Path of Science: International Electronic Scientific Journal

The majority of the population in Nigeria's semi-urban and urban areas depends on wells as their primary water source, due to a recent increase in cases of waterborne disease. This study was conducted to examine the quality of well water in the Ayobo area of Lagos State. Water samples from 10 protected and 10 unprotected wells were randomly selected and analysed for their physicochemical and bacteriological qualities. The results obtained for the protected wells were compared with those of the unprotected well. The physicochemical results show that all the parameters examined were within the Nigerian Standard for Drinking Water Quality (NSDWQ), except pH, which was below the acceptable range of 6.5-8.5. The bacteriological result indicated that all the water samples had coliform counts above the World Health Organisation acceptable standard of ≤ 1, also all the water samples were contaminated with bacterial pathogens such as Klebsiella spp 33.3%, Enterobacter spp 29.6%, Escherichia coli 18.5%, Proteus spp 11.1%, and Pseudomonas spp 7.4%. Comparative analysis showed no significant differences in the physicochemical parameters between the protected and unprotected wells. Compared with protected wells, the unprotected wells were more contaminated with bacterial pathogens. This result highlights that most wells analysed in Ayobo metropolis are not bacteriologically safe for drinking without disinfection, which could lead to an outbreak of waterborne disease. Therefore, it is necessary to prevent waterborne disease in this community by ensuring that well water is properly disinfected before drinking.

1. Some, S., Mondal, R., Mitra, D., Jain, D., Verma, D., & Das, S. (2021). Microbial pollution of water with special reference to coliform bacteria and their nexus with environment. Energy Nexus, 1, 100008. doi: 10.1016/j.nexus.2021.100008

2. United Nations. (2023). The 2023 UN Water Conference & How We're Supporting a BOLD Water Action Agenda. Retrieved from https://www.waterforpeople.org/2023-un-water-conference/?gad_source=1&gad_campaignid=22223095191&gbraid=0AAAAADoBNgJ71SiL-E3DxtToG7r2KFWaP&gclid=CjwKCAiAjojLBhAlEiwAcjhrDjvL4ROyGNwpTvR2pWIWTjteUaQSlVVL5p_jAxDQZ363UfK3gtYQzxoC2bIQAvD_BwE

3. Idowu, A., Oluremi, B., & Odubawo, K. (2011). Bacteriological analysis of well water samples in Sagamu. African Journal of Clinical and Experimental Microbiology, 12(2). doi: 10.4314/ajcem.v12i2.64324

4. Chenchouni, H., Chaminé, H. I., Khan, M. F., Merkel, B. J., Zhang, Z., Kallel, P. Li, A., & Khélifi, N. (Eds.), (2022). New Prospects in Environmental Geosciences and Hydrogeosciences. doi: 10.1007/978-3-030-72543-3

5. Lapworth, D. J., Boving, T. B., Kreamer, D. K., Kebede, S., & Smedley, P. L. (2022). Groundwater quality: Global threats, opportunities and realising the potential of groundwater. Science of The Total Environment, 811, 152471. doi: 10.1016/j.scitotenv.2021.152471

6. Lukubye, B., & Andama, M. (2017). Physico-Chemical Quality of Selected Drinking Water Sources in Mbarara Municipality, Uganda. Journal of Water Resource and Protection, 09(07), 707–722. doi: 10.4236/jwarp.2017.97047

7. Fida, M., Li, P., Wang, Y., Alam, S. M. K., & Nsabimana, A. (2022). Water Contamination and Human Health Risks in Pakistan: A Review. Exposure and Health, 15(3), 619–639. doi: 10.1007/s12403-022-00512-1

8. Magaji, J. Y., & Abimbola, T. A. (2020). Comparative analysis of water quality from different sources in Masaka, Nasarawa State, Nigeria. Australian Journal of Science and Technology, 4(3), 303-311.

9. Allaoua, N., Hafid, H., & Chenchouni, H. (2024). Exploring groundwater quality in semi-arid areas of Algeria: Impacts on potable water supply and agricultural sustainability. Journal of Arid Land, 16(2), 147–167. doi: 10.1007/s40333-024-0004-4

10. Dongzagla, A., Jewitt, S., & O'Hara, S. (2021). Seasonality in faecal contamination of drinking water sources in the Jirapa and Kassena-Nankana Municipalities of Ghana. Science of The Total Environment, 752, 141846. doi: 10.1016/j.scitotenv.2020.141846

11. McLarnan, S. M. (2017). Escherichia coli as a water quality indicator organism: A case for responsive, science-based policy. Retrieved from https://digitalcommons.csbsju.edu/honors_thesis/38/

12. Sathishagouda, S., Majagi, S. H., & Vijaykumar, K. (2022). Investigations of water quality of Chikkere water body, Sira, Tumkur District. Indian Journal of Applied & Pure Biology, 37(2), 420-428.

13. Srinivas, J., Purushotham, A. V., & Murali Krishna, K. V. S. G. (2013). Determination of water quality index in industrial areas of Kakinada, Andhra Pradesh, India. International Research Journal of Environmental Science, 2(5), 37-45.

14. Aex, F., & Kpormon L. B. (2023). A Comparative Assessment of the Physicochemical and Microbiological Qualities of Some Drinking Water Sources in Diobu, Portharcourt, Nigeria. South Asian Journal of Research in Microbiology, 17(3), 17–24. doi: 10.9734/sajrm/2023/v17i3329

15. Pal, S., & Chakraborty, K. (2017). Different aspects of Chloride in freshwater: A review. International Journal of Current Trends in Science and Technology, 7(8), 20295–20303.