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Evaluation of Acute Toxicity of Lead Acetate, Mercury Chloride, and Their Effects on Fasting Blood Glucose Level in the Common African Toad (Bufo regularis)

Received: 15 June 2023     Accepted: 3 July 2023     Published: 11 July 2023
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Abstract

Mercury and lead are heavy metals found in the environment which affect metabolic activity. However, few studies have investigated the acute toxicity tests for mercury chloride and lead acetate in amphibians. The present study evaluated acute toxicity values of lead acetate, mercury chloride and their effects on fasting blood glucose levels in the common African toad Bufo regularis. The acute toxicity test was performed using static renewal bioassays. A total of 90 adult toads of either sex was used for the study. The experiment was divided into two phases. Phase 1 study consisted of 50 toads divided into 10 groups of 5 toads per group. Animals in groups 1-5 were exposed to water (0mg/L), 4mg/L, 8mg/L, 16mg/L and 32mg/L of lead acetate solutions respectively while animals in groups 6-10 were exposed to water (0mg/L), 10mg/L, 20mg/L, 35mg/L, 50mg/L of mercury chloride solutions respectively for 96 hours. Mortality was recorded after 96h and LD50 values were calculated. The second phase of the experiment had 40 toads divided into eight groups of five animals each. Animals in groups 1-4 were exposed to sub lethal concentrations of mercury chloride 0mg/L, 1mg/L, 2mg/L, 3mg/L and 4mg/L while groups 5-8 animals were exposed to sub lethal concentrations of lead acetate 0mg/L, 1mg/L, 2mg/L, 3mg/L, and 4mg/L respectively for 7 days. The blood glucose level was measured one week after exposure using the modified glucose oxidase method. The results of the study showed the 96h LD50 values for mercury chloride was 43mg/L and 15.03mg/L for lead acetate in the common African toad. Acute exposure to low dose mercury chloride and lead acetate solutions caused a significant increase in fasting glucose levels of the toads compared with the controls. In conclusion, the study showed the 96h LD50 values for lead acetate was 15.03mg/L and 43mg/L for mercury chloride in the common African toad. This study also, demonstrated that acute exposure to low dose lead acetate and mercury chloride solutions caused harmful effects and increased fasting glucose levels in the common African toad. Therefore, it is suggested that exposure to lead acetate and mercury chloride be avoided.

Published in American Journal of Chemical and Biochemical Engineering (Volume 7, Issue 1)
DOI 10.11648/j.ajcbe.20230701.13
Page(s) 15-19
Creative Commons

This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.

Copyright

Copyright © The Author(s), 2023. Published by Science Publishing Group

Keywords

Acute Toxicity Test, Mercury Chloride, Lead Acetate, Fasting Blood Glucose, Common African Toad

References
[1] Agarwal, S. K. Bioassay evaluation of acute toxicity levels of mercuric chloride to an air-breathing fish Channa punctatus (Bloch): mortality and behavior study, 1991. J. Environ. Biol. Biology 12: 99-106.
[2] Bener, A., Obineche, E., Gillett, M., Pasha, M. A., Bishawi, B. Association between blood levels of lead, blood pressure and risk of diabetes and heart disease in workers, 2001. Int. Arch. Occup. Environ. Health 74, 3.
[3] Chen, Y. W; Huang, C. F; Tsai, K. S. The role of phosphoinositide 3-kinase/Akt signaling in iow-dose mercury-induced mouse pancreatic beta cell dysfunction in vitro and in vivo, 2006. Diabetes. 55: 1614-24.
[4] Clarkson TW and Magos L. The toxicology of mercury and its chemical compounds, 2006. Crit. Rev. Toxicol 36: 609–662. [PubMed: 16973445].
[5] El-Sikaily, A and Helal, M. Environmental pollution and diabetes mellitus, 2021. World journal of Meta-Analysis 9 (3): 234–256.
[6] Faulk C, Barks A, Liu K, Goodrich JM, Dolinoy DC. Early-life lead exposure results in dose- and sexspecific effects on weight and epigenetic gene regulation in weanling mice, 2013. Epigenomics; 5 (5): 487–500. doi: 10.2217/epi.13.49 PMID: 24059796 5.
[7] Goyer RA. Toxic effects of metals. In: Klaassen CD, editor. Cassarett and Doull’s Toxicology: The Basic Science of Poisons, 2001. New York: McGraw-Hill Publisher;, 811–867.
[8] Gooley, GJ, Gavine FM, Dalton W, De Silva SS, Bretherton M, Samblebe M. Feasibility of aquaculture in dairy manufacturing wastewater to enhance environmental performance and offset costs. Final Report DRDC Project No. MAF001, 2000. Marine and Freshwater Resources Institute, Snobs Creek.
[9] Gump BB, Stewart P, Reihman J, Lonky E, Darvill T, Parsons PJ, et al. Low-level prenatal and postnatal blood lead exposure, and adrenocortical responses to acute stress in children, 2008. Environmental health perspectives.; 116 (2): 249–55. doi: 10.1289/ehp.10391 PMID: 18288326.
[10] Hedayati A, Safahieh A, Savar A, Ghofleh Marammazi J. Detection of mercury chloride acute toxicity in Yellowfin Sea bream (Acanthopagrus latus), 2010. World J. Fish and Marine Sci. 2: 86-92.
[11] Hedayati, A; Jahanbakhshi, A; Shaluei, F; Kolbadinezhad, S. M. Acute toxicity test of mercuric chloride (Hgcl2), lead chloride (Pbcl2) and zinc sulphate (Znso4) in Common Carp (Cyprinus carpio), 2013. J. Clinic. Toxicol. 3:1.
[12] Jaishankar, M., Tseten, T., Anbalagan, N., Mathew, B. B., and Beeregowda, K. N. Toxicity, mechanism and health effects of some heavy metals, 2014. Interdisciplinary toxicology, 7 (2), 60–72. https://doi.org/10.2478/intox-2014-0009
[13] Lambert M, Leven BA, Green RM. New methods of cleaning up heavy metal in soils and water; 2000. Environmental science and technology briefs for citizens; Manhattan, KS: Kansas State University.
[14] Maqbool, F., Bahadar, H., Niaz, K., Baeeri, M., Rahimifard, M., Navaei-Nigjeh, M., Ghasemi-Niri, S. F., Abdollahi, M. Effects of methyl mercury on the activity and gene expression of mouse Langerhans islets and glucose metabolism. 2016, Food and Chem. Toxicol. doi: 10.1016/ j.fct.2016.05.005.
[15] Morakinyo, A. O., Iranloye, B. O., Oludare, G. O., Oyedele, O. J., and Ayeni, O. O. Mercury chloride-induced glucose intolerance in rats: Role of oxidative stress, 2012. Br J Pharmacol Toxicol, 3, 7–12.
[16] Mostafalou, S.; Baeeri, M.; Bahadar, H.; Soltany-Rezaee-Rad, M.; Gholami, M.; Abdollahi, M. Molecular mechanisms involved in lead induced disruption of hepatic and pancreatic glucose metabolism, 2015. Environ. Toxicol. Pharmacol, 39, 16–26.
[17] Rakib, M. S, Sujan, K. M, and Miah, M. A. Deleterious effects of mercuric chloride on blood biochemistry, liver and kidney histology in female albino mice 2021. J Agri. Food and Environ. (JAFE) Vol 2 No 2, Pp18–23.
[18] Rahimibashar, M. R., and Alipoor, V. The determination of LC50 and bioconcentration of mercury chloride (HgCl2) in (Esox lucius), 2012. World Applied Sciences Journal, 17 (6), 735–738.
[19] Rossi-George A, Virgolini MB, Weston D, Cory-Slechta DA. Alterations in glucocorticoid negative feedback following maternal Pb, prenatal stress and the combination: a potential biological unifying mechanism for their corresponding disease profiles, 2009. Toxicology and applied pharmacology; 234 (1): 117–27. doi: 10.1016/j.taap.2008.10.003 PMID: 18977374 9.
[20] Sharma R, Handa S, De D, Radotra BD, Rattan V. Role of dental restoration materials in oral mucosal lichenoid lesions, 2015. Indian J Dermatol Venereol Leprol. 81 (5): 478-84. doi: 10.4103/0378-6323.162341.
[21] Srivastava, S. K; Srivastav, A. K. Acute Toxicity of lead acetate and its effects on the behaviour of a freshwater catfish, Heteropneustes Fossils (BLOCH), 2019. J. Exp. Zool. India Vol. 22, No. 2, pp. 897-900.
[22] Trinder, E. Determination of blood glucose using 4 amino phenazone as oxygen acceptor, 1969. J. Chem. Pathol. 22: 246-248.
[23] Wan, H., Chen, S., Cai, Y., Chen, Y., Wang, Y., Zhang, W., Chen, C., Wang, N., Guo, Y., Lu, Y., Lead exposure and its association with cardiovascular disease and diabetic kidney disease in middle-aged and elderly diabetic patients, 2021a. Int. J. Hyg Environ. Health 231, 113663.
[24] Wan, H, Wang, B., Cui, Y, Wang, Y, Zhang, K, Chen, C, Xia, F, Ye, L, Wang, L, Wang, N, Lu Y. Low-level lead exposure promotes hepatic gluconeogenesis and contributes to the elevation of fasting glucose level, 2021b. Chemosphere 276, 130111.
[25] Wang, N., Chen, C., Nie, X., Han, B., Li, Q., Chen, Y., Zhu, C., Chen, Y., Xia, F., Cang, Z., Lu, M., Meng, Y., Zhai, H., Lin, D., Cui, S., Jensen, M. D., Lu, Y. Blood lead level and its association with body mass index and obesity in China - results from SPECT-China study, 2015a. Sci. Rep. 5, 18299.
[26] Wang, N., Chen, C., Nie, X., Han, B., Li, Q., Chen, Y., Zhu, C., Chen, Y., Xia, F., Cang, Z., Lu, M., Meng, Y., Zhai, H., Lin, D., Cui, S., Jensen, M. D., Lu, Y. Blood lead level and its association with body mass index and obesity in China - results from SPECT-China study. 2015b. Sci. Rep. 5, 18299.
[27] Wang X, Karvonen-Gutterez, CA, Herman WH, Mukherjee B, Harlow SD, Park SK. Urinary metals and incident diabetes in midlife women study of womens health across the nation (SWAN), 2020. BMI open Diabetes Res care 8.
[28] WHO. World Health Organisation. Exposure to mercury: a major public health Concern, 2018. https://www.who.int/ipcs/features/mercury
[29] Yang, A. M., Hu, X. B., Liu, S., Cheng, N., Zhang, D. S., Li, J. S., Li, H. Y., Ren, X. W., Li, N., Sheng, X. P., Ding, J., Zheng, S., Wang, M. Z., Zheng, T. Z., Bai, Y. N. Occupational exposure to heavy metals, alcohol intake, and risk of type 2 diabetes and prediabetes among Chinese male workers, 2019. Chronic diseases and translational medicine 5, 97e104.
[30] Zhai, H., Chen, C., Wang, N., Chen, Y., Nie, X., Han, B., Li, Q., Xia, F., Lu, Y. Blood lead level is associated with non-alcoholic fatty liver disease in the Yangtze River Delta region of China in the context of rapid urbanization, 2017. Environ. Health: a global access science source 16, 93.
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    Isehunwa Grace Olufunmilayo, Alabi Alimoh Helen, Ebeghe Aghoja, Osifo Innocent Aimen. (2023). Evaluation of Acute Toxicity of Lead Acetate, Mercury Chloride, and Their Effects on Fasting Blood Glucose Level in the Common African Toad (Bufo regularis). American Journal of Chemical and Biochemical Engineering, 7(1), 15-19. https://doi.org/10.11648/j.ajcbe.20230701.13

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    Isehunwa Grace Olufunmilayo; Alabi Alimoh Helen; Ebeghe Aghoja; Osifo Innocent Aimen. Evaluation of Acute Toxicity of Lead Acetate, Mercury Chloride, and Their Effects on Fasting Blood Glucose Level in the Common African Toad (Bufo regularis). Am. J. Chem. Biochem. Eng. 2023, 7(1), 15-19. doi: 10.11648/j.ajcbe.20230701.13

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    AMA Style

    Isehunwa Grace Olufunmilayo, Alabi Alimoh Helen, Ebeghe Aghoja, Osifo Innocent Aimen. Evaluation of Acute Toxicity of Lead Acetate, Mercury Chloride, and Their Effects on Fasting Blood Glucose Level in the Common African Toad (Bufo regularis). Am J Chem Biochem Eng. 2023;7(1):15-19. doi: 10.11648/j.ajcbe.20230701.13

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  • @article{10.11648/j.ajcbe.20230701.13,
      author = {Isehunwa Grace Olufunmilayo and Alabi Alimoh Helen and Ebeghe Aghoja and Osifo Innocent Aimen},
      title = {Evaluation of Acute Toxicity of Lead Acetate, Mercury Chloride, and Their Effects on Fasting Blood Glucose Level in the Common African Toad (Bufo regularis)},
      journal = {American Journal of Chemical and Biochemical Engineering},
      volume = {7},
      number = {1},
      pages = {15-19},
      doi = {10.11648/j.ajcbe.20230701.13},
      url = {https://doi.org/10.11648/j.ajcbe.20230701.13},
      eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ajcbe.20230701.13},
      abstract = {Mercury and lead are heavy metals found in the environment which affect metabolic activity. However, few studies have investigated the acute toxicity tests for mercury chloride and lead acetate in amphibians. The present study evaluated acute toxicity values of lead acetate, mercury chloride and their effects on fasting blood glucose levels in the common African toad Bufo regularis. The acute toxicity test was performed using static renewal bioassays. A total of 90 adult toads of either sex was used for the study. The experiment was divided into two phases. Phase 1 study consisted of 50 toads divided into 10 groups of 5 toads per group. Animals in groups 1-5 were exposed to water (0mg/L), 4mg/L, 8mg/L, 16mg/L and 32mg/L of lead acetate solutions respectively while animals in groups 6-10 were exposed to water (0mg/L), 10mg/L, 20mg/L, 35mg/L, 50mg/L of mercury chloride solutions respectively for 96 hours. Mortality was recorded after 96h and LD50 values were calculated. The second phase of the experiment had 40 toads divided into eight groups of five animals each. Animals in groups 1-4 were exposed to sub lethal concentrations of mercury chloride 0mg/L, 1mg/L, 2mg/L, 3mg/L and 4mg/L while groups 5-8 animals were exposed to sub lethal concentrations of lead acetate 0mg/L, 1mg/L, 2mg/L, 3mg/L, and 4mg/L respectively for 7 days. The blood glucose level was measured one week after exposure using the modified glucose oxidase method. The results of the study showed the 96h LD50 values for mercury chloride was 43mg/L and 15.03mg/L for lead acetate in the common African toad. Acute exposure to low dose mercury chloride and lead acetate solutions caused a significant increase in fasting glucose levels of the toads compared with the controls. In conclusion, the study showed the 96h LD50 values for lead acetate was 15.03mg/L and 43mg/L for mercury chloride in the common African toad. This study also, demonstrated that acute exposure to low dose lead acetate and mercury chloride solutions caused harmful effects and increased fasting glucose levels in the common African toad. Therefore, it is suggested that exposure to lead acetate and mercury chloride be avoided.},
     year = {2023}
    }
    

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  • TY  - JOUR
    T1  - Evaluation of Acute Toxicity of Lead Acetate, Mercury Chloride, and Their Effects on Fasting Blood Glucose Level in the Common African Toad (Bufo regularis)
    AU  - Isehunwa Grace Olufunmilayo
    AU  - Alabi Alimoh Helen
    AU  - Ebeghe Aghoja
    AU  - Osifo Innocent Aimen
    Y1  - 2023/07/11
    PY  - 2023
    N1  - https://doi.org/10.11648/j.ajcbe.20230701.13
    DO  - 10.11648/j.ajcbe.20230701.13
    T2  - American Journal of Chemical and Biochemical Engineering
    JF  - American Journal of Chemical and Biochemical Engineering
    JO  - American Journal of Chemical and Biochemical Engineering
    SP  - 15
    EP  - 19
    PB  - Science Publishing Group
    SN  - 2639-9989
    UR  - https://doi.org/10.11648/j.ajcbe.20230701.13
    AB  - Mercury and lead are heavy metals found in the environment which affect metabolic activity. However, few studies have investigated the acute toxicity tests for mercury chloride and lead acetate in amphibians. The present study evaluated acute toxicity values of lead acetate, mercury chloride and their effects on fasting blood glucose levels in the common African toad Bufo regularis. The acute toxicity test was performed using static renewal bioassays. A total of 90 adult toads of either sex was used for the study. The experiment was divided into two phases. Phase 1 study consisted of 50 toads divided into 10 groups of 5 toads per group. Animals in groups 1-5 were exposed to water (0mg/L), 4mg/L, 8mg/L, 16mg/L and 32mg/L of lead acetate solutions respectively while animals in groups 6-10 were exposed to water (0mg/L), 10mg/L, 20mg/L, 35mg/L, 50mg/L of mercury chloride solutions respectively for 96 hours. Mortality was recorded after 96h and LD50 values were calculated. The second phase of the experiment had 40 toads divided into eight groups of five animals each. Animals in groups 1-4 were exposed to sub lethal concentrations of mercury chloride 0mg/L, 1mg/L, 2mg/L, 3mg/L and 4mg/L while groups 5-8 animals were exposed to sub lethal concentrations of lead acetate 0mg/L, 1mg/L, 2mg/L, 3mg/L, and 4mg/L respectively for 7 days. The blood glucose level was measured one week after exposure using the modified glucose oxidase method. The results of the study showed the 96h LD50 values for mercury chloride was 43mg/L and 15.03mg/L for lead acetate in the common African toad. Acute exposure to low dose mercury chloride and lead acetate solutions caused a significant increase in fasting glucose levels of the toads compared with the controls. In conclusion, the study showed the 96h LD50 values for lead acetate was 15.03mg/L and 43mg/L for mercury chloride in the common African toad. This study also, demonstrated that acute exposure to low dose lead acetate and mercury chloride solutions caused harmful effects and increased fasting glucose levels in the common African toad. Therefore, it is suggested that exposure to lead acetate and mercury chloride be avoided.
    VL  - 7
    IS  - 1
    ER  - 

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Author Information
  • Department of Physiology, College of Medicine, University of Ibadan, Ibadan, Nigeria

  • Department of Chemistry, Faculty of Science, University of Ibadan, Ibadan, Nigeria

  • Department of Physiology, College of Medicine, University of Ibadan, Ibadan, Nigeria

  • Department of Physiology, College of Medicine, University of Ibadan, Ibadan, Nigeria

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