Prospects for using wastewater from a farm for algae cultivation: The case of Eastern Colombia

Urbina-Suarez, Nestor Andres; Barajas-Solano, Andres Fernando; Garcia-Martinez, Janet Bibiana; Lopez-Barrera, German Luciano; González-Delgado, Angel Dario

doi:10.24425/jwld.2022.140387

dc.contributor.author	Urbina-Suarez, Nestor Andres
dc.contributor.author	Barajas-Solano, Andres Fernando
dc.contributor.author	Garcia-Martinez, Janet Bibiana
dc.contributor.author	Lopez-Barrera, German Luciano
dc.contributor.author	González-Delgado, Angel Dario
dc.date.accessioned	2022-12-04T20:39:32Z
dc.date.available	2022-12-04T20:39:32Z
dc.date.issued	2021-05-24
dc.identifier.uri	https://repositorio.ufps.edu.co/handle/ufps/6629
dc.description.abstract	: In recent years, the technical and economic feasibility of using microalgae and cyanobacteria has been explored for the removal and exploitation of domestic, agricultural and industrial residual effluents with high C, N and P compounds content. To contribute to the understanding of the process and its technical viability for microalgae growth, the article discusses monitoring, flow determination, and physicochemical characteristics of two types of effluents generated in an experimental farm located in the east of Colombia, before (R1) and after biological treatment (R2). In general, the results showed the reduction of different parameters, such as total dissolved solids (TDS), hardness, salinity and phosphates after treatment with activated sludge. However, the conductivity value obtained in R1 and R2 showed the presence of a pollutant load. These findings can be attributed to the highest concentration of fats and oils in the water during early hours of the day. Finally, although the concentration of nitrates increased from 46.63 to 225.21 mg∙dm–3 and phosphate decreased slightly from 9.65 to 6.21 mg∙dm–3, no inhibition was generated in the microalgae, as evidenced in the growth of the microalgal biomass in effluents after nitrate and phosphate removal above 80%.	eng
dc.format.extent	7 paginas	spa
dc.format.mimetype	application/pdf	spa
dc.language.iso	eng	spa
dc.rights	© 2021. The Authors. Published by Polish Academy of Sciences (PAN) and Institute of Technology and Life Sciences	eng
dc.rights.uri	https://creativecommons.org/licenses/by-nc-nd/4.0/	spa
dc.source	https://journals.pan.pl/dlibra/publication/140387/edition/122643/content	spa
dc.title	Prospects for using wastewater from a farm for algae cultivation: The case of Eastern Colombia	eng
dc.type	Artículo de revista	spa
dcterms.references	ABDEL-RAOUF N., AL-HOMAIDAN A.A., IBRAHEEM I.B.M. 2012. Microalgae and wastewater treatment. Saudi Journal of Biological Sciences. Vol. 19. Iss. 3 p. 257–275. DOI 10.1016/j.sjbs.2012.04.005.	spa
dcterms.references	BAIRD R., BRIDGEWATER L. 2017. Standard methods for the examination of water and waste water. 23rd ed. Washington. APHA. ISBN 9780875532875 pp. 1796.	spa
dcterms.references	BAIRD R., BRIDGEWATER L. 2017. Standard methods for the examination of water and waste water. 23rd ed. Washington. APHA. ISBN 9780875532875 pp. 1796.	spa
dcterms.references	BEKKOUCH M., ZANAGUI A. 2018. Quality of Hamadian groundwater table of the continental tertiary of Wadi Mehiya in Tindouf province (South-West of Algeria). Journal of Water and Land Development. No. 39 p. 3–9. DOI 10.2478/jwld-2018-0053.	spa
dcterms.references	BENEMANN J., WOERTZ I., LUNDQUIST T. 2012. Life cycle assessment for microalgae oil production. Disruptive Science and Technology. Vol. 1. Iss. 2 p. 68–78. DOI 10.1089/dst.2012.0013.	spa
dcterms.references	BOROWITZKA M.A. 2015. Algal biotechnology. In: The algae world. Eds. D. Sahoo, J. Seckbach. Dordrecht, Netherlands. Springer p. 319–338.	spa
dcterms.references	BURZYŃSKA I. 2019. Monitoring of selected fertilizer nutrients in surface waters and soils of agricultural land in the river valley in Central Poland. Journal of Water and Land Development. No. 43 p. 41–48. DOI 10.2478/jwld-2019-0061.	spa
dcterms.references	CAI T., PARK S.Y., LI Y. 2013. Nutrient recovery from wastewater streams by microalgae: status and prospects. Renewable and Sustainable Energy Reviews. Vol. 19 p. 360–369. DOI 10.1016/j. rser.2012.11.030.	spa
dcterms.references	CAMARGO J., ALONSO A. 2006. Ecological and toxicological effects of inorganic nitrogen pollution in aquatic ecosystems: A global assessment. Environmental International. Vol. 32. Iss. 6 p. 831– 849. DOI 10.1016/j.envint.2006.05.002.	spa
dcterms.references	CARVALHO J.C., BORGHETTI I.A., CARTAS L.C., WOICIECHOWSKI A.L., SOCCOL V. T., SOCCOL C.R. 2018. Biorefinery integration of microalgae production into cassava processing industry: Potential and perspectives. Bioresource Technology. Vol. 247 p. 1165– 1172. DOI 10.1016/j.biortech.2017.09.213.	spa
dcterms.references	CHEN B., CAI D., LUO Z., CHEN C., ZHANG C., QIN P., CAO H., TAN T. 2018. Corncob residual reinforced polyethylene composites considering the biorefinery process and the enhancement of performance. Journal of Cleaner Production. Vol. 198 p. 452– 462. DOI 10.1016/j.jclepro.2018.07.080.	spa
dcterms.references	CHISTI Y. 2007. Biodiesel from microalgae. Biotechnology Advances. Vol. 25. Iss. 3 p. 294–306.	spa
dcterms.references	CLARENS A.F., RESURRECCION E.P., WHITE M.A., COLOSI L.M. 2010. Environmental life cycle comparison of algae to other bioenergy feedstocks. Environmental Science & Technology. Vol. 44. Iss. 5 p. 1813–1819	spa
dcterms.references	CRAMER M., SCHELHORN P., KOTZBAUER U., TRÄNCKNER J. 2019. Degradation kinetics and COD fractioning of agricultural wastewaters from biogas plants applying biofilm respirometry. Environmental Technology. Vol. 42. Iss. 15 p. 2391–2401. DOI 10.1080/09593330.2019.1701570.	spa
dcterms.references	CUÉLLAR-GARCÍA D.J., RANGEL-BASTO Y.A., URBINA-SUAREZ N.A., BARAJASSOLANO A.F., MUÑOZ-PEÑALOZA Y.A. 2019. Lipids production from Scenedesmus obliquus through carbon/nitrogen ratio optimization. Journal of Physics: Conference Series. Vol. 1388. Iss. 1, 012043. DOI 10.1088/1742-6596/1388/1/012043.	spa
dcterms.references	DOMAŃSKA M., BORAL A., HAMAL K., KUŚNIERZ M., ŁOMOTOWSKI J., PŁAZAOŻÓG P. 2019. Efficiency of municipal wastewater treatment with membrane bioreactor. Journal of Water and Land Development. No. 41 p. 47–54. DOI 10.2478/jwld-2019-0026.	spa
dcterms.references	EBRAHIMIAN A., KARIMINIA H.R., VOSOUGHI M. 2014. Lipid production in mixotrophic cultivation of Chlorella vulgaris in a mixture of primary and secondary municipal wastewater. Renewable Energy. Vol. 71 p. 502–508. DOI 10.1016/j.renene.2014.05.031.	spa
dcterms.references	FAZAL T., MUSHTAQ A., REHMAN F., KHAN A.U., RASHID N., FAROOQ W., XU J. 2018. Bioremediation of textile wastewater and successive biodiesel production using microalgae. Renewable and Sustainable Energy Reviews. Vol. 82 p. 3107–3126. DOI 10.1016/j.rser .2017.10.029.	spa
dcterms.references	FERNÁNDEZ D., CHICA C., PARRA M. 2013. Obtención de ácidos grasos a partir de biomasa microalgal cultivada bajo diferentes condiciones de iluminación [Obtaining fatty acids from microalgal biomass grown under different lighting conditions]. Revista Elementos. Num. 3 p. 111–119. DOI 10.15765/e.v3i3.418.	spa
dcterms.references	FLÓREZ L., CAÑIZARES R.O., MELCHY O., MARTÍNEZ F., FLORES C.M. 2017. Two stage heterotrophy/photoinduction culture of Scenedesmus incrassatulus: Potential for lutein production. Journal of Biotechnology. Vol. 262 p. 67–74. DOI 10.1016/j.jbiotec.2017.09.002.	spa
dcterms.references	GONZALEZ-DELGADO A., KAFAROV V. 2011. Microalgae based biorefinery: Issues to consider. CT&F-Ciencia, Tecnología y Futuro. Vol. 4. Iss. 4 p. 5–22. DOI 10.29047/01225383.225.	spa
dcterms.references	JAIMES D., SOLER W., VELASCO J., MUÑOZ Y., URBINA N. 2012. Characterization Chlorophytas microalgae with potential in the production of lipids for biofuels. CT&F-Ciencia, Tecnología y Futuro. Vol. 5 Iss. 1 p. 93–102. DOI 10.29047/01225383.210.	spa
dcterms.references	JAIMES D., SOLER W., VELASCO J., MUÑOZ Y., URBINA N. 2012. Characterization Chlorophytas microalgae with potential in the production of lipids for biofuels. CT&F-Ciencia, Tecnología y Futuro. Vol. 5 Iss. 1 p. 93–102. DOI 10.29047/01225383.210.	spa
dcterms.references	KONG W., SONG H., CAO Y., YONG H., HUA S., XIO C. 2011. The characteristics of biomass production, lipid accumul and chlorophyll biosynthesis of Chlorella vulgaris under mixotrophic cultivation. African Journal of Biotechnology. Vol. 10(55) p. 11620–11630. DOI 10.5897/AJB11.617.	spa
dcterms.references	LAM M.K., LEE K.T. 2012. Potential of using organic fertilizer to cultivate Chlorella vulgaris for biodiesel production. Applied Energy. Vol. 94 p. 303–308. DOI 10.1016/j.apenergy.2012.01.075.	spa
dcterms.references	LEAL MEDINA G.I., ABRIL BONETT J.E., MARTÍNEZ GÉLVEZ S.J., MUÑOZ PEÑALOZA Y.A., PEÑARANDA LIZARAZO E.M., URBINA SUÁREZ N.A. 2017. Producción de ácidos grasos poliinsaturados a partir de biomasa microalgal en un cultivo heterotrófico [Production of polyunsaturated fatty acids from microalgal biomass in a heterotrophic culture]. Revista Ion. Vol. 30(1) p. 91–103. DOI 10.18273/revion.v30n1-2017007.	spa
dcterms.references	LEE C.G. 1999. Calculation of light penetration depth in photobioreactors. Biotechnology and Bioprocess Engineering. Vol. 4 p. 78–81. DOI 10.1007/BF02931920.	spa
dcterms.references	LI Y., HAN F., XU H., MU J., CHEN D., FENG B., ZENG H. 2014. Potential lipid accumulation and growth characteristic of the green alga Chlorella with combination cultivation mode of nitrogen (N) and phosphorus (P). Bioresource Technology. Vol. 174 p. 24–32. DOI 10.1016/j.biortech.2014.09.142.	spa
dcterms.references	MARSELINA M., BURHANUDIN M. 2018. Phosphorus load concentration in tropical climates reservoir for each water quantity class. Journal of Water and Land Development. No. 36 p. 99–104. DOI 10.2478/jwld-2018-0010.	spa
dcterms.references	MERZOUGUI F., MAKHLOUFI A., MERZOUGUI T. 2019. Hydro-chemical and microbiological characterization of Lower Cretaceous waters in a semi-arid zone Beni-Ounif syncline, South-West of Algeria. Journal of Water and Land Development. Vol. 40 p. 67–80. DOI 10.2478/jwld-2019-0007.	spa
dcterms.references	MOHEIMANI N.R., BOROWITZKA M.A., ISDEPSKY A., SING S.F. 2013. Standard methods for measuring growth of algae and their composition. In: Algae for biofuels and energy. Eds. M.A. Borowitzka, N.R. Moheimani. Dordrecht. Springer p. 265–284.	spa
dcterms.references	OBETA M., OKAFOR U., NWANKWO C. 2019. Influence of discharged industrial effluents on the parameters of surface water in Onitsha urban area, southeastern Nigeria. Journal of Water and Land Development. No. 42 p. 136–142. DOI 10.2478/jwld-2019-0054.	spa
dcterms.references	Oilgae 2017. Comprehensive report on attractive algae product opportunities [online]. Tamilnadu, India pp. 259. [Access 05.07.2020]. Available at: http://www.oilgae.com/ref/benefitsalgae-fuel-venture.html	spa
dcterms.references	ONCEL S.S. 2013. Microalgae for a macroenergy world. Renewable Sustainable Energy Reviews. Vol. 26 p. 241–264.	spa
dcterms.references	ORTÍZ M.D., GELVEZ J.H.S., PÉREZ M.E., GONZÁLEZ Á.D., BARAJAS A.F., URBINA N.A. 2017. Removal of organic pollutants from San Pablo Farm Wastewater using a pilot-scale biological treatment. Contemporary Engineering Sciences. Vol. 10. Iss. 34 p. 1685–1691.	spa
dcterms.references	OUALI N., BELABED B., ZEGHDOUDI F., RACHEDI M. 2018. Assessment of metallic contamination in sediment and mullet fish (Mugil cephalus Linnaeus, 1758) tissues from the East Algerian coast. Journal of Water and Land Development. No. 38 p. 115–126. DOI 10.2478/jwld-2018-0048.	spa
dcterms.references	RAWAT I., KUMAR R.R., MUTANDA T., BUX F. 2011. Dual role of microalgae: phycoremediation of domestic wastewater and biomass production for sustainable biofuels production. Applied Energy. Vol. 88. Iss. 10 p. 3411–3424.	spa
dcterms.references	RICHMOND A. 2004. Biological principles of mass cultivation. In: Handbook of microalgal culture: Biotechnology and Applied Phycology. Ed. A. Richmond. Oxford, UK. Blackwell p. 125–177.	spa
dcterms.references	ROMERO ROJAS J.A. 1998. Tratamiento de aguas residuales. Teoria y principios de diseño [Wastewater treatment. Theory and principles of design]. Bogotá. Escuela Colombiana de Ingeniería. ISBN 958-8060-13-3 pp. 66.	spa
dcterms.references	ROSA M., PERALTA J., BOSCO D. 2010. Estimación de parámetros cinéticos de la degradación aeróbica de efluentes lácteos usando Aquasim V 2.1b [Estimation of Kinetic Parameters of the Aerobic Degradation of Dairy Wastewater using AQUASIM v 2.1b]. Información Tecnológica. Vol. 21(3) p. 51–56. DOI 10.1612/inf. tecnol.4373it.09.	spa
dcterms.references	ROSENBERG J.N., OYLER G.A., WILKINSON L., BETENBAUGH M.J. 2008. A green light for engineered algae: redirecting metabolism to fuel a biotechnology revolution. Current Opinion in Biotechnology. Vol. 19 p. 430–436. DOI 10.1016/j.copbio.2008.07.008.	spa
dcterms.references	SZE P. 1998. A biology of the algae. 3th ed. Columbus, OH. WCB/ McGraw-Hill. ISBN 0697219100 pp. 278.	spa
dcterms.references	TAUSSKY H., SHORR E. 1953. A microcolorimetric method for determination of inorganic phosphorus. Journal of Biological Chemistry. Vol. 202 p. 675–685.	spa
dcterms.references	TORRES D., SEPÚLVEDA S., ROA A. L., GELVEZ J., SUÁREZ N. 2017. Use of microalgae of Chlorophyta division in the biological treatment of acid drains of coal mines. Revista Colombiana de Biotecnología. Vol. 19(2) p. 95–104. DOI 10.15446/rev.colomb.biotec. v19N2.10429.	spa
dcterms.references	URBINA-SUÁREZ N., LILIANA-PABÓN S., SUÁREZ-GÁLVEZ J. 2006. Tratamiento biologico de aguas residuales de matadero. Caso: Frigorifico La Frontera Ltda., Villa del Rosario, Norte de Santander [Biological treatment of slaughterhouse wastewater. Case: fridge La Frontera Ltda., Villa del Rosario, Norte de Santander]. Respuestas. Vol. 11. Iss. 2 p. 39–50. DOI 10.22463/ 0122820X.607.	spa
dcterms.references	YANG C., HUA Q., SHIMIZU K. 2000. Energetics and carbon metabolism during growth of microalgal cells under photoautotrophic, mixotrophic and cyclic light-autotrophic/dark-heterotrophic conditions. Biochemical Engineering Journal. Vol. 6. Iss. 2 p. 87–102. DOI 10.1016/S1369-703X(00)00080-2.	spa
dc.contributor.corporatename	JOURNAL OF WATER AND LAND DEVELOPMENT	spa
dc.identifier.doi	10.24425/jwld.2022.140387
dc.identifier.eissn	2083-4535 V	spa
dc.relation.citationendpage	179	spa
dc.relation.citationissue	52	spa
dc.relation.citationstartpage	172	spa
dc.relation.citationvolume	2022	spa
dc.relation.ispartofjournal	Journal of Water and Land Development	spa
dc.rights.accessrights	info:eu-repo/semantics/openAccess	spa
dc.rights.creativecommons	Atribución-NoComercial-SinDerivadas 4.0 Internacional (CC BY-NC-ND 4.0)	spa
dc.subject.proposal	biological treatment	eng
dc.subject.proposal	characterisation	eng
dc.subject.proposal	microalgae	eng
dc.subject.proposal	monitoring	eng
dc.subject.proposal	nutrient wastewater	eng
dc.type.coar	http://purl.org/coar/resource_type/c_6501	spa
dc.type.content	Text	spa
dc.type.driver	info:eu-repo/semantics/article	spa
dc.type.redcol	http://purl.org/redcol/resource_type/ART	spa
oaire.accessrights	http://purl.org/coar/access_right/c_abf2	spa
oaire.version	http://purl.org/coar/version/c_970fb48d4fbd8a85	spa
dc.type.version	info:eu-repo/semantics/publishedVersion	spa