Extraction of E. citriodora essential oil (EEO)

Fresh leaves (5 kg) of E. citriodora were collected in the morning (7 a.m.) in the School of Chemistry, University of the Punjab (1° 30’ 15” N and 74° 18’ 23” E.) Lahore, Pakistan in April 2021 (high/low: 34/21 °C). The specimen was assigned to voucher no RP-2. The leaves were washed carefully to get rid of contaminants and dust particles. Essential oils from fresh leaves were obtained by hydrodistillation in a Clevenger apparatus for one hour. The hydrodistilled fraction, containing water and essential oil, was collected and dried with anhydrous Na₂SO₄ [14]. The oil samples were stored in sealed vials at 4 °C for further analysis.

GC-MS analysis of EEO

A sample of 1 µL is injected into GC-MS (Shimadzu GC-9A) equipped with a capillary column (SPB-5) maintained with a flame ionization detector at 220 °C. Carrier gas (N2:1.0 mL min-1) was adjusted at the initial temperature of 50 °C for an initial 5 min, followed by an increase in temperature (5 ºC min-1) up to 235 ºC and finally sustained for 5 min. A column (HP-5 with dimensions: 25 m × 0.22 mm and 0.25 μm df) was used for the complete analyses of the fraction. The observed mass chromatogram generated was interpreted.

Quality parameter analysis of EEO

Quality properties of EEO like density, viscosity, specific gravity, optical rotation, acid number, ester number, consistency, appearance, odor, color, odor, and purity were analyzed according to the prescribed methods.

Preparation of hand sanitizer gel

Hand sanitizer was formulated following the protocol described earlier with slight modifications [15]. Briefly, formulated hand sanitizer (FHS) was prepared by dissolving and stirring carbopol (0.25 g) in water (30 mL) at 60 rpm for 30 minutes at 80 °C (Mixture I). Afterward, a mixture of triethanolamine (0.2 mL), propylparaben (0.2 g), and glycerin (1 mL) was prepared in 50 mL of 70% alcohol (Mixture II). Finally, a homogeneous gel of FHS was obtained after mixing mixture II with the mixture I. For the preparation of FHS-EEO, drops of EEO (0.5% v/v) were added with constant stirring to the FHS. The remainder of each formula was completed with distilled water. Control formulation was also prepared without adding EEO.

Product characterization

The hand sanitizers (FHS and FHS-EEO) were examined for pH, density, and viscosity through prescribed methods. Organoleptic tests were carried out visually by observing the homogeneity, color, smell, and clarity of the hand sanitizer [15]. Consumers’ response to the formulated hand sanitizer was assessed by observing sensory tests (color, smell, viscosity, spreadability, and clarity) involving 20 untrained respondents. The respondents rated the product by scoring 1 (strongly disliked) to 5 (strongly liked) after applying the sample to their palms.

Antimicrobial assays

The antimicrobial activity of EEO, FHS-EEO, and FHS was studied against gram-positive bacteria viz., Escherichia coli (FCBP-WB-0005), Staphylococcus aureus (FCBP-WB-0005), and Bacillus subtilis (FCBP-WB-0005) using the agar diffusion method [16]. The bacterial cultures used were sub-cultured and maintained on LBA (Luria-Bertani agar).

For the antimicrobial assay, overnight nutrient agar-derived cultures were used for the preparation of inoculum suspension. EEO (5 mg/mL) was dissolved in dimethylsulfoxide (DMSO). About 300 µL of a colloidal suspension of the bacterium was spread on the fresh LBA. Wells of 6 mm diameter were punched in the agar medium with the help of a sterile cork-borer and filled with 100 µL of the EEO. Inoculated plates were incubated overnight at 37 °C for 24 hours. The antibacterial activity was determined by measuring the diameter of the zone of inhibition in millimeters (mm) around each well. The results are represented as the mean of three replicates. Controls using DMSO and water were adequately prepared. The antimicrobial activity of EEO, FHS, and FHS-EEO was compared with two commercially available hand sanitizers.

Figures & Tables

Among the species of Eucalyptus used for obtaining essential oils, E. citriodora is commonly used. In the present study, the essential oil extracted from the leaves of E. citriodora exhibited a yield of 0.60% (v/w), which was in accordance with the previous reports on the Eucalyptus spp. Accordingly, Boukhatem et al. [17] described 0.13-1.87% (v/w) yield of essential oil from different species of Eucalyptus from Algeria.  About 1.2 to 3.0% (w/w) yield of essential oils for the different Eucalyptus species was also documented in Tunisia, while the highest yield was obtained from E. cinerea and E. sideroxylon (3.0%) [18]. The differences in the yield of essential oil were ascribed to the difference in the Eucalyptus species, leave age, harvest date, and distillation method [18-21]. It has been known that hydro-distillation products hold greater market value than products from different extraction methods mostly due to the procurement of a greater number of essential oil components [22].

The results on physical and chemical attributes i.e., density (0.94 g/mL), refractive index (1.47 at 25°C), viscosity (11.10 mPa at 25°C), specific gravity (0.92 at 25°C), optical rotation (0-0.98 degree), acid number (11.20), ester number (50.60), consistency (thin), appearance (liquid), color (dark yellow), odor (fruity) and purity (97%) of EEO were comparable with the earlier findings [17, 23, 24, 25]. For an instant, Boukhatem et al. [17] and Subramanian et al. [23] acknowledged similar values of refractive (1.46 to 1.48), specific gravity (0.918 to 0.919), and optical rotation (0 to 10 degrees) in the essential oil of E. globulus. Furthermore, their findings also related high values to the refractive index with less water content and richness of 1,8-cineole. Zrira et al. [24] and Dalal [25] also noticed EEO as a pale yellow liquid, which exhibited a camphoraceous odor, 0.92 g/mL density, and 1, 8-cineole as a major component. Zhou et al. [26] documented yield of essential oil is 0.7% (w/w, relative to the dry weight) with a color of light yellow and a persistent smell from Eucalyptus grandis × E. urophylla leaves essential oils.

GC-MS profile of EEO-S showed the occurrence of eucalyptol, isopinocarveol, globulol, and terpinen-4-ol, along with other components. Most of the compounds belonging to monoterpene alcohol represented the main characterized class of the total oil content. Elaissi et al. [27] also documented oxygen-containing monoterpenoids as the key content in 20 different types of Eucalyptus oil in northern and northwestern Tunisia. Likewise, essential oils of different Eucalyptus species (E. maideni; E. astringent; E. cinerea; E. leucoxylon; E. lehmani; E. sideroxylon and E. bicostata) contained 1,8-cineole, α-pinene, and α-terpineol as major common compounds [18]. In many studies, eucalyptol (1,8-cineol) has been found as a major compound (44-84%) in the essential oil of Eucalyptus spp. and it is known to possess significant antioxidant and antimicrobial activity [18, 26, 28]. Moreover, the essential oil of eucalyptus exhibits 70% eucalyptol and is recommended for medicinal purposes, according to the European and British Pharmacopoeia [29]. However, in many other studies, citronellal was also reported as the major constituent in EEO [30, 31]. The disparity with currently reported results may be ascribed to the differences in the plant varieties and regions along with the associated factors (climate, nature of the soil, time of collection, mode of extraction, and the age of the tree). Another important monoterpene ester found in EEO was α-terpinyl acetate. It bears antimicrobial potential and has a sweet, herbaceous floral and lavender odor. Hence, α-terpinyl acetate is widely utilized as an important ingredient in air fresheners, laundry, dishwashing products deodorizers, soaps, shampoo, and lotions. Moreover, α-terpinyl acetate is used as a flavoring food additive in baked items, drinks, fruit ice creams, sugar candies, chewing gum, gelatin, and puddings [32].

Isopinocarveo [33] and viridiflorol [34] are well-known bioactive natural compounds, endowed with different medicinal properties including antiviral and radical scavenging potentials [35,36]. Over and above, globulol, isolated from the E. globulus has been recommended as an inexpensive and environmentally acceptable agrochemical in agriculture and pharmacy due to its strong antimicrobial potential. It was traditionally used in China to treat skin inflammation and infectious diseases [37]. GCMS profile of EEO confirmed the presence of chemical compounds of sweat odor, antimicrobial and antioxidant action, therefore, EEO could be a valid alternative as an additive in alcohol-based hand sanitizers on account of increasing consumer interest in natural products.

Formulated hand sanitizer (FHS-EEO) exhibited comparable attributes of pale yellow color, sweat odor, clear gel, light to spread with neutral pH, 9834 cP viscosity, and 0.90 g/mL density. Wijana et al. [15] also recognized similar properties of the alcoholic-based hand sanitizer formulated with citrus peel essential oil. The results also revealed that formulated hand sanitizer with EEO is safe for the skin as a pH range of 4.5 to 6.5 is recommended for a broad range of skin [38]. The density of the FHS-EEO was lower than water, which indicated easy application of the product on the skin. The viscosity (consistency) of the hand sanitizers was also in accordance with the specification standard (2381-16893 cP) which may show the ease with which the product can easily be poured and dripped on the palm [15]. The slightly higher viscosity values of FHS-EEO (11041 cP) among all hand sanitizer gels (>1000 cP) might be attributed to the presence of essential oil.

Antimicrobial assays confirmed the potential of all treatments to inhibit the growth of E. coli, S. aureus, and B. subtilis. The antimicrobial activity of all hand sanitizers seemed to be caused by alcohol, as alcohol-based hand sanitizers have been shown to kill gram-positive and negative bacteria by denaturing their protein and lipid membranes. Czerwinski et al. [39] and WHO [40] also recommended the utilization of alcohol-based hand sanitizers due to broad and rapid action against microbes with minimal risk of generating microbial resistance. EEO was also effective in performing an antimicrobial activity (50-55%), as indicated by the area of inhibition. High levels of eucalyptol in the EEO could be accountable for the antimicrobial potential. Similar investigations have been documented previously with essential oil of Eucalyptus species against E. coli, Staphylococcus aureus, Enterococcus faecalis, Listeria ivanovii, and Bacillus cereus [18]. However, other components may also contribute to the antimicrobial activity of EEO, which possibly caused cell lysis by disturbing microbial cell permeability. Bedsides, formulated hand sanitizer with EEO showed more antimicrobial potential (90-97%) as compared to hand sanitizer without EEO (70-74%) or EEO alone (50-55%). The antimicrobial activity of the formulated hand sanitizers was as good as available hand sanitizers in the market.

Essential oil from leaves of E. citriodora contained compounds that may have potential applications in food and pharmaceutical products. It can be a potential ingredient for alcohol-based hand sanitizer gel for improving the aroma, physical, and microbial quality parameters. The sensory test results revealed that the product was liked by the majority of the respondents (≤ 70%). It is essential to ensure the shelf-life of the formulated hand sanitizers by evaluating their stability test.

Author Contributions

Shabnam Javed: Extraction of essential oil; Amna Shoaib: Wrote and edited manuscript, prepared all tables; Amina Bibi: Experiments; Shagufta Perveen: Formatted manuscript; Malik Fiaz Hussain Firdosi: GC-MS analysis

Conflict of Interest

1. Pereira V, Dias CT, Vasconcelos MC, Rosa E, Saavedra MJ. Antibacterial activity and synergistic effects between Eucalyptus globulus leaf residues (essential oils and extracts) and antibiotics against several isolates of respiratory tract infections (Pseudomonas aeruginosa). Industrial Crops and Products, (2014); 52: 1-7.
2. Manika N, Chanotiya CS, Negi MP, Bagchi GD. Copious shoots as a potential source for the production of essential oil in Eucalyptus globulus. Industrial Crops and Products, (2013); 46: 80-84.
3. Rossi YE, Palacios SM. Insecticidal toxicity of Eucalyptus cinerea essential oil and 1, 8-cineole against Musca domestica and possible uses according to the metabolic response of flies. Industrial Crops and Products, (2015); 63: 133-137.
4. Ayinde BA. Chapter 46: Eucalyptus (Eucalyptus citriodora Hook., Myrtaceae) oils. Essential oils in food preservation, flavor, and safety, (2016); Academic Press, 413-419.
5. Gu Y, Yang L, Huo HQ, Zhou LZ, Wen RS, Zhu YJ. Essential oil yield in Eucalyptus citriodora in relation to foliage age after pollarding and tree age. The Journal of Tropical Forest Science, (2019); 31: 452-458.
6. Luis A, Duarte A, Gominho J, Domingues F, Duarte AP. Chemical composition, antioxidant, antibacterial and anti-quorum sensing activities of Eucalyptus globulus and Eucalyptus radiata essential oils. Industrial Crops and Products, (2016); 79: 274-282.
7. Ferraz AC, Mola-Yudego B, Ribeiro A, Scolforo JR, Loos RA, Scolforo HF. Height-diameter models for Eucalyptus sp. plantations in Brazil. Cerne, (2018); 24: 9-17.
8. Fathi E, Sefidkon F. Influence of drying and extraction methods on yield and chemical composition of the essential oil of Eucalyptus sargentii. Journal of Agricultural Science and Technology, (2012); 1035-1042.
9. Moudachirou M, Gbenou JD, Chalchat JC, Chabard JL, Lartigue C. Chemical composition of essential oils of Eucalyptus from Bénin: Eucalyptus citriodora and E. camaldulensis. Influence of location, harvest time, storage of plants and time of steam distillation. Journal of Essential Oil Research, (1999); 11: 109-118.
10. Mondello L, Verzera A, Bonaccorsi I, Chowdhury JU, Yusef M, Begum J. Studies in the essential oil bearing plants of Bangladesh. V. Composition of the leaf oils of Eucalyptus citriodora Hook and E. alba Reinw. ex Blume. Journal of Essential Oil Research, (1998); 10: 185-188.
11. Goodger JQ, Woodrow IE. Selection gains for essential oil traits using micro propagation of Eucalyptus polybractea. Forest Ecology and Management, (2008); 255: 3652-3658.
12. Warnke PH, Lott AJ, Sherry E, Wiltfang J, Podschun R. The ongoing battle against multi-resistant strains: in-vitro inhibition of hospital-acquired MRSA, VRE, Pseudomonas, ESBL E. coli and Klebsiella species in the presence of plant-derived antiseptic oils. The Journal of Cranio-Maxillofacial Surgery, (2013); 41: 321-326.
13. Dinwiddie MT, Terry PD, Chen J. Recent evidence regarding triclosan and cancer risk. International Journal of Environmental Research and Public Health, (2014); 11: 2209-2217.
14. Javed S, Shoaib A, Mehmood Z, Nawaz S, Khan KM. Phytochemical, pharmacological and GC-MS characterization of the lipophilic fraction of Monotheca buxifolia. Asian Journal of Agriculture and Biology, (2021); 31.
15. Wijana S, Pratama EP, Rahmah NL, Arwani M. Hand sanitizer formulation using orange peel essential oil. In IOP Conference Series. Environmental Earth Sciences, (2020); 524: 012021.
16. Elhawary EA, Mostafa NM, Labib RM, Singab AN. Metabolomic profiles of essential oils from selected rosa varieties and their antimicrobial activities. Plants, (2021); 10: 1721.
17. Boukhatem MN, Amine FM, Kameli A, Saidi F, Walid K, Mohamed SB. Quality assessment of the essential oil from Eucalyptus globulus Labill of Blida (Algeria) origin. International Letters of Chemistry, Physics and Astronomy, (2014); 17: 303-315.
18. Sebei K, Sakouhi F, Herchi W, Khouja ML, Boukhchina S. Chemical composition and antibacterial activities of seven Eucalyptus species essential oils leaves. Biological Research, (2015); 48: 1-5.
19. Zrira S, Elamrani A, Benjilali B. Chemical composition of the essential oil of Pistacia lentiscus L. from Morocco-a seasonal variation. Flavour and Fragrance Journal, (2003); 18: 475-480.
20. Elaissi A, Rouis Z, Mabrouk S, Salah KB, Aouni M, Khouja ML, Farhat F, Chemli R, Harzallah-Skhiri F. Correlation between chemical composition and antibacterial activity of essential oils from fifteen Eucalyptus species growing in the Korbous and Jbel Abderrahman arboreta (North East Tunisia). Molecules, (2012); 3: 3044-3057.
21. Jemaa JMB, Haouel S, Bouaziz M, Khouja ML. Seasonal variations in chemical composition and fumigant activity of five Eucalyptus essential oils against three moth pests of stored dates in Tunisia. The Journal of Stored Products Research, (2012); 48: 61-67.
22. Pal PK. Evaluation, genetic diversity, recent development of distillation method, challenges and opportunities of Rosa damascena: A review. Journal of Essential Oil Bearing Plants, (2013); 16: 1-10.
23. Subramanian PA, Gebrekidan A, Nigussie K. Yield, contents and chemical composition variations in the essential oils of different Eucalyptus globulus trees from Tigray, Northern Ethiopia. Journal of Pharmaceutical and Biomedical Sciences, (2012); 17: 1-6.
24. Zrira S, Bessiere JM, Menut C, Elamrani A, Benjilali B. Yield and chemical composition of the sawdust essential oil of Moroccan Tetraclinis articulata (Vahl). Journal of Essential Oil Bearing Plants, (2004); 7: 217-22.
25. Dalal P. Hydro distillation method extraction of Eucalyptus oil & Lemongrass oil. Social Science Journal, (2019); 4: 36-44.
26. Zhou L, Li J, Kong Q, Luo S, Wang J, Feng S, Yuan M, Chen T, Yuan S, Ding C. Chemical composition, antioxidant, antimicrobial, and phytotoxic potential of Eucalyptus grandis × E. urophylla leaves essential oils. Molecules, (2021); 26: 1450.
27. Elaissi A, Salah KH, Mabrouk S, Larbi KM, Chemli R, Harzallah-Skhiri F. Antibacterial activity and chemical composition of 20 Eucalyptus species’ essential oils. Food Chemistry, (2011); 129: 1427-34.
28. Sahi NM. Evaluation of insecticidal activity of bioactive compounds from Eucalyptus citriodora against Tribolium castaneum. International Journal of Pharmacognosy and Phytochemical Research, (2016); 8:1256-70.
29. Darshan S, Doreswamy R. Patented antiinflammatory plant drug development from traditional medicine. Phytotherapy Research: International Journal of Pharmacology and Toxicology, (2004);18: 343-57.
30. Hussein HS, Salem MZ, Soliman AM. Repellent, attractive, and insecticidal effects of essential oils from Schinus terebinthifolius fruits and Corymbia citriodora leaves on two whitefly species, Bemisia tabaci, and Trialeurodes ricini. Sci Horticulture, (2017);14; 216: 111-119.
31. Ribeiro AV, Farias ES, Santos AA, Filomeno CA, Santos IB, Barbosa LC, Picanço MC. Selection of an essential oil from Corymbia and Eucalyptus plants against Ascia monuste and its selectivity to two non-target organisms. Crop Protection, (2018); 110: 207-213.
32. Vaiciulyte V, Lozienė K, Svediene J, Raudoniene V, Paskevicius A. α-Terpinyl Acetate: Occurrence in essential oils bearing Thymus Pulegioides, phytotoxicity, and antimicrobial effects. Molecules, (2021); 26: 1065.
33. Mamadalieva NZ, Akramov DK, Böhmdorfer S, Azimova SS, Rosenau T. Extractives and biological activities of Lamiaceae species growing in Uzbekistan. Holzforschung, (2020); 74: 96-115.
34. Do Amaral JF, Silva MI, de Aquino Neto MR, Neto PF, Moura BA, de Melo CT, de Araujo FL, de Sousa DP, de Vasconcelos PF, de Vasconcelos SM, de Sousa FC. Antinociceptive effect of the monoterpene R-(+)-limonene in mice. Biological and Pharmaceutical Bulletin, (2007); 30: 1217-1220.
35. Beran J, Salapová E, Spajdel M. Inosine pranobex is safe and effective for the treatment of subjects with confirmed acute respiratory viral infections: analysis and subgroup analysis from a Phase 4, randomised, placebo-controlled, double-blind study. BMC Infectious Diseases, (2016); 16: 1-10.
36. Najar B, Mecacci G, Nardi V, Cervelli C, Nardoni S, Mancianti F, Ebani VV, Giannecchini S, Pistelli L. Volatiles and antifungal-antibacterial-antiviral activity of South African Salvia spp. Essential oils cultivated in uniform conditions. Molecules, (2021); 26: 2826.
37. Tan M, Zhou L, Huang Y, Wang Y, Hao X, Wang J. Antimicrobial activity of globulol isolated from the fruits of Eucalyptus globulus Labill. Natural Product Research, (2008); 22: 569-575.
38. Surini S, Amirtha NI, Lestari DC. Formulation and effectiveness of a hand sanitizer gel produced using salam bark extract. International Journal of Applied Pharmaceutics, (2018); 10: 216-220.
39. Czerwinski SE, Cozean J, Cozean C. Novel water-based antiseptic lotion demonstration rapid, broad-spectrum kill compared with alcohol antiseptic. The Journal of Infection and Public Health, (2014); 7: 199-204.
40. Safety W.P., World Health Organization. WHO guidelines on hand hygiene in health care (No. WHO/IER/PSP/2009/01). World Health Organization, (2009).