Wetlands are important in terms of supporting biodiversity, cycling of nutrients and the filtration of pollutants, but urban development is threatening the role played by these wetlands. This research projects the interaction of the concentration of nutrients and associated biogeochemical indicators over space and seasons in Rubirizi Wetland, Kigali City. The water was sampled on three occasions (inflow, midstream, outflow) between September 2024 and February 2025 and measured in terms of pH, COD, BOD, TSS, total nitrogen (TN) and total phosphorus (TP). Geospatial mapping determined the routes of flow dominance and possible sources of pollution. Findings indicate that the runoff and domestic wastewater are the major sources of pollutants: COD and BOD maximized at the inlet during the rainy season (mostly in November), whereas filtration adequacy in the wetland reduced COD/BOD at the outflow in the dry season. The highest TSS values were observed in high-runoff months and the lower ones were observed in drier months. High TN and TP at outflow points are signs of accumulation of nutrients and eutrophication. The majority of the parameters were within the WHO standards, and there were excesses of TN (September, November), COD (November) and BOD (some rainy-season and a few dry-season points). The trends suggest that there is a powerful seasonal effect and intense impacts of adjacent residential activities. We suggest specific wastewater control, local education, and regular surveillance to safeguard the ecological processes of Rubirizi and decrease the risk of eutrophication.
| Published in | American Journal of Environmental Protection (Volume 14, Issue 5) |
| DOI | 10.11648/j.ajep.20251405.16 |
| Page(s) | 222-236 |
| 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), 2025. Published by Science Publishing Group |
Urban Wetland, Nutrient Dynamics, Rubirizi, COD, BOD, TN, TP, Kigali
| [1] | Alikhani, S., Nummi, P., & Ojala, A. (2021). Urban wetlands: A review on ecological and cultural values. Water, 13(22), 3301. |
| [2] | Camacho-Valdez, V., Rodiles-Hernández, R., Navarrete-Gutiérrez, D. A., & Valencia-Barrera, E. (2022). Tropical wetlands and land use changes: The case of oil palm in neotropical riverine floodplains. PloS one, 17(5), e0266677. |
| [3] | De Mandal, S., Laskar, F., Panda, A. K., & Mishra, R. (2020). Microbial diversity and functional potential in wetland ecosystems. In Recent advancements in microbial diversity (pp. 289-314). Academic Press. |
| [4] | Dey, S., Botta, S., Kallam, R., Angadala, R., & Andugala, J. (2021). Seasonal variation in water quality parameters of Gudlavalleru Engineering College pond. Current Research in Green and Sustainable Chemistry, 4, 100058. |
| [5] | Gionchetta, G., Oliva, F., Romaní, A. M., & Bañeras, L. (2020). Hydrological variations shape diversity and functional responses of streambed microbes. Science of the Total Environment, 714, 136838. |
| [6] | Hossain, s. a. (2020). Application of constructed floating wetland (CFW) in treating urban waste water: a case study on hatirjheel lake (doctoral dissertation, department of civil engineering). |
| [7] | Jarvie, H. P., Pallett, D. W., Schäfer, S. M., Macrae, M. L., Bowes, M. J., Farrand, P.,... & Fisher, N. (2020). Biogeochemical and climate drivers of wetland phosphorus and nitrogen release: Implications for nutrient legacies and eutrophication risk (Vol. 49, No. 6, pp. 1703-1716). |
| [8] | Jie, H., Khan, I., Alharthi, M., Zafar, M. W., & Saeed, A. (2023). Sustainable energy policy, socio-economic development, and ecological footprint: The economic significance of natural resources, population growth, and industrial development. Utilities Policy, 81, 101490. |
| [9] | Julian, P., Osborne, T. Z., & Ellis, R. (2022). Evaluation of Biogeochemical Changes in Channelized and Restored Portions of a Subtropical Floodplain. Hydrobiology, 2(1), 1-18. |
| [10] | Lan, J., Liu, P., Hu, X., & Zhu, S. (2024). Harmful algal blooms in eutrophic marine environments: causes, monitoring, and treatment. Water, 16(17), 2525. |
| [11] | Mushtaq, N., Singh, D. V., Bhat, R. A., Dervash, M. A., & Hameed, O. B. (2020). Freshwater contamination: sources and hazards to aquatic biota. Fresh water pollution dynamics and remediation, 27-50. |
| [12] | Myers, J. H., Rose, G., Odell, E., Zhang, P., Bui, A., & Pettigrove, V. (2022). Household herbicide use as a source of simazine contamination in urban surface waters. Environmental Pollution, 299, 118868. |
| [13] | Ntsanwisi, M. C. (2019). An Assessment of Urban Expansion on a Wetland Ecosystem in Braamfischerville, Soweto, Gauteng Province, South Africa. University of Johannesburg (South Africa). |
| [14] | Ostad-Ali-Askari, K. (2022). Review of the effects of the anthropogenic on the wetland environment. Applied Water Science, 12(12), 260. |
| [15] | Pain, A. J., Martin, J. B., & Young, C. R. (2021). Biogeochemical and hydrological drivers of heterogeneous nutrient exports from subterranean estuaries. Frontiers in Marine Science, 8, 699916. |
| [16] | Pak, H. Y., Chuah, C. J., Yong, E. L., & Snyder, S. A. (2021). Effects of land use configuration, seasonality and point source on water quality in a tropical watershed: A case study of the Johor River Basin. Science of the Total Environment, 780, 146661. |
| [17] | Pandey, B., & Ghosh, A. (2023). Urban ecosystem services and climate change: a dynamic interplay. Frontiers in Sustainable Cities, 5, 1281430. |
| [18] | Patil, V., & Kurve, P. (2022). HYDRO-BIOLOGICAL STUDY OF KAMWARI RIVER AND ITS ESTUARY TO EVALUATE WATER QUALITY. Advance and Innovative Research, 22. (Local journal Journal, Volume 9, Issue 3). |
| [19] | Poth, C. N. (2023). The Sage handbook of mixed methods research design. |
| [20] | Rahman, M. E., Bin Halmi, M. I. E., Bin Abd Samad, M. Y., Uddin, M. K., Mahmud, K., Abd Shukor, M. Y.,... & Shamsuzzaman, S. M. (2020). Design, operation and optimization of constructed wetland for removal of pollutant. International Journal of Environmental Research and Public Health, 17(22), 8339. |
| [21] | Robotham, J., Old, G., Rameshwaran, P., Sear, D., Gasca-Tucker, D., Bishop, J.,... & McKnight, D. (2021). Sediment and nutrient retention in ponds on an agricultural stream: Evaluating effectiveness for diffuse pollution mitigation. Water, 13(12), 1640. |
| [22] | Rodak, C. M., Jayakaran, A. D., Moore, T. L., David, R., Rhodes, E. R., & Vogel, J. R. (2020). Urban stormwater characterization, control, and treatment. Water environment research, 92(10), 1552-1586. |
| [23] | Rouleau, T., Colgan, C. S., Adkins, J., Anthony, C., Patty, D., Lyons, S. andStevens, H. (2021). The economic value of America’s estuaries: 2021 report. |
| [24] | Scholz, M. (2023). Wetlands for water pollution control. Elsevier. |
| [25] | Suresh, K., Tang, T., Van Vliet, M. T., Bierkens, M. F., Strokal, M., Sorger-Domenigg, F., & Wada, Y. (2023). Recent advancement in water quality indicators for eutrophication in global freshwater lakes. Environmental Research Letters, 18(6), 063004. |
APA Style
Nibizi, D. F., Shimirwa, J. C., Ndokoye, P. (2025). Insight into the Changes of Urban Wetland Biogeochemical Functions in Rwanda: Variation of Nutrient Levels in Rubirizi Wetland, Kigali City. American Journal of Environmental Protection, 14(5), 222-236. https://doi.org/10.11648/j.ajep.20251405.16
ACS Style
Nibizi, D. F.; Shimirwa, J. C.; Ndokoye, P. Insight into the Changes of Urban Wetland Biogeochemical Functions in Rwanda: Variation of Nutrient Levels in Rubirizi Wetland, Kigali City. Am. J. Environ. Prot. 2025, 14(5), 222-236. doi: 10.11648/j.ajep.20251405.16
@article{10.11648/j.ajep.20251405.16,
author = {Don Fleury Nibizi and Jean Claude Shimirwa and Pancras Ndokoye},
title = {Insight into the Changes of Urban Wetland Biogeochemical Functions in Rwanda: Variation of Nutrient Levels in Rubirizi Wetland, Kigali City
},
journal = {American Journal of Environmental Protection},
volume = {14},
number = {5},
pages = {222-236},
doi = {10.11648/j.ajep.20251405.16},
url = {https://doi.org/10.11648/j.ajep.20251405.16},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ajep.20251405.16},
abstract = {Wetlands are important in terms of supporting biodiversity, cycling of nutrients and the filtration of pollutants, but urban development is threatening the role played by these wetlands. This research projects the interaction of the concentration of nutrients and associated biogeochemical indicators over space and seasons in Rubirizi Wetland, Kigali City. The water was sampled on three occasions (inflow, midstream, outflow) between September 2024 and February 2025 and measured in terms of pH, COD, BOD, TSS, total nitrogen (TN) and total phosphorus (TP). Geospatial mapping determined the routes of flow dominance and possible sources of pollution. Findings indicate that the runoff and domestic wastewater are the major sources of pollutants: COD and BOD maximized at the inlet during the rainy season (mostly in November), whereas filtration adequacy in the wetland reduced COD/BOD at the outflow in the dry season. The highest TSS values were observed in high-runoff months and the lower ones were observed in drier months. High TN and TP at outflow points are signs of accumulation of nutrients and eutrophication. The majority of the parameters were within the WHO standards, and there were excesses of TN (September, November), COD (November) and BOD (some rainy-season and a few dry-season points). The trends suggest that there is a powerful seasonal effect and intense impacts of adjacent residential activities. We suggest specific wastewater control, local education, and regular surveillance to safeguard the ecological processes of Rubirizi and decrease the risk of eutrophication.
},
year = {2025}
}
TY - JOUR T1 - Insight into the Changes of Urban Wetland Biogeochemical Functions in Rwanda: Variation of Nutrient Levels in Rubirizi Wetland, Kigali City AU - Don Fleury Nibizi AU - Jean Claude Shimirwa AU - Pancras Ndokoye Y1 - 2025/10/27 PY - 2025 N1 - https://doi.org/10.11648/j.ajep.20251405.16 DO - 10.11648/j.ajep.20251405.16 T2 - American Journal of Environmental Protection JF - American Journal of Environmental Protection JO - American Journal of Environmental Protection SP - 222 EP - 236 PB - Science Publishing Group SN - 2328-5699 UR - https://doi.org/10.11648/j.ajep.20251405.16 AB - Wetlands are important in terms of supporting biodiversity, cycling of nutrients and the filtration of pollutants, but urban development is threatening the role played by these wetlands. This research projects the interaction of the concentration of nutrients and associated biogeochemical indicators over space and seasons in Rubirizi Wetland, Kigali City. The water was sampled on three occasions (inflow, midstream, outflow) between September 2024 and February 2025 and measured in terms of pH, COD, BOD, TSS, total nitrogen (TN) and total phosphorus (TP). Geospatial mapping determined the routes of flow dominance and possible sources of pollution. Findings indicate that the runoff and domestic wastewater are the major sources of pollutants: COD and BOD maximized at the inlet during the rainy season (mostly in November), whereas filtration adequacy in the wetland reduced COD/BOD at the outflow in the dry season. The highest TSS values were observed in high-runoff months and the lower ones were observed in drier months. High TN and TP at outflow points are signs of accumulation of nutrients and eutrophication. The majority of the parameters were within the WHO standards, and there were excesses of TN (September, November), COD (November) and BOD (some rainy-season and a few dry-season points). The trends suggest that there is a powerful seasonal effect and intense impacts of adjacent residential activities. We suggest specific wastewater control, local education, and regular surveillance to safeguard the ecological processes of Rubirizi and decrease the risk of eutrophication. VL - 14 IS - 5 ER -