Milhares de toneladas de resíduos são gerados mensalmente na agroindústria, muito desses resíduos não tem um destino apropriado, algumas pesquisas têm verificado a utilização desses resíduos (sementes, cascas, medula, caules, pedúnculos, casca da semente, pericarpo e mesocarpo da fruta) na elaboração de coagulante natural para ser aplicado no tratamento de água e efluente, visto que a maioria dos coagulantes são compostos químicos que deixam algumas vezes resíduos tóxicos ao meio ambiente. Portanto a presente revisão fez um levantamento sobre quais resíduos agroindustriais foram utilizados como agente coagulante para tratamento de água e quais os principais métodos utilizados na elaboração, analise e resultados desses resíduos.

Ali, E. N., Muyibi, S. a, Salleh, H. M., Salleh, M. R. M., & Islamic, I. (2010). Production Technique of Natural Coagulant From Moringa oleifera seeds. Fourteenth International Water Technology Conference, 95–103.

Arantes, C. C., Ribeiro, T. A. P., Paterniani, J. E. S., Tateoka, M. S. S., & Silva, G. K. E. (2014). Uso de coagulantes naturais à base de moringa oleifera e tanino como auxiliares da filtração em geotêxtil sintético não tecido. Engenharia Agricola, 34(4), 780–788.

APHA. (2012). Standard methods for the examination of water and wastewater (22th ed). Washington: American Public Health Association, American Water Works Association.

Babu, R., & Chaudhuri, M. (2005). Home water treatment by direct filtration with natural coagulant. Journal of Water and Health, 03, 27–30.

Baptista, A. T. A., Coldebella, P. F., Cardines, P. H. F., Gomes, R. G., Vieira, M. F., Bergamasco, R., & Vieira, A. M. S. (2015). Coagulation-flocculation process with ultrafiltered saline extract of moringa oleifera for the treatment of surface water. Chemical Engineering Journal, 276, 166–173.

Beltrán-Heredia, J., Sánchez-Martín, J., & Gómez-Muñoz, M. C. (2010). New coagulant agents from tannin extracts: Preliminary optimisation studies. Chemical Engineering Journal, 162(3), 1019–1025.

Birima, A. H., Hammad, H. A., Desa, M. N. M., & Muda, Z. C. (2013). Extraction of natural coagulant from peanut seeds for treatment of turbid water. IOP Conference Series: Earth and Environmental Science, 16(1), 1–4.

Bodlund, I. (2013). Coagulant Protein from plant materials : Potential Water Treatment Agent. Theses, School of Biotechnology, Royal Institute of Technology, AlbaNova University Center, Stockholm, Sweden.

Chaudhuri, M., & Khairuldin, P. S. A. B. (2009). Coagulation-Clarification of Turbid ColouredWater by Natural Coagulant (Moringa oleifera) Seed Extract. Nature Environment and Pollution Technology, 8, 137–139.

Deepthi, P., Sarala, C., Kumar, P. S., & Mukkanti, K. (2017). Cucurbita pepo as a Coagulant Aid for Copper Removal. International Journal of Engineering Research & Technology, 6(9), 33–36.

Dehghani1, M., & Alizadeh, M. H. (2016). The effects of the natural coagulant Moringa oleifera and alum in wastewater treatment at the Bandar Abbas Oil Refinery. Environmental Health Engineering and Management Journal, 3, 225–230.

Dollah, Z., Abdullah, A. R. C., Hashim, N. M., Albar, A., Badrealam, S., & Mohd Zaki, Z. Z. (2019). Citrus fruit peel waste as a source of natural coagulant for water turbidity removal. Journal of Physics: Conference Series, 1349(1).

dos Santos, J. D., Veit, M. T., Juchen, P. T., da Cunha Gonçalves, G., Palácio, S. M., & Fagundes-Klen, M. (2018). Use of different coagulants for cassava processing wastewater treatment. Journal of Environmental Chemical Engineering, 6(2), 1821–1827.

Dotto, J., Fagundes-Klen, M. R., Veit, M. T., Palácio, S. M., & Bergamasco, R. (2019). Performance of different coagulants in the coagulation/flocculation process of textile wastewater. Journal of Cleaner Production, 208, 656–665.

Gobena, B., Adela, Y., & Alemayehu, E. (2017). Evaluation of Mix-Chemical Coagulants in Water Purification Process. International Journal of Engineering Research & Technology, 7(01), 431–435.

Grehs, B. W. N., Lopes, A. R., Moreira, N. F. F., Fernandes, T., Linton, M. A. O., Silva, A. M. T., Manaia, C. M., Carissimi, E., & Nunes, O. C. (2019). Removal of microorganisms and antibiotic resistance genes from treated urban wastewater: A comparison between aluminium sulphate and tannin coagulants. Water Research, 166, 115056.

Greses, S., Tomás-Pejó, E., & Gónzalez-Fernández, C. (2020). Agroindustrial waste as a resource for volatile fatty acids production via anaerobic fermentation. Bioresource Technology, 297.

Jain, R. K., Dange, P. S., & Lad, R. K. (2015). A treament of domestic sewage and generation of bio sludge using natural coagulants. International Journal of Research in Engineering and Technology, 04, 152–156.

Jian, H., & Fu, Y. (2018). Study on Coagulation Effect of Composite Peel Coagulant in Treating Humic Acid Simulated Water. Advances in Engineering Research, 1441–1443.

Kakoi, B., Kaluli, J. W., Ndiba, P., & Thiong’o, G. (2016). Banana pith as a natural coagulant for polluted river water. Ecological Engineering, 95, 699–705.

Kiew, P. L., & Chong, K. H. (2017). Development of fruit-based waste material as bioflocculant for water clarification. Journal of Mechanical Engineering, SI 4(5), 1–10.

Lee, C. S., Robinson, J., & Chong, M. F. (2014). A review on application of flocculants in wastewater treatment. Process Safety and Environmental Protection, 92(6), 489–508.

Lima Júnior, R. N., & Abreu, F. O. M. S. (2018). Produtos Naturais Utilizados como Coagulantes e Floculantes para Tratamento de Águas: Uma Revisão sobre Benefícios e Potencialidades. Revista Virtual de Quimica, 10(3), 709–735.

Lopes, E. C., Santos, S. C. R., Pintor, A. M. A., Boaventura, R. A. R., & Botelho, C. M. S. (2019). Evaluation of a tannin-based coagulant on the decolorization of synthetic effluents. Journal of Environmental Chemical Engineering, 7(3).

Mangale Sapana M., C., G., C. S., & D., R. P. (2012). Use of Moringa Oleifera (Drumstick) seed as Natural Absorbent. Research Journal of Recent Sciences, 1, 31–40.

Mohan, S. M. (2014). Use of naturalized coagulants in removing laundry waste surfactant using various unit processes in lab-scale. Journal of Environmental Management, 136, 103–111.

Muniz, G. L., Borges, A. C., & Silva, T. C. F. da. (2020). Performance of natural coagulants obtained from agro-industrial wastes in dairy wastewater treatment using dissolved air flotation. Journal of Water Process Engineering, 37, 101453.

Muralimohan, N., Palanisamy, T., & Vimaladevi, M. N. (2014). Experimental Study on Removal Efficiency of Blended Coagulants. International Journal of Research in Engineering and Technology, 2(2), 15–20.

Nascimento Filho, W. B. do, & Franco, C. R. (2015). Potential Assessment of Waste Produced Through the Agro-Industrial Processing in Brazil. Revista Virtual de Química, 7(6), 1968–1987.

Nonfodji, O. M., Fatombi, J. K., Ahoyo, T. A., Osseni, S. A., & Aminou, T. (2020). Performance of Moringa oleifera seeds protein and Moringa oleifera seeds protein-polyaluminum chloride composite coagulant in removing organic matter and antibiotic resistant bacteria from hospital wastewater. Journal of Water Process Engineering, 33.

Okuda, T., Baes, A. U., Nishijima, W., & Okada, M. (2001). Isolation and characterization of coagulant extracted from Moringa oleifera seed by salt solution. Water Research, 35(2), 405–410.

Othman, N., Abd-Rahim, N. S., Tuan-Besar, S. N. F., Mohd-Asharuddin, S., & Kumar, V. (2018). A Pontential Agriculture Waste Material as Coagulant Aid: Cassava Peel. IOP Conference Series: Materials Science and Engineering, 311(1), 012022.

Paterniani, J. E. S., Ribeiro, T. A. P., Mantovani, M. C., & Sant́anna, M. R. (2010). Water treatment by sedimentation and slow fabric filtration using moringa oleifera seeds. African Journal of Agricultural Research, 5(11), 1256–1263.

Priyatharishini, M., Mokhtar, N. M., & Kristanti, R. A. (2019). Study on the Effectiveness of Banana Peel Coagulant in Turbidity Reduction of Synthetic Wastewater. International Journal of Engineering Technology and Sciences, 6, 82–90.

Sánchez-Martín, J., Beltrán-Heredia, J., & Peres, J. A. (2012). Improvement of the flocculation process in water treatment by using Moringa oleifera seeds extract. Brazilian Journal of Chemical Engineering, 29(3), 495–501.

Sapana, M. M., Sonal, C. G., & D, R. P. (2012). Use of Moringa Oleifera (Drumstick) seed as Natural Absorbent and an Antimicrobial agent for Ground water Treatment. Research Journal of Recent Sciences, 1(3), 31–40.

Sillanpää, M., Ncibi, M. C., Matilainen, A., & Vepsäläinen, M. (2018). Removal of natural organic matter in drinking water treatment by coagulation: A comprehensive review. Chemosphere, l(190), 54–71.

Skoronski, E., Niero, B., Fernandes, M., Alves, M. V., & Trevisan, V. (2014). Estudo da aplicação de tanino no tratamento de água para abastecimento captada no rio Tubarão, Na cidade de Tubarão, SC. Revista Ambiente e Água, 9(4), p. 679–687.

Sutherland, J. P., Folkard, G. K., Mtawali, M. A., & Grant, W. D. (1994). Moringa oleifera as a natural coagulant. 20th WEDC Conference, 1–3.

Taiwo, A. S., Adenike, K., & Aderonke, O. (2020). Efficacy of a natural coagulant protein from Moringa oleifera (Lam) seeds in treatment of Opa reservoir water, Ile-Ife, Nigeria. Heliyon, 6(1).

Trevisan, T. S. (2014). Coagulante Tanfloc Sg Como Alternativa Ao Uso De Coagulantes Químicos No Tratamento De Água Na Eta Cafezal Trabalho De Conclusão De Curso (p. 106).

Tropea, A., Wilson, D., Torre, L. G. La, Curto, R. B. Lo, Saugman, P., Troy-Davies, P., Dugo, G., & Waldron, K. W. (2014). Bioethanol Production From Pineapple Wastes. Journal of Food Research, 3(4), 60.

Ugwu, S. N., Umuokoro, A. F., Echiegu, E. A., Ugwuishiwu, B. O., & Enweremadu, C. C. (2017). Comparative study of the use of natural and artificial coagulants for the treatment of sullage (domestic wastewater). Cogent Engineering, 4(1).

Villaseñor-Basulto, D. L., Astudillo-Sánchez, P. D., del Real-Olvera, J., & Bandala, E. R. (2018). Wastewater treatment using Moringa oleifera Lam seeds: A review. Journal of Water Process Engineering, 23, 151–164.

Warrier, R. R., Sing, B., Balaji, C., & Priyadarshini, P. (2014). Storage Duration and Temperature Effects of Strychnos potatorum Stock Solutions on its Coagulation Efficiency. Journal of Tropical Forestry and Environment, 4(2), 45–56.

Yongabi, K. (2010). Biocoagulants for water and waste water purification: a review. International review of chemical engineering, 2(3), 444–458.

Yusuf, M. (2017). Agro-Industrial Waste Materials and their Recycled Value-Added Applications: Review. In Handbook of Ecomaterials (p. 1–11).

Zaidi, N. S., Muda, K., Loan, L. W., Sgawi, M. S., & Abdul Rahman, M. A. (2019). Potential of Fruit Peels in Becoming Natural Coagulant for Water Treatment. International Journal of Integrated Engineering, 11(1), 140–150.

Zurina, A. Z., Mohd Fadzli, M., & Abdul Ghani, L. A. (2014). Preliminary Study of Rambutan (Nephelium lappaceum) Seed as Potential Biocoagulant for Turbidity Removal. Advanced Materials Research, 917, 96–105.