Biology, Medicine, & Natural Product Chemistry  ISSN 2089-6514 (paper) 
Volume 11, Number 2, October 2022 | Pages: 161-167 | DOI: 10.14421/biomedich.2022.112.161-167 ISSN 2540-9328 (online) 
 

 

 

 

Chemical Compositions and Antioxidant Activity of Volatile Oils from 

Morinda citrifolia and Beta vulgaris Leaves from Nigeria 

 
Adesegun Olusimbo Onanuga1, Ejike Onwudiegwu Okpala2,* 
1Organic Chemistry Unit, Department of Chemistry, University of Ibadan, Ibadan, Nigeria 

2Department of Chemistry, Faculty of Science, Federal University Lokoja, Kogi State-Nigeria. 

 

Corresponding author* 
ejike.okpala@fulokoja.edu.ng; okpalaejike@gmail.com 

 

 
Manuscript received: 27 July, 2022. Revision accepted: 15 August, 2022. Published: 31 August, 2022. 

 

 

Abstract 

 

Morinda citrifolia L. and Beta Vulgaris L leaves are both ethnomedicinal use for the treatment of arthritis, indigestion and skin infections 

with no reports on their essential oils compositions. The colourless volatile oils with a percentage yield of 0.6 and 0.4 (w/w) for Morinda 

citrifolia L. and Beta Vulgaris L respectively were obtained. Forty-five compounds representing 94.31 % of the total percentage 

compositions were identified in the leaf essential oil of M. citrifolia with the most abundant compound as 14-beta-H-pregna- (33.13%). 

Forty-eight compounds representing 74.18% of the total oil composition were identified in the leaf oil of B. Vulgaris with phytol (24.20%) 

as the dominant compound. The essential oils showed good free radical scavenging activity when compared to ascorbic acid used as 

control, with % inhibition varying from 88.74 ± 0.010 to 96.61 ± 0.004 as compared to 95.68 ± 0.010 to 97.31±0.003 of the ascorbic acid 

at (100 to 6.25 mg/ml) concentrations. The leaves essential oils of Morinda citrifolia L. and Beta Vulgaris L contains chemical compounds 

that might be responsible for their antioxidant activity. This result validates the traditional usage of these plants in the treatment of 

arthritis, indigestion and skin infections. 

 

Keywords: Morinda citrifolia L.; Beta Vulgaris L.; Antioxidant; free radical scavenging activity volatile oil. 

 

 

INTRODUCTION 
 

The Morinda citrifolia L (figure 1), also known as Noni 

in Nigeria, belongs to the Rubiaceae family 

(Arunachalam, 2018). It is a plant native to Southeast 

Asia and Australia that has long been used medicinally. 

According to reports, M. citrifolia can treat a wide range 
of medical conditions, including arthritis, heartburn, 

headaches, wounds, and skin infections. Additionally, 

there are some reports on the antitumor and anticancer 

activity of this plant and biological activities such as 

antihypoglycemia have been reported (Algenstaedt et 
al., 2018).  

Beta Vulgaris L. (figure 1), popularly known as 

beetroot, is a member of the Chenopodiaceae family 

(Mello et al., 2008). It is a biennial herbaceous plant. It 

is eaten in Nigeria as a vegetable. It has traditionally 

been believed to treat or prevent conditions like arthritis, 

colon, prostate, dyspepsia, and skin infections. Beta 

Vulgaris leaf consumption lowers the risk of diabetes 
mellitus, obesity, and cardiovascular illnesses. It is also 

recognized for its potential to treat cancer (Kumar et al., 

2016). It is known to have a wide range of biological 
activities, including properties that are antibacterial, 

antioxidant, anticancer, antiviral, and anti-diabetic 

(Kavitha et al., 2020). Consequently, in continuation of 

our search for biologically active compounds from 

plants with ethnomedicinal uses (Okpala et al., 2021; 

Okpala et al., 2022; Onanuga and Oloyede, 2021), we 
present chemical compositions of the volatile oils and 

antioxidant activities of leaves of Beta Vulgaris L. and 
Morinda citrifolia L. The chemical compositions of the 

essential oils (EOs) of the leaves of both plants have not 

been reported in the literature to the best of our 

knowledge. 

 

 
 Beta Vulgaris Leaves  Morinda citrifolia Leaves 
 

Figure 1. The image of the studied plants. 

 

 
MATERIAL AND METHODS 
 

Plant Material 

The samples of Morinda citrifolia L. leaves were 
obtained fresh from Akobo Ibadan, Oyo state, South-

https://doi.org/10.14421/biomedich.2022.112.161-167


 

 

 

162 Biology, Medicine, & Natural Product Chemistry 11 (2), 2022: 161-167 
 

 

west, Nigeria (7o22' 39’’N; 3o 54’21’’E), on 10th April, 

2021 while Beta Vulgaris L. leaves were purchased from 

Bodija market Ibadan, Oyo State. The plants were 

identified by Dr. S. K. Odewo of Forestry Research 

Institute of Nigeria (FRIN) Ibadan, Oyo State. 

 

Extraction of the Essential Oil 

The air dried and pulverized leaves of M. citrifolia (200 

g) and B. Vulgaris (200 g) were weighed and separately 
subjected to extraction using hydro-distillation method 

with Clevenger type apparatus for four hours following 

British Pharmacopoeia specifications with modifications 

(British Pharmacpoeiae, 1980). The samples were added 

into a 2 L round-bottomed flask containing 1.0 L 

distilled water and heated to boiling. There was the 

evaporation of the essential oils together with water 

vapour and these were collected in a condenser. The 

upper phase that contained the EOs was separated from 

the lower one and anhydrous sodium sulphate was used 

for drying the oils isolated. Oils extracted were 

preserved in a sealed amber glass vial at 4oC until 

analyses. The percentage yields (w/w) were determined. 

 

Gas Chromatograph-Mass Spectrometry (GC-MS) 

of the Oils 

GC-MS analysis of the oils was performed using Gas 

chromatography 7890 coupled with mass spectrometer 

5975 Agilent technology. The chemical components 

were identified by matching their mass spectra with 

those recorded in the mass spectra library (W11N17 

main). The stationary phase was the column of model 

Agilent technologies HP-5 MS of length 30 m, the 

internal diameter of 0.320 mm and thickness of 0.25 µm 

while the mobile phase was helium gas. The oven 

temperature was at 80oC held for 2 mins at 12 degrees 

per minute to the final temperature of 240oC held for 6 

mins. The ion source was set at 240oC and electron 

ionization at 70 eV. The scan ranges were from 50 to 

550 amu and the interface temperature between GC and 

MS was 250oC. A sample of (1.0 µL) of diluted oils in 

hexane was manually injected into the GC-MS. 

 

Antioxidant Assay 
The antioxidant activity of the essential oils was 

evaluated using the DPPH (2, 2-diphenyl-1-

picrylhydrazyl) free radical scavenging ability method. 

The concentrations (100 mg/mL, 50 mg/mL, 25 mg/mL, 

12.5 mg/mL and 6.25 µg/mL) of the essential oils were 

mixed with 100 µM methanol- DPPH solution (2.0 mL) 

prepared by dissolving 3.94 mg of DPPH in 100 ml of 

methanol to give a purple solution. The mixture was 

shaken vigorously and left to incubate for 30 minutes in 

the dark at room temperature and the absorbance was 

then measured at 517 nm and recorded as A (sample) using 

a GS UV-12, UV-VIS Spectrophotometer. In its radical 

form, DPPH absorbs, but upon reduction by antioxidant 

species, its absorption reduces. A blank experiment was 

carried out applying the same procedure without 

essential oil (DPPH + Methanol) and the absorbance 

was recorded as A (control). Ascorbic acid was used as a 

standard antioxidant for comparison. The free radical 

scavenging activities of each essential oil were then 

calculated as percentage inhibition according to the 

following equation: 
 

% 𝐼 =
Acontrol − Asample

Acontrol
 × 100 

 

 

RESULTS  
 

The physical properties and percentage yields of the 

volatile oils obtained from M. citrifolia and B. Vulgaris 
leaves are presented in Table 1. 

Forty five compounds representing 94.31 % of the 

total percentage compositions were identified in the leaf 

essential oil of M. citrifolia (figure 2). The most 

abundant compounds are 14-beta-H-pregna- (33.13%), 

1-Hexacosane (11.11%), Heneicosane (7.90%) and 

Tricosane (7.17%). The constituents of the oil were 

mainly non-terpenoids: hydrocarbon (43.67%), steroids 

(33.13%), alcohols, esters and fatty acids (9.26%) while 

the terpenes present are monoterpene (0.40%), diterpene 

(6.05%) and triterpene (1.28%) Table 2. Forty eight 

compounds representing 74.18% of the total oil 

composition were identified in the leaf oil of B. Vulgaris 
(figure 3). The dominant compounds are phytol (24.20 

%), 1, 3-dimethylbenzene (14.84%) and neophytadiene 

(6.13%). The major class of compounds identified are 

diterpene alcohol (24.20) and aromatic compounds 

(18.70%) Table 3.  

Some similarities of the ethnomedicinal uses of the 

two plants could be related to the presence of 

compounds such as phytol, neophytadiene, mesitylene, 

3-hexanol, decane, Docosane, tetracosane, eicosane and 

heneicosane which were identified in the essential oils 

of both plants. The GC-MS chromatograms of the 

essential oils are given in Figures 2 and 3. The 

antioxidant activity of the essential oils of the leaves of 

M. citrifolia and B. Vulgaris are presented in Tables 4 

and 5. The DPPH scavenging ability of the essential oils 

was compared with ascorbic acid a known standard 

antioxidant. 



 

 

 

 Onanuga & Okpala – Chemical compositions and Antioxidant activity of … 163 
 

 

 
Figure 2. The GC-MS chromatogram of the leaf essential oil of M. citrifolia. 
 

 

 
Figure 3. The GC-MS chromatogram of the leaf essential oil of B. Vulgaris. 

 
 

 

 



 

 

 

164 Biology, Medicine, & Natural Product Chemistry 11 (2), 2022: 161-167 
 

 

Table 1. Physical properties and yields of essential oils from M. citrifolia and B. Vulgaris leaves. 

 

Plant  
Weight of leaf 

sample (g) 

Weight of oil 

obtained (g) 

% (w/w) yield of 

the oil obtained 
Physical Properties 

Morinda citrifolia L. 200 1.2 0.6 Colourless, herbaceous 

Beta vulgaris L. 200 0.8 0.4 Colourless; leafy and aromatic odour 

 
 

Table 2. Chemical compositions of M. citrifolia essential oils. 
 

S/N RT (min) Chemical constituents % composition Class of compound 

1 3.260 3-hexanol 0.14 Alcohol 

2 3.325 6-methyl-2-heptanol 0.25 Alcohol 

3 3.800 Ethyl-cyclohexane 0.15 Cycloalkane 

4 4.124 2-hexenal 0.24 Aldehyde 

5 4.189 3-hexen-1-ol (z) 4.66 Alcohol 

6  4.357 2-hexen-1-ol (E) 0.77 Alcohol 

7 4.394 1-hexanol 0.74 Alcohol 

8  4.465 3-methylene-1-vinyl-1-cyclopentene 0.25 Cycloalkane 

9 4.902 2-heptanol 1.20 Alcohol 

10 5.858 2-hexanol 0.22 Alcohol 

11 6.204 1-octen-3-ol 0.35 Alcohol 

12 6.415 Mesitylene 0.13 Aromatic 

13 6.534 Decane 0.11 Alkane 

14 6.663  3-hexen-1-ol, acetate 0.57 Ester 

15 7.684 Benzofuran 0.94 Heterocyclic 

16 8.133 3-carene 0.12 Monoterpene 

17 9.235 Cinnamaldehyde (E)-  0.30 Aldehyde 

18 9.872 2-methyl-2-nonen-4-one 0.10 Ketone 

19 10.050 Citronellol 0.28 Monoterpene 

20 10.520 2-decanal (E) - 0.15 Aldehyde 

21 13.502  4-(2,6,6-trimethyl-1-cyclohexen-1-yl 3-buten-2-one 0.19 Ketone 

22 17.408 Neophytadiene 0.66 Diterpene 

23 17.473 3-octadecene (3E)- 0.18 Alkene 

24 17.840 3-eicosene (E) 0.24 Alkene 

25 18.013 Nonadecane 0.13 Alkane 

26 18.623 n-hexadecanoic acid 0.34 Fatty acid 

27 18.985 Eicosane 1.05 Alkane 

28  19.093 14-beta-H-pregna 33.13 Steroid 

29 19.785 1-nonadecene 0.68 Alkene 

30 19.920 Heneicosane 0.85 Alkane 

31 20.66 Phytol 5.39 Diterpene 

32 20.207 1-heneicosene 0.36 Alkene 

33 20.325 1-eicosene 1.20 Alkene 

34 20.482 1-tetracosene 0.62 Alkene 

35 20.817 Docosane 1.69 Alkane 

36 21.670 Tricosane 7.17 Alkane 

37 21.750 1-Hexacosene 11.11 Alkene 

38 22.491 Tetracosane 3.16 Alkane 

39 23.291 Heneicosane 7.90 Alkane 

40 24.053 Hexacosane 3.65 Alkene 

41 25.317 9-Hexacosene 0.53 Alkene 

42 25.500 Octacosane 0.98 Alkane 

43 25.733 Supraene 1.28 Triterpene 

44 26.186 Nonacosane 0.44 Alkane 

45 27.499 3-Ethyl-2,6,10-trimethyl undecane 0.24 Alkane 

Total percentage composition                                                                                       94.31 

 



 

 

 

 Onanuga & Okpala – Chemical compositions and Antioxidant activity of … 165 
 

 

Table 3.  Chemical compositions of B. Vulgaris essential oils. 
 

S/N RT (min) Chemical constituents % composition Class of compounds 

1 3.125 3-Hexanone 0.31 Ketone 

2 3.152 1-ethyl-3-methyl cyclopentane 0.41 Cycloalkane 

3 3.179 2-Hexanone 0.89 Ketone 

4 3.260 3-Hexanol 1.22 Alcohol 

5 3.250 2,5-dimethyl-1-hepten-4-ol 1.20 Unsaturated alcohol 

6 3.384 1, 3-dimethyl-trans- cyclohexane 0.39 Cycloalkane 

7 3.730 1,2-dimethylcyclohexane 0.33 Cycloalkane 

8 3.800 Ethyl-cyclohexane 0.82 Cycloalkane 

9 4.081 1,2,4-trimethyl cyclohexane 0.26 Cycloalkane 

10 4.124 2-Hexanal (E)- 0.60 Aldehyde 

11 4.243 Ethylbenzene 2.57 Aromatic 

12 4.308 Nonane 0.31  Alkane 

13 4.470 1,3-dimethylbenzene 14.84 Aromatic 

14 4.659 Cis-1-ethyl-3-methyl-cyclohexane 0.13 Cycloalkane 

15 4.886 Nonane 0.18 Alkane 

16 5.858 2-methyl-3-propyl-trans oxirane 1.30 Cyclo ether 

17 6.415 Mesitylene 0.56 Aromatic 

18 6.534 Decane 0.61 Alkane 

19 6.885 1-ethyl-3-methyl benzene 0.12 Aromatic 

20  7.360 1-methyl-3-propylbenzene 0.13 Aromatic 

21 7.479 1-ethyl-3,5-dimethyl benzene 0.14 Aromatic 

22 7.895 1,2,4,5-tetramethyl benzene 0.13 Aromatic 

23 8.203 Nonanal 0.12 Aldehyde 

24 8.754 3-methyl-6-(1-methyl ethyl ) cyclohexene 0.68 Cycloalkane 

25 9.251 4-acetyl-1-methyl cyclohexene 0.24 Cycloalkane 

26 9.872 1-cyclopropyl-2-propanone 0.72 Cycloketone 

27 9.964 1-carboxaldehde, 2,6,6-trimethyl-1cyclohexene 0.33 Cycloalkane 

28 11.039 Tridecane 0.17 Alkane 

29 12.363 Tetradecane 0.15 Alkane 

30 13.059 6,10-dimethyl, 5,9-undecadien-2-one 0.18 Unsaturated ketone 

31 13.173 1-[(E)-3-methylbut-1-enyl]cyclohexene 0.32 Cycloalkane 

32 13.281 1-(1,1-dimethylethyl)4-ethyl benzene 0.21 Aromatic 

33 13.502 4-(2,6,6- trimethyl-1-cyclohexen-1-yl) 3-buten-2-one 1.83 Cycloketone 

34 13.967 Copaene 0.23 Alkene 

35 14.707 2-methyl-4-(2,6,6, trimethyl-1-cyclohexen-1-yl) 2 butenal 0.16 Cycloaldehyde 

36 15.922 Heptadecane 0.27 Alkane 

37 17.354 3,7,11,15 tetramethylhexadec-2-ene 1.78 Alkene 

38 17.408 Neophytadiene  6.13 Diterpene 

39 17.948 1-Nonadecene 0.18 Alkene 

40 19.780 E-15-heptadecanal 0.34 Aldehyde 

41 19.839 1-octadecene 0.40 Alkene 

42 19.920 Heneicosane 0.29 Alkene 

43 20.066 Phytol 24.20 Diterpene 

44 20.325 Diallylacetal, palmitaldehyde 3.18 Aldehyde 

45 20.811 Docosane 0.87 Alkane 

46 21.665 Eicosane 1.98 Alkane 

47 22.491 Tetracosane 0.68 Alkane 

48 23.285 3-pentacosene (E) 1.09 Alkene 

Total percentage composition                                                                                       74.18 

 

 

 
 

 

 

 

 

 



 

 

 

166 Biology, Medicine, & Natural Product Chemistry 11 (2), 2022: 161-167 
 

 

Table 4. Absorbance values at 517 nm of DPPH method of antioxidant 

assay. 

 

Conc. 

(mg/ml) 
M. citrifolia B. Vulgaris Asc. Acid 

100 0.251 ± 0.003 0.102 ± 0.004 0.081 ± 0.003 

50 0.270 ± 0.002 0.106 ± 0.007 0.097 ± 0.004 

25 0.280 ± 0.013 0.116 ± 0.007 0.105 ± 0.009 

12.5 0.312 ± 0.005 0.123 ± 0.005 0.127 ± 0.005 

6.25 0.339 ± 0.010 0.133 ± 0.005 0.130 ± 0.010 

Absorbance values in mean ± standard error; Asc.Acid = Ascorbic Acid at 
517nm; ± Standard deviation for measurement, Absorbance of control 

=3.010±0.005 

 

 

 
Table 5. Percentage inhibition calculated from DPPH method of 

antioxidant assay. 

 

Conc. (mg/ml) M. citrifolia B. Vulgaris Asc. Acid 

100 91.66 96.61 97.31 

50 91.02 96.48 96.78 

25 90.69 96.15 96.51 

12.5 89.63 96.91 95.78 

6.25 88.74 95.58 95.68 

 

 
DISCUSSION 
 

Methyl hexanoate, methyl octanoate, ethyl octanoate 

and methyl 4 E-decanoate have been reported in the 
volatile oil of M. citrifolia fruit, they are found to 

contain flavonoids as the major phytochemicals (Pino et 

al., 2010). 14-b-H-Pregna, a steroid considered to be a 
sex pheromone specific to males, and also a defensive 

chemical with diabetic retinopathy prevention and 

treatment effects. The presence of 14-b-H-pregna has 

been reported in the essential oils from different parts of 

some plants, including Scutellaria plants, Urginea 
indica Kunth, Allium rotundum, Gundelia tournefortii L 

(Farhang et al., 2016). Citrus limon (Akhila et al., 

2015). Dehpour et al.2012 reported that 14-b-H-pregna 
was the major compound in the essential oil of lower 

Allium rotundum which displayed antibacterial activity. 
Neophytadiene is a good analgesic, antimicrobial, 

antipyretic, antioxidant and anti-inflammatory 

compound (Venkata et al., 2012). Phytol, known to 
exhibit antioxidant and antinociceptive effects is a 

precursor of synthetic vitamins E and K and is cytotoxic 

against breast cancer cell lines (MCF7) (Casuga et al., 

2016; Sermakkani and Thangapandian, 2012). 

The measured absorbance values and calculated 

percentage inhibition show that the antioxidant activity 

of the two essential oils and standard (Ascorbic acid) is 

concentration dependant. From the results, the % 

inhibition of the essential oils of both plants exhibited 

good scavenging ability on DPPH radical which were 
comparable to ascorbic acid at all concentrations (100-

6.25 mg/ml) investigated.  

 

CONCLUSIONS 
 

Analysis of the essential oils of M. citrifolia and B. 

Vulgaris leaves showed that they contained different 
major constituents. The major constituent of M. citrifolia 

leaves essential oil were steroids: 14-beta-H-pregna- 

(33.13%) and 1-Hexacosane (11.11%), while the 

dominant compounds identified in B. Vulgaris were 

phytol (24.20 %) and 1,3-dimethylbenzene (14.84%. 

These major constituents of both oils have been reported 

to possess similar properties such as antibacterial, 

antioxidant and antinociceptive. Most of the chemical 

compounds identified from the essential oils of M. 

citrifolia and B. Vulgaris were biologically active 
compounds and the essential oils exhibited good 

scavenging ability at all concentrations investigated.  

The plants’ parts could be a source of drug development 

for oxidative diseases.  

 

Competing Interests: A. O. ONANUGA and E. O. 

OKPALA declare that they have no competing interests. 

 
Acknowledgements: The authors are grateful to the 

University of Ibadan, Nigeria for providing the 

laboratory space and facilities for the extraction and 

antioxidant analysis of the essential oils. 
 
 

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