Screening the possible effect of a phytofabricated nanoselenium-composite from Eruca sativa extract in reducing infertility in males
Keywords:
selenium; nanoselenium; testosterone; luteinizing hormone; follicle-stimulating hormone; sperm indices
Abstract
The antifertility effects of ketoconazole can be avoided or diminished by administering nano-selenium-based-antioxidant plant extract simultaneously or sequentially. Using selenium as nanoparticles (SeNPs) is one of the essential methods for enhancing its therapeutic effects and lowering toxicities. This study aimed to analyze the changes made to the parameters of androgens, such as testosterone and gonadotropin hormones: luteinizing hormone and follicle stimulating hormones together with sperm indexes after administration of antioxidant phytofabricated nanoselenium to mitigate oxidative damage brought on by ketoconazole. In brief, 1% weight-per-volume of the extract was loaded into a solution of 10 mM sodium selenite in various ratios on a magnetic stirrer (50 °C, PH 9) in the dark for 12 hours, left for 48 hours and then sent for characterization, which was performed using ultraviolet-visible spectroscopy (UV-vis spectra), Fourier transform infrared spectroscopy (FTIR), and dynamic light scattering (DLS). Then after the selection of the solution containing the optimal fabricated selenium nanoparticles it was administered to three groups out of seven groups of albino rats with eight animals in each one as follows: Gr. A negative control (no treatment), Gr. B oral ketoconazole 50 mg/kg for fourteen days, Gr. BC, BD, BE1, BE2 and BE3; each one received oral ketoconazole 50 mg/kg for fourteen days followed by: 200 mg/kg Eruca sativa (Gr. BC), 0.5 mg/kg oral sodium selenite (Gr. BD), 0.5 mg/kg/cm2 skin area local nanoselenium (Gr. BE1), 0.25 mg/kg oral nanoselenium (Gr. BE2) and 0.5 mg/kg oral nano selenium (Gr. BE3) respectively for 28 days. After this period, the animals were anesthetized, and plasma testosterone, luteinizing, and follicle stimulating hormones were assessed using Elisa Kit; after that, they were euthanized, and the epididymis of the right testis was carefully removed for evaluation of sperm indices (count, viability, abnormality, and motility). The reduction of selenium ions into PF-SeNPs induced by Eruca sativa extracts at a ratio of (1:2) (Na2SeO3: Eruca sativa) solution was confirmed by the gradual conversion of colour from dark brown to light yellow and then to reddish-orange after the addition of acidic sodium selenite solution and reacting for 12 h. The final reddish-orange colour is the most significant property of nanoparticles. In UV-vis spectroscopy, a strong absorption peak appeared between 268–964 nm with maxima at 268 nm, confirming the formation of nanoselenium. The optimal phytofabricated nanoselenium particles were obtained with a spherical shape, highly stable, and the smallest in size (39.4 nm in diameter) as proved by DLS with Poly Dispersity Index of 0.242 and zeta potential value of –56.57 mV. In the current study, testicles were damaged by administering ketoconazole at a dose of 50 mg/kg/day orally for 14 days. This testicular damage was linked to significant reductions in testosterone levels, elevated levels of LH and FSH, and significant decreases in sperm count, motility, and viability, which in turn affected spermatogenesis. Concurrently, the administration of Eruca sativa extract, sodium selenite and nanoselenium solution (in different doses and routes) following ketoconazole was shown to significantly improve biochemical parameters. These improvements included an increase in testosterone levels with little to no impact on LH and FSH levels as well as improved sperm indices. Additionally, the oral nanoselenium groups in 0.25 and 0.50 mg/kg produced the best outcomes with only minor differences between them. In conclusion, the antioxidant effects of the phytofabricated nanoselenium-based Eruca sativa leaf extract considerably improved testicular tissues.References
Abd-Elsalam, R. M., El Badawy, S. A., Ogaly, H. A., Ibrahim, F. M., Farag, O. M., & Ahmed, K. A. (2021). Eruca sativa seed extract modulates oxidative stress and apoptosis and up-regulates the expression of Bcl-2 and Bax genes in acrylamide-induced testicular dysfunction in rats. Environmental Science and Pollution Research, 28(38), 53249–53266.
Alizadeh, M., Nasebakht, A., Valizadeh, R., Mohammadi Fallah, M., Taghizadeh Afshari, A., Rahimi, M. M., & Daneshyar, C. (2018). A preliminary evaluation of serum testosterone, LH, and FSH levels in patients with varicocele after varicocelectomy as a kidney-related disease. Therapeutics and Clinical Risk Management, 14, 1585–1590.
Alsalman, A. R. S., Almashhedy, L. A., & Hadwan, M. H. (2018). Effect of oral zinc supplementation on the thiol oxido-reductive index and thiol-related enzymes in seminal plasma and spermatozoa of Iraqi asthenospermic patients. Biological Trace Element Research, 184(2), 340–349.
Amin, A. (2008). Ketoconazole-induced testicular damage in rats reduced by Gentiana extract. Experimental and Toxicologic Pathology, 59, 377–384.
Anbu, J., Mahendra, S. A., Sundar, L. M., Reddy, R. P., & Nayak, D. (2019). Evaluation of the antifertility potential of ketoconazole and assessment of its reversible effect on concomitant treatment with metformin and hydroxytyrosol in rats. Asian Journal of Pharmacy and Pharmacology, 5(1), 1–15.
Ashidi, J. S., Owagboriaye, F. O., Yaya, F. B., Payne, D. E., Lawal, O. I., & Owa, S. O. (2019). Assessment of reproductive function in male albino rats fed dietary meal supplemented with Mucuna pruriens seed powder. Heliyon, 5(10), e02716.
Assumaidaee, A. A. M., Ali, N. M., Ibraheem, Z. O., Fadhil, A. A., & Al-Helli, K. A. A. (2020). Anti-oxidoreductive stress effects of Iraqi Olea europaea L. leaves extract against low double doses of alloxan induced diabetes mellitus in rats. Systematic Reviews in Pharmacy, 11(1), 292–302.
Darbandi, M., Darbandi, S., Agarwal, A., Sengupta, P., Durairajanayagam, D., Henkel, R., & Sadeghi, M. R. (2018). Reactive oxygen species and male reproductive hormones. Reproductive Biology and Endocrinology, 16(1), 87.
Dorostkar, K., Alavi-Shoushtari, S. M., & Mokarizadeh, A. (2012). Effects of in vitro selenium addition to the semen extender on the spermatozoa characteristics before and after freezing in water buffaloes (Bubalus bubalis). Veterinary Research Forum, 3(4), 263–268.
Eendebak, R. J., Ahern, T., Swiecicka, A., Pye, S. R., O'Neill, T. W., Bartfai, G., Casanueva, F. F., Maggi, M., Forti, G., & Giwercman, A. (2018). Elevated luteinizing hormone despite normal testosterone levels in older men – natural history, risk factors, and clinical features. Clinical Endocrinology, 88(3), 479–490.
El-Kazaz, S. E., Abo-Samaha, M. I., Hafez, M. H., El-Shobokshy, S. A., & Wirtu, G. (2020). Dietary supplementation of nano-selenium improves reproductive performance, sexual behavior and deposition of selenium in the testis and ovary of Japanese quail. Journal of Advanced Veterinary and Animal Research, 7(4), 597–607.
Gaber, D. A., Alsubaiyel, A. M., Alabdulrahim, A. K., Alharbi, H. Z., Aldubaikhy, R. Alharbi, R. S., Albishr, W. K., & Mohamed, H. A. (2023). Nano-emulsion based gel for topical delivery of an anti-inflammatory drug: In vitro and in vivo evaluation. Drug Design, Development and Therapy, 17, 1435–1451.
Ghafarizadeh, A. A., Vaezi, G., Shariatzadeh, M. A., & Malekirad, A. A. (2018). Effect of in vitro selenium supplementation on sperm quality in asthenoteratozoospermic men. Andrologia, 50(2), e12869.
Hoshyar, N., Gray, S., Han, H., & Bao, G. (2016). The effect of nanoparticle size on in vivo pharmacokinetics and cellular interaction. Nanomedicine, 11(6), 673–692.
Khalaf, A. A., Ahmed, W., Moselhy, W. A., Abdel-Halim, B. R., & Ibrahim, M. A. (2019). Protective effects of selenium and nano-selenium on bisphenol-induced reproductive toxicity in male rats. Human and Experimental Toxicology, 38(4), 398–408.
Khamees, E. J. (2021). Nanotechnology and its applications in disease diagnosis, drug delivery, and medical imaging. Journal of University of Babylon for Pure and Applied Sciences, 29(3), 196–206.
Khurana, A., Tekula, S., Saifi, M. A., Venkatesh, P., & Godugu, C. (2019). Therapeutic applications of selenium nanoparticles. Biomedicine and Pharmacotherapy, 111, 802–812.
Kmkm, A. M., & Ghareeb, M. M. (2023). Natural oil nanoemulsion-based gel vehicle for enhancing antifungal effect of topical luliconazole. Journal of the Faculty of Medicine Baghdad, 65(1), 65–73.
Landis-Piwowar, K. R., & Iyer, N. R. (2014). Cancer chemoprevention: Current state of the art. Cancer Growth Metastasis, 7, 19–25.
Morsi, N., Ibrahim, M., Refai, H., & El Sorogy, H. (2017). Nanoemulsion-based electrolyte triggered in situ gel for ocular delivery of acetazolamide. European Journal of Pharmaceutical Sciences, 104, 302–314.
Oduwole, O. O., Huhtaniemi, I. T., & Misrahi, M. (2021). The roles of luteinizing hormone, follicle-stimulating hormone, and testosterone in spermatogenesis and folliculogenesis revisited. International Journal of Molecular Sciences, 22(23), 12735.
Oduwole, O. O., Peltoketo, H., & Huhtaniemi, I. T. (2018). Role of follicle-stimulating hormone in spermatogenesis. Frontiers in Endocrinology, 9, 763.
Patra, J. K., Das, G., Fraceto, L. F., Campos, E. V. R., Rodriguez-Torres, M. D. P., Acosta-Torres, L. S., Diaz-Torres, L. A., Grillo, R., Swamy, M. K., Sharma, S., Habtemariam, S., & Shin, H. S. (2018). Nano-based drug delivery systems: Recent developments and prospects. Journal of Nanobiotechnology, 16(1), 71.
Salman, F. S., Al-Qadhi, H. I., & Al Kareem, B. A. (2022). N-acetyl cysteine affects semen parameters in a sample of Iraqi men with oligoasthenoteratozoospermia. Journal of the Faculty of Medicine Baghdad, 64(3), 170–174.
Semet, M., Paci, M., Saïas-Magnan, J., Metzler-Guillemain, C., Boissier, R., Lejeune, H., & Perrin, J. (2017). The impact of drugs on male fertility: A review. Andrology, 5(4), 640–663.
Seyedi, J., Kalbassi, M. R., Esmaeilbeigi, M., Tayemeh, M. B., & Amiri Moghadam, J. (2021). Toxicity and deleterious impacts of selenium nanoparticles at supra nutritional and imbalance levels on male goldfish (Carassius auratus) sperm. Journal of Trace Elements in Medicine and Biology, 66, 126758.
Shareef, B., Al Qadhi, H. I., Amran, M., & Ibrahim, Z. O. (2023). Implementation of Eruca sativa extract for the preparation of nano-selenium particles. Al-Rafidain Journal of Medical Sciences, 5, 26–33.
Smith, L. B., & Walker, W. H. (2014). The regulation of spermatogenesis by androgens. Seminars in Cell and Developmental Biology, 30, 2–13.
Alizadeh, M., Nasebakht, A., Valizadeh, R., Mohammadi Fallah, M., Taghizadeh Afshari, A., Rahimi, M. M., & Daneshyar, C. (2018). A preliminary evaluation of serum testosterone, LH, and FSH levels in patients with varicocele after varicocelectomy as a kidney-related disease. Therapeutics and Clinical Risk Management, 14, 1585–1590.
Alsalman, A. R. S., Almashhedy, L. A., & Hadwan, M. H. (2018). Effect of oral zinc supplementation on the thiol oxido-reductive index and thiol-related enzymes in seminal plasma and spermatozoa of Iraqi asthenospermic patients. Biological Trace Element Research, 184(2), 340–349.
Amin, A. (2008). Ketoconazole-induced testicular damage in rats reduced by Gentiana extract. Experimental and Toxicologic Pathology, 59, 377–384.
Anbu, J., Mahendra, S. A., Sundar, L. M., Reddy, R. P., & Nayak, D. (2019). Evaluation of the antifertility potential of ketoconazole and assessment of its reversible effect on concomitant treatment with metformin and hydroxytyrosol in rats. Asian Journal of Pharmacy and Pharmacology, 5(1), 1–15.
Ashidi, J. S., Owagboriaye, F. O., Yaya, F. B., Payne, D. E., Lawal, O. I., & Owa, S. O. (2019). Assessment of reproductive function in male albino rats fed dietary meal supplemented with Mucuna pruriens seed powder. Heliyon, 5(10), e02716.
Assumaidaee, A. A. M., Ali, N. M., Ibraheem, Z. O., Fadhil, A. A., & Al-Helli, K. A. A. (2020). Anti-oxidoreductive stress effects of Iraqi Olea europaea L. leaves extract against low double doses of alloxan induced diabetes mellitus in rats. Systematic Reviews in Pharmacy, 11(1), 292–302.
Darbandi, M., Darbandi, S., Agarwal, A., Sengupta, P., Durairajanayagam, D., Henkel, R., & Sadeghi, M. R. (2018). Reactive oxygen species and male reproductive hormones. Reproductive Biology and Endocrinology, 16(1), 87.
Dorostkar, K., Alavi-Shoushtari, S. M., & Mokarizadeh, A. (2012). Effects of in vitro selenium addition to the semen extender on the spermatozoa characteristics before and after freezing in water buffaloes (Bubalus bubalis). Veterinary Research Forum, 3(4), 263–268.
Eendebak, R. J., Ahern, T., Swiecicka, A., Pye, S. R., O'Neill, T. W., Bartfai, G., Casanueva, F. F., Maggi, M., Forti, G., & Giwercman, A. (2018). Elevated luteinizing hormone despite normal testosterone levels in older men – natural history, risk factors, and clinical features. Clinical Endocrinology, 88(3), 479–490.
El-Kazaz, S. E., Abo-Samaha, M. I., Hafez, M. H., El-Shobokshy, S. A., & Wirtu, G. (2020). Dietary supplementation of nano-selenium improves reproductive performance, sexual behavior and deposition of selenium in the testis and ovary of Japanese quail. Journal of Advanced Veterinary and Animal Research, 7(4), 597–607.
Gaber, D. A., Alsubaiyel, A. M., Alabdulrahim, A. K., Alharbi, H. Z., Aldubaikhy, R. Alharbi, R. S., Albishr, W. K., & Mohamed, H. A. (2023). Nano-emulsion based gel for topical delivery of an anti-inflammatory drug: In vitro and in vivo evaluation. Drug Design, Development and Therapy, 17, 1435–1451.
Ghafarizadeh, A. A., Vaezi, G., Shariatzadeh, M. A., & Malekirad, A. A. (2018). Effect of in vitro selenium supplementation on sperm quality in asthenoteratozoospermic men. Andrologia, 50(2), e12869.
Hoshyar, N., Gray, S., Han, H., & Bao, G. (2016). The effect of nanoparticle size on in vivo pharmacokinetics and cellular interaction. Nanomedicine, 11(6), 673–692.
Khalaf, A. A., Ahmed, W., Moselhy, W. A., Abdel-Halim, B. R., & Ibrahim, M. A. (2019). Protective effects of selenium and nano-selenium on bisphenol-induced reproductive toxicity in male rats. Human and Experimental Toxicology, 38(4), 398–408.
Khamees, E. J. (2021). Nanotechnology and its applications in disease diagnosis, drug delivery, and medical imaging. Journal of University of Babylon for Pure and Applied Sciences, 29(3), 196–206.
Khurana, A., Tekula, S., Saifi, M. A., Venkatesh, P., & Godugu, C. (2019). Therapeutic applications of selenium nanoparticles. Biomedicine and Pharmacotherapy, 111, 802–812.
Kmkm, A. M., & Ghareeb, M. M. (2023). Natural oil nanoemulsion-based gel vehicle for enhancing antifungal effect of topical luliconazole. Journal of the Faculty of Medicine Baghdad, 65(1), 65–73.
Landis-Piwowar, K. R., & Iyer, N. R. (2014). Cancer chemoprevention: Current state of the art. Cancer Growth Metastasis, 7, 19–25.
Morsi, N., Ibrahim, M., Refai, H., & El Sorogy, H. (2017). Nanoemulsion-based electrolyte triggered in situ gel for ocular delivery of acetazolamide. European Journal of Pharmaceutical Sciences, 104, 302–314.
Oduwole, O. O., Huhtaniemi, I. T., & Misrahi, M. (2021). The roles of luteinizing hormone, follicle-stimulating hormone, and testosterone in spermatogenesis and folliculogenesis revisited. International Journal of Molecular Sciences, 22(23), 12735.
Oduwole, O. O., Peltoketo, H., & Huhtaniemi, I. T. (2018). Role of follicle-stimulating hormone in spermatogenesis. Frontiers in Endocrinology, 9, 763.
Patra, J. K., Das, G., Fraceto, L. F., Campos, E. V. R., Rodriguez-Torres, M. D. P., Acosta-Torres, L. S., Diaz-Torres, L. A., Grillo, R., Swamy, M. K., Sharma, S., Habtemariam, S., & Shin, H. S. (2018). Nano-based drug delivery systems: Recent developments and prospects. Journal of Nanobiotechnology, 16(1), 71.
Salman, F. S., Al-Qadhi, H. I., & Al Kareem, B. A. (2022). N-acetyl cysteine affects semen parameters in a sample of Iraqi men with oligoasthenoteratozoospermia. Journal of the Faculty of Medicine Baghdad, 64(3), 170–174.
Semet, M., Paci, M., Saïas-Magnan, J., Metzler-Guillemain, C., Boissier, R., Lejeune, H., & Perrin, J. (2017). The impact of drugs on male fertility: A review. Andrology, 5(4), 640–663.
Seyedi, J., Kalbassi, M. R., Esmaeilbeigi, M., Tayemeh, M. B., & Amiri Moghadam, J. (2021). Toxicity and deleterious impacts of selenium nanoparticles at supra nutritional and imbalance levels on male goldfish (Carassius auratus) sperm. Journal of Trace Elements in Medicine and Biology, 66, 126758.
Shareef, B., Al Qadhi, H. I., Amran, M., & Ibrahim, Z. O. (2023). Implementation of Eruca sativa extract for the preparation of nano-selenium particles. Al-Rafidain Journal of Medical Sciences, 5, 26–33.
Smith, L. B., & Walker, W. H. (2014). The regulation of spermatogenesis by androgens. Seminars in Cell and Developmental Biology, 30, 2–13.
Published
2023-08-24
How to Cite
Basman, Q. S., Huda, I. A.-Q., & Shayma’a, J. A. (2023). Screening the possible effect of a phytofabricated nanoselenium-composite from Eruca sativa extract in reducing infertility in males . Regulatory Mechanisms in Biosystems, 14(3), 439-443. https://doi.org/10.15421/10.15421/022364
Section
Статті
This work is licensed under a Creative Commons Attribution 4.0 International License.
Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a Creative Commons «Attribution» 4.0 License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.
