EC Pharmacology and Toxicology

Research Article Volume 11 Issue 2 - 2023

Mitigation of Experimentally-Induced Testicular Toxicity by Corchorus olitorius Leaves

AI Airaodion1*, CL Uche2, EO Ezirim3, OAI Otuka4, IO Abali5, MU Nwobodo6, PI Ejikem7, UP Okite8 and K Chikezie9

1Department of Biochemistry, Federal University of Technology, Owerri, Imo State, Nigeria
2Department of Haematology, Abia State University, Uturu, Nigeria
3Department of Obstetrics and Gynecology, Abia State University, Uturu, Nigeria
4Department of Surgery, Abia State University, Teaching Hospital, Aba, Nigeria
5Department of Surgery, Abia State University, Uturu, Nigeria
6Department of Internal Medicine, University of Port-Harcourt Teaching Hospital, Rivers state, Nigeria
7Department of Community Medicine, Abia State University Teaching Hospital, Aba, Nigeria
8Department of Haematology and Blood Transfusion, University of Port Harcourt, Nigeria
9Department of Haematology, Federal Medical Centre, Umuahia, Abia State, Nigeria

*Corresponding Author: AI Airaodion, Department of Biochemistry, Federal University of Technology, Owerri, Imo State, Nigeria.
Received: December 19, 2022; Published: January 05, 2023



Background: In order to learn more about the extent to which Corchorus olitorius (C. olitorius) leaves may affect experimentally-induced testicular toxicity in light of the fact that the literature in this area is quite scanty, this study investigated the mitigative effects of C. olitorius leaf extract against infertility induced by potassium bromate on male Wistar rats.

Methodology: C. olitorius was extracted with soxhlet extractor with ethanol as the solvent. Twenty-four adult male Wistar rats were acclimatized under laboratory conditions and were randomly grouped into A, B, C and D. Group A was given distilled water orally. Animals in groups B, C and D were administered 100 mg/kg body weight of potassium bromate, but groups C and D were also treated with 100 and 200 mg/kg body weight of C. olitorius respectively. Both potassium bromate and C. olitorius were freshly prepared on daily basis and administered to rats by oral gavage. After 28 days of treatment, the animals were sacrificed under mild diethyl ether anaesthetization 24 hours after cessation of last treatment. The testes were removed homogenized in the ice cold 0.25M sucrose solution. The homogenates were centrifuged at 5000 ×g for 10 minutes in a refrigerated centrifuge. The supernatant was collected and stored frozen for further analysis. The parameters were measured using standard methods.

Results: When compared to animals in the control group, animals intoxicated with KBrO3 had lower testicular levels of total cholesterol, total protein, glycogen, sialic acid, GSH, as well as ALP, SOD, and CAT activity. Additionally, it was shown that as compared to the animals in the control group, KBrO3 boosted the testicular MDA and ACP's activity. However, C. olitorius treatment of intoxicated rats reduced these alterations in a dose-dependent manner.

Conclusion: Potassium bromate induced testicular toxicity by unhinging the biochemical indices and increasing lipid peroxidation in the testes of exposed animals. This effect was mitigated by coadministration with C. olitorius leaf extract. Therefore, it is advised that clinical trials involving human volunteers be conducted to further explore these findings.

Keywords: Corchorus olitorius; Oxidative Stress; Potassium Bromate; Testicular Toxicity

  1. Airaodion AI., et al. “Consumption of coconut (Cocos nucifera) water improved fertility parameters in male Wistar rats”. Asian Journal of Pregnancy and Childbirth 2.3 (2019): 1-7.
  2. Agarwal A., et al. “A unique view on male infertility around the globe”. Reproductive Biology and Endocrinology 13 (2015): 37-46.
  3. Eze KN. “Anti-fertility effects of ethanolic extract of Xylopia aethiopica on male reproductive organ of wistar rats”. The American Journal of the Medical Sciences 2 (2012): 12-15.
  4. Airaodion AI., et al. “Carica papaya leaves might cause miscarriage”. Asian Research Journal of Gynaecology and Obstetrics2 (2019): 1-9.
  5. Airaodion AI., et al. “Effect of common household insecticides used in Nigeria on rat male reproductive hormones”. International Journal of Research and Reports in Gynaecology1 (2019): 1-8.
  6. Hideyuki K., et al. “Focus issue on male infertility”. Advances in Urology (2012): 1-6.
  7. Abarikwu SO. “Causes and risk factors for male-factor infertility in Nigeria: A review”. African Journal of Reproductive Health 1 (2013): 150-166.
  8. Kumar N and Singh AK. “Trends of male factor infertility, an important cause of infertility: A review of literature”. Journal of Human Reproductive Sciences 8 (2015): 191-196.
  9. Hussain SA., et al. “Evaluation of the Spermatogenic Activity of Polyherbal Formulation in Oligospermic Males”. BioMed Research International7 (2018): 08-15.
  10. Hsu PC and Guo YL. “Antioxidant nutrients and lead toxicity”. Toxicology 180 (2002): 33-44.
  11. Nikkhah E., et al. “Protective Effects of Taurine against Hepatotoxicity Induced by Pharmaceuticals and Environmental Chemicals”. Environmental Toxicology and Chemistry 103 (2021): 56-84.
  12. Kamalakkanan N and Prince PSM. “Antidiabetic and anti-oxidant activity of Aegle marmelos extract in streptozotocin-induced diabetic rats”. Pharmaceutical Biology 42 (2004): 125-130.
  13. Apaydın FG., et al. “Histopathological and biochemical studies on the effect of curcumin and taurine against bisphenol A toxicity in male rats”. Environmental Science and Pollution Research 26 (2019): 12302-12310.
  14. Dixit AK., et al. “Antioxidant potential and radioprotective effect of soy isoflavone against gamma irradiation induced oxidative stress”. Journal of Functional Foods 4 (2012): 197-206.
  15. Rames T. “Oxidative stress and hepatocellular mitochondrial dysfunction attenuated by asiatic acid in streptozotocin-induced diabetic rats”. Journal of King Saud University – Science 33 (2021): 101369.
  16. Dewanjee S., et al. “Toxic effects of lead exposure in Wistar rats: Involvement of oxidative stress and the beneficial role of edible jute (Corchorus olitorius) leaves”. Food and Chemical Toxicology 55 (2013): 78-91.
  17. Jones DP. “Redox potential of GSH/GSSG couple: assay and biological significance”. Methods in Enzymology 348 (2002): 93-112.
  18. Airaodion AI., et al. “Antifertility effect of ethanolic leaf extract of Carica papaya in male Wistar rats”. Merit Research Journal of Medicine and Medical Science10 (2019): 374-381.
  19. Jahan S., et al. “Histomorphological study to evaluate anti-fertility effect of Abrus precatorius in adult male mice”. The Journal of Medicinal Plants Research 3 (2009): 1021-1028.
  20. Orieke D., et al. “Semen quality, hormone profile and histological changes in male albino rats treated with Corchorus olitorius leaf extract”. Avicenna Journal of Phytomedicine6 (2019): 551-562.
  21. Ujah OF., et al. “Phytochemical and hepatoprotective effect of ethanolic leaf extract of Corchorus olitorius on carbon tetrachloride induced toxicity”. European Journal of Medicinal Plants 4 (2014): 882-892.
  22. Airaodion AI., et al. “Effect of Methanolic extract of Corchorus olitorius leaves on hypoglycemic and hypolipidaemic activities in albino rats”. Asian Plant Research Journal4 (2019): 1-13.
  23. Oyedeji KO and Bolarinwa AF. “Effect of Corchorus olitorius extract on haematological and plasma biochemical parameters in male albino rats”. IOSR Journal of Dental and Medical Sciences (IOSR-JDMS) 3 (2013): 68-71.
  24. Oyedeji KO., et al. “Effect of Corchorus olitorius extract on reproductive functions in male albino rats”. International Journal of Pharmacy and Pharmaceutical Sciences 5 (2013): 427-431.
  25. Orieke D., et al. “Acute and Sub-acute Toxicity Evaluation of Methanolic Leaf Extract of Corchorus olitorius in Experimental Animal Models”. Asian Journal of Research in Animal and Veterinary Sciences23 (2018): 1-16.
  26. Airaodion AI., et al. “Effect of Oral Intake of African Locust Bean on Fasting Blood Sugar and Lipid Profile of Albino Rats”. Asian Journal of Research in Biochemistry4 (2019): 1-9.
  27. Airaodion AI., et al. “Antifertility Effect of Ethanolic Leaf Extract of Carica papaya in Male Wistar Rats”. Merit Research Journal of Medicine and Medical Science9 (2019): 121-129.
  28. National Research Council. United States Committee for the update of the Guide for the Care and Use of Laboratory Animals. “Guide for the Care and Use of Laboratory Animals”. 8th, Washington (DC): National Academies Press (US) (2011).
  29. Gornall AG., et al. “Determination of serum proteins by means of the biuret reaction”. The Journal of Biological Chemistry2 (1949): 751-766.
  30. Kemp A., et al. “A colorimetric micro-method for the determination of glycogen in tissues”. Biochemistry Journal 56 (2019): 646-648.
  31. Fredrickson DS., et al. “Fat transport in lipoproteins-an integrated approach to mechanisms and disorders”. New England Journal of Medicine 276 (2017): 34-44.
  32. Yao K., et al. “Direct determination of bound sialic acids in sialoglycoproteins of the acidic Ninhydrine reaction”. Analytical Biochemistry 179 (2019): 332-335.
  33. Wright PJ., et al. “Enzyme in rat urine alkaline phosphatase”. Enzymologia 42 (1972): 317-327.
  34. Airaodion AI., et al. “Hepatoprotective effect of Parkia biglobosa on acute ethanol-induced oxidative stress in Wistar rats”. International Research Journal of Gastroenterology and Hepatology1 (2019): 1-11.
  35. Gupta RS., et al. “Antifertility effects of metabolic pod extract of Albizzia lebbeck”. Asian Journal of Andrology 6 (2004): 155-159.
  36. Kerr JB., et al. “Morphometric studies on lipid inclusions in Sertoli cells during the spermatogenic cycle in the rat”. Cell and Tissue Research 236 (2014): 699-709.
  37. Hu JZZ., et al. “Cellular cholesterol delivery, intracellular processing and utilization for biosynthesis of steroid hormones”. Nutrition and Metabolism7 (2010): 47.
  38. Shima Y., et al. “Contribution of Leydig and Sertoli cells to testosterone production in mouse fetal testes”. Molecular Endocrinology1 (2013): 63-73.
  39. Weinbauer GF., et al. “Physiology of testicular function Nieschlag (Edition.)”, andrology, Berlin: Springer Berlin Heidelberg (2010): 11-59.
  40. Kasturi M., et al. “Changes in epididymal structure and function of albino rat treated with Azadirachta indica leaves”. The Indian Journal of Experimental Biology10 (1995): 74-82.
  41. Ahmad MK and Mahmood R. “Protective effect of taurine against potassium bromate-induced hemoglobin oxidation, oxidative stress, and impairment of antioxidant defense system in blood”. Environmental Toxicology 31 (2018): 304-313.
  42. Mohamed EAK and Saddek EA. “The protective effect of taurine and/or vanillin against renal, testicular, and hematological alterations induced by potassium bromate toxicity in rats”. The Journal of Basic and Applied Zoology3 (2019): 1-11.
  43. Villarroel-Espíndola F., et al. “Muscle glycogen synthase isoform is responsible for testicular glycogen synthesis: glycogen overproduction induces apoptosis in male germ cells”. Journal of Cellular Biochemistry 114 (2013): 1653-1664.
  44. Datta K., et al. “Glycogen metabolism in human fetal testes”. Journal of Bioscience2 (2018): 19-27.
  45. Mann T. “Biochemistry of the semen and the male reproductive tract”. London, MA: John Wiley and Sons (2019): 391-392.
  46. Pathak S and Prakash AO. “Post-coital contraceptive effect of jaeschkeana Vatke and its hormonal properties”. Phytotherapy Research 3 (2019): 61-66.
  47. Joshi SC., et al. “Testicular toxicity of chlorpyrifos (an organophosphate pesticide) in the albino rat”. Toxicology and Industrial Health 23 (2007): 439-444.
  48. Geeta P and Gyan CJ. “Assessment of molybdenum induced alteration in oxidative indices, biochemical parameters and sperm quality in testis of wistar male rats”. Asian Journal of Biochemistry6 (2015): 267-280.
  49. Nwonuma CO., et al. “Effect of Thaumatococcus daniellii leaf rat-feed on potassium bromate induced testicular toxicity”. Asian Pacific Journal of Reproduction 5 (2016): 500-505.
  50. Airaodion AI., et al. “Effect of Methanolic extract of Corchorus olitorius leaves on hypoglycemic and hypolipidaemic activities in albino rats”. Asian Plant Research Journal4 (2019): 1-13.
  51. Samarth RM., et al. The Indian Journal of Experimental Biology 39 (2001): 479-482.
  52. Madhu K., et al. “Radioprotective effect of panax ginseng on the phosphatases and lipid peroxidation level in testes of Swiss albino mice”. Biological and Pharmaceutical Bulletin3 (2003): 308-312.
  53. Rene AA., et al. Testicular toxicity of chlorpyrifos (an organophosphate pesticide) in the albino rat Lab Invest 25 (2017): 230-233.
  54. Nwonuma CO., et al. “Protective potentials of brown chicken eggshell against potassium bromate effect on testicular functional indices in Wistar rats”. American Journal of Bio Science5 (2015): 183-189.
  55. Kerr JB., et al. “Morphometric studies on lipid inclusions in Sertoli cells during the spermatogenic cycle in the rat”. Cell and Tissue Research 236 (2004): 699-709.
  56. Turner RMO and McDonnell SM. “Alkaline phosphatase in stallion semen: characterization and clinical applications”. Theriogenology 60 (2003): 1-10.
  57. Turner RM and Sertich PL. “Use of alkaline phosphatase activity as a diagnostic tool in stallions with a zoospermia and oligospermia”. Animal Reproduction Science 68 (2001): 315-316.
  58. Ortavant R. In: Cole, Cupps, editors. Reproduction in domestic animals, volume II. New York and London: Academic Press Inc (1959).
  59. Rahman MF., et al. “Acid and alkaline phosphatase activities in a novel phosphorothionate (RPR-11) treated male and female rats. Evidence of dose and time-dependent response”. Drug and Chemical Toxicology 23 (2000): 497-509.
  60. Airaodion AI., et al. “Evaluation of potassium bromate in bread in Ibadan metropolis: Fifteen years after ban in Nigeria”. Asian Food Science Journal4 (2019): 1-7.
  61. Airaodion AI., et al. “Assessment of Bread in Ogbomoso Metropolis for the Presence of Potassium Bromate”. Asian Journal of Research in Biochemistry2 (2019): 1-6.
  62. Iwuoha CE., et al. “Perturbation of sex hormones by potassium bromate and preventive effect of African locust bean (Parkia biglobosa) seed”. Asian Journal of Research in Biochemistry11 (2022): 21-31.
  63. Ugwu CN., et al. “Ameliorative effect of Parkia biglobosa (African locust bean) seed against potassium bromate-induced oxidative stress”. Merit Research Journal of Medicine and Medical Science8 (2022): 213-219.
  64. Ugwu CN., et al. “In vivo attenuation of experimentally-induced oxidative stress by common African vegetable (Corchorus olitorius)”. GSC Biological and Pharmaceutical Sciences01 (2022): 116-122.
  65. Airaodion AI., et al. “Hepatoprotective potency of ethanolic extract of Garcinia kola (Heckel) seed against acute ethanol-induced oxidative stress in Wistar rats”. International Research Journal of Gastroenterology and Hepatology2 (2020): 1-10.
  66. Ezirim EO., et al. “Attenuation of potassium bromate-induced infertility by African locust bean (Parkia biglobosa) seed”. Asian Journal of Medicine and Health11 (2022): 112-123.
  67. Onyeaghala CA., et al. “Common African Vegetable (Corchorus olitorius) Alleviated Potassium Bromate-Induced Sperm Abnormalities”. EC Gynaecology11 (2022): 09-19.
  68. Ezirim EO., et al. “Effect of Corchorus olitorius leaves on sex hormones of animals induced with potassium bromate”. International Journal of Chemical and Life Science10 (2022): 22-31.
  69. Khan RA., et al. “Protective effects of Sonchus asper (L.) against KBrO3-induced oxidative stress in rat testis”. Pakistan Journal of Pharmaceutical Sciences3 (2013): 567-570.
  70. Airaodion AI., et al. “Comparative Assessment of Phytochemical Content and Antioxidant Potential of Azadirachta indica and Parquetina nigrescens leaves”. Asian Plant Research Journal3 (2019): 1-14.
  71. Airaodion AI., et al. “Evaluation of Phytochemical Content and Antioxidant Potential of Ocimum gratissimum and Telfairia occidentalis Leaves”. Asian Journal of Research in Medical and Pharmaceutical Sciences1 (2019): 1-11.
  72. Airaodion AI., et al. “Ameliorative Efficacy of Methanolic Extract of Corchorus olitorius Leaves against Acute Ethanol-Induced Oxidative Stress in Wistar Rats”. Asian Journal of Biochemistry, Genetics and Molecular Biology6 (2019): 1-9.

AI Airaodion.,et al. Mitigation of Experimentally-Induced Testicular Toxicity by Corchorus olitorius Leaves. EC Pharmacology and Toxicology 11.2 (2023): 14-24.

ECronicon Journal

Our Services

Quick Links

Information

Creative Commons LicenseOpen Access by ECronicon is licensed under a Creative Commons Attribution 4.0 International License
Based on a work at www.ecronicon.net