Ecotoxicological Assessment of Leachate from Municipal Solid Waste Dumpsites

The urbanization, industrialization and commercialization, has had its effects to the significant upswing of waste streams ^{1, 2, 3}. In addition, most developing country are challenged by poor funding, legislation and sensitization of the populace on waste reduction, reuse and recycling ⁴. Due to poor or inadequate waste management policies in most developing countries, the application of landfills system have become a threat to biodiversity ⁴.

Huge streams of untreated and unsegregated waste are seen littered across most metropolis with potential infringement of the ecosystem. These wastes undergoes environmental transformation infringing on vital components of the ecosystem, including soil, are and water are most obliged media of environmental pollution. For instance leachates from dumpsites infiltrate to pollute groundwater or swept by runoff thereby causing surface water contamination. Toxicants from leachate have been found to have attendant adverse effect on biodiversity especially groundwater resource and aquatic biota ^{3, 5, 6}.

Yenagoa Metropolis is the capital city of Bayelsa State, which is a deltaic wetland that forms part of the Niger Delta Region. Its climate is humid tropical, with high precipitation that favour the transformation and mobility of leachate contaminants ⁴. Heavy metals are major toxic component in waste leachate, in contaminated soil can enrich the ecosystem, and accumulated in food chain complexes with potential adverse effects ⁷.

Heavy metals like Cadmium can cause acute systemic impairment of the heart, brain, and kidney ⁷. Heavy metal like iron from the Niger Delta Region have been reported for fish kill ⁸, inhibit plant growth and metabolic processes like; ascorbic acid and chlorophyll levels of ⁹. Consequently, the Ecotoxicological assessment of leachate from municipal solid waste dumpsites have become necessary.

Table 1 presents the results of general physicochemical properties of the leachates. The leachate from Akenpai station had pH of 5.87 and turbidity of 94.33NTU, also the leachate indicated BOD5 and COD level of 75.33 and 95.67 mg/l respectively. The physicochemical properties of leachate from Etegwe station had pH of 5.57 and turbidity of 211.00NTU, also the BOD5 and COD level of the leachate were 81.67 and 111.00 mg/l respectively. The physicochemical assessment of leachate from Opolo market station recorded pH of 6.33, turbidity of 182.33NTU, as well as BOD₅ and COD level of 61.33 and 84.33 mg/l respectively (Table 1). The physicochemical properties of leachate from Kpansia market station had pH value of 6.13 and turbidity of 198.00NTU, BOD5 of 53.00 mg/l and a COD level of 74.33 mg/l respectively (Table 1).

The physicochemical properties of leachate from the first station of the central dumpsite was more acidic with pH of 4.87 and turbidity of 285.67NTU, also BOD5 and COD level of 109.67 and 130.67 mg/l respectively (Table 1). The physicochemical properties of leachate from the second station of the central dumpsite indicated pH level of 5.20, turbidity of 232.67NTU, as well as BOD5 and COD levels of 93.00 and 124.00 mg/l respectively (Table 1).

Table 2 presents results of the rapid toxicity screening of fingerlings and adult catfish assayed against leachates from 6 dumpsite stations. Result of the all leachates bioassay against the fingerling indicated total mortalities (Table 1). Furthermore at concentrations of 500 and 1000ppm in less than 8 hours. On the other hand, the toxicity bioassay of leachates from all dumpsites against the adult catfish significantly (p<0.05) induced no mortalities at the already established concentrations (500 and 1000ppm), within 96 hours. Notwithstanding, sublethal effects against the adult fish were observed during the bioassay.

Meanwhile the negative control induced no mortality to both adult and fingerlings throughout the exposure of the bioassay at 500 and 1000ppm. On the other hand, the positive control significantly (p<0.05) induced total mortalities to both fingerling and adult fish at 500 and 1000ppm respectively. As such, the fingerling bioassay that induced mortalities at concentration ≤ 500ppm is further subjected to final screening, as opposed to the adult species that had no adverse effects at concentrations ≥1000ppm.

Table 3 presents the results of the final screening of leachates from the dumpsite stations, assayed against the fingerlings. Leachates from the Akenpai station had No Observable Adverse Effect Level (NOAEL) at concentration of 50ppm, while Lowest Observable Adverse Effect Level (LOAEL) was induced at concentration of 75ppm with mortality rate of 13.33% (p<0.05). Meanwhile, the minimal lethal concentration (LC100) was indicated at concentration of 200ppm within exposure of 5 hours (p<0.05), with mortality time of 10 hours.

Table 3 presents the results of the final screening of leachates from the dumpsite stations, assayed against the fingerlings. Leachates from the Akenpai station had No Observable Adverse Effect Level (NOAEL) at concentration of 50ppm, while Lowest Observable Adverse Effect Level (LOAEL) was induced at concentration of 75ppm with mortality rate of 13.33% (Figure 1). Meanwhile, the minimal lethal concentration (LC₁₀₀) was indicated at concentration of 200ppm within exposure of 5 hours (p<0.05), with mortality time of 10 hours.

Furthermore, based on the dose-response curve statistical assessment of the leachate from the Akenpai station induced mortality with LC₅₀ value of 124.57ppm (Figure 1). The physicochemical properties of leachate from Akenpai station had pH of 5.87 and turbidity of 94.33NTU, also the leachate indicated BOD5 and COD level of 75.33 and 95.67 mg/l respectively (Table 25). Table 3 presents the results of the final screening of leachates from the dumpsite stations, assayed against the fingerlings. Leachates from the Akenpai station had No Observable Adverse Effect Level (NOAEL) at concentration of 50ppm, while Lowest Observable Adverse Effect Level (LOAEL) was induced at concentration of 75ppm with mortality rate of 13.33% (Figure 1). Meanwhile, the minimal lethal concentration (LC₁₀₀) was indicated at concentration of 200ppm within exposure of 5 hours (p<0.05), with mortality time of 10 hours. Furthermore, based on the dose-response curve statistical assessment of the leachate from the Akenpai station induced mortality with LC₅₀ value of 124.57ppm.

Figure 1.Dose-Response of Leachate from Akenpai Station

Results of the final screening of leachates from the dumpsite at Etegwe station, assayed against the fingerlings had NOAEL value at concentration of 25ppm (Table 3). However, LOAEL was induced at concentration of 50ppm with mortality rate of 16.67%. Meanwhile, the minimal lethal concentration (LC₁₀₀) was significantly (p<0.05) induced at concentration of 175ppm within exposure of 4 hours. Furthermore, based on the dose-response curve statistical assessment of the leachate from the Etegwe station induced mortality with LC₅₀ value of 95.38ppm (Figure 2).

Figure 2.Dose-Response of Leachate from Etegwe Station

Leachates from the Opolo Market station, indicated NOAEL at concentration of 75ppm (Table 3). However, LOAEL was induced at concentration of 50ppm with mortality rate of 3.33%. Meanwhile, the minimal lethal concentration was reported at concentration of 225ppm, within exposure of 10 hours. Furthermore, leachate from the Opolo market had LC₅₀ value of 157.95ppm as presented in Figure 3.

Figure 3.Dose-Response of Leachate from Opolo Market Station

Furthermore, results of the toxicity bioassay from leachate in the Kpansia Market station against the fingerlings induced NOAEL at concentration of 100ppm (Table 3). Notwithstanding, the LOAEL was induced at concentration of 125ppm with mortality rate of 13.33%. Meanwhile, the minimal lethal concentration (LC₁₀₀) was significantly (p<0.05) induced at concentration of 225ppm within exposure of 7 hours. Furthermore, based on statistical assessment of the dose-response curve of the leachate from the Kpansia market station induced mortality with LC₅₀ value of 123.82ppm (Figure 4).

Figure 4.Dose-Response of Leachate from Kpansia Market Station

In terms of mortality rate result of the toxicity bioassay from the first station of the central dumpsite (CDS 1) showed NOAEL at concentration of 25ppm (Table 3). However, the LOAEL was induced at concentration of 50ppm with mortality rate of 26.67%. In addition, the minimal lethal concentration (LC₁₀₀) was induced with significant difference (p<0.05) at concentration of 150ppm within exposure of 3 hours. Notwithstanding, based on the statistical dose-response assay, leachate from the first station of the central dumpsite demonstrated mortality with LC₅₀ value of 67.97ppm (Figure 5).

Figure 5.Dose-Response of Leachate from First Station of the Central Dumpsite

Furthermore, compared to the first station of the central dumpsite, results showed that the second station of the central dumpsite (CDS 2), similarly had NOAEL and LOAEL at concentrations of 25 and 50ppm respectively (Table 25). However, a dissimilar mortality rate of the LOAEL was induced at 23.33%. Notwithstanding, the minimal lethal concentration (LC₁₀₀) value of CDS 2 was demonstrated a concentration of 175ppm within similar exposure of 3 hours compared to CDS 1. Based on the statistical dose-response analysis the CDS 2 demonstrated toxicity with LC₅₀ value of 76.65ppm (Figure 6).

Figure 6.Dose-Response of Leachate from Second Station of the Central Dumpsite

On a general basis the order of toxicological activities of the leachates are reported as; CDS 1<CDS2<Etegwe< Akenpai<Kpansia market<Opolo Market. An earlier study of the characterization of leachates from the Niger Delta reported the levels of heavy metals in leachate as; Cadmium (0.00 – 0.17 mg/l), Chromium (0.00 – 0.46mg/l), Copper (0.00 – 0.70mg/l), Manganese (0.20 – 0.60mg/l), mercury (0.00 – 0.27 mg/l), Fe (0.20 – 8.41mg/l), lead (0.27 – 2.77 mg/l) and Zinc which ranged from 0.00 – 4.10 mg/l ¹². In their study, the order of toxicological activities of the heavy metals were; Iron>Lead>Zinc>Manganese>Copper>Chromium>Mercury>Cadmium ¹². The toxicity of the leachates from MSW dumpsite is largely attributed to the presence of heavy metal. Notwithstanding, high level of iron is not farfetched as it is a typical characteristic of the Niger Delta region ^{8, 13, 14}. Another study by Ohimain et al., ⁸, reported high mortality of in a bioassay of ground water containing high level of iron (5.119 - 11.131mg/l), with acidic pH (3.97 - 6.40) against fingerlings of Clariasgariepinus.

The result on pH of leachate from Jeram Sanitary Landfill in Malaysia was less acidic (7.35), the BOD and COD levels were 27,000 and 51,200 mg/l respectively, with acute toxicity test against Orechromismossambicus indicating LC₅₀ value of 3.2% v/v ¹⁵. Comparatively, leachate of our study was more acidic. However, the acidity of leachate from dumpsite may vary depending on its characteristics in terms of maturity and stability ^{15, 16}, type of waste stream and even climatic condition of the location. Other factors may include waste composition, technology adopted, and the dumpsite mode operation, physicochemical properties, meteorological and hydrogeological ^{17, 18}.

Another author reported mortality of dumpsite leachate against tilapia specie (Sarotherodonmossambicus) with LC₅₀ values of 1.4 and 12% v/v in two respective sampling months ¹⁹. Toxicity test of leachate using fish Tawes was carried out and result demonstrated toxicity with LC50 value of 0.358%, with clinical signs of protruded eyes and brown skinned stomach ²⁰. Carp (Cyprinus carpio) from Malasia were tested against dumpsite leachates from three different locations, results had COD and ammonia levels of 1640 - 7600 mg/l and 321.22 - 956.86 mg/l respectively, and also toxicities were demonstrated with LC₅₀ values of 1.132, 2.0 and 3.822% respectively ²¹.

As reported by Sisinno et al. ²² the 48hours acute toxicity of pure and treated dumpsite leachate were investigated against zebrafish (Brachydanio rerio) with LC₅₀ values of pure leachate samples inclusive in the range of 2.2 - 5.7% (v/v). Another author reported LC50 values as 19.2% and 53.0% after 48 hours for adults and fingerlings of Japanese killifish medaka (Oryziaslatipes), respectively ²³.

The research investigated the toxicological activities of leachate from Municipal Solid Waste dumpsite. The results obtained revealed varying degree of toxicity from the leachates. The highest degree of toxicity was demonstrated from the most acidic leachate, with more adverse effect on the fingerlings. This study confirmed that leachates from dumpsite are toxic to biodiversity. Hence policies to characterize, treat, reduce, reuse and recycle waste stream should be encouraged. In addition regulators and all stakeholders should enact laws to check anthropogenic activities.

1. 1.Owusu-Sekyere E, Harris E, Bonyah E. (2013) Forecasting and planning for solid waste generation in the Kumasi Metropolitan Area of Ghana: An ARIMA time series approach. , Int J Sci 2, 69-83.
   Search at Google Scholar

1. 2.Abur B T, Oguche E E, Duvuna G A. (2014) Characterization of Municipal Solid Waste in the Federal Capital Abuja. , Nigeria, Global Journal of Science Frontier Research: Environment & Earth Science 14(2), 6.
   Search at Google Scholar

1. 3.Akoto O, Nimako C, Asante J, Bailey D. (2016) Heavy Metals Enrichment in Surface Soil from Abandoned Waste Disposal Sites in a Hot and Wet Tropical Area. Environ. Process
   Search at Google Scholar

1. 4.E I Seiyaboh, Angaye T C N. (2018) Bioavalability of some heavy metals associated with Municipal Solid waste in. , Yenagoa Metropolis, Nigeria, Journal of Medical Toxicology 1(2), 1-5.
   Search at Google Scholar

1. 5.E A Oluyemi, Feuyit G, JAO Oyekunle, Ogunfowokan A O. (2008) Seasonal variations in heavy metal concentrations in soil and some selected crops at a landfill in Nigeria. , Afr J Environ Sci Technol 2(5), 89-96.
   Search at Google Scholar

1. 6.Angaye T C N, Abowei J F N. (2017) Review on the Environmental Impacts of Municipal Solid Waste in Nigerian Challenges and Prospects. , Greener Journal of Environmental Management and Public Safety 6(2), 18-33.
   Search at Google Scholar

1. 7.M O Eze. (2014) Evaluation of Heavy Metal Accumulation intalinumtriangularegrown around Municipal solid waste dumpsites in Nigeria. , Bulletin of Environment, Pharmacology and Life Sciences 4(1), 92-100.
   Search at Google Scholar

1. 8.E I Ohimain, Angaye T C N, Inyang I R. (2014) Toxicological Assessment of Ground Water Containing High Iron Level against fresh water fish (Clariasgariepinus). , American Journal of Environmental Protection 3(2), 59-63.
   Search at Google Scholar

1. 9.B A Falusi, Odedokun O A, Abubakar A, Agoh A. (2016) Effects of dumpsites air pollution on the ascorbic acid and chlorophyll contents of medicinal plants. , Cogent Environmental Science 2, 1-13.
   Search at Google Scholar

1. 10.I O Agboola, G O Ajayi, S A Adesegun, S A Adesanya. (2011) Comparative Molluscicidal activity of fruit pericarp, leaves, seed and stem Bark ofBlighiaunijugataBaker. , Pharmacology Journal 3, 63-66.
   Search at Google Scholar

1. 11.Angaye T C N, D V Zige, Didi B, Biobelemoye N, E A Gbodo. (2014) Comparative molluscicidal activities of Methanolic and crude extracts ofJatrophacurcasleaves againstBiomphalariapfeifferi. , Greener Journal of Epidemiology and Public Health 2(1), 016-022.
   Search at Google Scholar

1. 12.Angaye T C N, D V Zige, S C Izah. (2015) Microbial load and heavy metals properties of leachates from solid wastes dumpsites in the Niger. , Delta, Nigeria, Journal of Environmental Treatment Techniques 3(3), 175-180.
   Search at Google Scholar

1. 13.E I Ohimain, Angaye T C N. (2014) Iron levels, other selected physicochemical and microbiological Properties of earthen and concrete catfish ponds in central Niger Delta. , InternationalJournal of Biological and Biomedical Sciences 3(5), 041-043.
   Search at Google Scholar

1. 14.Ohimain E I, TCN Angaye, Okiongbo K S. (2014) Removal of Iron, Coliforms and Acidity from Ground Water obtained from Shallow Aquifer using Trickling Filter Method. , Journal of Environmental Science and Engineering
   Search at Google Scholar

1. 15.C U Emenike, S H Fauziah, Agamuthu P. (2011) Characterization of active landfill leachate and associated Impacts on edible fish (Orechromismossambicus). , Malaysian Journal of Science 30(2), 99-104.
   Search at Google Scholar

1. 16.Chian E, DeWalle F, Hammerberg E. (1976) . Effect of Moisture Regime and other Factors on Municipal Solid Waste Stabilization in Gas and Leachate from Landfills,U.S.EPA-600/0-76-004 73, 85.
   Search at Google Scholar

1. 17.J M Lema, Mendez R, Blazquez R. (1988) Characteristics of landfill leachates and alternatives for their treatment: A review. , Water Air Soil Pollut 40, 223-250.
   View article·Search at Google Scholar

1. 18.P Kjeldsen Christensen, Albrechtsen T H, Heron H J, Nielsen G, Bjerg PL PH et al. (1994) Attenuation of landfill leachate pollutants in aquifers. , Crit. Rev. Environ. Sci. Technol 24, 119-202.
   Search at Google Scholar

1. 19.Wong M. (1989) Toxicity test of landfill leachate usingSarotherodonmossambicus(freshwater fish).Ecotoxicology and Environmental. Safety.17: 149-156.
   Search at Google Scholar

1. 20.Juliardi N A R, R I Wiyanti. (2017) . The Test ability of fish Tawes to Leachate garbage Dump (TPA) Benowo. IOP Conf. Series: Journal of Physics: Conf. Series 953 .
   Search at Google Scholar

1. 21.Alkassasbeh JYM, Heng Yook, L, Surif S. (2009) Testing and the Effect of Landfill Leachate in Malaysia on. , Behavior of Common Carp (CyprinuscarpioL., 1758; Pisces, Cyprinidae). American Journal of Environmental Sciences 5(3), 209-217.
   Search at Google Scholar

1. 22.Sisinno C L S, E C Oliveira-Filho, Dufrayer E M C, J C Moreira, Paumgartten F J R. (2000) Toxicity evaluation of a municipal dump leachate using zebrafish acute tests. , Bull. Environ. Contam. Toxicol 64, 107-113.
   PubMed·View article·Search at Google Scholar

1. 23.Osaki K, Shosaku K, Norihisa T, Yoshiro O. (2006) Toxicity testing of leachate from waste landfills using Medaka (oryziaslatipes) for monitoring environmental safety. , Environ. Monitor. Assess 117, 73-84.
   Search at Google Scholar

1. 1.Šourková Markéta, Adamcová Dana, Zloch Jan, Skutnik Zdzisław, Vaverková Magdalena Daria, 2020, Evaluation of the Phytotoxicity of Leachate from a Municipal Solid Waste Landfill: The Case Study of Bukov Landfill, Environments, 7(12), 111, 10.3390/environments7120111

1. 2.Arliyani Isni, Tangahu Bieby Voijant, Mangkoedihardjo Sarwoko, Zulaika Enny, Kurniawan Setyo Budi, 2023, Enhanced leachate phytodetoxification test combined with plants and rhizobacteria bioaugmentation, Heliyon, 9(1), e12921, 10.1016/j.heliyon.2023.e12921