Phytochemistry and Biological Activities of Hibiscus sabdariffa Leaf Extract: A Comprehensive Analysis and In Silico Approaches

https://doi.org/10.22146/ijc.113325

Mohammed Babiker Suliman(1*), Muna Ali Othman(2), Ghandoura Musa Ahlaal(3), Salawa Ibrahim Eltawaty(4), Sanadelaslam El-Hddad(5)

(1) Department of Pharmaceutical Chemistry, Faculty of Pharmacy, Omar Al-Mukhtar University, Al-Bayda 919, Libya
(2) Department of Pharmaceutical Chemistry, Faculty of Pharmacy, Omar Al-Mukhtar University, Al-Bayda 919, Libya
(3) Department of Pharmaceutical Chemistry, Faculty of Pharmacy, Omar Al-Mukhtar University, Al-Bayda 919, Libya
(4) Department of Biomedical Science, Faculty of Pharmacy, Omar Al-Mukhtar University, Al-Bayda 919, Libya
(5) Department of Pharmaceutical Chemistry, Faculty of Pharmacy, Omar Al-Mukhtar University, Al-Bayda 919, Libya
(*) Corresponding Author

Abstract


Gas chromatography-mass spectrometry (GC-MS) and liquid chromatography-mass spectrometry (LC-MS) methods were used to simultaneously isolate and determine phytochemicals in the Hibiscus sabdariffa leaf extract. GC-MS analysis revealed the presence of oleic acid (52.05%), hexadecenoic acid (19.78%), and docosenoic acid (7.62%). LC-MS analysis identified six flavonoids and four phenolic acids. Quantitative analysis of some identified phenolic compounds (mg/g in dried leaves) showed the presence of quercetin-rutinoside (11.87), neochlorogenic acid (5.64), and quercetin (4.75). The total phenolic content of the extract, determined using the Folin-Ciocalteu assay, was 22.2 mg GAE/g. The in vitro antioxidant activity was measured by the ABTS radical cation decolorization assay (135.7 µmol trolox/g). The antibacterial activity was evaluated using the disc diffusion method against three Gram-positive bacteria and three Gram-negative bacteria. The leaves extract demonstrated antibacterial activity against all tested bacteria, with inhibition diameters ranging from 8 to 28 mm. The binding energies for ciprofloxacin, levofloxacin, and quercetin, ranging from −5.2 to −5.8, suggest strong interactions with the B subunit of DNA gyrase and the ParE subunit of topoisomerase IV. The study indicates that H. sabdariffa leaf extract has potent antioxidant and antibacterial properties. Additionally, quercetin from H. sabdariffa shows antibacterial potential against DNA gyrase and topoisomerase.


Keywords


Hibiscus sabdariffa; quercetin; antioxidant activity; antibacterial activity; molecular docking

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References

[1] Huang, H.C., Chang, W.T., Wu, Y., Yang, B.C., Xu, M.R., Lin, M.K., Chen, H.J., Cheng, J.H., and Lee, M.S., 2022, Phytochemicals levels and biological activities in Hibiscus sabdariffa L. were enhanced using microbial fermentation, Ind. Crops Prod., 176, 114408.

[2] Mohamed, B.B., Sulaiman, A.A., and Dahab, A.A., 2012, Roselle (Hibiscus sabdariffa L.) in Sudan, cultivation and their uses, Bull. Environ., Pharmacol. Life Sci., 1 (6), 48–54.

[3] Singh, M., Thrimawithana, T., Shukla, R., and Adhikari, B., 2021, Extraction and characterization of polyphenolic compounds and potassium hydroxycitrate from Hibiscus sabdariffa, Future Foods, 4, 100087.

[4] Mahadevan, N., Shivali, S., and Kamboj, P., 2021, Hibiscus sabdariffa Linn.–An overview, Nat. Prod. Radiance, 8 (1), 77–83.

[5] Riaz, G., and Chopra, R., 2018, A review on phytochemistry and therapeutic uses of Hibiscus sabdariffa L, Biomed. Pharmacother., 102, 575–586.

[6] Nazir, H., Baig, M.O., and Anwer, S., 2026, Pharmacognostic and therapeutic insights into Hibiscus sabdariffa L. and its cultivation in Qarshi botanical garden, GSC Biol. Pharm. Sci., 34 (1), 125–135.

[7] Pooja, G., Shweta, S., and Patel, P., 2025, Oxidative stress and free radicals in disease pathogenesis: A review, Discover Med., 2 (1),104.

[8] Ajay, M., Chai, H.J., Mustafa, A.M., Gilani, A.H., and Mustafa, M.R., 2007, Mechanisms of the anti-hypertensive effect of Hibiscus sabdariffa L. calyces, J. Ethnopharmacol., 109 (3), 388–393.

[9] Cira-Chávez, L.A., Gassós-Ortega, L.E., Nuñez-Vega, J., Camelo-Méndez, G.A., Cañedo-Urias, R., Blanco-Rios, A.K., and Estrada-Alvarado, M.I., 2025, Green extraction or roselle (Hibiscus sabdariffa L) calyces: An enzymatic assisted extraction to increase bioactive compounds and antioxidant capacity, Appl. Food Res., 5 (2), 101149.

[10] Tan, J., Han, Y., Han, B., Qi, X., Cai, X., Ge, S., and Xue, H., 2022, Extraction and purification of anthocyanins: A review, J. Agric. Food Res., 8, 100306.

[11] Kao, E.S., Yang, M.Y., Hung, C.H., Huang, C.N., and Wang, C.J., 2016, Polyphenolic extract from Hibiscus sabdariffa reduces body fat by inhibiting hepatic lipogenesis and preadipocyte adipogenesis, Food Funct., 7 (1), 171–182.

[12] Juliani, H.R., Welch, C.R., Wu, Q., Diouf, B., Malainy, D., and Simon, J.E., 2009, Chemistry and quality of Hibiscus (Hibiscus sabdariffa) for developing the natural-product industry in Senegal, J. Food Sci., 74 (2), S113–S121.

[13] Bule, M., Albelbeisi, A.H., Nikfar, S., Amini, M., and Abdollahi, M., 2020, The antidiabetic and antilipidemic effects of Hibiscus sabdariffa: A systematic review and meta-analysis of randomized clinical trials, Food Res. Int., 130, 108980.

[14] Chen, J.H., Wang, C.J., Wang, C.P., Sheu, J.Y., Lin, C.L., and Lin, H.H., 2013, Hibiscus sabdariffa leaf polyphenolic extract inhibits LDL oxidation and foam cell formation involving up-regulation of LXRα/ABCA1 pathway, Food Chem., 141 (1), 397–406.

[15] Tsai, M.C., Chen, C.C., Tseng, T.H., Chang, Y.C., Lin, Y.J., Tsai, I.N., Wang, C.C., and Wang, C.J., 2023, Hibiscus anthocyanins extracts induce apoptosis by activating AMP-activated protein kinase in human colorectal cancer cells, Nutrients, 15 (18), 3972.

[16] Krishnamurthy, Z.M.R., Ali, I.M., Dayoob, M., Hussein, S.S., and Khan, N.A.K., 2020, Hibiscus sabdariffa extract as anti-aging supplement through its antioxidant and anti-obesity activities, Biomed. Res. Ther., 7 (1), 3572–3578.

[17] Zhen, J., Villani, T.S., Guo, Y., Qi, Y., Chin, K., Pan, M.H., Ho, C.T., Simon, J.E., and Wu, Q., 2016, Phytochemistry, antioxidant capacity, total phenolic content and anti-inflammatory activity of Hibiscus sabdariffa leaves, Food Chem., 190, 673–680.

[18] Hamrita, B., Emira, N., Papetti, A., Badraoui, R., Bouslama, L., Ben Tekfa, M.I., Hamdi, A., Patel, M., Elasbali, A.M., Adnan, M., Ashraf, S.A., and Snoussi, M., 2022, Phytochemical analysis, antioxidant, antimicrobial, and anti-swarming properties of Hibiscus sabdariffa L. calyx extracts: In vitro and in silico modelling approaches, Evidence-Based Complementary Altern. Med., 2022 (1), 1252672.

[19] Pala, F.S., and Gürkan, H., 2008, The role of free radicals in ethiopathogenesis of diseases, Adv. Mol. Biol., 1, 1–9.

[20] Song, X., Wang, Y., and Gao, L., 2020, Mechanism of antioxidant properties of quercetin and quercetin-DNA complex, J. Mol. Model., 26 (6), 133.

[21] Boo, H.J., Yoon, D., Choi, Y., Kim, Y., Cha, J.S., and Yoo, J., 2025, Quercetin: Molecular insights into its biological roles, Biomolecules, 15 (3), 313.

[22] El-Tawaty, S.I., Suliman, M.B, El-Hadad, S., Emgwer, H.K., and Shaieb, F.M., 2025, Phytochemical screening, GC-MS analysis, and antibacterial activity of Dittrichia graveolens (L.) Greuter, Trop. J. Nat. Prod. Res., 9 (4), 1476–1481.

[23] Suliman, M.B., and El-Hddad, S., 2023, Characterization of chemical constituents of Adansonia digitata L. using GC-MS and LC-MS/QTOF and theirin vitro anti-cervical cancer effects, Trop. J. Nat. Prod. Res., 7 (6), 3191–3197.

[24] Kalpoutzakis, E., Chatzimitakos, T., Athanasiadis, V., Mitakou, S., Aligiannis, N., Bozinou, E., Gortzi, O., Skaltsounis, L.A., and Lalas, S.I., 2023, Determination of the total phenolics content and antioxidant activity of extracts from parts of plants from the Greek Island of Crete, Plants, 12 (5), 1092.

[25] Puspitasari, A.D., Ulfah, M., Hartati, I., Vifta, R.L., Hermawan, F., Ekasari, M., and Marlina, L.A., 2025, Free radical scavenging activity of chlorochalcones: An integrated computational and experimental study, Indones. J. Chem., 25 (5), 1559–1577.

[26] Eltawaty, S.I.A., Suliman, M.B., and El-Hddad, S., 2023, Chemical composition, and antibacterial and antifungal activities of crude extracts from Pistacia lentiscus L. fruit, Trop. J. Nat. Prod. Res., 7 (9), 4049–4054.

[27] Abdulhamid, A., Awad, T.A., Ahmed, A.E., Koua, F.H.M., and Ismail, A.M., 2021, Acetyleugenol from Acacia nilotica (L.) exhibits a strong antibacterial activity and its phenyl and indole analogues show a promising anti-TB potential targeting PknE/B protein kinases, Microbiol. Res., 12 (1), 1–15.

[28] Hashem, A.S., Ramadan, M.M., Abdel-Hady, A.A., Sut, S., Maggi, F., and Dall’Acqua, S., 2020, Pimpinella anisum essential oil nanoemulsion toxicity against Tribolium castaneum? Shedding light on its interactions with aspartate aminotransferase and alanine aminotransferase by molecular docking, Molecules, 25 (20), 4841.

[29] Okore, G.J., Oguzie, E.E., Ogukwe, C.E., and Akalezi, C.O., 2021, GC-MS analysis of phytochemicals from the extract of Hibiscus sabdariffa grown in northern Nigeria, J. Chem. Soc. Niger., 46 (2), 0417–0423.

[30] Lopez-Huertas, E., 2014, Health effects of oleic acid and long chain omega-3 fatty acids (EPA and DHA) enriched milks. A review of intervention studies, Pharmacol. Res., 61 (3), 200–207.

[31] Petersen, K.S., Maki, K.C., Calder, P.C., Belury, M.A., Messina, M., Kirkpatrick, C.F., and Harris, W.S., 2024, Perspective on the health effects of unsaturated fatty acids and commonly consumed plant oils high in unsaturated fat, Br. J. Nutr., 132 (8), 1039–1050.

[32] Rodríguez-Medina, I.C., Beltrán-Debón, R., Molina, V.M., Alonso-Villaverde, C., Joven, J., Menéndez, J.A., Sequra-Carretero, A., and Fernández-Gutiérrez, A., 2009, Direct characterization of aqueous extract of Hibiscus sabdariffa using HPLC with diode array detection coupled to ESI and ion trap MS, J. Sep. Sci., 32 (20), 3441–3448.

[33] Saoudi, S., Khennouf, S., Mayouf, N., Amira, S., Dahamna, S., and Hosni, K., 2020, Phytochemical screening and in vivo and in vitro evaluation antioxidant capacity of Fargaria ananassa, Prunus armeniaca and Prunus persica fruits growing in Algeria, Prog. Nutr., 22 (1), 236–252.

[34] Savsani, H., Srivastava, A., Gupta, S., and Patel, K., 2020, Strengthening antioxidant defense & cardio protection by Piper betle: An in-vitro study, Heliyon, 6 (1), e03041.

[35] Adebiyi, O.E., Olayemi, F.O., Ning-Hua, T., and Guang-Zhi, Z., 2017, In vitro antioxidant activity, total phenolic and flavonoid contents of ethanol extract of stem and leaf of Grewia carpinifolia, Beni-Suef Univ. J. Basic Appl. Sci., 6 (1), 10–14.

[36] Mohammed, B.S., Sanadelaslam, E., Salwa, I.A.E., and Ahmed, S.J., 2024, HPLC-PDA-MS identification of phenolic profile and in vitro antioxidant activity of Adansonia digitata L. leaves from Sudan, Morrocan J. Chem., 12 (1), 221–232.

[37] Ghaly, H.K.F., Younis, F.A.A.Y., Soliman, A.M., and El-Sabbagh, S.M., 2025, Phytochemical and antibacterial properties of calyces Hibiscus sabdariffa L.: An in vitro and in silico multitarget-mediated antibacterial study, BMC Complementary Med. Ther., 25 (1), 62.

[38] Elagdi, C., Bouaouda, K., Rahhal, R., Hsaine, M., Badri, W., Fougrach, H., and EL Hajjouji, H., 2023, Phenolic compounds, antioxidant and antibacterial activities of the methanolic extracts of Euphorbia resinifera and Euphorbia echinus, Sci. Afr., 21, e01779.

[39] Koohsari, H., Ghaemi, E.A., Sheshpoli, M.S., Jahedi, M., and Zahiri, M., 2015, The investigation of antibacterial activity of selected native plants from North of Iran, J. Med. Life, 8 (2), 38.

[40] Peng, Y., Liu, F., and Ye, J., 2005, Determination of phenolic acids and flavones in Lonicera japonica Thunb. by capillary electrophoresis with electrochemical detection, Electroanalysis, 17 (4), 356–362.

[41] Awatif, A.M., and Suliman, M.B., 2018, Antibacterial activity and fatty acid composition of Sudanese castor bean (Ricinus communis L) seed oil, Arabian J. Med. Aromat. Plants, 4 (1), 1–8.

[42] Jonville-Béra, A.P., Largeau, B., di Meglio, F., and Pariente, A., 2025, The safety profile of fluoroquinolones, Infect. Dis. Now, 55 (4), 105064.

[43] Usmani, J., Kausar, H., Akbar, S., Sartaj, A., Mir, S.R., Hassan, M.J., Sharma, M., Ahmad, R., Rashid, S., and Ansari, M.N., 2023, Molecular docking of bacterial protein modulators and pharmacotherapeutics of Carica papaya leaves as a promising therapy for sepsis: Synchronising in silico and in vitro studies, Molecules, 28 (2), 574.

[44] Majumdar, G., and Mandal, S., 2024, Evaluation of broad-spectrum antibacterial efficacy of quercetin by molecular docking, molecular dynamics simulation and in vitro studies, Chem. Phys. Impact, 8, 100501.



DOI: https://doi.org/10.22146/ijc.113325

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