Comparative study of the chemical properties and composition of the Mentha pulegium L. of Algerian origin and that of Tunisian origin

The aim of this study was to compare the chemical composition, antioxidant, antifungal and antileishmanial activities of the essential oils that were obtained from Mentha pulegium L. cultivated both in Algeria and in Tunisia. The kinetics of antioxidant activity was also studied.

The essential oils are obtained by steam distillation with a yield of 1.30 and analyzed by gas chromatography coupled to mass spectrometry (GC/MS) where 30 compounds were identified.

The Antioxidant activity was defined using the scavenging test of free radicals (DPPH), while ascorbic acid is used as positive control. The values of IC50 are between 95-107 µg.mL-1.

The results obtained by the study of the antifungal activity, show that the essential oils of the Algerian and Tunisian Mentha pulegium have significant antifungal activity.

The antileishmanial activity was tested against Leishmania Major and Donovani (LV9) axenic amastigotes. The IC50 values evaluated in L. Major promastigote and axenic amastigote forms were in the range of 100 µg.mL-1.

Introduction

Since antiquity, men have used essential oils for their cosmetic, nutritional and therapeutic needs [1-3].

Studies have also shown that vegetable extracts rich in phenolic compounds and with a marked antioxidant power could play an interesting role in the prevention of cancer because they are stabilizers of free radicals [4].

Several works have highlighted the different biological activities of aromatic and medicinal plants, especially their antifungal [5-7], antibacterial [8], antioxidant [9]. By these properties, the essential oils could therefore serve as a preservative of food. In this context, many studies have shown that extracts of certain aromatic plants have an inhibitory action on the growth and toxinogenesis of several bacteria and fungi responsible for food infections [10-14].

Mentha pulegium L. is one of the aromatic and medicinal plants widely used in traditional medicine, its antimicrobial potency has been demonstrated according to several studies [15].

Therefore, biological control through the use of natural antioxidant and antifungal substances, can be an alternative to chemicals. Among these natural substances are the essential oils extracted from aromatic plants [16].

The use of natural products to fight against microbial pathogenesis and stress-related diseases is a very promising strategy to compact theses diseases. Indeed, medicinal plant secondary metabolites and their derivatives have shown antibacterial antileishmanial, antioxidant, and cytotoxic activities [17-18].

Fresh flower fumigations by Mentha pulegium were an efficient remedy to rid animals of chips. It is mostly grown as a condiment plant and its leaves are rich in aromatic menthol. In cosmetology, it is considered to be labeled herbaceous plant used especially in men’s fragrance for its fresh and tonic character. Currently, in medicine, it is still used as an antiseptic and also as a stomachic and an analgesic [19].

Material and methods

Plant material

The plants of Mentha pulegium L were collected in March 2018 from Bouira (Algeria) and Bizerte (Tunisia). The recovery of essential oils was achieved by using steam distillation and there covery time was optimized to two hours. The obtained EO was dried over anhydrous sodium sulphate and, after filtration, stored at 4°C until tested.

Methods

Gas chromatography coupled to mass spectrometry (GC-MS): Gas Chromatography-Mass Spectrometry (GC-MS) is the most popular and strongest method for the determination of essential oil composition. Components existing in the essential oil can be identified by comparison of their relative retention indices and their Mass Spectra (MS). Identification of individual components of essential oils, however, is not always possible using MS data alone. Often different spectra are reported in a library for a single compound, with different common names, or systematic name, corresponding to an individual component sometimes apparent [20].

The composition of essential oils was investigated by GC and GC-MS. GC analysis was performed in a gas chromatograph (HP 5890) using two fused silica capillary columns, HP5 (non-polar) and Innovax (polar) (30 m×0.25 mm, film thickness 0.25 µm) and a Flame Ionization Detector (FID). Injector and detector temperatures were set at 240°C and 280°C, respectively. The oven temperature programmed as 50°C for 3 min, then 50-280°C at 9°C. min-1 and finally 280°C for 3 min. Nitrogen was the carrier gas at a flow rate of 1 mL. min-1. The samples were injected as 0.1 µL of 1% solution diluted in hexane in the split mode. The percentage of the constituents was calculated by electronic integration of FID peak areas and normalized without the use of response factor correction.

The Components identification was carried out by comparison of their MS spectra with the relative retention indices with those of standard compounds reported in the literature (Adams, 2007) [21].

IR measurements: A qualitative analysis with IR was made in order to characterize the different components of essential oils. The infrared spectrum was recorded using a ‘‘Perkin-Elmer Spectrum 1000’’ spectrophotometer. The scanning is performed in the 4000-400 cm-1 spectral domain.

The identification of functional groups was carried out by using the usual infrared tables and by comparing the frequencies of the peaks with those reported in literature [22].

Radical scavenging activity test: Scavenging test of free radical DPPH (2,2-diphenyl-1-picrylhydrazyl) was carried out by using the method described by Braca and et al. [23]. A sample of 500 µL is placed in the presence of 500 µL of a solution of DPPH 0.4% in methanol. After stirring, the mixture is placed at 37°C for 15 minutes in the dark. For each concentration, the test is repeated three times and the absorbance measurement is made at 517 nm by a UV-visible spectrophotometer.

The control solution is composed of 500 μl of the DPPH methanol solution and 500 μl of methanol. Ascorbic acid was used as a positive control. The results are expressed as Percentage Inhibition (PI) according to the following formula:

$PI=\frac{[AbsBlank-AbsSample]}{AbsBlank}\times 100$

Where Abs_Blank is the absorbance of the control solution and Abs_Sample is the absorbance in the presence of the essential oil.

Sample concentration capable of scavenging 50% of the DPPH radicals (IC50) can be graphically determined by plotting the absorbance (the percentage of inhibition of DPPH radicals) against the log concentration of DPPH and determining the slope of the nonlinear regression.

The kinetic of the antioxidant activity was also studied. 50 μL of essential oil are added to 1.5 mL of a DPPH solution at 0.4% in methanol. The UV absorbance is read at a wavelength of 517 nm.

Antifungal activity: The study of antifungal activities was carried out at Dr. Robert McFeeters’ Laboratory (University of Alabama in Huntsville USA). The Minimum Inhibitory Concentrations (MIC) are determined according to the following protocol:

Microdilution assays were performed with Aspergillus niger and Candida albicans to evaluate the antifungal potential of Mentha pulegium essential oils. 100 µL of RPMI media buffered with MOPS was added to every well microdilution plate. 100 µL of a 1% solution of the essential oils in DMSO, along with 100 µL of media (RPMI) and solvent (DMSO) controls, were added to the first well of each row and serial diluted down each respective column by 100 µL. 100 µL of C. albicans cells or C. neoformans at a concentration of 4.000 cells/mL or A. niger conidia at a concentration of 4.000 conidia/mL in PDB was added to all wells in the plate. C. albicans and C. neoformans plates were incubated at 37°C for 2 days and A. niger plates at room temperature for 7 days [24-26]. All results were interpreted visually.

Antileishmanial activity: Leishmaniasis is a family of parasitic diseases that affect about 12 million people in tropical and subtropical areas in the form of three clinical expressions: visceral leishmaniasis, which is fatal in the absence of treatment, muco-cutaneous leishmaniasis, and cutaneous leishmaniasis, which is often self-curing. Classical drugs such as antimonials (Pentostam and Glucantime) are toxic, and drug resistance is increasing dangerously in the field. Toxicity and the appearance of drug resistance justify the search for new chemical series in order to find an orally safe and active drug [27,28].

The study of antileishmanial activities was carried out at Pr. Philippe M Loiseau Laboratory (Faculty of Pharmaceutical Sciences. Chatenay-Malabry, France).

The IC50 values are determined according to the following protocols.

Protocol in vitro

Cell lines and cultures: The mouse monocyte/macrophage cell line RAW264.7 was maintained in culture in DMEM supplemented with 10% heat-inactivated fetal bovine serum.

L. Major and L. Donovani (LV9) were used for in vitro experiments. Promastigotes forms were grown in M-199 medium supplemented with 40 mM HEPES, 100 µM adenosine, 0.5 mg/mL haemin, 10% heat-inactivated Fœtal Bovine Serum (FBS) and 50 µg/ml gentamycine at 26°C in a dark environment under an atmosphere of 5% CO2. Differentiation of promastigotes into axenic amastigotes was achieved by dilution of 106 promastigotes in 5 mL of axenic amastigote medium (1×M-199, supplemented with 40 mM HEPES, 100 µM adenosine, 0.5 mg/mL haemin, 10% FBS; 2 mM MgCl2, 2 mM CalCl2). The pH was adjusted to pH5.5. Axenic amastigotes were grown at 37°C in 5% CO2. All the experiments were performed with parasites in their logarithmic phase of growth.

in vitro antileishmanial evaluation of the compounds on Leishmania Major and Donovani (LV9) axenic amastigotes. Two fold serial dilutions of the compounds from a maximal concentration of 100 μM were performed in 100 μl of complete medium in 96-well microplates.Triplicates were used for each concentration. A suspension of axenic amastigote forms was prepared to yield 107 cells/mL and amastigotes were then added to each well at a density of 106/mL in a 200 μL final volume. Cultures wereincubated at 37°C for 72 h in the dark and under a 5% CO2atmosphere, then the viability of the amastigotes was assessed using the SYBR1 Green I (Invitrogen, France) incorporation method. Parasite growth was determined by using SYBR1 Green I, a dye with marked fluorescence enhancement upon contact with parasite DNA. After incubation, the plates were subjected to 3 freeze/thaw cycles to achieve complete hemolysis. The parasite lysis suspension was diluted 1:2 in lysis buffer (10 mM NaCl, 1 mM Tris HCl pH8, 2.5 mM EDTA pH 8, 0.05% SDS, 0,01 mg/mL proteinase K and 1X SYBR Green I). Incorporation of SYBR Green I in parasite was measured using the Master epRealplex cycler® (Eppendorf, France) according the following program to increase the SYBR green incorporation: 90°C for 1 min, decrease in temperature from 90°C to 10°C for 5 min with reading the fluorescence 10°C for 1 min and a new reading at 10°C for 2 min.

Axenic amastigotes viability could also be measured using a resazurin assay. After 72 h incubation time at 37°C with 5% CO2,10 μl of a resazurin solution at 450 μM was added to each well, and the plates were further incubated in the dark for 24 h at 37°C with 5% CO2.Cell viability was then monitored by using the resazurin test. In living cells, resazurin is reduced in resorufin and this conversion is monitored by measuring OD570nm (resorufin) and OD600nm (resazurin; Lab systems Multiskan MS).

The IC50 was calculated by nonlinear regression. Fluorescence obtained was compared to those from the range obtained with different parasite densities. Miltefosine wasused as reference compound. The antileishmanial activity was expressed as IC50 in µM (concentration of drug inhibiting the parasite growth by 50%, comparatively to the controls treated with the excipient only).

Evaluation of compounds cytotoxicity using the rezasurin method

Cytotoxicity was evaluated on RAW 264.7 macrophages. RAW 264.7 cells were seeded into a 96-well microtiter plate at a density of 2×104 cells/well in 100 µl of DMEM. After incubation in a 5% CO2 incubator at 37°C for 24 h, the culture medium was replaced with 100 µl of fresh DMEM containing two-fold serial dilutions of the test compounds. The starting final concentration was 100 µM. After 48 h incubation time at 37°C with 5% CO2,10 μl of a resazurin solution at 450 μM was added to each well, and the plates were further incubated in the dark for 4 h at 37°C with 5% CO2.Cell viability was then monitored by using the resazurin test. In living cells, resazurin is reduced in resorufin and this conversion is monitored by measuring OD570nm (resorufin) and OD600nm (resazurin; Lab systems Multiskan MS). The cytotoxicity of the compounds was expressed as CC50 (Cytotoxic Concentration 50%: concentration inhibiting the macrophages growth by 50%). Miltefosine was used as the reference drug.

in vitro antileishmanial evaluation on intramacrophage amastigotes. The mouse monocyte/macrophage cell line RAW 264.7 was maintained in DMEM supplemented with 10% heat-inactivatedfetal bovine serum. RAW 264.7 cells were seeded into a 96-wellmicrotiter plate at a density of 2×104 cells/well in 100 µL ofDMEM. After incubation in a 5% CO2 incubator at 37 °C for 24 h, theculture medium was replaced with 100 µl of fresh DMEM containing a suspension of axenic amastigote forms to reach a ratio amastigotes/macrophage of 16:1. Each plate has 8 wells with axenic amastigotes (control of the parasite growth), 8 wells with only macrophages (control of the macrophage growth) and finally 8 wells with infected macrophages (control of the growth of intramacrophage parasites). After incubation in a 5% CO2 incubator at 37 °C for 24 h, the culture medium was replaced with 100 µL of fresh DMEM containing the test compounds for a new incubation of 48 h. The viability of the amastigotes into macrophages was then assessed using the SYBR1Green I (Invitrogen, France) incorporation method. Thus, the medium was removed and the cells were lysed in 100 µL lysis buffer.After the plates were subjected to 3 freeze thaw cycles to achieve complete lysis. The parasite lysis suspension was diluted 1:2 in lysis buffer with SYBR Green I like previously. Incorporation of SYBR Green I in parasite DNA amplification was measured using the Master epRealplex cycler® (Eppendorf, France) according the following program to increase the SYBR green incorporation: 90°C for 1 min, decrease in temperature from 90°C to 10°C for 5 min with reading the fluorescence 10°C for 1 min and a new reading at 10°C for 2 min. Fluorescence obtained was compared to those from the range obtained with parasite, infected cell and non-infected cell densities. The activity of the compounds was expressed as IC50 (concentration of drug inhibiting the parasite growth by 50%, comparatively to the controls treated with the excipient only). Miltefosine was used as the reference drug.

Results and Discussion

Gas chromatography coupled to mass spectrometry (GC-MS)

The identification of the constituents of Mentha pulegium Leaves essential oils using GC-MS has enabled us to identify 31 compounds, with a contribution of 94.22% for Algerian sample and 30 compounds, with a contribution of 92.91% for the Tunisian. It was noted that pulegone is the major compound with 67.95% for Algerian Menthe Pulegium and 48.78% for the Tunisian.

The percentage content of the individual components, the retention indices and the chemical of the oil compounds are summarized in Table 1.

The chemical composition of Mentha pulegium essential oil has been determined by previously studies in other counties [18, 29-35]. A comparison between these studies showed the variability of volatile compounds.

Table 2 shows the percentages of the pulegone identified in some essential oils from Mentha pulegium in some different countries.

The large variability in this species and the chemical differences can be most probably explained by the existence of different chemotypes. So the geographical distribution of this plant influenced significantly the chemical composition of its essential oils.

Infrared spectroscopy

The results of IR spectroscopic analysis are shown in Table 3. We notice the presence of broad and intense bands located at 3332-3516 cm-1 corresponding to the alcohol functions (OH), confirmed by the presence of a characteristic band of the CO bond aliphatic around 1060-1140 cm-1 and aromatic or α, β unsaturated around 1200 cm-1.

The unsaturation and aromaticity is confirmed by the presence of vibration bands of deformation outside the plane around 700 cm-1.

Radical scavenging activity test

Antioxidants can scavenge the radical by hydrogen donation, which causes a decrease of DPPH (2.2-diphenyl-1-picrylhydrazyl) absorbance at 517 nm [36].

In the current study, the assessment of the antioxidant activity using the DPPH free radical method was evaluated. The DPPH scavenging index and the half maximal inhibitory concentration (IC50) value were determined to assess the antioxidant activity of essential oils.

IC50 value is negatively related to the antioxidant activity, the lower the IC50 value, higher is the antioxidant activity of tested sample.

The results obtained show that the essential oil of Algerian Mentha pulegium has antioxidant ability, with (IC50= 95 µg.mL-1) stronger than that of Tunisian Mentha pulegium (IC50= 107 µg.mL-1).

The antioxidant activities of essential oils from aromatic plants are mainly attributed to the active compounds present in them. The most powerful scavenging compounds were reported to be the monoterpene, ketones, menthone and isomenthone [37].

The kinetic of the antioxidant activity of essential oils is presented by the curves of Figure 1.

Figure 1: DPPH reduction kinetics obtained with the essential oils of Mentha pulegium L. C1 corresponds to Tunisian M.P. Tunisian while C2 is that of Algerian M.P.

For the essential oils examined, the reaction is biphasic, with a rapid decline in absorbance in the first minutes, followed by a slower step, until equilibrium is reached, then there are two areas:

• Zone with strong kinetics of trapping of the radical observed after the first fifteen minutes for the Algerian essential oil and less fast of the order of 50 minutes for the Tunisian essential oil.

• Zone with low kinetics of trapping of the DPPH radical or zone of trend towards equilibrium for the two oils.

The results show that the reaction between DPPH and essential oils reaches equilibrium after a short time for the Algerian essential oil.

Antifungal activity

For antifungal activity, we are interested in the three pathogens that are responsible for a majority of human fungal infections which are Aspergillus niger, Candida albicans, and Cryptococcus neoformans. For each of the three pathogenic fungal species studied, MIC values essential oils have been determined.

The essential oils activity against C. neoformans is more interesting than A. niger and C. albicans. However the results obtained show that the essential oils of the Algerian and Tunisian Mentha pulegium have moderate antifungal activity.

Results of the Minimum Inhibitory Concentrations (MIC) are summarized in Table 4.

To get an idea for the values of the minimum concentration of inhibition for the 3 pathogens studied, we present in table 5 the minimum and maximum (MIC) values for certain essential oils according to (Robert L. McFeeters) [25].

The essential oils of both species have shown significant antifungal activity against the tested fungi. This bioactive power observed in the two oils is mainly attributed to their high contents in terpene phenols [38].

Antileishmanial activity

Antileishmanial properties of essential oils are described in Table 6.

The IC50 values evaluated in L. Major promastigote and axenic amastigote forms were around 80-100 μg.mL-1.

In the present study, the extracts of Mentha pulegium had in vitro effects on Leishmania Major and Donovani (LV9) axenic amastigotes.

Secondary metabolites such as alkaloids, flavonoids, saponins and terpenoids were known to possess antileishmanial activities. Thus the inhibitory effect of the extracts could be due to presence of wide range of secondary metabolites with different polarities [39-41].

This activity was explained by the mechanism of extract either by killing parasites or causing metabolic disorders to inhibit the reproduction of parasites [42].

Conclusion

The present study has allowed us to describe and to compare chemical composition of Algerian and Tunisian Mentha pulegium essential oils. We have also studied antioxidant, antifungal and antileishmanial activities.

It can be concluded that essential oils of Algerian and Tunisian Mentha pulegium appears to be a natural way to help in antifungal and antileishmanial treatment and a good enough antioxidant They can be used as an antibiotic or organic food preservative, therefore a natural replacement for harmful synthesized chemicals. However, the toxicological effects of these oils have to be investigated before human consumption before considering their use for food preservation or medicinal purposes.

1. Kouassi EK, Ouattara S, Seguin C, Fournel S, Frisch B (2018) Etudes de quelques propriétés biolgiques de Ocimum Gratissimum L., laminaceae récoltée à Daloa (Côte d'Ivoire). Eur Sci J 14: 1857- 7881. Link: https://bit.ly/3charJ7
2. Heath HB (1981) Source Book of Flavours. Westport: Avi 890. Link: https://bit.ly/3b2k1iN
3. Robert G (2000) Les Sens du Parfum. Osman Eroylles Multimedia. Paris 224.
4. Owen RW, Giacosa A, Hull WE, Haubner R, Spiegelhalder B, et al. (2000) The antioxidant/anticancer potential of phenolic compounds isolated from olive oil. Eur J Cancer 36: 1235-1247.Link: https://bit.ly/2xgtrIZ
5. Hmiri S, Rahouti M, Habibi Z, Satrani B, Ghanmi M, et al. (2011) Evaluation du potential antifongique de Mentha pulegium et d'eucalyptus camaldulensis dans la lute biologique contre les champignons responsables de la deterioration des pommes en conservation. Bulletin de la Société Royale des Sciences de Liège 80: 824-836. Link: https://bit.ly/3a2UNQ9
6. Moleyar V, Narasimham P (1986) Antifungal activity of some essential oil components. Food Microbiology 3: 331-336. Link: https://bit.ly/2VofuAA
7. Soliman KM, Badeaa RI (2002) Effect of oil extracted from some medicinal plants on different mycotoxigenic fungi. Food Chem Toxicol 40: 1669-1675. Link: https://bit.ly/3ehWlsI
8. Magina MDA, Dalmarco EM, Wisniewski A, Simionatto EL, Dalmarco JB, et al. (2009) Chemical composition and antibacterial activity of essential oils of Eugenia species. J Nat Med 63: 345-350. Link: https://bit.ly/2K1k3vp
9. Bouzouita N, Kachouri F, Ben Halima M, Chaabouni MM (2008) Composition chimique et activités antioxydante, antimicrobienne et insecticide de l’huile essentielle de Juniperus phoenicea. J Soc Chim Tunis 10: 119-125. Link: https://bit.ly/3b2kAsV
10.  Bruneton J (1993) Pharmacognosie Phytochimie Plantes médicinales. 2ème edition. Lavoisier, Paris 915. Link: https://bit.ly/3b7M3t9
11. Cremieux A (1990) Etude de six huiles essentielles: composition chimique et activité antibactérienne. Study of six essential oils: chemical composition and antibacterial activity. J food Science 85: 2437-2444.
12. Bhaskara Reddy MV, Angers P, Gosselin A, Arul J (1997) Characterization and use of essential oil from Thymus vulgaris against Botrytis cinerea and Rhizopus stolonifer in strawberry fruits. Phytochemistry 47: 1515-1520. Link: https://bit.ly/34AmGhp
13. Tzortzakis NG (2007) Maintaining postharvest quality of fresh produce with volatile compounds. Innovative Food Sci Emerg Technol 8: 111-116. Link: https://bit.ly/2VqFLyf
14.  Amarti F, Satrani B, Ghanmi M, Farah A, Aafi A, et al. (2010) Composition chimique et activité antimicrobienne des huiles essentielles de Thymus algeriensis Boiss. and Reut et Thymus ciliatus (Desf) Benth. du Maroc, Biotechnol. Agron Soc Environ 14: 141-148. Link: https://bit.ly/2K2w2sH
15.  Mahboubi M, Haghi G (2008) Antimicrobial activity and chemical composition of Mentha pulegium L. essential oil. J Ethnopharmacol 119: 325-327. Link: https://bit.ly/2wGvwO2
16.  Maihebiau P (1994) La nouvelle aromathérapie: biochimie aromatique et influence psychosensorielle des odeurs. Lausanne 635. Link: https://bit.ly/3a5ZMQ1
17.  Bouyahya A, Et-Touys A, Bakri Y, Fellah H, Abrini J, et al. (2017) Chemical composition of Mentha pulegium and Rosmarinus officinalis essential oils and their antileishmanial, antibacterial and antioxidant activities. Microb Pathog 111: 41-49. Link: https://bit.ly/2V47hmi
18.  El-Ghorab AH (2006) The Chemical Composition of the Mentha pulegium L. Essential Oil from Egypt and its Antioxidant Activity. Journal of Essential Oil-Bearing Plants 9: 183-195. Link: https://bit.ly/2XxxY4r
19.  Abdellia M, Moghrani H, Aboun A, Maachi R (2016) Algerian Mentha pulegium L. leaves essential oil: Chemical composition, antimicrobial, insecticidal and antioxidant activities. Industrial Crops and Products 94: 197-205. Link: https://bit.ly/3elq2t2
20.  Sheille R, Mondello L, Marriott P, Dugo G (2002) Characterisation of lavender essential oils by using gas chromatography–mass spectrometry with correlation of linear retention indices and comparison with comprehensive two-dimensional gas chromatography. Journal of Chromatography A 970: 225-234. Link: https://bit.ly/2xiWb3T
21.  Adams RP (2007) Identification of Essential Oil Components by Gas Chromatography/Mass Spectrometry, 4th edn 804. Link: https://bit.ly/3ejSOKr
22. Belboukhari N, Merzoug Z, Cheriti A, Sekkoum K, Yakoubi M (2013) Etude de la caractérisation et la composition qualitative des huiles essentielles de six plantes médicinales par spectroscopie IR. PhytoChem BioSub J 7. Link: https://bit.ly/2VqmBIH
23. Braca A, Sortino C, Politi M, Morelli I, Mendez J (2002) Antioxidant activity of flavonoids from Licania licaniaeflora. J Ethnopharmacol 79: 379-381. Link: https://bit.ly/34xTGGZ
24. Jones TH, McClelland EE, McFeeters H, McFeeters RL (2017) Novel Antifungal Activity for the Lectin Scytovirin: Inhibition of Cryptococcus neoformans and Cryptococcus gattii. Front Microbiol 8: 755. Link: https://bit.ly/2VEBW8X
25. Powers CN, Satyal P, Mayo JA, McFeeters H, McFeeters RL (2019) Bigger Data Approach to Analysis of Essential Oils and Their Antifungal Activity against Aspergillus niger, Candida albicans, and Cryptococcus neoformans. Molecules 24: 2868. Link: https://bit.ly/2XtCzoe
26. Powers CN, Osier JL, McFeeters RL, Brazell CB, Olsen EL, et al. (2018) Antifungal and Cytotoxic Activities of Sixty Commercially-Available Essential Oils. Molecules.23: 1549. Link: https://bit.ly/3ejk1Ng
27. Loiseau PM, Gupta S, Verma A, Srivastava S, Puri SK, et al. (2011) in vitro Activities of New 2-Substituted Quinolines against Leishmania donovani. Antimicrob Agents Chemother 55: 1777-1780. Link: https://bit.ly/3cgLJbG
28.  Vieira NC, Vacus J, Fournet A, Baudouin R, Bories C, et al. (2011) Antileishmanial activity of a formulation of 2-n-propylquinoline by oral route in mice model. Activité antileishmanienne d’une formulation de 2-n- propylquinoléine administrée par voie orale chez la souris. Parasite 18: 333–336. Link: https://bit.ly/2V3COVg
29. Uwineza MS, El Yousfi B, Lamiri A (2018) Activités antifongiques in vitro des huiles essentielles de Mentha pulegium, Eugenia aromatica et Cedrus atlantica sur Fusarium culmorum et Bipolaris sorokiniana. Revue Marocaine de Protection des Plantes. 12: 19-32. Link: https://bit.ly/2y8720p
30.  Foganholi AMAP, Daniel JFS, Santiago DC, Orives JR, Pereira JP, et al. (2015) Chemical composition and antifungal activity of pennyroyal essential oil in different stages of development. Composição química e atividade antifúngica do óleo essencial de poejo em diferentes estágios de desenvolvimento. Ciências Agrárias, Londrina 36: 3091-3100. Link: https://bit.ly/34y84Pq
31. Kamkar A, Javan AJ, Asadi F, Kamalinejad M (2010) The antioxidative effect of Iranian Mentha pulegium extracts and essential oil in sunflower oil. Food Chem Toxicol 48: 1796-1800. Link: https://bit.ly/3a2X7GR
32. Stoyanova A, Georgie V, Kula J, Majda T (2005) Chemical composition of the essential oil of Mentha pulegium from Bulgaria. J Essential Oil Res 17: 475–477. Link: https://bit.ly/3a1Xbq5
33. Lorenzo D, Paz D, Dellacassa E, Davies P, Vila R, et al. (2002) Essential oils of Mentha pulegium and M. rotudifolia from Uruguay. Brazilian Archives of Biology and Technology 45: 519–524. Link: https://bit.ly/3a4kuQk
34. Teixeira B, Marques A, Ramos C, Batista I, Serrano C, et al. (2012) European pennyroyal (Mentha pulegium) from Portugal : Chemical composition of essential oil and antioxidant and antimicrobial properties of extracts and essential oil. Industrial Crops and Products 36: 81–87. Link: https://bit.ly/2K1C4d3
35. Yasa H, Onar ÇH, Yusufoglu AS (2012) Chemical Composition of the Essential Oil of Mentha pulegium L. from Bodrum, Turkey. Journal of Essential Oil Bearing Plants 15: 1040-1043. Link: https://bit.ly/2XwrUsL
36. Ennigrou A, Casabianca H, Vulliet E, Hanchi B, Hosni K (2018) Assessing the fatty acid, essential oil composition, their radical scavenging and antibacterial activities of Schinus terebinthifolius Raddi leaves and twigs. J Food Sci Technol 55: 1582-1590. Link: https://bit.ly/2VplclP
37. Brahmia F, Abdenourb A, Brunoc M, Silviac P, Alessandrac P, et al. (2016) Chemical composition and in vitro antimicrobial, insecticidal andantioxidant activities of the essential oils of Mentha pulegium L. and Mentha rotundifolia (L.) Huds growing in Algeria 88: 96-105. Link: https://bit.ly/2RBgQqw
38. El Ajjouri M, Satrani B, Ghanmi M, Aafi A (2008) Activité antifongique des huiles essentielles de Thymus bleicherianus Pomel et Thymus capitatus (L.) Hoffm. & Link contre les champignons de pourriture du bois d’oeuvre. Biotechnol Agron Soc Environ 12: 345-351. Link: https://bit.ly/2RzAjbi
39. Chan-Bacab MJ, Peña-Rodríguez LM (2001) Plant natural products with leishmanicidal activity. Nat Prod Rep 18: 674-688. Link: https://bit.ly/2JZ7rFc
40. Salehabadi A, Karamian M, Farzad MH, Namaei MH (2014) Effect of root bark extract of Berberis vulgaris L. on Leishmania major on Balb/c mice. Parasitol Res 113: 953-957. Link: https://bit.ly/2K1naDB
41. Ogungbe IV, Setzer WN (2013) In-silico Leishmania target selectivity of antiparasitic terpenoids. Molecules 18: 7761-7847. Link: https://bit.ly/3cgOcmx
42. Ahmet O, Cenk D, Husniye K, Hatice E, Cumhur G, et al. (2014) Antileishmanial Activity of Selected Turkish Medicinal Plants. Trop J Pharm Res 13: 2047-2055. Link: https://bit.ly/2RzQ5CK