As population increases, more buildings for housing, commerce and industry are also required and the resultant effect of this change is a rise in demand for electric power availability accompanied with harmful emissions from power plants installed for electricity generation and other industrial activities. More than 50% of power generated in Nigeria is from thermal power plants (TPP) which utilizes natural gas for their operations. The environmental and health impacts of thermal power plant are quite devastating as it is known for the emission of large amount of CO, CO2, SOx, NOx and SPMs into the atmosphere responsible for most respiratory disorders. This study was aimed at tracking Respiratory Tract Infections (RTI) among residents of Ndokwa within the vicinity of Okpai gas power plant due to pollutant emissions from the plant. The reported cases of RTI was obtained from the archive of Anieze Primary Health Centre while other relevant data was collected through questionnaire distributed among residents within 200m, 400m, 600m, 800m, 1000m and 2000m distances from the gas plant. The Spearman Rank Correlation coefficient value, r=0.827 revealed that there is a significant relationship between RTI and pollutant emission at (F= 28.02, p<0.05. It was also found that 68.4% of RTI in the area was due to pollutant emission, though it occurrence varies significantly with distance. Arising from the findings, regular RTI screening and early detection/treatment, investment in alternative environmentally friendly sources of power generation, constant air quality monitoring and enforcement of regulated threshold, installation of gadgets that will ameliorate the level of gaseous emissions at the gas plant were recommended for urgent implementation in order to cause a significant reduction in air pollutant emission and further prune its associated health hazards in the area.
Published in | International Journal of Infectious Diseases and Therapy (Volume 8, Issue 3) |
DOI | 10.11648/j.ijidt.20230803.15 |
Page(s) | 109-116 |
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 |
Respiratory Tract Infection, Air Quality, Pollutants Emission, Thermal Gas Plant, Residents
[1] | Arbex, M. A., de Souza Conceicao, G. M., Cendon, S. P., Arbex, F. F., Lopes, A. C., Moyses, E. P., Santiago, S. L., Saldiva, P. H., Pereira, L. A., and Braga, A. L. (2009). Urban air pollution and chronic obstructive pulmonary disease-related emergency department visits. Journal of Epidemiology Community Health, 63 (10): 777–83. |
[2] | Abdulkareem, J., Odigure, O. and Abenege, S. (2009) “Predictive Model for Pollutant Dispersion from Gas Flaring: A Case Study of Oil Producing Area of Nigeria,” Energy Sources, Part A, Vol. 31, No. 12, 2009, pp. 1004-1015. |
[3] | Abdul Raheem A. M. O. and Adekola F. A. (2011). Air Pollution: A Case Study of Ilorin and Lagos Outdoor Air. |
[4] | Ayansina, A., Orimoogunje, O., Akinkuolie, T., and Odiong, A. (2010) “Perception on Effect of Gas Flaring on the Environment,” Research Journal of Environmental and Earth Sciences, 2 (4). 188-193. |
[5] | Babatunde, A. O. (2017). Environmental Insecurity and Poverty in the Niger Delta: A Case of Ilaje. African Conflict and Peace building Review, 7 (2), 36-59. |
[6] | Barmen, L. D. and Chronicle, G. Y. (2004). Chronicle of a Conference: Barmen/Belhar Consultation-18 and 19 October 2004. Dutch Reformed Theological Journal Nederduitse Gereformeerde Teologiese Tydskrif, 46 (3-4), 402-423. |
[7] | Bruce, N., Perez-Padilla, R., & Albalak, R. (2000). Indoor air pollution in developing countries: a major environmental and public health challenge. Bulletin of the World Health organization, 78, 1078-1092. |
[8] | Coffin, D. L., and Stokinger, H. E. (1976): Air Pollution, 3rd edition; Vol. II, A. C. Stemed., Academic Press, New York pp. 59-66. |
[9] | Edino, M., Nsofor, G., and L. Bombom, L. (2010) “Perceptions and attitudes towards gas flaring in the Niger Delta, Nigeria,” The Environmentalist, 30 (1). 67-75. |
[10] | Emovon, I., Kareem, B., and Adeyeri, M. K. (2011). Power generation in Nigeria; Problems and solution. In International conference of Nigerian association for energy economics. NAEE, Abuja. |
[11] | Gobo, A. E., Richard, G and Ubong, I. U. (2009) “Health Impact of Gas Flares on Igwuruta/Umuechem Communities in Rivers State,” Journal of Applied Science & Environmental Management, 13 (3), 27-33. |
[12] | Hunt, D., and Johnson, C. (1995) Environmental Management Systems. McGraw Hill, London. |
[13] | Katsouyanni, K., Touloumi, G., Samoli, E., Gryparis, A., Le Tertre, A., Monopolis, Y., Rossi, G., Zmirou, D., Ballester, F., Boumghar, A., Anderson, H. R., Wojtyniak, B., Paldy, A., Braunstein, R., Pekkanen, J., Schindler, C., and Schwartz, J. (2001). Confounding and effect modification in the short-term effects of ambient particles on total mortality: results from 29 European cities within the APHEA2 project. Epidemiology, 12 (5): 521–31. |
[14] | Kurt, O. K., Zhang, J., and Pinkerton, K. E. Pulmonary health effects of air pollution (2016). Current Opinion in Pulmonary Medicine, 22: 138–43. |
[15] | Lieffering, M., Kim, H. Y., Kobayashi, K., & Okada, M. (2004). The impact of elevated CO2 on the elemental concentrations of field-grown rice grains. Field Crops Research, 88 (2-3), 279-286. |
[16] | Mitra, A. P., and Sharma, C. (2002). Indian aerosols: present status. Chemosphere, 49 (9), 1175-1190. |
[17] | NCC, N. (2015). Clinical practice guidelines in oncology. Central nervous system cancers. Version 1. |
[18] | Nriagu, J., Udofia, E. A., Ekong, I., Ebuk, G. (2016) Health risks associated with oil pollution in the Niger Delta, Nigeria. International Journal of Environmental Research and Public Health. 13 (3): 346. |
[19] | Nwaichi, E. O., Frac, M., Nwoha, P. A., and Eragbor, P. (2015). Enhanced phytoremediation of crude oil-polluted soil by four plant species: effect of inorganic and organic bioaugumentation. International journal of phytoremediation, 17 (12), 1253-1261. |
[20] | Pappas, C., Karakosta, C., Marinakis, V., & Psarras, J. (2012). A comparison of electricity production technologies in terms of sustainable development. Energy conversion and management, 64, 626-632. |
[21] | Pokale, W. K. (2012). Effects of thermal power plant on environment. Scientifics Reviews & Chemical Communications, 2 (3), 212-215. |
[22] | Polyzakis, A. L., Koroneos, C and Xydis, G. (2008). "Optimum gas turbine cycle for combined cycle power plant." Energy conversion and management, 49 (4): 551-563. |
[23] | Savabi, M. R., and Stockle, C. O. (2001). Modelling the possible impact of increased CO2 and temperature on soil water balance, crop yield and soil erosion. Environmental Modelling & Software, 16 (7), 631-640. |
[24] | Sonibare, J. A. (2010). Air pollution implications of Nigeria’s present strategy on improved electricity generation. Energy Policy, 38 (10), 5783-5789. |
[25] | Steiner, R. (2010). Double Standard: Shell Practices in Nigeria Compared with International Standards to Prevent and Control Pipeline Oil Spills and the Deepwater Horizon Oil spill. Amsterdam: Milieu Defensie. |
[26] | Weli, V., Adegoke, J., and Kpang, M. (2016). The Epidemiology of Cardio-Vascular Diseases in Relation to the Air Quality of Abattoirs in Port Harcourt, Nigeria. World Journal of Cardiovascular Diseases, 6, 94-106. |
[27] | Westenbarger, D. A., & Frisvold, G. B. (1994). Agricultural exposure to ozone and acid precipitation. Atmospheric Environment, 28 (18), 2895-2907. |
[28] | Xu, X., Li, B., and Huang, H. (1995). Air pollution and unscheduled hospital outpatient and emergency room visits. Environmental Health Perspective, 103 (3): 286–9. |
[29] | Zielinska, B., Sagebiel, J., McDonald, J. D., Whitney, K., Lawson, D. R. (2004) Emission rates and comparative chemical composition from selected in-use diesel and gasoline-fueled vehicles. Journal of Air Waste Management Association 54: 1138-1150. |
APA Style
Prince-Mang Ndidi Loretta, Kpang Meelubari BarinuaTsaro, Imiete Godspower. (2023). Tracking Respiratory Tract Infections Among Residents Due to Pollutant Emissions from Okpai Gas Power Plant in Ndokwa East Local Government Area, Delta State, Nigeria. International Journal of Infectious Diseases and Therapy, 8(3), 109-116. https://doi.org/10.11648/j.ijidt.20230803.15
ACS Style
Prince-Mang Ndidi Loretta; Kpang Meelubari BarinuaTsaro; Imiete Godspower. Tracking Respiratory Tract Infections Among Residents Due to Pollutant Emissions from Okpai Gas Power Plant in Ndokwa East Local Government Area, Delta State, Nigeria. Int. J. Infect. Dis. Ther. 2023, 8(3), 109-116. doi: 10.11648/j.ijidt.20230803.15
AMA Style
Prince-Mang Ndidi Loretta, Kpang Meelubari BarinuaTsaro, Imiete Godspower. Tracking Respiratory Tract Infections Among Residents Due to Pollutant Emissions from Okpai Gas Power Plant in Ndokwa East Local Government Area, Delta State, Nigeria. Int J Infect Dis Ther. 2023;8(3):109-116. doi: 10.11648/j.ijidt.20230803.15
@article{10.11648/j.ijidt.20230803.15, author = {Prince-Mang Ndidi Loretta and Kpang Meelubari BarinuaTsaro and Imiete Godspower}, title = {Tracking Respiratory Tract Infections Among Residents Due to Pollutant Emissions from Okpai Gas Power Plant in Ndokwa East Local Government Area, Delta State, Nigeria}, journal = {International Journal of Infectious Diseases and Therapy}, volume = {8}, number = {3}, pages = {109-116}, doi = {10.11648/j.ijidt.20230803.15}, url = {https://doi.org/10.11648/j.ijidt.20230803.15}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ijidt.20230803.15}, abstract = {As population increases, more buildings for housing, commerce and industry are also required and the resultant effect of this change is a rise in demand for electric power availability accompanied with harmful emissions from power plants installed for electricity generation and other industrial activities. More than 50% of power generated in Nigeria is from thermal power plants (TPP) which utilizes natural gas for their operations. The environmental and health impacts of thermal power plant are quite devastating as it is known for the emission of large amount of CO, CO2, SOx, NOx and SPMs into the atmosphere responsible for most respiratory disorders. This study was aimed at tracking Respiratory Tract Infections (RTI) among residents of Ndokwa within the vicinity of Okpai gas power plant due to pollutant emissions from the plant. The reported cases of RTI was obtained from the archive of Anieze Primary Health Centre while other relevant data was collected through questionnaire distributed among residents within 200m, 400m, 600m, 800m, 1000m and 2000m distances from the gas plant. The Spearman Rank Correlation coefficient value, r=0.827 revealed that there is a significant relationship between RTI and pollutant emission at (F= 28.02, p<0.05. It was also found that 68.4% of RTI in the area was due to pollutant emission, though it occurrence varies significantly with distance. Arising from the findings, regular RTI screening and early detection/treatment, investment in alternative environmentally friendly sources of power generation, constant air quality monitoring and enforcement of regulated threshold, installation of gadgets that will ameliorate the level of gaseous emissions at the gas plant were recommended for urgent implementation in order to cause a significant reduction in air pollutant emission and further prune its associated health hazards in the area.}, year = {2023} }
TY - JOUR T1 - Tracking Respiratory Tract Infections Among Residents Due to Pollutant Emissions from Okpai Gas Power Plant in Ndokwa East Local Government Area, Delta State, Nigeria AU - Prince-Mang Ndidi Loretta AU - Kpang Meelubari BarinuaTsaro AU - Imiete Godspower Y1 - 2023/08/22 PY - 2023 N1 - https://doi.org/10.11648/j.ijidt.20230803.15 DO - 10.11648/j.ijidt.20230803.15 T2 - International Journal of Infectious Diseases and Therapy JF - International Journal of Infectious Diseases and Therapy JO - International Journal of Infectious Diseases and Therapy SP - 109 EP - 116 PB - Science Publishing Group SN - 2578-966X UR - https://doi.org/10.11648/j.ijidt.20230803.15 AB - As population increases, more buildings for housing, commerce and industry are also required and the resultant effect of this change is a rise in demand for electric power availability accompanied with harmful emissions from power plants installed for electricity generation and other industrial activities. More than 50% of power generated in Nigeria is from thermal power plants (TPP) which utilizes natural gas for their operations. The environmental and health impacts of thermal power plant are quite devastating as it is known for the emission of large amount of CO, CO2, SOx, NOx and SPMs into the atmosphere responsible for most respiratory disorders. This study was aimed at tracking Respiratory Tract Infections (RTI) among residents of Ndokwa within the vicinity of Okpai gas power plant due to pollutant emissions from the plant. The reported cases of RTI was obtained from the archive of Anieze Primary Health Centre while other relevant data was collected through questionnaire distributed among residents within 200m, 400m, 600m, 800m, 1000m and 2000m distances from the gas plant. The Spearman Rank Correlation coefficient value, r=0.827 revealed that there is a significant relationship between RTI and pollutant emission at (F= 28.02, p<0.05. It was also found that 68.4% of RTI in the area was due to pollutant emission, though it occurrence varies significantly with distance. Arising from the findings, regular RTI screening and early detection/treatment, investment in alternative environmentally friendly sources of power generation, constant air quality monitoring and enforcement of regulated threshold, installation of gadgets that will ameliorate the level of gaseous emissions at the gas plant were recommended for urgent implementation in order to cause a significant reduction in air pollutant emission and further prune its associated health hazards in the area. VL - 8 IS - 3 ER -