acetate extract exhibited maximum activity followed by chloroform extract, methanol extract, butanol extract, aqueous extract and petroleum ether extract. β-carotene-linoleate and metal chelation tests showed closely the same order, ethyl acetate, chloroform, methanol, butanol, aqueous and petroleum ether extracts. Antioxidant activity measured using cyclic voltammetry method demonstrated activity in the order of ethyl acetate, chloroform, methanol, butanol and aqueous while petroleum ether extract did not show any activity. Results also demonstrated that some extracts possessed antibacterial activity. In conclusion, Fraxinus excelsior extracts contain active compounds, which have antioxidant and antibacterial effects and could be useful in the treatment of pathologies where these activities are needed.
Phytochemical screening, Fraxinus excelsior L., ß-carotene, antioxidant capacity, cyclic voltammetry, antibacterial effect
The human body produces reactive oxygen species (ROS) such as superoxide anion radical, hydroxyl radical and hydrogen peroxide by many enzymatic systems through oxygen consumption. In small amounts, these ROS can be beneficial as signal transducers and growth regulators. However, during oxidative stress, large amounts of these ROS can be produced and may be dangerous because of their ability to attack numerous biomolecules. In fact, it has been reported that ROS contribute largely to cellular aging, mutagenesis, and coronary heart disease through several ways including membrane destabilization, DNA breakage and generally by oxidizing low-density lipoproteins. The cell can reduce the impact of ROS either by an endogenous system implicating enzymes such as catalase and superoxide dismutase or by an exogenous system using antioxidants, vitamin C and α-tocopherol.
A great number of plants showed antioxidant and scavenger activities against free radicals. This antioxidant capacity can be explored in food industry by using plants as a source of antioxidants to prevent the rancidity and oxidation of lipids. Ash (Fraxinus excelsior L.), belonging to the Oleaceae family, locally known as “l’ssanel’ousfour”. It is known worldwide as an antioxidant, antiinflammatory, antirheumatic, analgesic and antipyretic plant. It has been reported that seed extract of F. excelsior possessed hypoglycaemic activity. In the present study, the antioxidant capacity of many extracts of F. excelsior was investigated using DPPH and β-carotene/linoleic acid tests and compared those with the results obtained using an electrochemical method. Antimicrobial activity was also examined and a relationship was established between these activities and the contents of polyphenols and flavonoids.
Materials and Methods
Fruits of F. excelsior were collected from M’sila region in the middle east of Algeria during 2010. The plants were identified in the Department of Ecology and Vegetal Biology, Faculty of Nature and Life, University Ferhat Abbas Setif1. A voucher specimen was deposited in the department under the No: DBEV/010/25593. Extractions were carried out using various polar and non-polar solvents. The protocol of extraction in presented in the flow chart (Figure 1).
Phytochemical tests to detect the presence of different phytoconstituents were performed according to the method described by Bruneton. The tests were based on visual observation of colour changes or formation of a precipitate after the addition of specific reagents. TLC plates were sprayed with Dragendorrf’s reagent, AlCl3 (10 %) or Stiasny’s reagent for the detection of alkaloids, tannins and flavonoids, respectively. Detection of anthraquinones, sterols/ triterpenes and mucilage was carried out using NH4OH (10 %), acetic anhydride, H2SO4 and ethanol reagents, respectively[9,10].
Determination of total polyphenols and flavonoids
Total phenol content was determined using the Folin- Ciocalteu method as described by Boumerfeg et al.. In brief, 100 μl of extracts were well mixed with 0.5 ml of the Folin-Ciocalteu stock reagent, 0.4 ml of 0.75 % Na2CO3 reagent was added after 4 min and incubated at room temperature for 1.5 h. The absorbance of the mixture was measured at 760 nm. The amount of total polyphenols was expressed as milligram of gallic acid equivalents per gram of extract. Flavonoids were quantified using AlCl3 . One milliliter of the extract or fraction was dissolved in methanol, 1 ml of 2 % AlCl3 in methanol was added. After 10 min of incubation at room temperature the absorbance was measured at 430 nm. The amount of flavonoids was expressed as milligram of quercetin and rutin equivalents per gram of extract.
2,2’-diphenyl-1- picrylhydrazyl (DPPH) radical scavenging activity
The free radical scavenging activities of extracts were measured using DPPH test. An equal volume of each extracts with different concentrations were added to methanol solution of DPPH and shaken vigorously at room temperature. After 30 min, the absorbance was recorded at 517 nm. Radical scavenging activity was expressed as the inhibition percentage and was calculated using the following Eqn., I % = (Ablank– Asample/Ablank)×100, where Asample: absorbance of the sample, Ablank: absorbance of the blank.
Antioxidant capacity was determined by measuring the inhibition of the volatile organic compounds and conjugated diene hydroperoxides arising from linoleic acid oxidation. Emulsion (2.5 ml) containing ß-carotene, linoleic acid and Tween-40, was added to 0.35 ml of the sample then incubated for a total period of 48 h at room temperature. The absorbance of the mixture was measured at 490 nm after 0, 1, 2, 4, 6, 24 and 48 h within the incubation period. The same procedure was repeated with a butyl hydroxytoluene (BHT), a synthetic antioxidant as positive control, and MeOH or H2O as negative blanks. The antioxidant activity (AA) of the extracts was evaluated as a percent of bleaching of ß-carotene: AA % = (Asample/ABHT)×100, where Asample is the compound absorbance and ABHT the absorbance of a sample with BHT.
Chelating activity on ferrous ions
Chelating activities of the extracts were assayed following the method reported by Dinis et al., with some modifications. Briefly, the solutions of samples (250 μl) were initially mixed with 50 μl FeCl2 (11.9 mg in 100 ml of distilled water) and 450 μl of methanol. After 5 min, 100 μl of ferrozine (12.3 mg in 5 ml of methanol) were added, the mixture was agitated then left to react during 5 min at room temperature thus allowing the formation of complex with a purple colour (Fe2+- ferrozine) having a maximum absorption at 562 nm. EDTA was used as a positive control. The chelating activity of the test compound was calculated as follows, chelating activity (%) = [1–(Asimple– Acontrol)]×100, where Asample: absorbance of the sample, Acontrol: absorbance of the control.
Evaluation of antioxidant capacity by electrochemical techniques
The antioxidant capacity of samples was determined using an electrochemical method based on cyclic voltammetry techniques (Potentionstat Galvanostat Autolab, AUT7219). Cyclic voltammetry measurements were in an electrochemical cell with a volumetric capacity of 50 ml containing a glassy carbon electrode as the working electrode, a platinum wire counter electrode and an Hg/Hg2Cl2 reference electrode (saturated with KCl). The potential was swept in inverse scanning mode starting from (–200 to + 800 mV) with a scanning rate of 25 mV/s. The samples in the electrochemical cell were deaerated by purging with high purity nitrogen during the electrochemical measurements. The antioxidant capacity of the studied samples was determined. Ascorbic and gallic acids were used as standards in the calculation of antioxidant capacity. The antioxidant capacity was calculated as follows: AC (g/mg) = Ceq/C, where, AC was the antioxidant capacity, Ceq was the equivalence concentration and C was the initial concentration.
The antibacterial activity of the extracts was tested against 9 bacterial species, Escherichia coli ATCC 25922, Pseudomonas aeruginosa ATCC 27853, Klebsiella pneumonia ATCC 700603, Salmonella typhimurium ATCC 13311, Acinetobacter baumanii ATCC 19606, Staphylococcus aureus ATCC 25923, Bacillus cereus ATCC 10876, Listeria monocytogenes ATCC 15313, Enterobacter faecalis ATCC 49452. Disc difusion technique was used to evaluate the antibacterial activity. Ten microlitres of each extract (dissolved at different concentrations in DMSO) on a disc of Whatman paper No. 1 was applied into Muller- Hinten medium inoculated with bacterial suspension at a concentration equivalent to 0.5 McFarland. The plates were incubated at 37° for 48 h then the inhibition diameters were measured.
Results and Discussion
As an initial step of the phytochemical screening, the main groups of chemical constituents were qualitatively determined (Table 1). The results of F. excelsior extracts showed the presence of polyphenols, tannins, flavonoids, sterols/triterpenes, alkaloids and coumarins. The phytochemical analysis results of ethyl acetate, methanol, butanol, chloroform and aqueous extracts showed the presence of tannins (gallic and catechol tannins) and flavonoids, and the absence of coumarin. The presence of alkaloids was detected only in the methanol extract. The AA of phenolic compounds is mainly due to their redox properties, which can play an important role in absorbing and neutralizing free radicals. Flavonoids, tannins, phenolic acids, phenolic diterpenes, lignans and coumarins are the examples of phenolic components with antioxidant properties[15,16]. The result showed that the chloroform extract contained the highest amount of polyphenols (0.109 ± 0.001 g gallic acid equivalent, GAE/g) and the ethyl acetate extracts contained the highest amount of flavonoids (0.010 ± 0.0006 g quercetin equivalent QE/g; Table 2).
|Alkaloids||Gallic Tannins||Catechol Tannins||Flavonoids||Coumarins|
Table 1: Phytochemical Screening of the Fruit Extracts of Fraxinus excelsior.
|µg QE/mg||µg RE/mg|
|ME||109.19 ± 1.67||04.9 ± 0.26||08.06 ± 0.45|
|PEE||029.77 ± 5.27||01.12 ± 0.03||01.37 ± 0.45|
|CE||157.41 ± 1.35||05.1 ± 0.05||29.67 ± 0.41|
|EAE||047.75 ± 1.54||10.58 ± 0.06||16.44 ± 0.60|
|BE||065.30 ± 1.06||04.54 ± 0.05||06.84 ± 0.40|
|AE||039.51 ± 0.53||01.98 ± 0.00||02.83 ± 0.00|
Table 2: Total Polyphenol and Flavonoids Contents of Fraxinus excelsior Extracts
Free radical scavenging activity of the extracts was tested using the DPPH method. The role of antioxidants is their interaction with oxidative free radicals. The essence of DPPH method is that the antioxidants react with the stable free radical, DPPH• which has deep violet colour and convert it to DPPH-H, which has deep yellow colour. The degree of discoloration indicated the scavenging potential of the antioxidant sample. The DPPH activity of the extracts was increased in a dosedependent manner. The results presented in the Figure 2 showed that extract activity expressed as IC50 values were in the order ethyl acetate>chloroform>butanol> methanol>aqueous>petroleum ether extract (3722.5 μg/mg). In this study, the extracts and standard drugs reduced significantly the DPPH radical. AA might be related to the contents of phenolics and flavonoids compounds and confirmed the data of Ovedemi et al.. The scavenger effect on the free radicals depends on the presence of free OH groups in particular 3-OH on ring C, with a configuration 3’,4’-dihydroxyl on ring B in the polyphenols.
The results of β-carotene bleaching method showed the same trend that of DPPH assay. In fact, the ethyl acetate extract of F. excelsior showed the highest AA with AA % = 91.19 ± 1.08 (Figure 3). The difference in antioxidant activities of extracts of F. excelsior might be attributed to a difference in total polyphenols and/ or flavonoids contents. Several studies showed a correlation between AA and phenolics and flavonoids content. Generally in the β-carotene bleaching method, linoleic acid produces hydroperoxides as free radicals during incubation. The presence of antioxidants in the extracts would minimize the oxidation of β-carotene by hydroperoxides. This effect is due to inhibition of the peroxidation of the linoleic acid or to trapping of the radicals hydroperoxides formed during the linoleic acid oxidation.
Ferrous ion chelating activities of samples are shown in Figure 4. Ferrozine can quantitatively form complexes with Fe2+. In the presence of chelating agents, complex formation is disrupted, resulting in a decrease in the colour of the complex. Measurement of colour reduction therefore allows an estimation of the metal chelating activity. In this assay, the samples interfered with the formation of ferrous and ferrozine complexes, suggest that they have chelating activity and are able to capture ferrous ion before ferrozine. Because EDTA is a strong metal chelator, it was used as a standard in this study. Extracts or compounds with chelating activity are believed to inhibit lipid peroxidation by stabilizing transition metals, and form σ-bonds with metals.
Excess of metal ions can lead to various anomalies in the body. The iron (II) chelating activity of plant extracts is of great significance, because it has been proposed that the transition metal ions contribute to the oxidative damage in neurodegenerative disorders like Alzheimer’s and Parkinson’s diseases. The absorbance of Fe2+-ferrozine complex decreased by extracts in a dose-dependent manner. The capacity of the metal chelating of EDTA and extracts is presented in Figure 4. The petroleum ether extracts showed the lowest potential (24.54 ± 0.2 mg/ml).
Many different spectroscopic methods can be used to measure the AA, with the DPPH approach as one of the most popular. Therefore, complementary methods that specifically present a different analytical principle for the same type of analysis are often recommended. In this context, the development of novel techniques to evaluate the AA is an area of interest of many research groups. Electroanalytical methods, mostly voltammetric techniques, represent one of these novel tools, presenting many advantages such as speed, low cost, simplicity and low consumption of reagents when compared to other methods. Another great advantage is the fact that they do not rely on the use of oxidizable compounds to measure the antioxidant capacity of the sample, but instead depend only on the inherent electrochemical properties of antioxidants in the sample.
The cyclic voltammetry voltammograms obtained at different concentrations of ascorbic and gallic acids used as standards are shown in Figure 5. The voltammograms present typical irreversible oxidation processes. There is an increase in peak current with the increase in ascorbic and gallic acids concentrations, which leads to a linear relationship between these two parameters. The same irreversible electrochemical (no cathodic peak) was observed on inverting the scan direction, indicating the irreversibility of oxidation behaviour for F. excelsior extracts (Figure 6). The ethyl acetate fraction has the highest antioxidant capacity (44.87 ± 0.38 mg/g GAE and 80.49 ± 7.32 mg/g AAE). This capacity may be dependent mainly on the phenolic and flavonoid content. The Table 3 gathers the antioxidant capacity by electrochemical way of extracts.
Figure 5: Cyclic voltammograms of different concentrations of gallic and ascorbic acids
Cyclic voltammograms of different concentrations of (A) gallic and (B) ascorbic acid solutions in 0.1 mol/l phosphate buffer, pH-7 containing 0.1 mol/l NaCl at a scan rate 25 mV/s A: 10 mmol/l; 8 mmol/l; 6 mmol/l; 4 mmol/l; 2 mmol/l; 1 mmol/l; 0.8 mmol/l; 0.6 mmol/l; 0.4 mmol/l; 0.2 mmol/l; 0.1 mmol/l; B: 10 mmol/l; 8 mmol/l; 6 mmol/l; 4 mmol/l; 2 mmol/l; 1 mmol/l; 0.4 mmol/l; 0.6 mmol/l; 0.4 mmol/l; 0.2 mmol/l; 0.1 mmol/l
Figure 6: Cyclic voltammograms
A: ME 10 mg/ml; 20 mg/ml; 30 mg/ml; B: PEE 200 mg/ml; C: CE 10 mg/ml; 20 mg/ml; 30 mg/ml; D: EAE 10 mg/ml; 20 mg/ml; 30 mg/ml; E: BE 10 mg/ml; 20 mg/ml; 30 mg/ml and F: AE 10 mg/ml; 30 mg/ml; 100 mg/ml, in pH=7, 0.1 M phosphate buffer solution containing 0.1 M NaCl at scan rate 25 mV/s
|Eq. gallic acid||06.83 ± 0.16||--||07.30 ± 0.00||44.87 ± 0.38||05.22 ± 0.00||--|
|Eq. ascorbic acid||16.16 ± 2.28||--||21.50 ± 2.49||80.49 ± 7.32||16.67 ± 0.61||--|
Table 3: Electrochemical Analysis of Antioxidant Capacity of Extracts of Fraxinus excelsior
The results obtained showed that the F. excelsior extracts (Figure 7, Table 4) possessed antibacterial activity, which varied with the type of the extract and also the type of the bacteria, Gram-positive or Gram-negative.
Figure 7: Inhibition of the bacterial growth by F. excelsior extracts in the disc diffusion method
AE: aqueous extract, BE: butanol extract, EAE: ethyl acetate extract, ME: methanol extract, PEE: petroleum ether extract, DMSO: dimethyl sulfoxide. A: Escherichia coli; B: Bacillus cereus; C: Enterobacter faecalis; C: Salmonella typhimurium
|Extracts||Gram-negative bacteria||Gram-positive bacteria|
|E. coli||P. aeruginosa||K. pneumonia||S. typhimurium||A. baumanii||S. aureus||B. cereus||E. faecalis||L. monocytogenes|
Table 4: Antibacterial Activity Indices of Extracts Against Bacteria
In conclusion, the AA of F. excelsior extracts collected from M’Sila was investigated. Different assays employed DPPH, ß-carotene-linoleate system, chelating activity on ferrous ions and cyclic voltammetry, the application of electrochemistry an important means of characterizing many antioxidants.
All these methods showed that the AA depended mainly on the phenolic composition. These results also suggested that F. excelsior can serve as a potential source of bioactive compounds, which could be useful in the prevention/treatment of diseases where AA is needed. Bioautography would be used to determine the number of bioactive compounds in each extract.
This work was supported by the Algerian Ministry of Higher Education and Scientific Research (MESRS, DGRSDT) and by the Algerian Thematic Agency for Scientific Research in Health (ATRSS). We express our gratitude to these organizations. Authors thank Prof. H. Laouer, Department of Ecology and Vegetal Biology, Faculty of Nature and Life, University Ferhat Abbas Setif 1 for identifying and authentication of the collected plant material.
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