Development of Heavy Metals Bioaccumulation on Anaerobic Support System with Sulfate Reducing Bacteria Media

Suyasa, I. Wayan Budiarsa; Sukarta, I Nyoman; Suprihatin, Iryanti Eka

doi:10.12911/22998993/188878

Nowa wersja platformy, zawierająca wyłącznie zasoby pełnotekstowe, jest już dostępna.
Przejdź na https://bibliotekanauki.pl

Artykuł - szczegóły

Czasopismo

Journal of Ecological Engineering

2024 | Vol. 25, nr 7 | 295--304

Tytuł artykułu

Development of Heavy Metals Bioaccumulation on Anaerobic Support System with Sulfate Reducing Bacteria Media

Autorzy

Suyasa, I. Wayan Budiarsa , Sukarta, I Nyoman , Suprihatin, Iryanti Eka

Treść / Zawartość

Pełne teksty:

Pobierz

Warianty tytułu

Języki publikacji

Abstrakty

Heavy metals in wastewater come from processes related to heavy metals as raw materials and contaminants. Heavy metals pose a significant threat. Bioaugmentation technique that utilizes communities of microorganisms to bioaccumulation heavy metals from wastewater. However, the application of SRB in anaerobic system installations for wastewater treatment needs to continue to be developed with more practical applications. In this study, the enriched SRB colony source was applied to an anaerobic tank. The grown SRB is used to extract heavy metals from wastewater with the addition of sulfate and supporting nutrients. Throughout the treatment process, the anaerobic system with SRB consistently maintained a sulfate removal efficiency of 87–88%, indicating continued sulfate consumption activity by the SRB colony. Despite the high initial concentration of heavy metals, the system effectively removed>91% of Pb, Cd, Zn, and Cr on days 15, 30, and 45. Additionally, the system reduced the Cu content by 43.6%, thereby reaching peak metal removal heavy. the level was 85% on day 30 and decreased slightly to 83% on day 45. This study bridges the gap in understanding the application of SRB in wastewater treatment systems with effective performance.

Słowa kluczowe

anaerobic system with SRB bioaccumulation heavy metals wastewater Sulphate-reducing bacteria

Wydawca

Czasopismo

Journal of Ecological Engineering

Rocznik

2024

Tom

Vol. 25, nr 7

Strony

295--304

Opis fizyczny

Bibliogr. 46 poz., rys.

Twórcy

autor

Suyasa, I. Wayan Budiarsa

Environmental Chemistry Laboratory, Faculty of Math and Sciences, Udayana University, Jimbaran, BadungBali 80361, Indonesia, budiarsa_suyasa@unud.ac.id

autor

Sukarta, I Nyoman

Chemistry Departement, Faculty of Mathematics and Natural Sciences, Universitas Pendidikan Ganesha, Bandung Indonesia, nyoman.sukarta@undiksha.ac.id
Student in the Environmental Science Doctoral Program at Udayana University, Indonesia

autor

Suprihatin, Iryanti Eka

Chemistry Departement, Faculty of Mathematics and Natural Sciences, Udayana University, Jimbaran, Bali, Indonesia, eka_suprihatin@unud.ac.id

Bibliografia

1. Kibangou, V.A., Lilly, M., Busani Mpofu, A., de Jonge, N., Oyekola, O.O., Jean, W.P. 2022. Sulphatereducing and methanogenic microbial community responses during anaerobic digestion of tannery eff luent. Bioresource Technology, 347, 126308.
2. Amanze, C., Zheng, X., Man, M., Yu, Z., Ai, C., Wu, X., Xiao, S., Xia, M., Yu, R., Wu, X., Shen, L., Liu, Y., Li, J., Dolgor, E., Zeng, W. 2022. Recovery of heavy metals from industrial wastewater using bioelectrochemical system inoculated with novel Castellaniella species. Environmental Research, 205, 112467.
3. Ayala-Parra, P., Sierra-Alvarez, R., Field, J.A. 2016. Treatment of acid rock drainage using a sulphatereducing bioreactor with zero-valent iron. Journal of Hazardous Materials, 308, 97–105.
4. Ayangbenro, A.S., Olanrewaju, O.S., Babalola, O.O. 2018. Sulphate-reducing bacteria as an effective tool for sustainable acid mine bioremediation. Frontiers in Microbiology, 9, 1986.
5. Chen, C., Li, L., Huang, K., Zhang, J., Xie, W.-Y., Lu, Y., Dong, X., Zhao, F.-J. 2019. Sulphate-reducing bacteria and methanogens are involved in arsenic methylation and demethylation in paddy soils. The ISME Journal, 13(10), 2523–2535.
6. Chen, S., Xie, J., Wen, Z. 2021. Chapter Four - Microalgae-based wastewater treatment and utilization of microalgae biomass (Y. Li and W.B. T.-A. in B. Zhou (eds.); 6 (1), 165–198. Elsevier.
7. Cruz Viggi, C., Pagnanelli, F., Cibati, A., Uccelletti, D., Palleschi, C., Toro, L. 2010. Biotreatment and bioassessment of heavy metal removal by sulphate reducing bacteria in fixed bed reactors. Water Research, 44(1), 151–158.
8. Dar, S.A., Kleerebezem, R., Stams, A.J.M., Kuenen, J.G., Muyzer, G. 2008. Competition and coexistence of sulphate-reducing bacteria, acetogens and methanogens in a lab-scale anaerobic bioreactor as affected by changing substrate to sulphate ratio. Applied Microbiology and Biotechnology, 78(6), 1045–1055.
9. Dhall, P., Siddiqi, T.O., Ahmad, A., Kumar, R., Kumar, A. 2012. Restructuring BOD : COD Ratio of Dairy Milk Industrial Wastewaters in BOD Analysis by Formulating a Specific Microbial Seed. The Scientific World Journal, 2012, 105712.
10. Guo, X., Hu, Z., Fu, S., Dong, Y., Jiang, G., Li, Y. 2022. Experimental study of the remediation of acid mine drainage by Maifan stones combined with SRB. PLOS ONE, 17(1), 0261823.
11. Icgen, B., Harrison, S. 2006. Exposure to sulphide causes populations shifts in sulphate-reducing consortia. Research in Microbiology, 157(8), 784–791.
12. Jong, T., Parry, D.L. 2003. Removal of sulphate and heavy metals by sulphate reducing bacteria in short-term bench scale upflow anaerobic packed bed reactor runs. Water Research, 37(14), 3379–3389.
13. Kapoor, R.T., Bani Mfarrej, M.F., Alam, P., Rinklebe, J., Ahmad, P. 2022. Accumulation of chromium in plants and its repercussion in animals and humans. Environmental Pollution, 301, 119044.
14. Kinuthia, G.K., Ngure, V., Beti, D., Lugalia, R., Wangila, A., Kamau, L. 2020. Levels of heavy metals in wastewater and soil samples from open drainage channels in Nairobi, Kenya: community health implication. Scientific Reports, 10, 8434.
15. Kumar, A., Dhall, P., Kumar, R. 2010. Redefining BOD:COD ratio of pulp mill industrial wastewaters in BOD analysis by formulating a specific microbial seed. International Biodeterioration & Biodegradation, 64(3), 197–202.
16. Kushkevych, I., Dordević, D., Vítězová, M. 2019. Toxicity of hydrogen sulphide toward sulphate-reducing bacteria Desulfovibrio piger Vib-7. Archives of Microbiology, 201(3), 389–397.
17. Li, X., Dai, L., Zhang, C., Zeng, G., Liu, Y., Zhou, C., Xu, W., Wu, Y., Tang, X., Liu, W., Lan, S. 2017. Enhanced biological stabilization of heavy metals in sediment using immobilized sulphate reducing bacteria beads with inner cohesive nutrient. Journal of Hazardous Materials, 324, 340–347.
18. Liu, Z., Li, L., Li, Z., Tian, X. 2018. Removal of sulphate and heavy metals by sulphate-reducing bacteria in an expanded granular sludge bed reactor. Environmental Technology, 39(14), 1814-1822.
19. Loomis, D., Guha, N., Hall, A. L., Straif, K. 2018. Identifying occupational carcinogens: an update from the IARC Monographs. Occupational and Environmental Medicine, 75(8), 593–603.
20. Magowo, W.E., Sheridan, C., Rumbold, K. 2020. Global co-occurrence of Acid Mine Drainage and organic rich industrial and domestic effluent: Biological sulphate reduction as a co-treatment-option. Journal of Water Process Engineering, 38, 101650.
21. Mansourri, G., Madani, M. 2016. Examination of the level of heavy metals in wastewater of bandar abbas wastewater treatment plant. Open Journal of Ecology, 6(2), 55–61.
22. McCartney, D.M., Oleszkiewicz, J.A. 1993. Competition between methanogens and sulphate reducers: effect of COD:sulphate ratio and acclimation. Water Environment Research, 65(5), 655–664.
23. Mosivand, S., Kazeminezhad, I., Fathabad, S.P. 2019. Easy, fast, and efficient removal of heavy metals from laboratory and real wastewater using electrocrystalized iron nanostructures. Microchemical Journal, 146, 534–543.
24. Najib, T., Solgi, M., Farazmand, A., Heydarian, S.M., Nasernejad, B. 2017. Optimization of sulphate removal by sulphate reducing bacteria using response surface methodology and heavy metal removal in a sulfidogenic UASB reactor. Journal of Environmental Chemical Engineering, 5(4), 3256–3265.
25. Naushad, M., Mittal, A., Rathore, M., Gupta, V. 2015. Ion-exchange kinetic studies for Cd(II), Co(II), Cu(II), and Pb(II) metal ions over a composite cation exchanger. Desalination and Water Treatment, 54(10), 2883–2890.
26. Neria-González, M.I., Aguilar-López, R. 2021. Heavy metal removal processes by sulphatereducing bacteria. environmental pollution and Remediation, 367–394.
27. Obaid, S.S., Gaikwad, D.K., Sayyed, M.I., Al-Rashdi, K., Pawar, P.P. 2018. Heavy metal ions removal from waste water bythe natural zeolites. Materials Today: Proceedings, 5(9), 17930–17934.
28. Oladipo, A.A., Adeleye, O.J., Oladipo, A.S., Aleshinloye, A.O. 2017. Bio-derived MgO nanopowders for BOD and COD reduction from tannery wastewater. Journal of Water Process Engineering, 16, 142–148.
29. Piña-Salazar, E.Z., Cervantes, F.J., Meraz, M., Celis, L.B. 2011. Biofilm development during the start-up of a sulphate-reducing down-flow fluidized bed reactor at different COD/SO4 2− ratios and HRT. Water Science and Technology, 64(4), 910–916.
30. Pinto, P.X., Al-Abed, S.R., McKernan, J. 2018. Comparison of the efficiency of chitinous and ligneous substrates in metal and sulphate removal from mining-influenced water. Journal of Environmental Management, 227, 321–328.
31. Ren, N.-Q., Chua, H., Chan, S.-Y., Tsang, Y.-F., Sin, N. 2007. Effects of COD/SO42- ratios on an Acidogenic sulphate-reducing reactor. Industrial & Engineering Chemistry Research, 46(6), 1661–1666.
32. Santini, T.C., Degens, B.P., Rate, A.W. 2010. Organic substrates in bioremediation of acidic saline drainage waters by sulphate-reducing bacteria. Water, Air, and Soil Pollution, 209, 251–268.
33. Seong, J.P., Jerng, C.Y., Shin, K.S., Eung, H.K., Yim, S., Cho, Y.J., Gi, M.S., Lee, D.G., Seung, B.K., Lee, D.U., Woo, S.H., Koopman, B. 2007. Dominance of endospore-forming bacteria on a rotating activated bacillus contactor biofilm for advanced wastewater treatment. Journal of Microbiology, 45(2), 113–121.
34. Shi, X., Gao, G., Tian, J., Wang, X. C., Jin, X., Jin, P. 2020. Symbiosis of sulphate-reducing bacteria and methanogenic archaea in sewer systems. Environment International, 143, 105923.
35. Singh, V., Singh, N., Verma, M., Kamal, R., Tiwari, R., Sanjay Chivate, M., Rai, S.N., Kumar, A., Singh, A., Singh, M.P., Vamanu, E., Mishra, V. 2022. Hexavalent-chromium-induced oxidative stress and the protective role of antioxidants against cellular toxicity. Antioxidants, 11(12), 2375.
36. Soliman, N.K., Moustafa, A.F. 2020. Industrial solid waste for heavy metals adsorption features and challenges; a review. Journal of Materials Research and Technology, 9(5), 10235–10253.
37. Sudiartha, G.A. W., Imai, T. 2022. An investigation of temperature downshift influences on anaerobic digestion in the treatment of municipal wastewater sludge. Journal of Water and Environment Technology, 20(5), 154–167.
38. Sudiartha, G.A.W., Imai, T., Hung, Y.-T. 2022. Effects of stepwise temperature shifts in anaerobic digestion for treating municipal wastewater sludge: A Genomic Study. International Journal of Environmental Research and Public Health, 19(9), 5728.
39. Suyasa, W.B., Sudiartha, G.A.W., Pancadewi, G.A.S.K. 2023. Optimization of sulphate-reducing bacteria for treatment of heavy metals-containing laboratory wastewater on anaerobic reactor. Pollution, 9(2), 545–556.
40. Tripathi, A.K., Thakur, P., Saxena, P., Rauniyar, S., Gopalakrishnan, V., Singh, R.N., Gadhamshetty, V., Gnimpieba, E.Z., Jasthi, B.K., Sani, R.K. 2021. Gene sets and mechanisms of sulphate-reducing bacteria biofilm formation and quorum sensing with impact on corrosion. Frontiers in Microbiology, 12, 754140.
41. Virpiranta, H., Sotaniemi, V.-H., Leiviskä, T., Taskila, S., Rämö, J., Johnson, D.B., Tanskanen, J. 2022. Continuous removal of sulphate and metals from acidic mining-impacted waters at low temperature using a sulphate-reducing bacterial consortium. Chemical Engineering Journal, 427, 132050.
42. Wang, F., Peng, S., Fan, L., Li, Y. 2022. Improved sulphate reduction efficiency of sulphate-reducing bacteria in sulphate-rich systems by acclimatization and multiple-grouting. Alexandria Engineering Journal, 61(12), 9993–10005.
43. Wu, J., Niu, Q., Li, L., Hu, Y., Mribet, C., Hojo, T., Li, Y.-Y. 2018. A gradual change between methanogenesis and sulfidogenesis during a long-term UASB treatment of sulphate-rich chemical wastewater. Science of The Total Environment, 636, 168–176.
44. Wu, Z., Firmin, K.A., Cheng, M., Wu, H., Si, Y. 2022. Biochar enhanced Cd and Pb immobilization by sulphate-reducing bacterium isolated from acid mine drainage environment. Journal of Cleaner Production, 366, 132823.
45. Xu, P., Zeng, G., Huang, D., Hu, S., Feng, C., Lai, C., Zhao, M., Huang, C., Li, N., Wei, Z., Xie, G. 2013. Synthesis of iron oxide nanoparticles and their application in Phanerochaete chrysosporium immobilization for Pb(II) removal. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 419, 147–155.
46. Xu, Y.N., Chen, Y. 2020. Advances in heavy metal removal by sulphate-reducing bacteria. Water Science and Technology, 81(9), 1797–1827.

Typ dokumentu

Bibliografia

Identyfikatory

DOI

10.12911/22998993/188878

Identyfikator YADDA

bwmeta1.element.baztech-2306e55e-1d19-42c6-9dc1-a498d2f1c441