Phytochemical Screening and chemical investigation of lipoidal matter of the leaves of Latania verschaffeltii Lem. Family Arecaceae cultivated in Egypt

, Mohamed Fared Shawky; Ibrahim, Makboul Ahmed Makboul; Attia, Ahmed Abdeen Mohamed; Malak, Lourin Gamal Gobraeil

doi:10.1590/s2175-97902024e23348

Abstract

This study presents the first preliminary phytochemical screening and investigation of the lipoidal matter of Latania verschaffeltii Lem. leaves, belonging to the Arecaceae family. Gas chromatography coupled with mass spectroscopy (GC/MS) was used to analyze and identify compounds of saponifiable and unsaponifiable content. The preliminary phytochemical screening of total methanolic extract of Latania verschaffeltii Lem. leaves revealed the presence of unsaturated sterols and/or triterpenes, carbohydrates and/or glycosides, flavonoids, tannins, saponins, and phenolic acids in the leaves. However, cardenolides, cyanogenic compounds, alkaloids, and iridoids were not detected. The results of the gas chromatography/mass spectrometry (GC/MS) analysis indicated that the percentage of saturated fatty acids (83.82%) is higher than that of unsaturated fatty acids (9.42%). The predominant methyl ester of a saturated fatty acid detected in the sample was hexadecanoic acid methyl ester, accounting for 41.68% of the total. The composition of the unsaponifiable matter consisted of hydrocarbons (5.66%), fatty alcohols (0.96%), terpenes (85.97%), and sterols (2.18%). The major terpenes observed were phytol (43.62%) and squalene (39.27%).

Keywords:
Latania verschaffeltii Lem; GC/MS; Lipoidal matter; Phytochemical screening

INTRODUCTION

Family Arecaceae (Palmae) comprises approximately 181 genera and an estimated 2600 species distributed in tropical and subtropical regions (Christenhusz, Maarten, Byng, 2016Christenhusz, Maarten JM, Byng JW. The number of known plants species in the world and its annual increase. Phytotaxa. 2016;261(3):201-217.). This family includes monocot shrubs, climbers, and palm trees (Basu, Sengupta, Zandi, 2014Basu S, Sengupta R, Zandi P. Arecaceae: The Majestic Family of Palms. 2014. Retrieved from http://www.eoearth.org/view/article/53dc075c0cf2541de6d02774.
http://www.eoearth.org/view/article/53dc... ). Phoenix and Areca catechu are the most chemically and biologically investigated genera. In addition, some genera belonging to the family Arecaceae hold significant economic value, such as coconuts, true sago palm, date palm, and oil palm (De Souza et al., 2020De Souza FG, De Araújo F, De Paulo FD, Zanotto AW, Neri-Numa IA, Pastore GM. Brazilian fruits of Arecaceae family: An overview of some representatives with promising food, therapeutic and industrial applications. Food Res Int. 2020;138:109-690.). It has been reported that members of the family Arecaceae are characterized mainly by the presence of flavonoids, steroids, terpenoids, phenolic acids, and fatty acids derivatives (Mohammed, Fouad, 2022Mohammed MH, Fouad MA. Chemical and biological review on various classes of secondary metabolites and biological activities of Arecaceae (2021-2006). J Adv Biomed Pharm Sci. 2022;5(3):113-150.). Plants belonging to this family have demonstrated various biological properties, including anti-hyperlipidemic, anti-diabetic, antioxidant, anti-parasitic, renal protective, antimicrobial (antibacterial, antifungal, and antiviral), antipyretic, cardioprotective, anti-mutagenic, antihypertensive, anti-ulcer, neuropharmacological, hepatoprotective, anti-acetylcholinesterase, anti-inflammatory, and cytotoxic activities (Mohammed, Fouad, 2022Mohammed MH, Fouad MA. Chemical and biological review on various classes of secondary metabolites and biological activities of Arecaceae (2021-2006). J Adv Biomed Pharm Sci. 2022;5(3):113-150.).

The genus Latania, commonly known as Latan palm, belongs to the family Arecaceae and is regional to the Mascarene Islands in the western Indian Ocean (Govaerts, Dransfield, 2005Govaerts R, Dransfield J. World Checklist of Palms. The Board of Trustees of the Royal Botanic Gardens, Kew. England. 2005;1-223.). Latania is a large, single-stem palm with unisexual plants (dioecy), characterized by its leaf shedding and scarred trunk. The stamens are small in clusters and emerge from within leather-like inflorescences. The pistils are comparatively larger, and they are present as individual structures rather than being concealed within the bracts. The fruit contains 1-3 pyrenes, seeds enclosed in wooded endocarps (Dransfield et al., 2008Dransfield J, Uhl NW, Asmussen CB, Baker WJ, Harley MM, Lewis CE. Genera Palmarum - Evolution and Classification of Palms. Royal Botanic Gardens, Kew. England. 2008.). It includes three species, namely Latania lontaroides (Gaertn.) H.E.Moore, Latania loddigesii Mart., and Latania verschaffeltii Lem. Species are most likely differentiated based on leaf color by exclusively considering young leaves, as the variations in color among palm trees tend to fade with age. The entire leaf of Latania loddigesii Mart. (blue latan) is blue-gray. Petiole, leaf margins, and veins of Latania lontaroides (Gaertn.) H.E. Moore (red latan) and Latania verschaffeltii Lem. (yellow latan) are reddish and deep orange-yellow, respectively (Dehgan, 2023Dehgan B. Garden Plants Taxonomy: Volume 1: Ferns, Gymnosperms, and Angiosperms (Monocots). Springer Nature. 2023;173-603.). The leaves are used as thatch, trunks as wood sources, and young seeds are considered edible. All species are beautiful ornamentals (Dransfield et al., 2008Dransfield J, Uhl NW, Asmussen CB, Baker WJ, Harley MM, Lewis CE. Genera Palmarum - Evolution and Classification of Palms. Royal Botanic Gardens, Kew. England. 2008.). Cleophora verschaffeltii Lem. O.F. Cook and Latania aurea Duncan are synonyms for Latania verschaffeltii Lem. There is a scarcity of specific data pertaining to these species. Nevertheless, compelling data has been documented regarding other members of this particular family, including Areca catechu seeds, which exhibit significant anti-cell adhesive activity. The treatment of venereal diseases involves the utilization of a decoction prepared by combining the roots and leaves of Argemone mexicana and Caesalpinia bonduc (Gurib-Fakim et al., 1996Gurib-Fakim A, Sewraj MD, Gueho J, Dulloo E. Medicinal plants of Rodrigues. Int J Pharmacogn. 1996;34(1):2-14.‏).

MATERIAL AND METHODS

Plant Material

The fresh leaves of the plant used in this study were collected from Mazhar Botanical Garden, Nahia, Imbaba, Giza, Egypt. Engineer Teres Labib, director of El-Orman Garden in Giza, Egypt, and consultant of plant taxonomy at the Ministry of Agriculture, provided and authenticated this plant. The voucher specimen (Aun-Phg-102021) was maintained in the Pharmacognosy Department Herbarium, Faculty of Pharmacy, Assiut University.

Chemicals

For phytochemical screening, we used 1 % hydrochloric acid, 20 % sodium hydroxide, concentrated ammonium hydroxide solution, pyridine, sodium nitroprusside, sodium picrate paper, 10% NaCl, 1% gelatin, 10 % alcoholic solution of α-naphthol, sulfuric acid, concentrated hydrochloric acid, 5% ferric chloride solution, chloroform, Molish’s solution, Trim-Hill reagent (prepared using 10 ml acetic acid, 1 ml of 0.2% copper sulfate (CuSO₄, 5H₂O), and Dragendorff’s reagent (stock solution: 5.2gm bismuth carbonate+4gm sodium iodide+50mL glacial acetic acid, boiled for few min., after 12 hr. precipitated sodium acetate crystals are filtered by sintered glass funnel; 40mL filtrate+160mL ethyl acetate+1 mL distilled water, (stored in amber-colored glass bottle). The working solution included 10 mL stock solution+20 mL acetic acid+distilled water to make the final volume 100 mL). For investigation of Lipoidal matter, n-Hexane, 0.5N alcoholic potassium hydroxide, ether, 10 % 2N hydrochloric acid, 10, 20 % sulphuric acid, methanol, anhydrous sodium sulfate, and dilute ammonium hydroxide were utilized.

Apparatus

Thermo Scientific™ TRACE™ 1310 GC system, equipped with Electron Impact Ionization (EI) detector, TR-5 MS column (30 m x 0.32 mm i.d., 0.25 μm film thickness) was used (Faculty of Science, Assiut University).

Methods

Preparation of Extract for Phytochemical Screening

The methanol extraction method was employed to obtain a 20g viscous residue from 100g of air-dried powdered leaves of Latania verschaffeltii Lem. Qualitative phytochemical screening was conducted on the residue using the standard procedure for each constituent (Trease, Evans, 1989Trease GE, Evans WC. A Textbook of Pharmacognosy, 11th ed, Brailliar Tindall Ltd, London. 1989;45-50.; Evans, 1996Evans WC. Trease and Evan›s Pharmacognosy, Edn 14, WB Saunders Company Ltd, London, Philadelphia, Toronto, Sydney, Tokyo. 1996, pp. 47-48.).

Test for Sterols and Triterpenoids

Salkowski’s Test: About 0.5 g of the plant extract was dissolved in 5 chloroform and filtered, then a few milliliters of the filtrate mixed with a few drops of conc. After shaking H₂SO₄ well and allowing it to stand, the formation of a golden yellow layer at the bottom indicates a positive test for steroids and triterpenoids (Singh, Kumar, 2017Singh V, Kumar R. Study of Phytochemical Analysis and Antioxidant Activity of Allium sativum of Bundelkhand Region. IJLPR. 2017;3(6):1451-1458).

Test for Saponins

The Foam Test: powder of the plant was mixed with 10 mL water. The mixture was vigorously shaken and observed for the presence of froth. The froth persisted for a duration of 10 min, indicating a positive result (Tiwari et al., 2011Tiwari P, Kumar B, Kaur M, Kaur G, Kaur H. Phytochemical screening and Extraction: A Review. Int pharm sci. 2011;1(1):98-106.).

Test for Tannins

The Gelatin Test: It involves dissolving 1 g of plant extract in 10 milliliters of distilled water, which is then mixed with a 1% gelatin solution and 10% sodium chloride. The formation of a white precipitate would indicate the presence of tannins (Tiwari et al., 2011Tiwari P, Kumar B, Kaur M, Kaur G, Kaur H. Phytochemical screening and Extraction: A Review. Int pharm sci. 2011;1(1):98-106.; Pandey, Tripathi, 2014Pandey A, Tripathi S. Concept of standardization, extraction and pre phytochemical screening strategies for herbal drug. J pharmacogn phytochem. 2014;2(5):115-119.)

Test for Flavonoids

The Ammonia Test: It involved combining approximately 0.5 units of extract with 5 mL of diluted ammonia solution. The addition of concentrated H₂SO₄ resulted in the formation of yellow color, indicating the presence of flavonoids (Kumar et al., 2013Kumar RS, Venkateshwar C, Samuel G, Rao SG. Phytochemical screening of some compounds from plant leaf extracts of Holoptelea integrifolia (Planch.) and Celestrus emarginata (Grah.) used by Gondu tribes at Adilabad District, Andhra Pradesh, India. IJSEI. 2013;2(8):65-70.).

Test for Phenolic Compounds

The Ferric Chloride Test: Approximately 2 g of extract was added to a few drops of 5% ferric chloride sol. would result in the formation of a dark green/bluish-black color, indicating the presence of phenolic compounds (Raaman, 2006Raaman N. Phytochemical Techniques. New India Publishing Agency, New Delhi, 2006, 19-24.; Tiwari et al., 2011Tiwari P, Kumar B, Kaur M, Kaur G, Kaur H. Phytochemical screening and Extraction: A Review. Int pharm sci. 2011;1(1):98-106.).

Test for Carbohydrates and/or Glycosides

Molish’s Test: About 0.1 g solvent free extract is dissolved in 5 mL of distilled water and filtered then 2 mL filtrate was mixed with two drops of alcoholic α-naphthol and 1mL conc.H₂SO₄ (along the sides of test tube) a violet ring indicating the presence of Carbohydrates and/or glycosides (Raaman, 2006Raaman N. Phytochemical Techniques. New India Publishing Agency, New Delhi, 2006, 19-24.; Singh, Kumar, 2017Singh V, Kumar R. Study of Phytochemical Analysis and Antioxidant Activity of Allium sativum of Bundelkhand Region. IJLPR. 2017;3(6):1451-1458).

Test for Cardenolides

About 0.5 g of extract of the plant was added to pyridine, Sodium nitroprusside, and 20% NaOH give red colour, fades to brownish yellow colour indicating the presence of Cardenolides (Audu, Mohammad, Kaita, 2007Audu SA, Mohammad I, Kaita HA. Phytochemical screening of the leaves of Lophira lanceolata (Ochanaceae). Life Sci. 2007;4(4):75-79.).

Test for Alkaloid

Dragendroff’s Test: About 0.5g plant extract was mixed with a few millimeters of dil. HCl and then filtered, then a few millimeters of the filtrate was mixed with 1-2 mL Dragendorff’s reagents to give a reddish-brown precipitate. A positive result is indicated by the formation of a reddish-brown precipitate (Silva, Abeysundara, Aponso, 2017Silva GO, Abeysundara AT, Aponso MM. Extraction methods, qualitative and quantitative techniques for screening of phytochemicals from plants. Am J Essent Oil. Nat Prod. 2017;5(2):29-32.; Singh, Kumar, 2017Singh V, Kumar R. Study of Phytochemical Analysis and Antioxidant Activity of Allium sativum of Bundelkhand Region. IJLPR. 2017;3(6):1451-1458).

Test for Cyanogenic Glycoside

Guignard’s Test: When the powder is wet in water and heated for 30 min in a water bath, the yellow color of the sodium picrate paper inserted into the test tube will turn brick-red due to the formation of sodium isopurpurate, indicating the presence of cyanogenic glycoside (Brinker, David, 1989Brinker AM, David S. Methods for the detection and quantitative determination of cyanide in plant materials. Phytochem Bull. 1989;21(2):24.‏).

Test for Iridoids

Trim & Hill Color Reaction: It involved the collection of approximately 0.4 g of plant extract in a test tube. This extract was then combined with 5 ml of 1% aqueous HCl. Following a time interval of 3 to 6 hours, a volume of 0.1 mL from the macerate was transferred into a separate tube containing 1 mL of the Trim-Hill reagent. When the tube is heated in flame briefly, a color is produced if certain iridoids are present (Wagner, Baldt, Zgainski, 1984Wagner H, Baldt S, Zgainski EM. Plant Drug Analysis. Springer Verlag, Berlin/New York. 1984.).

Preparation of Lipoidal Matter

The air-dried powder of Latania verschaffeltii Lem. (100g) was extracted utilizing n-hexane. The solvent was evaporated at 40ºC under reduced pressure to yield 5 g residue of lipoidal matter.

Preparation of Unsaponifiable Matter

The n-hexane extract of the leaves was saponified with about 5 g of 0.5 N alc. KOH for 3 hrs. and refluxed into a boiling water bath. A significant part of the alcohol present was distilled, and the concentrated extract was diluted with distilled water. Afterward, the unsaponifiable matter (1.75 g) was extracted utilizing several portions of ether until exhaustion (Johnson, Davenport, 1971Johnson AR, Davenport JB, Biochemistry and methodology of lipids. John Wiley & Sons, Inc, 1971.).

Preparation of Saponifiable Matter

The alkaline aqueous solution (soap) that remained after the removal of the unsaponifiable matter was acidified with sulphuric acid (20%), and the liberated fatty acids were extracted with ether. The combined ether extract was washed several times with distilled water until the washings were acidity-free. The ether extract was dried over anhydrous sodium sulfate. The solvent was subjected to distillation under reduced pressure, resulting in the formation of a thick residue composed of free fatty acids. These fatty acids exhibited a yellowish-brown color. The residue was subsequently subjected to methylation (Johnson, Davenport, 1971Johnson AR, Davenport JB, Biochemistry and methodology of lipids. John Wiley & Sons, Inc, 1971.).

Preparation of Fatty Acid Methyl Esters

The obtained fatty acid residue was dissolved in 150 mL of 10% H₂SO₄ in MeOH and then refluxed for 4 - 6 hrs. The solvent was distilled off, and the residue was taken in 10 mL of distilled water. The aqueous solution was made alkaline with dilute ammonium hydroxide, where an oily layer was separated and extracted with ether till exhaustion. The ethereal extracts were combined and distilled to give a yellowish-brown residue (2.45 g). A part of this residue was kept for further investigation (Johnson, Davenport, 1971Johnson AR, Davenport JB, Biochemistry and methodology of lipids. John Wiley & Sons, Inc, 1971.).

Gas Chromatography-Mass Spectrometry Technique (Gc-Ms)

The sample was analyzed on Thermo Scientific™ TRACE™ 1310 GC system, equipped with Electron Impact Ionization (EI) detector, TR-5 MS column (30 m x 0.32 mm i.d., 0.25 μm film thickness) and connected to Mass Spectrometer operating in EI mode (70 eV; m/z 40-750; source temperature, 300 °C; Run Time: 74.00 min.; Initial temperature: 60.0 °C; Initial hold time: 2.00 min; Sample volume: 2.00 µL). The final temperature at the first ramp was 150 °C for 10 min, increased to 200 °C at 10 °C/min, and maintained for 15 min at 280°C. The carrier gas was helium at a 1.0 mL/min flow rate. The transfer line temperature was maintained at 280 °C, and the split ratio was 1:10.

Investigation of Lipoidal Matter

The GC chromatogram of the analyzed sample is shown in (Figures 1 & 2). Components were identified based on their retention times and interpretation of spectrometric fragmentation using the National Institute of Standards and Technology (NIST) database. The database is based on more than sixty thousand patterns of known compounds. Non-congruent peaks with corresponding peaks in a library spectrum were excluded, whereas congruent peaks were classified as impurities to ensure a rigorous standard of accuracy and precision in the results.

FIGURE 1
Chromatogram of GC/MS analysis of the fatty acid methyl esters of Latania verschaffeltii Lem. leaves.

FIGURE 2
Chromatogram of GC/MS analysis of the unsaponifiable matter of Latania verschaffeltii Lem. leaves.

RESULTS

Preliminary Phytochemical Screening

The preliminary phytochemical screening of Latania verschaffeltii Lem. leaves showed the presence of carbohydrates and/or glycosides, unsaturated sterols and/or triterpenes, phenolic acids, tannins, flavonoids, and saponins. Conversely, cardienolides, cyanogenic compounds, alkaloids, and iridoids were absent.

Gc-Ms Analysis of Fatty Acid Methyl Esters and Unsaponifiable Matter

The results of GC-MS analysis of fatty acid methyl esters are depicted in (Figure 1 & Table I). The analysis detected the presence of 25 compounds. Most of these compounds are saturated fatty acids methyl esters (83.82%). In contrast, the unsaturated fatty acids methyl esters and the unidentified compound represent 9.42% and 6.76%, respectively. The most abundant saturated fatty acid methyl esters in the saponifiable fraction are hexadecanoic acid methyl ester (41.68%), thiophene-2-acetic acid undecyl ester (18.73%), methyl tetradecanoate (7.24%), dodecanoic acid methyl ester (6.25%), and octadecanoic acid methyl ester (3.95%). The major unsaturated fatty acid was (E)-9-octadecenoic acid methyl ester (2.90%).

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TABLE I
Results of GC/MS analysis of fatty acid methyl esters of Latania verschaffeltii Lem. Leaves

The results of GC-MS analysis of the unsaponifiable matter are depicted in (Figure 2 and Table II). The analysis revealed the presence of 85.97% terpenes, 5.66% hydrocarbons, 2.18% sterols, 0.96% fatty alcohols, and 5.23 % unidentified compounds. (1-butyloctyl)-Benzene (0.47%) and 2-phenyl-pentadecane (0.45%) represented the major hydrocarbons. 2-Propyl-1-pentanol (0.75%) was the major fatty alcohol, phytol (43.62%) and squalene (39.27%) were the major terpenes. Cyclic 1, 2-ethanediylaetal, (5á)-cholestan-3-one (1.20%) was the major sterol identified.

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TABLE II
Results of GC/MS analysis of the unsaponifiable matter of Latania verschaffeltii Lem. leaves

DISCUSSION

The preliminary phytochemical profiling of Latania verschaffeltii Lem. leaves revealed a high composition of saponins, tannins, phenolic acids, flavonoids, carbohydrate and/or glycosides, unsaturated sterols and/or triterpenes. Lipoidal matter investigation of Latania verschaffeltii Lem. by GC/MS analysis revealed that the most abundant terpenes are phytol (43.62%) and squalene (39.27%), and the major fatty acid methyl ester was palmitic acid methyl ester (hexadecanoic acid methyl ester) (41.68%).

Many biological activities have been reported for palmitic acids, such as antibacterial, antifungal, antioxidant, anti-inflammatory, hypocholesterolemic activities, and hemolytic properties (Kamal et al., 2017Kamal AM, Ziada A, Soliman R, Selim M. Chemical Investigation of Lipoidal Matter of Ficus craterostoma. J Adv Pharm Res. 2017;1(3):150-154.; Starlin et al., 2019Starlin T, Prabha PS, Thayakumar BKA, Gopalakrishnan VK. Screening and GC-MS profiling of ethanolic extract of Tylophora pauciflora. BiomedInform. 2019;15(6):425-429.). Palmitic acid methyl ester was proven to be a hemolytic, 5-alpha-reductase inhibitor, and nematicide agent (Rajeswari, Murugan, Mohan, 2012Rajeswari G, Murugan M, Mohan VR. GC-MS analysis of bioactive components of Hugonia mystax L. (Linaceae). Res J Pharm Biol Chem Sci. 2012;3(4):301-308.). It decreases blood cholesterol and exhibits selective anti-inflammatory action by inhibiting the cyclooxygenase 2 enzyme (Belakhdar, Benjouad, Abdennebi, 2015Belakhdar G, Benjouad A, Abdennebi EH. Determination of some bioactive chemical constituents from Thesium humile Vahl. J Mater Environ Sci. 2015;6(10):2778-2783.). Phytol, a cyclic diterpenoid, was reported to have neuroprotective, antimicrobial, anti-inflammatory, and anti-diuretic activities (Kumar, Kumaravel, Lalitha, 2010Kumar P, Kumaravel S, Lalitha C. Screening of antioxidant activity, total phenolics and GC-MS study of Vitex negundo. Afr J Biomed Res. 2010;4(7):191-195.; Banjare et al., 2017Banjare, Jyotibala, Salunke, Megha, Indapurkar, Kavita, et al. Estimation of serum malondialdehyde as a marker of lipid peroxidation in medical students undergoing examination-induced psychological stress. J Sci Soc. 2017;44(3):137-139.). Phytol has been documented to demonstrate anti-tumor and antioxidant properties. Since phytol is a branching chain of unsaturated alcohol, its antioxidant properties can be attributed to the hydroxyl group present in molecules (Serafini et al., 2011Serafini MR, Santos RC, Guimarães AG, Dos Santos JP, da Conceicão Santos AD, Alves IA, et al. Morinda citrifolia Linn leaf extract possesses antioxidant activities and reduces nociceptive behavior and leukocyte migration. J Med Food. 2011;14(10):1159-1166.; Oyugi et al., 2011Oyugi DA, Ayorinde FO, Gugssa A, Allen A, Izevbigie EB, Eribo B, et al. Biological activity and mass spectrometric analysis of Vernonia amygdalina fractions. J Biosci Tech. 2011;2:287-304.). Squalene was reported to have antibacterial, immunostimulant, anti-tumor, cancer preventive, chemopreventive, lipoxygenase-inhibitor, antioxidant, pesticide, and diuretic activities (Rajeswari, Murugan, Mohan, 2012Rajeswari G, Murugan M, Mohan VR. GC-MS analysis of bioactive components of Hugonia mystax L. (Linaceae). Res J Pharm Biol Chem Sci. 2012;3(4):301-308.; Quesada et al., 2018Quesada CS, Biedma AL, Toledo E, Gaforio JJ. Squalene stimulates a key innate immune cell to foster wound healing and tissue repair. Evid Based Complement Alternat Med. 2018;9473094: 1-9.).

CONCLUSION

The qualitative preliminary phytochemical screening of Latania verschaffeltii Lem. leaves have demonstrated that they contain a diverse range of bioactive secondary metabolites, including phenolic acids, saponins, tannins, flavonoids, carbohydrates and/or glycosides, as well as unsaturated sterols and/or triterpenes. GC/MS analysis showed that the percentage of saturated fatty acids (83.82%) is higher than that of unsaturated ones (9.42%). Palmitic acid methyl ester was the major saturated fatty acid methyl ester (41.68%), while phytol (43.62%) and squalene (39.27%) represented the major terpenes. The presence of these valuable compounds in the leaves suggests the potential for medicinal applications of this palm. Consistent with the worldwide imperative to explore bioactive metabolites derived from natural origins, the plant currently under investigation can serve as a potential source of compounds with medicinal properties.

ACKNOWLEDGMENTS

We express our gratitude to Engineer Teres Labib (consultant of plant taxonomy at the Ministry of Agriculture and director of El-Orman Garden, Giza, Egypt) for the provision and identification of the plant.

REFERENCES

Audu SA, Mohammad I, Kaita HA. Phytochemical screening of the leaves of Lophira lanceolata (Ochanaceae). Life Sci. 2007;4(4):75-79.
Banjare, Jyotibala, Salunke, Megha, Indapurkar, Kavita, et al. Estimation of serum malondialdehyde as a marker of lipid peroxidation in medical students undergoing examination-induced psychological stress. J Sci Soc. 2017;44(3):137-139.
Basu S, Sengupta R, Zandi P. Arecaceae: The Majestic Family of Palms. 2014. Retrieved from http://www.eoearth.org/view/article/53dc075c0cf2541de6d02774
» http://www.eoearth.org/view/article/53dc075c0cf2541de6d02774
Belakhdar G, Benjouad A, Abdennebi EH. Determination of some bioactive chemical constituents from Thesium humile Vahl. J Mater Environ Sci. 2015;6(10):2778-2783.
Brinker AM, David S. Methods for the detection and quantitative determination of cyanide in plant materials. Phytochem Bull. 1989;21(2):24.‏
Christenhusz, Maarten JM, Byng JW. The number of known plants species in the world and its annual increase. Phytotaxa. 2016;261(3):201-217.
Dehgan B. Garden Plants Taxonomy: Volume 1: Ferns, Gymnosperms, and Angiosperms (Monocots). Springer Nature. 2023;173-603.
De Souza FG, De Araújo F, De Paulo FD, Zanotto AW, Neri-Numa IA, Pastore GM. Brazilian fruits of Arecaceae family: An overview of some representatives with promising food, therapeutic and industrial applications. Food Res Int. 2020;138:109-690.
Dransfield J, Uhl NW, Asmussen CB, Baker WJ, Harley MM, Lewis CE. Genera Palmarum - Evolution and Classification of Palms. Royal Botanic Gardens, Kew. England. 2008.
Evans WC. Trease and Evan›s Pharmacognosy, Edn 14, WB Saunders Company Ltd, London, Philadelphia, Toronto, Sydney, Tokyo. 1996, pp. 47-48.
Govaerts R, Dransfield J. World Checklist of Palms. The Board of Trustees of the Royal Botanic Gardens, Kew. England. 2005;1-223.
Gurib-Fakim A, Sewraj MD, Gueho J, Dulloo E. Medicinal plants of Rodrigues. Int J Pharmacogn. 1996;34(1):2-14.‏
Johnson AR, Davenport JB, Biochemistry and methodology of lipids. John Wiley & Sons, Inc, 1971.
Kamal AM, Ziada A, Soliman R, Selim M. Chemical Investigation of Lipoidal Matter of Ficus craterostoma. J Adv Pharm Res. 2017;1(3):150-154.
Kumar P, Kumaravel S, Lalitha C. Screening of antioxidant activity, total phenolics and GC-MS study of Vitex negundo. Afr J Biomed Res. 2010;4(7):191-195.
Kumar RS, Venkateshwar C, Samuel G, Rao SG. Phytochemical screening of some compounds from plant leaf extracts of Holoptelea integrifolia (Planch.) and Celestrus emarginata (Grah.) used by Gondu tribes at Adilabad District, Andhra Pradesh, India. IJSEI. 2013;2(8):65-70.
Mohammed MH, Fouad MA. Chemical and biological review on various classes of secondary metabolites and biological activities of Arecaceae (2021-2006). J Adv Biomed Pharm Sci. 2022;5(3):113-150.
Oyugi DA, Ayorinde FO, Gugssa A, Allen A, Izevbigie EB, Eribo B, et al. Biological activity and mass spectrometric analysis of Vernonia amygdalina fractions. J Biosci Tech. 2011;2:287-304.
Pandey A, Tripathi S. Concept of standardization, extraction and pre phytochemical screening strategies for herbal drug. J pharmacogn phytochem. 2014;2(5):115-119.
Quesada CS, Biedma AL, Toledo E, Gaforio JJ. Squalene stimulates a key innate immune cell to foster wound healing and tissue repair. Evid Based Complement Alternat Med. 2018;9473094: 1-9.
Rajeswari G, Murugan M, Mohan VR. GC-MS analysis of bioactive components of Hugonia mystax L. (Linaceae). Res J Pharm Biol Chem Sci. 2012;3(4):301-308.
Raaman N. Phytochemical Techniques. New India Publishing Agency, New Delhi, 2006, 19-24.
Serafini MR, Santos RC, Guimarães AG, Dos Santos JP, da Conceicão Santos AD, Alves IA, et al. Morinda citrifolia Linn leaf extract possesses antioxidant activities and reduces nociceptive behavior and leukocyte migration. J Med Food. 2011;14(10):1159-1166.
Silva GO, Abeysundara AT, Aponso MM. Extraction methods, qualitative and quantitative techniques for screening of phytochemicals from plants. Am J Essent Oil. Nat Prod. 2017;5(2):29-32.
Singh V, Kumar R. Study of Phytochemical Analysis and Antioxidant Activity of Allium sativum of Bundelkhand Region. IJLPR. 2017;3(6):1451-1458
Starlin T, Prabha PS, Thayakumar BKA, Gopalakrishnan VK. Screening and GC-MS profiling of ethanolic extract of Tylophora pauciflora. BiomedInform. 2019;15(6):425-429.
Tiwari P, Kumar B, Kaur M, Kaur G, Kaur H. Phytochemical screening and Extraction: A Review. Int pharm sci. 2011;1(1):98-106.
Trease GE, Evans WC. A Textbook of Pharmacognosy, 11th ed, Brailliar Tindall Ltd, London. 1989;45-50.
Wagner H, Baldt S, Zgainski EM. Plant Drug Analysis. Springer Verlag, Berlin/New York. 1984.

Publication Dates

Publication in this collection
26 Feb 2024
Date of issue
2024

History

Received
17 May 2023
Accepted
02 Oct 2023

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Audu SA, Mohammad I, Kaita HA. Phytochemical screening of the leaves of Lophira lanceolata (Ochanaceae). Life Sci. 2007;4(4):75-79.

[2] Banjare, Jyotibala, Salunke, Megha, Indapurkar, Kavita, et al. Estimation of serum malondialdehyde as a marker of lipid peroxidation in medical students undergoing examination-induced psychological stress. J Sci Soc. 2017;44(3):137-139.

[3] Basu S, Sengupta R, Zandi P. Arecaceae: The Majestic Family of Palms. 2014. Retrieved from http://www.eoearth.org/view/article/53dc075c0cf2541de6d02774
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Component name	Classification of compounds	Molecular Formula	Similarity %	RT (min)	Molecular ion peak (m/z)	PA (%)
Decanoic acid methyl ester	Saturated fatty acid	C₁₁H₂₂O₂	22.8	21.47	186	0.12
Dodecanoic acid methyl ester (Lauric acid methyl ester)	Saturated fatty acid methyl ester	C ₁₃ H ₂₆ O ₂	76.4	27.78	214	6.25
Tridecanoic acid methyl ester	Saturated fatty acid methyl ester	C₁₄H₂₈O₂	35.6	30.92	228	0.17
Methyl tetradecanoate	Saturated fatty acid methyl ester	C ₁₅ H ₃₀ O ₂	71.4	35.02	242	7.24
Pentadecanoic acid methyl ester	Saturated fatty acid methyl ester	C₁₆H₃₂O₂	68.9	39.51	256	0.75
11-Hexadecenoic acid methyl ester	Unsaturated fatty acid methyl ester	C₁₇H₃₂O₂	7.1	42.52	268	0.16
(Z)-9-Hexadecenoic acid methyl ester (Methyl palmitoleate)	Unsaturated fatty acid methyl ester	C₁₇H₃₂O₂	10.5	42.88	268	0.12
Hexadecanoic acid methyl ester (Palmitic acid methyl ester)	Saturated fatty acid methyl ester	C ₁₇ H ₃₄ O ₂	85.8	43.06	270	41.68
Hexadecanoic acid ethyl ester	Saturated fatty acid ethyl ester	C₁₈H₃₆O₂	63.4	45.01	284	0.10
(Z, Z)-9-Hexadecenoic acid, 9-octadecenyl ester	Unsaturated fatty acid 9-octadecenyl ester	C₃₄H₆₄O₂	5	45.47	504	0.13
Heptadecanoic acid methyl ester (Margaric acid methyl ester)	Saturated fatty acid methyl ester	C₁₈H₃₆O₂	57.1	45.92	284	2.00
(E, E)-9,12-Octadecadienoic acid methyl ester (Linolelaidic acid methyl ester)	Unsaturated fatty acid methyl ester	C₁₉H₃₄O₂	10.1	47.67	294	0.29
9,12-Octadecadienoic acid (Z, Z)-, methyl ester (Linoleic acid methyl ester)	Unsaturated fatty acid methyl ester	C₁₉H₃₄O₂	12.5	47.99	294	1.46
(E)-9-Octadecenoic acid methyl ester (Elaidic acid methyl ester)	Unsaturated fatty acid methyl ester	C ₁₉ H ₃₆ O ₂	10.1	48.26	296	2.90
8,11-Octadecadienoic acid methyl ester	Unsaturated fatty acid methyl ester	C₁₉H₃₄O₂	8.1	48.51	294	0.60
Octadecanoic acid methyl ester (Stearic acid methyl ester)	Saturated fatty acid methyl ester	C ₁₉ H ₃₈ O ₂	61.8	48.79	298	3.95
Linoleic acid ethyl ester	Unsaturated fatty acid ethyl ester	C₂₀H₃₆O₂	6.3	49.13	308	0.23
10,13-Eicosadienoic acid methyl ester	unsaturated fatty acid methyl ester	C₂₀H₃₆O₂	8.3	49.29	322	0.27
7,10-Octadecadienoic acid methyl ester	unsaturated fatty acid methyl ester	C₁₉H₃₄O₂	10.9	50.87	294	0.64
2-Furanoctanoic acid,5-hexyltetrahydro-methyl ester	Unsaturated carboxylic acid methyl ester	C₁₉H₃₆O₃	18.4	51.12	312	1.22
Docosanoic acid, 8,9-dihydroxy- methyl ester	Saturated fatty acid methyl ester	C₂₃H₄₆O₄	3.9	51.25	386	1.49
6,9,12,15-Docosatetraenoic acid methyl ester	unsaturated fatty acid methyl ester	C₂₃H₃₈O₂	5.8	51.64	346	1.40
Thiophene-2-acetic acid undecyl ester	saturated fatty acid undecyl ester	C ₁₇ H ₂₈ O ₂ S	79.6	60.98	296	18.73
Docosanoic acid methyl ester (Behenic acid methyl ester)	saturated fatty acid methyl ester	C₂₂H₄₄O₂	4.8	63.26	340	0.53
Tetracosanoic acid methyl ester (Methyl lignocerate)	saturated fatty acid methyl ester	C₂₅H₅₀O₂	10.8	70.54	382	0.81
Saturated fatty acids						83.82
Unsaturated fatty acids						9.42
Unidentified compounds						6.76

Component name	Classification of compounds	Molecular Formula	Similarity (%)	RT (min)	Molecular ion peak (m/z)	PA (%)
2-Propyl-1-pentanol	fatty alcohol	C ₈ H ₁₈ O	59.3	11.70	130	0.75
3-ethyl-5-(2-ethylbutyl)-Octadecane	hydrocarbon	C₂₆H₅₄	17.5	13.22	366	0.18
6-methyl -Octadecane	hydrocarbon	C₁₉H₄₀	17.9	14.91	368	0.15
Dodecane	hydrocarbon	C₁₂H₂₆	20.7	16.04	170	1.00
(E)-6,10-dimethyl-5,9-Undecadien-2-one	terpene	C₁₃H₂₂O	44.9	26.05	194	0.61
(1-butylhexyl)-Benzene.	hydrocarbon	C₁₆H₂₆	26.2	28.47	218	0.17
(1-propylheptyl)-Benzene	hydrocarbon	C₁₆H₂₆	14.2	28.75	218	0.15
17-Pentatriacontene	hydrocarbon	C₃₅H₇₀	6.7	29.85	490	0.12
(1-methylhexadecyl)-Benzene.	hydrocarbon	C₂₃H₄₀	22.5	30.59	316	0.18
(1-pentylhexyl)-Benzene	hydrocarbon	C₁₇H₂₈	38.4	31.57	232	0.21
(1-butyloctyl)-Benzene	hydrocarbon	C₁₈H₃₀	67.3	31.70	246	0.47
(1-propylheptadecyl)-Benzene	hydrocarbon	C₂₆H₄₆	55	32.12	358	0.38
(1-ethyldecyl)-Benzene	hydrocarbon	C₁₈H₃₀	58	33.02	246	0.40
2-phenyl-Pentadecane	hydrocarbon	C₂₁H₃₆	63.4	34.62	288	0.45
3,7,11-trimethyl-1-Dodecanol	fatty alcohol	C₁₅H₃₂O	12.7	35.33	228	0.21
(1-hexyltetradecyl)-Benzene	hydrocarbon	C₂₆H₄₆	75.6	35.68	358	0.38
(1-propylnonyl)-Benzene	hydrocarbon	C₁₈H₃₀	82.6	35.94	246	0.37
(1-methylnonadecyl)-Benzene	hydrocarbon	C₂₆H₄₆	60.7	39.27	358	0.43
13-phenyl-Pentacosane	hydrocarbon	C₃₁H₅₆	20.9	39.95	428	0.32
(1-butylnonyl)-Benzene	hydrocarbon	C₁₉H₃₂	15.3	40.23	260	0.15
2-Pentadecanone, 6,10,14-trimethy	terpene	C ₁₈ H ₃₆ O	86.2	40.40	268	2.33
3-acetoxy-7,8-Epoxylanostan-11-ol	Sterol	C₃₂H₅₄O₄	8.8	45.01	502	0.15
Phytol	terpene	C ₂₀ H ₄₀ O	76.1	48.58	296	43.62
Ethyl iso-allocholate	Sterol	C₂₆H₄₄O₅	31.2	51.95	436	0.10
cyclic 1,2-ethanediyl aetal, (5á)-cholestan-3-one	Sterol	C ₂₉ H ₅₀ O ₂	10.9	58.09	430	1.20
Lycopene	terpene	C₄₀H₅₆	10.3	67.51	536	0.14
(3á,22E)-Ergosta-5,22-dien-3-ol, acetate	Sterol	C₃₀H₄₈O₂	12.6	72.33	440	0.73
Squalene	terpene	C ₃₀ H ₅₀	39.6	75.78	410	39.27
Total hydrocarbons						5.66
Fatty alcohols			0.96
Total terpenes			85.97
Total sterols			2.18
Total identified			94.77
Unidentified compounds			5.23

Brasil

Brasil

Phytochemical Screening and chemical investigation of lipoidal matter of the leaves of Latania verschaffeltii Lem. Family Arecaceae cultivated in Egypt

Abstract

INTRODUCTION

MATERIAL AND METHODS

Plant Material

Chemicals

Apparatus

Methods

Preparation of Extract for Phytochemical Screening

Test for Sterols and Triterpenoids

Test for Saponins

Test for Tannins

Test for Flavonoids

Test for Phenolic Compounds

Test for Carbohydrates and/or Glycosides

Test for Cardenolides

Test for Alkaloid

Test for Cyanogenic Glycoside

Test for Iridoids

Preparation of Lipoidal Matter

Preparation of Unsaponifiable Matter

Preparation of Saponifiable Matter

Preparation of Fatty Acid Methyl Esters

Gas Chromatography-Mass Spectrometry Technique (Gc-Ms)

Investigation of Lipoidal Matter

RESULTS

Preliminary Phytochemical Screening

Gc-Ms Analysis of Fatty Acid Methyl Esters and Unsaponifiable Matter

DISCUSSION

CONCLUSION

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History