EFFECT OF GALLIC ACID ON LIPID PROFILE AND ANTIOXIDANT STATUS IN CADMIUM CHLORIDE TREATED RATS

Authors

DOI:

https://doi.org/10.36103/ijas.v54i3.1755

Keywords:

GSH, MDA, Dyslipidemia, Lipoproteins, Oxidative stress.

Abstract

This study was aimed to explore the role of gallic acid (GA) in ameliorating in reducing adverse effects of cadmium chloride (CdCl2) on antioxidant status and lipid profile in adult male rats. Twenty-eight (28) adult male rats were divided randomly into four equal groups; they were daily handled for 30 days, as follows: control group (C), received tap water only. (G1), received 100ppm of CdCl2 in drinking tap water, animals in proceeding groups were given in addition to CdCl2 in drinking water the following: intraperitoneal injection of GA 100 mg/kg. daily (G2 group) and the combination of GA and CdCl2 were given to rats in group (G3) in the same pattern.  At the end of the experiment, fasting blood samples were collected and serum was isolated for measuring of antioxidant status and lipid profile. The results showed that administration CdCl2 (G1 group) caused a case of dyslipidemia illustrated by significant elevation in serum cholesterol concentration in lipoprotein low density lipoprotein-cholesterol (LDL-C) and very low-density lipoprotein-cholesterol (VLDL-C), total cholesterol (TC), triglyceride (TAG) and non-HDL-C accompanied with significant decrease in cholesterol of high density lipoprotein (HDL-C) concentrations. The results also revealed a significant elevation in lipid indices including, coronary risk index (CRI), and cardiovascular risk index (CVRI) in CdCl2 exposed rats. While significant elevation in malondialdehyde (MDA) and reduction in (GSH) concentrations observed in the same group comparing to gallic acid and control group, indicating a case of oxidative stress. The current results also recorded that intraperitoneal injection of GA against CdCl2 caused amelioration of all previously estimated parameters.

References

Abarikwu, S.O., G. Simple and C.S. Onuoha. 2020. Morphometric evaluation of the seminiferous tubules and the antioxidant protective effects of gallic acid and quercetin in the testis and liver of butyl phthalate treated Rats. Indian J. Clin. Biochem., 35(1):20-31.

Abbott, R.D., P.W. Wilson, W.B. Kannel, and W.P. Castelli. 1988. High density lipoprotein cholesterol, total cholesterol screening and myocardial infarction. The Framingham Study. Arteriosclerosis. 8: 207–211

Abdeen, A., O.A. Abou-Zaid, H.A. Abdel-Maksoud, M. Aboubakr, A. Abdelkader, A. Abdelnaby, A.I. Abo-Ahmed, A. El-Mleeh, O. Mostafa, M. Abdel-Daim and L. Aleya. 2019. Cadmium overload modulates piroxicam-regulated oxidative damage and apoptotic pathways, Environ. Sci. Pollut. Res., 26(24): 25167–25177.

Abeysekera, W. and S.P.G. Arachchige. 2017. Bark extracts of ceylon cinnamon pcossess antilipidemic activities and bind bile acids in vitro. Evid Based Complement Alternat Med., 1-10.

Aja, P.M., E.U. Ekpono, J.N. Awoke, A.C. Famurewa, F.I. Izekwe, E.J. Okoro, C.F. Okorie, C.L. Orji, F. Nwite, B.A. Ale, A.F. Aku, I.O. Igwenyi, B.U. Nwali, O.U. Orji, O.G. G.R. Ani, Ozoemena and G.C. Anizoba. 2020. Hesperidin ameliorates hepatic dysfunction and dyslipidemia in male Wistar rats exposed to cadmium chloride. Toxicol. Rep., 7: 1331–1338

Alladi, S., A. Khada and M. Shanmugan. 1989. Induction of hypercholesterolemia by simple soil protein with acetate generating amino acid. Nutr. Rep. Int., 40: 893–894

Branca, J., C. Fiorillo, D. Carrino, F. Paternostro, N.Taddei, M. Gulisano, A. Pacini and M. Becatti. 2020. Cadmium induced oxidative Stress: Focus on the central nervous system. Antioxidants. 9(6): 492

Burtis, C.A. and E.R. Ashwood. 1999. Tietz Textbook of Clinical Chemistry, 3th edi. Clinical Chemistry. 45(6): 913–914

Darwish, W.S., Z. Chen, Y.Li, Y. Wu, H. Chiba and S.P. Hui. 2020. Identification of cadmium-produced lipid hydroperoxides, transcriptomic changes in antioxidant enzymes, xenobiotic transporters, and pro-inflammatory markers in human breast cancer cells (MCF7) and protection with fat-soluble vitamins. Environ. Sci. Pollut. Res., 27: 1978–1990

Diab, K.A., N.E. Ibrahim, M.A. Fahmy, E.M. Hassan and E.A. Omara. 2020. Inhibitory activity of flaxseed oil against CdCl2 induced liver and kidney damage: histopathology, genotoxicity, and gene expression study. Toxicol. Rep., 7: 1127–1137

El-Habit, O. and A.E. AbdelMoneim. 2014. Testing the genotoxicity, cytotoxicity, and oxidative stress of cadmium and nickel and their additive effect in male mice. Biol. Trace. Elem. Res., 159 (1–3): 364–372

Friedewald, W.T., R.I. Levy and D.S. Fredrickson. 1972. Estimation of the concentration of low-density lipoprotein cholesterol in plasma, without use of the preparative ultracentrifuge. Clin. Chem., 18(6):499-502.

Gabr, S.A., A.H. Alghadir and G.A. Ghoniem. 2019. Biological activities of ginger against cadmium-induced renal toxicity. Saudi J. Biol. Sci., 26(2):382-389.

Gao, J., H. Jiangxia, H. Dongyi and Y. Xiao. 2019. A Role of gallic acid in oxidative damage diseases: A Comprehensive Review. Natural Product Communications, 1-9

Gasevic, D., J. Frohlich, G.B. Mancini and S.A. Lear. 2014. Clinical usefulness of lipid ratios to identify men and women with metabolic syndrome: A cross-sectional study. Lipids Heal. Dis., 13: 159

Huang, D., W. Chang, J. Wu, R. Shih and S. Shen. 2016. Gallic acid ameliorates hyperglycemia and improves hepatic carbohydrate metabolism in rats fed a high-fructose diet. Nutr Res., 36(2): 150-60

Jeon, M., N. Rahman and Y.S. Kim. 2016. Wnt/β-catenin signaling plays a distinct role in methyl gallate-mediated inhibition of adipogenesis. Biochem. Biophys. Res. Commun., 479(1): 22-7.

Júnior, J.E.G.P., P.Z. Moraes, M.D. Rodriguez, M.R. Sim˜oes, F. Cibin, S. Pinton, F. B. Junior, F.M. Peçanha, D.V. Vassallo, M. Miguel and G.A. Wiggers. 2020. Cadmium exposure activates NADPH oxidase, renin–angiotensin system and cyclooxygenase 2 pathways in arteries, inducing hypertension and vascular damage. Toxicol. Lett., 333: 80–89

Kahkeshani, N., F. Farzaei, M. Fotouhi, S.S. Alavi, R. Bahramsoltani, R. Naseri, S. Momtaz, Z. Abbasabadi, R. Rahimi, M.H. Farzaei and A. Bishayee. 2018. Pharmacological effects of gallic acid in health and diseases: a mechanistic review. Iran J. Basic Med. Sci., 22(3): 225-237

Karimi-Khouzani, O., A. Sharifi and A. Jafari. 2018. A systematic review of the potential gallic acid effective in liver oxidative stress in Rats. J. Med. Res., 4(1): 5-12

López-Romero, J., M. Valenzuela-Melendres, V.K. Juneja, J. García-Dávila, J.P. Camou, A. Peña-Ramos and H. González-Ríos. 2018. Effects and interactions of gallic acid, eugenol and temperature on thermal inactivation of Salmonella spp. in ground chicken. Food Res. Int., 103: 289-294

Lu, Z., G., G. Nie, P.S. Belton, H. Tang and B. Zhao. 2006. Structure-activity relationship analysis of antioxidant ability and neuroprotective effect of gallic acid derivatives. Neurochem Int., 48:263–274

Maruszewska, A. and J. Tarasiuk. 2019. Antitumor effects of selected plant polyphenols, gallic acid and ellagic acid, on sensitive and multidrug-resistant leukemia HL60 cells. Phytother Res., 33(4):1208-1221

Matovi´c, V., A. Buha, D. Duki´c-´C osi´c and Z. Bulat. 2015. Insight into the oxidative stress induced by lead and/or cadmium in blood, liver and kidneys. Food Chem. Toxicol., 78:130–140.

Mehraban, Z., M.G.H. Novin, M. Golmohammadi, M. Sagha, S. Ziai, M. Abdollhifar and H. Nazarian. 2020. Protective effect of gallic acid on testicular tissue, sperm parameters, and DNA fragmentation against toxicity induced by cyclophosphamide in adult NMRI mice. Urol J., 17(1):78-85

Mezynska, M., M. Brzóska, J. Rogalska and B. Piłat-Marcinkiewicz. 2018. Extract from Aronia melanocarpa L. berries prevents cadmium-induced oxidative stress in the liver: A Study in a rat model of low-level and moderate lifetime human exposure to this toxic metal. Nutrients, 11: 21

Mouro, V.G.S., V.A. Siman, J. da Silva, F.C.R. Dias, E.M. Damasceno, M.D.C. Cupertino, F.C.S.A. de Melo and S.L.P. da Matta. 2020. Cadmium-induced testicular toxicity in mice: subacute and subchronic route-dependent effects. Biol. Trace Elem. Res., 193:466–482

Naka, K.S., L.C.S. Mendes, T.K.L. de Queiroz, B.N.S. Costa, I.M. de Jesus, M. C. Cˆamara and M.O. Lima. 2020. A comparative study of cadmium levels in blood from exposed populations in an industrial area of the Amazon. Sci. Total Environ., 698:134309.

Nam, S.H., J. Park, W. Jun, D. Kim, J.A. Ko, A.M. Abd El-Aty, J.Y. Choi, D.I. Kim and K.Y. Yang. 2017. Transglycosylation of gallic acid by using leuconostoc glucansucrase and its characterization as a functional cosmetic agent. AMB Express, 7(1):224.

Nemmiche, S. (2017). Oxidative signaling response to cadmium Exposure. Toxicol. Sci., 156:4–10.

Ojeaburu, S. and K. Oriakhi. 2021. Hepatoprotective, antioxidant and, anti-inflammatory potentials of gallic acid in carbon tetrachloride-induced hepatic damage in Wistar rats. Toxicol. Rep., 8:177-185

Oladele, J.O, O.O. Adewale, O.I. Oyewole, M.O. Salami, G. Owoade and O.M. Oyeleke . 2020. Annona muricata protects against cadmium-mediated oxidative damage in the brain and liver of rats. Acta Facultatis Medicae Naissensis, 37(3):252-260

Punithavathi, V.R., S.M.P. Prince, M.R. Kumar and C.J. Selvakumari. 2011. Anti-hyperglycemic, anti-lipid peroxidative and antioxidant effects of gallic acid on streptozotocin induced diabetic Wistar rats. Eur. J. Pharmacol., 650: 465–471

Rajan, V. K. and K. Muraleedharan. 2017. A computational investigation on the structure, global parameters and antioxidant capacity of a polyphenol, gallic acid. Food Chem., 220: 93-99

Samarghandian, S., M. MAzimi-Nezhad, M.M. Shabestari, F.J. Azad, T. Farkhondeh and F. Bafandeh. 2015. Effect of chronic exposure to cadmium on serum lipid, lipoprotein and oxidative stress indices in male rats. Interdiscip Toxicol., 8: 151–154

Setayesh, T., A. Nersesyan, M. Mišík, R. Noorizadeh, E. Haslinger, T. Javaheri, E. Lang, M. Grusch, W. Huber, A. Haslberger and S. Knasmüller. 2019. Gallic acid, a common dietary phenolic protects against high fat diet induced DNA damage. Eur. J. Nutr., 58(6): 2315–2326

Snedecor, G.W. and W.G. Cochran. 1973. Statistical Methods. 6th ed. The Iowa State University Press. 238-248

Tchounwou, P.B., C.G. Yedjou, A.K. Patlolla and D.J. Sutton. 2014. Heavy metal toxicity and the environment, Experientia Suppl., 101: 133–164

Vega, G.L., C.E. Barlow, S.M. Grundy, D. Leonard and L.F. DeFina. 2014. Triglyceride-to high-density- lipoprotein-cholesterol ratio is an index of heart disease mortality and of incidence of type 2 diabetes mellitus in men. J. Investig. Med., 62: 345–349

Wu, S. and L. Tian. 2018. A new flavone glucoside together with known ellagitannins and flavones with anti-diabetic and anti-obesity activities from the flowers of pomegranate (Punica granatum). Nat. Prod. Res., 33(2):252-257.

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Published

2023-06-25

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Vol. 54 No. 3 (2023)

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How to Cite

S. Jaffer Ramadhan, K. Khadim Khudair, & B. Najim Al-Okaily. (2023). EFFECT OF GALLIC ACID ON LIPID PROFILE AND ANTIOXIDANT STATUS IN CADMIUM CHLORIDE TREATED RATS. IRAQI JOURNAL OF AGRICULTURAL SCIENCES, 54(3), 735-740. https://doi.org/10.36103/ijas.v54i3.1755
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