Innovación en tecnologías en plantas de tratamiento de agua residual para la eliminación de antibióticos, bacterias resistentes y genes de resistencia antibiótica: una revisión

El uso excesivo de los antibióticos ha dado paso a su presencia en las aguas residuales y ecosistemas acuáticos, ocasionando alteraciones en estos y afectando la salud pública por la proliferación de bacterias resistentes a los antibióticos (BRA) y sus genes de resistencia antibiótica (GRA). Una for...

Full description

Autores:: Parra Pérez, Miguel Angel
Zapata Zúñiga, Maria Camila

Tipo de recurso:: Trabajo de grado de pregrado

Fecha de publicación:: 2020

Institución:: Universidad Santo Tomás

Repositorio:: Repositorio Institucional USTA

Idioma:: spa

id	SANTTOMAS2_08c57a6de4fa4b3a604d5e8d704ac49c
oai_identifier_str	oai:repository.usta.edu.co:11634/21176
network_acronym_str	SANTTOMAS2
network_name_str	Repositorio Institucional USTA
repository_id_str
dc.title.spa.fl_str_mv	Innovación en tecnologías en plantas de tratamiento de agua residual para la eliminación de antibióticos, bacterias resistentes y genes de resistencia antibiótica: una revisión
title	Innovación en tecnologías en plantas de tratamiento de agua residual para la eliminación de antibióticos, bacterias resistentes y genes de resistencia antibiótica: una revisión
spellingShingle	Innovación en tecnologías en plantas de tratamiento de agua residual para la eliminación de antibióticos, bacterias resistentes y genes de resistencia antibiótica: una revisión Antibiotics Sewage treatment Antibiotic resistance genes Antibiotic resistance bacteria Water treatment Drinking water -- Process Water -- purification disinfection Tratamiento del agua Procesos de potabilización del agua Desinfección del agua Antibióticos Tratamiento de aguas residuales Bacterias de resistencia antibiótica Genes de resistencia antibiótica
title_short	Innovación en tecnologías en plantas de tratamiento de agua residual para la eliminación de antibióticos, bacterias resistentes y genes de resistencia antibiótica: una revisión
title_full	Innovación en tecnologías en plantas de tratamiento de agua residual para la eliminación de antibióticos, bacterias resistentes y genes de resistencia antibiótica: una revisión
title_fullStr	Innovación en tecnologías en plantas de tratamiento de agua residual para la eliminación de antibióticos, bacterias resistentes y genes de resistencia antibiótica: una revisión
title_full_unstemmed	Innovación en tecnologías en plantas de tratamiento de agua residual para la eliminación de antibióticos, bacterias resistentes y genes de resistencia antibiótica: una revisión
title_sort	Innovación en tecnologías en plantas de tratamiento de agua residual para la eliminación de antibióticos, bacterias resistentes y genes de resistencia antibiótica: una revisión
dc.creator.fl_str_mv	Parra Pérez, Miguel Angel Zapata Zúñiga, Maria Camila
dc.contributor.advisor.none.fl_str_mv	Molina Gómez, Nidia Isabel Álvarez Berrio, Johan Alexander
dc.contributor.author.none.fl_str_mv	Parra Pérez, Miguel Angel Zapata Zúñiga, Maria Camila
dc.contributor.orcid.spa.fl_str_mv	https://orcid.org/0000-0003-4485-262X
dc.contributor.googlescholar.spa.fl_str_mv	https://scholar.google.es/citations?user=pbio7wUAAAAJ&hl=es https://scholar.google.es/citations?user=Y4UC0goAAAAJ&hl=es
dc.subject.keyword.spa.fl_str_mv	Antibiotics Sewage treatment Antibiotic resistance genes Antibiotic resistance bacteria Water treatment Drinking water -- Process Water -- purification disinfection
topic	Antibiotics Sewage treatment Antibiotic resistance genes Antibiotic resistance bacteria Water treatment Drinking water -- Process Water -- purification disinfection Tratamiento del agua Procesos de potabilización del agua Desinfección del agua Antibióticos Tratamiento de aguas residuales Bacterias de resistencia antibiótica Genes de resistencia antibiótica
dc.subject.lemb.spa.fl_str_mv	Tratamiento del agua Procesos de potabilización del agua Desinfección del agua
dc.subject.proposal.spa.fl_str_mv	Antibióticos Tratamiento de aguas residuales Bacterias de resistencia antibiótica Genes de resistencia antibiótica
description	El uso excesivo de los antibióticos ha dado paso a su presencia en las aguas residuales y ecosistemas acuáticos, ocasionando alteraciones en estos y afectando la salud pública por la proliferación de bacterias resistentes a los antibióticos (BRA) y sus genes de resistencia antibiótica (GRA). Una forma de reducir estos impactos negativos es mediante el mejoramiento del tratamiento de las aguas residuales urbanas. Esta revisión expone 46 investigaciones sobre 10 tecnologías para la eliminación de los antibióticos, BRA y GRA después de realizar una revisión sistemática del tema, con el fin de evaluar la eficiencia de eliminación de cada una, así como la influencia de los países donde se han implementado y de esta manera mitigar el riesgo de exposición en fuentes hídricas. Como resultado, se obtuvo que los tratamientos de foto-fenton y la electroquímica son los que obtienen mayores eficiencias de eliminación de antibióticos; sin embargo, para los agentes microbianos BRA y GRA, la radiación gamma y la fotocatálisis con TiO2 y UV resultaron ser superiores por sus porcentajes de remoción correspondientes a 99.9%. Se encontró que China es el país con más investigaciones científicas realizadas frente al tema, aspecto que se puede correlacionar con las afectaciones a la salud que enfrentan los habitantes de este país, siendo uno de los mayores consumidores de antibióticos en el mundo; le sigue en materia de publicaciones Colombia que resalta por sus estudios sobre la eficiencia de la electroquímica.
publishDate	2020
dc.date.accessioned.none.fl_str_mv	2020-01-24T18:46:52Z
dc.date.available.none.fl_str_mv	2020-01-24T18:46:52Z
dc.date.issued.none.fl_str_mv	2020-01-16
dc.type.local.spa.fl_str_mv	Trabajo de Grado
dc.type.version.none.fl_str_mv	info:eu-repo/semantics/acceptedVersion
dc.type.category.spa.fl_str_mv	Formación de Recurso Humano para la Ctel: Trabajo de grado de Pregrado
dc.type.coar.none.fl_str_mv	http://purl.org/coar/resource_type/c_7a1f
dc.type.drive.none.fl_str_mv	info:eu-repo/semantics/bachelorThesis
format	http://purl.org/coar/resource_type/c_7a1f
status_str	acceptedVersion
dc.identifier.citation.spa.fl_str_mv	Parra, M. A. & Zapata, M. C. (2019). Innovación en tecnologías en plantas de tratamiento de agua residual para la eliminación de antibióticos, bacterias resistentes y genes de resistencia antibiótica: una revisión (Trabajo de pregrado de Ingeniería Ambiental). Universidad Santo Tomás. Bogotá, Colombia.
dc.identifier.uri.none.fl_str_mv	http://hdl.handle.net/11634/21176
dc.identifier.reponame.spa.fl_str_mv	reponame:Repositorio Institucional Universidad Santo Tomás
dc.identifier.instname.spa.fl_str_mv	instname:Universidad Santo Tomás
dc.identifier.repourl.spa.fl_str_mv	repourl:https://repository.usta.edu.co
identifier_str_mv	Parra, M. A. & Zapata, M. C. (2019). Innovación en tecnologías en plantas de tratamiento de agua residual para la eliminación de antibióticos, bacterias resistentes y genes de resistencia antibiótica: una revisión (Trabajo de pregrado de Ingeniería Ambiental). Universidad Santo Tomás. Bogotá, Colombia. reponame:Repositorio Institucional Universidad Santo Tomás instname:Universidad Santo Tomás repourl:https://repository.usta.edu.co
url	http://hdl.handle.net/11634/21176
dc.language.iso.spa.fl_str_mv	spa
language	spa
dc.relation.references.spa.fl_str_mv	C. Peña et al., “Emerging pollutants in the urban water cycle in Latin America: A review of the current literature,” J. Environ. Qual., vol. 237, pp. 408-423, 2019. A. Kumar and D. Pal, “Antibiotic resistance and wastewater: Correlation, impact and critical human health challenges,” J. Environ. Chem. Eng., vol. 6, no. 1. pp. 52–58, 2018. S. P. De León, R. Arredondo and Y. López, “Resistance to antibiotic: A serious global problem”, Gac. Med. Mex., vol. 151, no. 5, p. 632-639, 2015. J. Carlet1 et al., “Ready for a world without antibiotics? The Pensières Antibiotic Resistance Call to Action,” Antimicrob. Resist. Infect. Control., vol. 1, no 11, 2012. E. Kleina et al., “Global increase and geographic convergence in antibiotic consumption between 2000 and 2015,” PNAS, vol. 115, no. 15, 2018. W. Qing et al., “Occurrence and distribution of clinical and veterinary antibiotics in the faeces of a Chinese population,” J. Hazard. Mater., vol. 383, pp. 121-129, 2019. J. Machado and D. González, “Dispensación de antibióticos de uso ambulatorio en una población colombiana,” Rev. Salud pública, vol. 11, no. 5, pp 734-744, 2009. A. Villalobos, L. Barrero, S. Rivera, M. Ovalle and D. Valera, “Vigilancia de infecciones asociadas a la atención en salud, resistencia bacteriana y consumo de antibióticos en hospitales de alta complejidad, Colombia, 2011,” Biomédica, vol. 34, no. 1. pp. 67-80, abril, 2014. O. Hernández, O. Camacho, H. González, Y. Pajaro and M. Silva, “Estudio de utilización de antibióticos en Hospitales de Mediana y Alta Complejidad del Departamento del Atlántico-Colombia entre el 2016 y 2017,” Rev. AVFT, vol. 37, no. 5, 2018. A. Almakki, E. Jumas, H. Marchandin and P. Licznar, “Antibiotic resistance in urban runoff,” Sci. Total Environ, vol. 667, pp. 64-76, 2019. O. Malik, A. Hsu, L. Johnson and A. de Sherbinin, “A global indicator of wastewater treatment to inform the Sustainable Development Goals (SDGs),” Environ. Sci. Policy, vol. 48, pp. 172-185, 2015. O. Golovko, V. Kumar, G. Fedorova, T. Randak, and R. Grabic, “Seasonal changes in antibiotics, antidepressants/psychiatric drugs, antihistamines and lipid regulators in a wastewater treatment plant,” Chemosphere, vol. 111, pp. 418–426, Sep. 2014. K. D. Brown, J. Kulis, B. Thomson, T. H. Chapman, and D. B. Mawhinney, “Occurrence of antibiotics in hospital, residential, and dairy effluent, municipal wastewater, and the Rio Grande in New Mexico,” Sci. Total Environ., vol. 366, no. 2, pp. 772–783, 2006. M. Harrabi et al., “Analysis of multiclass antibiotic residues in urban wastewater in Tunisia,” Environ. Nanotechnol. Monit. Manage., vol. 10, pp. 163–170, 2018. A. M. Botero et al., “An investigation into the occurrence and removal of pharmaceuticals in Colombian wastewater,” Sci. Total Environ., vol. 642, pp. 842–853, 2018. X. Domènech, W. F. Jardim and M. I. Litter, Procesos avanzados de oxidación para la eliminación de contaminantes. 2001. I. Iakovides et al., “Continuous ozonation of urban wastewater: Removal of antibiotics, antibiotic-resistant Escherichia coli and antibiotic resistance genes and phytotoxicity,” Water Res., vol. 159, pp. 333–347, Aug. 2019. Y. Zhuang et al., “Inactivation of antibiotic resistance genes in municipal wastewater by chlorination, ultraviolet, and ozonation disinfection,” Environ. Sci. Pollunt. Res., vol. 22, no. 9, pp. 7037–7044, 2015. J. Alexander, G. Knopp, A. Dötsch, A. Wieland, and T. Schwartz, “Ozone treatment of conditioned wastewater selects antibiotic resistance genes, opportunistic bacteria, and induce strong population shifts,” Sci. Total Environ., vol. 559, pp. 103–112, Jul. 2016. C. Stange, J. P. . Sidhu, S. Toze, and A. Tiehm, “Comparative removal of antibiotic resistance genes during chlorination, ozonation, and UV treatment,” vol. 222, no. 3, pp. 541–548, Apr. 2019. F. Lüddeke, S. Heß, C. Gallert, J. Winter, H. Güde, and H. Löffler, “Removal of total and antibiotic resistant bacteria in advanced wastewater treatment by ozonation in combination with different filtering techniques,” Water Res., vol. 69, pp. 243–251, Feb. 2015. J. Castillo, A. López and E. Bandala, “Desinfección de agua mediante el uso de tecnologías emergentes basadas en procesos avanzados de oxidación,” Temas de Ingeniería de Alimentos, vol. 4, no. 1, pp. 74-83, 2010. V. Kavitha and K. Palanivelu, “Degradation of 2-Chlorophenol by Fenton and Photo-Fenton Processes - A Comparative Study,” J. Environ. Sci. Health. Part A Toxic/Hazard. Subst. Environ. Eng., vol. A38, no. 7, pp. 1215-1231, 2003. N. De la Cruz et al., “Degradation of 32 emergent contaminants by UV and neutral photo-fenton in domestic wastewater effluent previously treated by activated sludge,” Water Res., vol. 46, no. 6, pp. 1947–1957, Apr. 2012. S. Li et al., “M. electro-F. A. promising system for antibiotics resistance genes degradation and energy generation,” Sci. Total Environ., pp. 134-160, 2019. M. Hassana et al., “Energy-efficient degradation of antibiotics in microbial electro-Fenton system catalysed by M-type strontium hexaferrite nanoparticles,” Chem. Eng. J., vol. 138, 2020. M. Verma and A. Haritash, “Degradation of amoxicillin by Fenton and Fenton-integrated hybrid oxidation processes,” J. Environ. Chem. Eng., vol. 7, no. 1, 2019. L. Souza, A. Moreira and L. Lang, “Degradation of antibiotics norfloxacin by Fenton, UV and UV/H2O2,” J. Environ. Manage., vol. 154, pp. 8-12, 2015. A. H. Mamaghani, F. Haghighat, and C. S. Lee, “Photocatalytic oxidation technology for indoor environment air purification: The state-of-the-art,” Appl. Catal. B Environ., vol. 203, pp. 247–269, Apr. 2017. C. Guo et al., “H2O2 and/or TiO2 photocatalysis under UV irradiation for the removal of antibiotic resistant bacteria and their antibiotic resistance genes,” J. Hazard. Mater., vol. 323, pp. 710–718, Feb. 2017. M. Matos et al., “Enhanced degradation of the antibiotic sulfamethoxazole by heterogeneous photocatalysis using Ce0, 8Gd0, 2O2-d/TiO2 particles”, J. Alloys Compd., vol. 808, no. 5, 2019. P. Karaolia et al., “Removal of antibiotics, antibiotic-resistant bacteria and their associated genes by graphene-based TiO2 composite photocatalysts under solar radiation in urban wastewaters,” Appl. Catal. B Environ., vol. 224, pp. 810–824, May 2018. M.-T. Guo and X.-B. Tian, “Impacts on antibiotic-resistant bacteria and their horizontal gene transfer by graphene-based TiO2&Ag composite photocatalysts under solar irradiation,” J. Hazard. Mater., vol. 380, p. 120877, Dec. 2019. M. Jiménez, I. J. Ferreira, S. da Silva, P. R. Guimarães, and E. M. Saggioro, “Removal of contaminants of emerging concern (CECs) and antibiotic resistant bacteria in urban wastewater using UVA/TiO2/H2O2 photocatalysis,” Chemosphere, vol. 210, pp. 449–457, Nov. 2018. F. Hernández, “Un mordente, un electrolito y grabado en cualquier metal”, Rev. Cient., no. 11, pp. 181-188, Dec. 2014. Y. Liu, Y. Gao, B. Yao, and D. Zou, “Removal of chlortetracycline by nano- micro-electrolysis materials: Application and mechanism,” Chemosphere, vol. 238, pp. 124543, 2020. H. Mahdizadeh and M. Malakootian, “Optimization of ciprofloxacin removal from aqueous solutions by a novel semi-fluid Fe/charcoal micro-electrolysis reactor using response surface methodology,” Process Saf. Environ. Prot., vol. 123, pp. 299–308, Mar. 2019. Y. Liu, C. Wang, Z. Sui, and D. Zou, “Degradation of chlortetracycline using nano micro-electrolysis materials with loading copper,” Sep. Purif. Technol., vol. 203, pp. 29–35, Sep. 2018. X. Cui, X. Li, N. Li, G. Chen, and H. Zheng, “Sludge based micro-electrolysis filler for removing tetracycline from solution,” J. Colloid Interface Sci., vol. 534, pp. 490–498, Jan. 2019. Yusuf G Adewuyi, “Sonochemistry in environmental remediation. 2. Heterogeneous sonophotocatalytic oxidation processes for the treatment of pollutants in water,”Environ. Sci. Technol., vol. 39, no. 22, pp. 8557-857, 2005. E. A. Serna, J. Silva, A. L. Giraldo, O. A. Flórez, and R. A. Torres, “High frequency ultrasound as a selective advanced oxidation process to remove penicillinic antibiotics and eliminate its antimicrobial activity from water,” Ultrason. Sonochem., vol. 31, pp. 276–283, Jul. 2016. J. Jin et al., “3D Bombax-structured carbon nanotube sponge coupling with Ag3PO4 for tetracycline degradation under ultrasound and visible light irradiation,” Sci. Total Environ., vol. 695, 2019. K. V. Patiño, S. M. Arroyave and J. M. Marín, “Oxidación electroquímica y ozonización aplicadas al tratamiento de aguas de lavado de la producción de biodiesel” Información Tecnológica, vol. 23, no. 2, pp. 41-52, 2012. A. L. Giraldo, E. D. Erazo, O. A. Flórez, E. A. Serna and R. A. Torres, “Tratamiento electroquímico de aguas que contienen antibióticos β-lactámicos,” Rev. Ciencia Desarrollo, vol. 7, no. 1, pp. 21–29, Jun. 2016. H. Zhang, F. Liu, X. Wu, J. Zhang, and D. Zhang, “Degradation of tetracycline in aqueous medium by electrochemical method,” Asia-Pac. J. Chem. Eng., vol. 4, no. 5, pp. 568–573, Sep. 2009. S. D. Jojoa, J. Silva, E. Herrera and R. A. Torres, “Elimination of the antibiotic norfloxacin in municipal wastewater, urine and seawater by electrochemical oxidation on IrO2 anodes,” Sci. Total Environ., vol. 575, pp. 1228–1238, Jan. 2017. B. G. Padilla et al., “Electrochemical degradation of amoxicilin in aqueous media,” Chem. Eng. Process., vol. 94, pp. 93-98, 2015. E. Serna, K. Berrio, and R. Torres, “Electrochemical treatment of penicillin, cephalosporin, and fluoroquinolone antibiotics via active chlorine: evaluation of antimicrobial activity, toxicity, matrix, and their correlation with the degradation pathways,” Environ. Sci. Pollunt Res., vol. 24, no. 30, pp. 23771–23782, Oct. 2017. W. R. Calero Cáceres, “Evaluación de reservorios ambientales de partículas fágicas portadoras de genes resistencia a antibióticos,” tesis doctoral, Universitat de Barcelona, 2016. Y. Hu et al., “Removal of sulfonamide antibiotic resistant bacterial and intracellular antibiotic resistance genes by UVC-activated peroxymonosulfate,” Chem. Eng. J., vol. 368, pp. 888–895, Jul. 2019. J. Rodríguez-Chueca et al., “Assessment of full-scale tertiary wastewater treatment by UV-C based-AOPs: Removal or persistence of antibiotics and antibiotic resistance genes?,” Sci. Total Environ., vol. 652, pp. 1051–1061, Feb. 2019. T. Zhang et al., “Removal of antibiotic resistance genes and control of horizontal transfer risk by UV, chlorination and UV/chlorination treatments of drinking water,” Chem. Eng. J., vol. 358, pp. 589–597, Feb. 2019. C. Ferradini, “Kinetic Behavior of the Radiolysis Products of Water,” Adv. Inorg. Chem. Radiochem., vol. 3. Academic Press, pp. 171–205, 1961. W. Song, W. Chen, W. J. Cooper, J. Greaves and G. E. Miller, “Free-Radical destruction of b-Lactam antibiotics in aqueous solution,” J. Phys. Chem., vol. 112, no. 32, pp. 7411-7417, Jun. 2008. D. Chen et al., “Degradation of antibiotic cephalosporin C in aqueous solution and elimination of antimicrobial activity by gamma irradiation,” Chem. Eng. J., vol. 374, pp. 1102–1108, Oct. 2019. R. Zhuan and J. Wang, “Enhanced degradation and mineralization of sulfamethoxazole by integrating gamma radiation with Fenton-like processes,” Radiat. Phy. Chem., vol. 166, 2020. R. Changotra, J. P. Guin, L. Varshney, and A. Dhir, “Assessment of reaction intermediates of gamma radiation-induced degradation of ofloxacin in aqueous solution,” Chemosphere, vol. 208, pp. 606–613, Oct. 2018. W. Zheng, X. Wen, B. Zhang, and Y. Qiu, “Selective effect and elimination of antibiotics in membrane bioreactor of urban wastewater treatment plant,” Sci. Total Environ., vol. 646, pp. 1293–1303, Jan. 2019. T.H. Le, C. Ng, N. H. Tran, H. Chen, and K. Y.-H. Gin, “Removal of antibiotic residues, antibiotic resistant bacteria and antibiotic resistance genes in municipal wastewater by membrane bioreactor systems,” Water Res., vol. 145, pp. 498–508, 2018. Y. Zhu, Y. Wang, S. Zhou, X. Jiang, X. Ma, and C. Liu, “Robust performance of a membrane bioreactor for removing antibiotic resistance genes exposed to antibiotics: Role of membrane foulants,” Water Res., vol. 130, pp. 139–150, Mar. 2018. B.-J. Shi et al., “Application of membrane bioreactor for sulfamethazine-contained wastewater treatment,” Chemosphere, vol. 193, pp. 840–846, Feb. 2018 Z. Xu, X. Song, G. Li, Y. Li, and W. Luo, “Removal of antibiotics by sequencing-batch membrane bioreactor for swine wastewater treatment,” Sci. Total Environ., vol. 684, pp. 23–30, Sep. 2019. W. Zhao, Q. Sui, X. Mei, and X. Cheng, “Efficient elimination of sulfonamides by an anaerobic/anoxic/oxic-membrane bioreactor process: Performance and influence of redox condition,” Sci. Total Environ., vol. 633, pp. 668–676, Aug. 2018. T. T. Nguyen et al., “Removal of antibiotics in sponge membrane bioreactors treating hospital wastewater: Comparison between hollow fiber and flat sheet membrane systems,” Bioresour. Technol. Rep., vol. 240, pp. 42–49, Sep. 2017. G. Prados Joya, “Tratamiento de aguas para la eliminación de antibióticos -nitroimidazoles- mediante adsorción sobre carbón activado y tecnologías avanzadas de oxidación”, tesis doctoral, Universidad de Granada, 2010. A. A. Basheer, “New generation nano-adsorbents for the removal of emerging contaminants in water,” J. Mol. Liq., vol. 261, pp. 583–593, Jul. 2018. S. A. Snyder et al., “Role of membranes and activated carbon in the removal of endocrine disruptors and pharmaceuticals,” Desalination, vol. 202, no. 1. pp. 156–181, 2007. M. J. Ahmed and S. K. Theydan, “Fluoroquinolones antibiotics adsorption onto microporous activated carbon from lignocellulosic biomass by microwave pyrolysis,” J. Taiwan Inst. Chem. Eng., vol. 45, no. 1, pp. 219–226, Jan. 2014. G. Nazari, H. Abolghasemi, and M. Esmaieli, “Batch adsorption of cephalexin antibiotic from aqueous solution by walnut shell-based activated carbon,” J. Taiwan Inst. Chem. Eng., vol. 58, pp. 357–365, Jan. 2016. Q. Tang, P et al., “Control of antibiotic resistance in China must not be delayed: The current state of resistance and policy suggestions for the government, medical facilities, and patients,” BioSci. Trends, vol. 10, no. 1, pp. 1-6, 2016. M. Ferech et al., “European Surveillance of Antimicrobial Consumption (ESAC): outpatient antibiotic use in Europe,” J. Antimicrob. Chemother., vol. 48, pp. 401-407, 2006. F. Reinthaler et al., “Antibiotic resistance of E. coli in sewage and sludge,” Water Res., vol. 37, no. 8, pp. 1685-1692, Abril, 2003. S. Mosquito, J. Ruiz, J. Bauer and T. Ochoa, “Mecanismos moleculares de Resistencia antibiótica en Escherichia coli asociadas a diarrea,” Rev. Peru Med. Exp. Salud Pública, vol. 28, no. 4, pp. 648-656, 2011. G. Pliego et al., “Trends in the intensification of the Fenton process for wastewater treatment -An overview,” Crit. Rev. Env. Sci. Technol., vol. 45, no. 24, pp. 2611-2692, 2015. J. Pignatello, E. Oliveros and A. MacKay, “Advanced Oxidation Processes for Organic Contaminant Destruction Based on the Fenton Reaction and Related Chemistry,” J. Hazard. Mater., vol. 36, pp. 1-84, 2006. P. Kajitvichyanukul, L. Ming-Chun, L. Chih-Hsiang, W. Wirojanagud and T. Koottateo, “Degradation and detoxification of formaline wastewater by advanced oxidation processes”, J. Hazard. Mater., vol. 135, pp. 337-343, July, 2006. A. Vorontsov, “Advancing Fenton and photo-Fenton water treatment through the catalyst design”, vol. 372, pp. 103-112, 2019. Crit. Rev. Env. Sci. Technol., vol. 45, no. 24, pp. 2611-2692, 2015. B. Feier, A. Florea, C. Cristea and R. Sandulescu, “Electrochemical detection and removal of pharmaceuticals in waste waters,” Curr. Opin. Electrochem., vol. 11, pp. 1-11, Octuber 2018. P. Liu, H. Zhang, Y. Feng, C. Shen and F. Yang, “Integrating electrochemical oxidation into forward osmosis process for removal of trace antibiotics in wastewater,” J. Hazard. Mater., vol. 296, pp. 248-255, 2015. E. Lacasa, S. Cotillas, C. Saez, J. Lobato, P. Cañizares and M. Rodrigo, “Environmental applications of electrochemical technology. What is needed to enable full-scale applications?” Curr. Opin. Electrochem., vol. 16, pp. 149-156, 2019. C. Byrne, G. Subramanian and S. Pillai, “Recent advances in photocatalysis for environmental applications”, J. Environ. Chem. Eng., vol. 6, no. 3, pp. 3531-3555, Jun, 2018. L. Garcés, E. Mejía and J. Santamaría, “La fotocatálisis como alternativa para el tratamiento de aguas residuales,” Rev. Lasallista Investig., vol. 1, no. 1, pp. 83-92, 2004. J. You, Y. Guo, R. Guo and X. Liu, “A review of visible light-active photocatalysts for water disinfection: Features and prospects,” Chem. Eng. J., vol. 373, pp. 624-641, Octubre, 2019. W. Jianlong, “Application of radiation technology to sewage sludge processing: A review,” J. Hazard. Mater., vol.143, pp. 2-7, 2007. M. Salgot and M. Folch, “Wastewater treatment and water reuse,” Curr. Opin. Environ. Sci. Health, vol. 2, pp. 64-74, Ap. 2018. H. Jo et al., “Improvement of biodegradability of industrial wastewaters by radiation treatment,” J. Radioanal. Nucl. Chem., vol. 268, no. 1, pp. 145-150, 2006.
dc.rights.*.fl_str_mv	Atribución-NoComercial-SinDerivadas 2.5 Colombia
dc.rights.uri.*.fl_str_mv	http://creativecommons.org/licenses/by-nc-nd/2.5/co/
dc.rights.local.spa.fl_str_mv	Abierto (Texto Completo)
dc.rights.accessrights.none.fl_str_mv	info:eu-repo/semantics/openAccess
dc.rights.coar.none.fl_str_mv	http://purl.org/coar/access_right/c_abf2
rights_invalid_str_mv	Atribución-NoComercial-SinDerivadas 2.5 Colombia http://creativecommons.org/licenses/by-nc-nd/2.5/co/ Abierto (Texto Completo) http://purl.org/coar/access_right/c_abf2
eu_rights_str_mv	openAccess
dc.format.mimetype.spa.fl_str_mv	application/pdf
dc.coverage.campus.spa.fl_str_mv	CRAI-USTA Bogotá
dc.publisher.spa.fl_str_mv	Universidad Santo Tomás
dc.publisher.program.spa.fl_str_mv	Pregrado de Ingeniería Ambiental
dc.publisher.faculty.spa.fl_str_mv	Facultad de Ingeniería Ambiental
institution	Universidad Santo Tomás
bitstream.url.fl_str_mv	https://repository.usta.edu.co/bitstream/11634/21176/4/license_rdf https://repository.usta.edu.co/bitstream/11634/21176/5/license.txt https://repository.usta.edu.co/bitstream/11634/21176/6/2019mariazapata.pdf.jpg https://repository.usta.edu.co/bitstream/11634/21176/7/Carta_de_aprobaci%c3%b3n_de_la_facultad.pdf.jpg https://repository.usta.edu.co/bitstream/11634/21176/8/Carta_de_derechos_de_autor.pdf.jpg https://repository.usta.edu.co/bitstream/11634/21176/1/2019mariazapata.pdf https://repository.usta.edu.co/bitstream/11634/21176/2/Carta_de_aprobaci%c3%b3n_de_la_facultad.pdf https://repository.usta.edu.co/bitstream/11634/21176/3/Carta_de_derechos_de_autor.pdf
bitstream.checksum.fl_str_mv	217700a34da79ed616c2feb68d4c5e06 f6b8c5608fa6b2f649b2d63e10c5fa73 2a59e8883a29d6bf88e02c7c0e9d4509 637a0f3de54611f1f202fbe6a9aac3d8 c905336a15af87c71fd24b73b690f9b8 79500557b562086f1cabc36f69530162 aee0c64fc7adef73e29c9047a2848954 94d7ce7740a7e79ef3ccf460e33e806f
bitstream.checksumAlgorithm.fl_str_mv	MD5 MD5 MD5 MD5 MD5 MD5 MD5 MD5
repository.name.fl_str_mv	Repositorio Universidad Santo Tomás
repository.mail.fl_str_mv	repositorio@usantotomas.edu.co
_version_	1782026328792367104
spelling	Molina Gómez, Nidia IsabelÁlvarez Berrio, Johan AlexanderParra Pérez, Miguel AngelZapata Zúñiga, Maria Camilahttps://orcid.org/0000-0003-4485-262Xhttps://scholar.google.es/citations?user=pbio7wUAAAAJ&hl=eshttps://scholar.google.es/citations?user=Y4UC0goAAAAJ&hl=es2020-01-24T18:46:52Z2020-01-24T18:46:52Z2020-01-16Parra, M. A. & Zapata, M. C. (2019). Innovación en tecnologías en plantas de tratamiento de agua residual para la eliminación de antibióticos, bacterias resistentes y genes de resistencia antibiótica: una revisión (Trabajo de pregrado de Ingeniería Ambiental). Universidad Santo Tomás. Bogotá, Colombia.http://hdl.handle.net/11634/21176reponame:Repositorio Institucional Universidad Santo Tomásinstname:Universidad Santo Tomásrepourl:https://repository.usta.edu.coEl uso excesivo de los antibióticos ha dado paso a su presencia en las aguas residuales y ecosistemas acuáticos, ocasionando alteraciones en estos y afectando la salud pública por la proliferación de bacterias resistentes a los antibióticos (BRA) y sus genes de resistencia antibiótica (GRA). Una forma de reducir estos impactos negativos es mediante el mejoramiento del tratamiento de las aguas residuales urbanas. Esta revisión expone 46 investigaciones sobre 10 tecnologías para la eliminación de los antibióticos, BRA y GRA después de realizar una revisión sistemática del tema, con el fin de evaluar la eficiencia de eliminación de cada una, así como la influencia de los países donde se han implementado y de esta manera mitigar el riesgo de exposición en fuentes hídricas. Como resultado, se obtuvo que los tratamientos de foto-fenton y la electroquímica son los que obtienen mayores eficiencias de eliminación de antibióticos; sin embargo, para los agentes microbianos BRA y GRA, la radiación gamma y la fotocatálisis con TiO2 y UV resultaron ser superiores por sus porcentajes de remoción correspondientes a 99.9%. Se encontró que China es el país con más investigaciones científicas realizadas frente al tema, aspecto que se puede correlacionar con las afectaciones a la salud que enfrentan los habitantes de este país, siendo uno de los mayores consumidores de antibióticos en el mundo; le sigue en materia de publicaciones Colombia que resalta por sus estudios sobre la eficiencia de la electroquímica.The excessive use of antibiotics has given way to their presence in wastewater and aquatic ecosystems, causing alterations in these and affecting public health by the proliferation of antibiotic resistant bacteria (ARB) and their antibiotic resistance genes (ARG). One way to reduce these negative impacts is by improving urban wastewater treatment. This review presents 46 research out of 10 antibiotic elimination technologies, ARBs and ARGs after a systematic review of the subject, in order to evaluate the elimination efficiency of each, as well as the influence of the countries where they have been implemented and thus mitigate the risk of exposure in water sources. As a result, it was obtained that the photo-fenton treatments and the electrochemistry are the ones that obtain greater efficiencies of elimination of antibiotics; however, for the microbial agents ARB and ARG, the gamma radiation and the photocatalysis with TiO2 and UV turned out to be superior by their percentages of removal corresponding to 99.9%. It was found that China is the country with more scientific research conducted on the subject, an aspect that can be correlated with the health effects faced by the population of this country, being one of the largest consumers of antibiotics in the world, followed by publications Colombia that stands out for its studies on the efficiency of electrochemistry.Ingeniero Ambientalhttp://unidadinvestigacion.usta.edu.coPregradoapplication/pdfspaUniversidad Santo TomásPregrado de Ingeniería AmbientalFacultad de Ingeniería AmbientalAtribución-NoComercial-SinDerivadas 2.5 Colombiahttp://creativecommons.org/licenses/by-nc-nd/2.5/co/Abierto (Texto Completo)info:eu-repo/semantics/openAccesshttp://purl.org/coar/access_right/c_abf2Innovación en tecnologías en plantas de tratamiento de agua residual para la eliminación de antibióticos, bacterias resistentes y genes de resistencia antibiótica: una revisiónAntibioticsSewage treatmentAntibiotic resistance genesAntibiotic resistance bacteriaWater treatmentDrinking water -- ProcessWater -- purification disinfectionTratamiento del aguaProcesos de potabilización del aguaDesinfección del aguaAntibióticosTratamiento de aguas residualesBacterias de resistencia antibióticaGenes de resistencia antibióticaTrabajo de Gradoinfo:eu-repo/semantics/acceptedVersionFormación de Recurso Humano para la Ctel: Trabajo de grado de Pregradohttp://purl.org/coar/resource_type/c_7a1finfo:eu-repo/semantics/bachelorThesisCRAI-USTA BogotáC. Peña et al., “Emerging pollutants in the urban water cycle in Latin America: A review of the current literature,” J. Environ. Qual., vol. 237, pp. 408-423, 2019.A. Kumar and D. Pal, “Antibiotic resistance and wastewater: Correlation, impact and critical human health challenges,” J. Environ. Chem. Eng., vol. 6, no. 1. pp. 52–58, 2018.S. P. De León, R. Arredondo and Y. López, “Resistance to antibiotic: A serious global problem”, Gac. Med. Mex., vol. 151, no. 5, p. 632-639, 2015.J. Carlet1 et al., “Ready for a world without antibiotics? The Pensières Antibiotic Resistance Call to Action,” Antimicrob. Resist. Infect. Control., vol. 1, no 11, 2012.E. Kleina et al., “Global increase and geographic convergence in antibiotic consumption between 2000 and 2015,” PNAS, vol. 115, no. 15, 2018.W. Qing et al., “Occurrence and distribution of clinical and veterinary antibiotics in the faeces of a Chinese population,” J. Hazard. Mater., vol. 383, pp. 121-129, 2019.J. Machado and D. González, “Dispensación de antibióticos de uso ambulatorio en una población colombiana,” Rev. Salud pública, vol. 11, no. 5, pp 734-744, 2009.A. Villalobos, L. Barrero, S. Rivera, M. Ovalle and D. Valera, “Vigilancia de infecciones asociadas a la atención en salud, resistencia bacteriana y consumo de antibióticos en hospitales de alta complejidad, Colombia, 2011,” Biomédica, vol. 34, no. 1. pp. 67-80, abril, 2014.O. Hernández, O. Camacho, H. González, Y. Pajaro and M. Silva, “Estudio de utilización de antibióticos en Hospitales de Mediana y Alta Complejidad del Departamento del Atlántico-Colombia entre el 2016 y 2017,” Rev. AVFT, vol. 37, no. 5, 2018.A. Almakki, E. Jumas, H. Marchandin and P. Licznar, “Antibiotic resistance in urban runoff,” Sci. Total Environ, vol. 667, pp. 64-76, 2019.O. Malik, A. Hsu, L. Johnson and A. de Sherbinin, “A global indicator of wastewater treatment to inform the Sustainable Development Goals (SDGs),” Environ. Sci. Policy, vol. 48, pp. 172-185, 2015.O. Golovko, V. Kumar, G. Fedorova, T. Randak, and R. Grabic, “Seasonal changes in antibiotics, antidepressants/psychiatric drugs, antihistamines and lipid regulators in a wastewater treatment plant,” Chemosphere, vol. 111, pp. 418–426, Sep. 2014.K. D. Brown, J. Kulis, B. Thomson, T. H. Chapman, and D. B. Mawhinney, “Occurrence of antibiotics in hospital, residential, and dairy effluent, municipal wastewater, and the Rio Grande in New Mexico,” Sci. Total Environ., vol. 366, no. 2, pp. 772–783, 2006.M. Harrabi et al., “Analysis of multiclass antibiotic residues in urban wastewater in Tunisia,” Environ. Nanotechnol. Monit. Manage., vol. 10, pp. 163–170, 2018.A. M. Botero et al., “An investigation into the occurrence and removal of pharmaceuticals in Colombian wastewater,” Sci. Total Environ., vol. 642, pp. 842–853, 2018.X. Domènech, W. F. Jardim and M. I. Litter, Procesos avanzados de oxidación para la eliminación de contaminantes. 2001.I. Iakovides et al., “Continuous ozonation of urban wastewater: Removal of antibiotics, antibiotic-resistant Escherichia coli and antibiotic resistance genes and phytotoxicity,” Water Res., vol. 159, pp. 333–347, Aug. 2019.Y. Zhuang et al., “Inactivation of antibiotic resistance genes in municipal wastewater by chlorination, ultraviolet, and ozonation disinfection,” Environ. Sci. Pollunt. Res., vol. 22, no. 9, pp. 7037–7044, 2015.J. Alexander, G. Knopp, A. Dötsch, A. Wieland, and T. Schwartz, “Ozone treatment of conditioned wastewater selects antibiotic resistance genes, opportunistic bacteria, and induce strong population shifts,” Sci. Total Environ., vol. 559, pp. 103–112, Jul. 2016.C. Stange, J. P. . Sidhu, S. Toze, and A. Tiehm, “Comparative removal of antibiotic resistance genes during chlorination, ozonation, and UV treatment,” vol. 222, no. 3, pp. 541–548, Apr. 2019.F. Lüddeke, S. Heß, C. Gallert, J. Winter, H. Güde, and H. Löffler, “Removal of total and antibiotic resistant bacteria in advanced wastewater treatment by ozonation in combination with different filtering techniques,” Water Res., vol. 69, pp. 243–251, Feb. 2015.J. Castillo, A. López and E. Bandala, “Desinfección de agua mediante el uso de tecnologías emergentes basadas en procesos avanzados de oxidación,” Temas de Ingeniería de Alimentos, vol. 4, no. 1, pp. 74-83, 2010.V. Kavitha and K. Palanivelu, “Degradation of 2-Chlorophenol by Fenton and Photo-Fenton Processes - A Comparative Study,” J. Environ. Sci. Health. Part A Toxic/Hazard. Subst. Environ. Eng., vol. A38, no. 7, pp. 1215-1231, 2003.N. De la Cruz et al., “Degradation of 32 emergent contaminants by UV and neutral photo-fenton in domestic wastewater effluent previously treated by activated sludge,” Water Res., vol. 46, no. 6, pp. 1947–1957, Apr. 2012.S. Li et al., “M. electro-F. A. promising system for antibiotics resistance genes degradation and energy generation,” Sci. Total Environ., pp. 134-160, 2019.M. Hassana et al., “Energy-efficient degradation of antibiotics in microbial electro-Fenton system catalysed by M-type strontium hexaferrite nanoparticles,” Chem. Eng. J., vol. 138, 2020.M. Verma and A. Haritash, “Degradation of amoxicillin by Fenton and Fenton-integrated hybrid oxidation processes,” J. Environ. Chem. Eng., vol. 7, no. 1, 2019.L. Souza, A. Moreira and L. Lang, “Degradation of antibiotics norfloxacin by Fenton, UV and UV/H2O2,” J. Environ. Manage., vol. 154, pp. 8-12, 2015.A. H. Mamaghani, F. Haghighat, and C. S. Lee, “Photocatalytic oxidation technology for indoor environment air purification: The state-of-the-art,” Appl. Catal. B Environ., vol. 203, pp. 247–269, Apr. 2017.C. Guo et al., “H2O2 and/or TiO2 photocatalysis under UV irradiation for the removal of antibiotic resistant bacteria and their antibiotic resistance genes,” J. Hazard. Mater., vol. 323, pp. 710–718, Feb. 2017.M. Matos et al., “Enhanced degradation of the antibiotic sulfamethoxazole by heterogeneous photocatalysis using Ce0, 8Gd0, 2O2-d/TiO2 particles”, J. Alloys Compd., vol. 808, no. 5, 2019.P. Karaolia et al., “Removal of antibiotics, antibiotic-resistant bacteria and their associated genes by graphene-based TiO2 composite photocatalysts under solar radiation in urban wastewaters,” Appl. Catal. B Environ., vol. 224, pp. 810–824, May 2018.M.-T. Guo and X.-B. Tian, “Impacts on antibiotic-resistant bacteria and their horizontal gene transfer by graphene-based TiO2&Ag composite photocatalysts under solar irradiation,” J. Hazard. Mater., vol. 380, p. 120877, Dec. 2019.M. Jiménez, I. J. Ferreira, S. da Silva, P. R. Guimarães, and E. M. Saggioro, “Removal of contaminants of emerging concern (CECs) and antibiotic resistant bacteria in urban wastewater using UVA/TiO2/H2O2 photocatalysis,” Chemosphere, vol. 210, pp. 449–457, Nov. 2018.F. Hernández, “Un mordente, un electrolito y grabado en cualquier metal”, Rev. Cient., no. 11, pp. 181-188, Dec. 2014.Y. Liu, Y. Gao, B. Yao, and D. Zou, “Removal of chlortetracycline by nano- micro-electrolysis materials: Application and mechanism,” Chemosphere, vol. 238, pp. 124543, 2020.H. Mahdizadeh and M. Malakootian, “Optimization of ciprofloxacin removal from aqueous solutions by a novel semi-fluid Fe/charcoal micro-electrolysis reactor using response surface methodology,” Process Saf. Environ. Prot., vol. 123, pp. 299–308, Mar. 2019.Y. Liu, C. Wang, Z. Sui, and D. Zou, “Degradation of chlortetracycline using nano micro-electrolysis materials with loading copper,” Sep. Purif. Technol., vol. 203, pp. 29–35, Sep. 2018.X. Cui, X. Li, N. Li, G. Chen, and H. Zheng, “Sludge based micro-electrolysis filler for removing tetracycline from solution,” J. Colloid Interface Sci., vol. 534, pp. 490–498, Jan. 2019.Yusuf G Adewuyi, “Sonochemistry in environmental remediation. 2. Heterogeneous sonophotocatalytic oxidation processes for the treatment of pollutants in water,”Environ. Sci. Technol., vol. 39, no. 22, pp. 8557-857, 2005.E. A. Serna, J. Silva, A. L. Giraldo, O. A. Flórez, and R. A. Torres, “High frequency ultrasound as a selective advanced oxidation process to remove penicillinic antibiotics and eliminate its antimicrobial activity from water,” Ultrason. Sonochem., vol. 31, pp. 276–283, Jul. 2016.J. Jin et al., “3D Bombax-structured carbon nanotube sponge coupling with Ag3PO4 for tetracycline degradation under ultrasound and visible light irradiation,” Sci. Total Environ., vol. 695, 2019.K. V. Patiño, S. M. Arroyave and J. M. Marín, “Oxidación electroquímica y ozonización aplicadas al tratamiento de aguas de lavado de la producción de biodiesel” Información Tecnológica, vol. 23, no. 2, pp. 41-52, 2012.A. L. Giraldo, E. D. Erazo, O. A. Flórez, E. A. Serna and R. A. Torres, “Tratamiento electroquímico de aguas que contienen antibióticos β-lactámicos,” Rev. Ciencia Desarrollo, vol. 7, no. 1, pp. 21–29, Jun. 2016.H. Zhang, F. Liu, X. Wu, J. Zhang, and D. Zhang, “Degradation of tetracycline in aqueous medium by electrochemical method,” Asia-Pac. J. Chem. Eng., vol. 4, no. 5, pp. 568–573, Sep. 2009.S. D. Jojoa, J. Silva, E. Herrera and R. A. Torres, “Elimination of the antibiotic norfloxacin in municipal wastewater, urine and seawater by electrochemical oxidation on IrO2 anodes,” Sci. Total Environ., vol. 575, pp. 1228–1238, Jan. 2017.B. G. Padilla et al., “Electrochemical degradation of amoxicilin in aqueous media,” Chem. Eng. Process., vol. 94, pp. 93-98, 2015.E. Serna, K. Berrio, and R. Torres, “Electrochemical treatment of penicillin, cephalosporin, and fluoroquinolone antibiotics via active chlorine: evaluation of antimicrobial activity, toxicity, matrix, and their correlation with the degradation pathways,” Environ. Sci. Pollunt Res., vol. 24, no. 30, pp. 23771–23782, Oct. 2017.W. R. Calero Cáceres, “Evaluación de reservorios ambientales de partículas fágicas portadoras de genes resistencia a antibióticos,” tesis doctoral, Universitat de Barcelona, 2016.Y. Hu et al., “Removal of sulfonamide antibiotic resistant bacterial and intracellular antibiotic resistance genes by UVC-activated peroxymonosulfate,” Chem. Eng. J., vol. 368, pp. 888–895, Jul. 2019.J. Rodríguez-Chueca et al., “Assessment of full-scale tertiary wastewater treatment by UV-C based-AOPs: Removal or persistence of antibiotics and antibiotic resistance genes?,” Sci. Total Environ., vol. 652, pp. 1051–1061, Feb. 2019.T. Zhang et al., “Removal of antibiotic resistance genes and control of horizontal transfer risk by UV, chlorination and UV/chlorination treatments of drinking water,” Chem. Eng. J., vol. 358, pp. 589–597, Feb. 2019.C. Ferradini, “Kinetic Behavior of the Radiolysis Products of Water,” Adv. Inorg. Chem. Radiochem., vol. 3. Academic Press, pp. 171–205, 1961.W. Song, W. Chen, W. J. Cooper, J. Greaves and G. E. Miller, “Free-Radical destruction of b-Lactam antibiotics in aqueous solution,” J. Phys. Chem., vol. 112, no. 32, pp. 7411-7417, Jun. 2008.D. Chen et al., “Degradation of antibiotic cephalosporin C in aqueous solution and elimination of antimicrobial activity by gamma irradiation,” Chem. Eng. J., vol. 374, pp. 1102–1108, Oct. 2019.R. Zhuan and J. Wang, “Enhanced degradation and mineralization of sulfamethoxazole by integrating gamma radiation with Fenton-like processes,” Radiat. Phy. Chem., vol. 166, 2020.R. Changotra, J. P. Guin, L. Varshney, and A. Dhir, “Assessment of reaction intermediates of gamma radiation-induced degradation of ofloxacin in aqueous solution,” Chemosphere, vol. 208, pp. 606–613, Oct. 2018.W. Zheng, X. Wen, B. Zhang, and Y. Qiu, “Selective effect and elimination of antibiotics in membrane bioreactor of urban wastewater treatment plant,” Sci. Total Environ., vol. 646, pp. 1293–1303, Jan. 2019.T.H. Le, C. Ng, N. H. Tran, H. Chen, and K. Y.-H. Gin, “Removal of antibiotic residues, antibiotic resistant bacteria and antibiotic resistance genes in municipal wastewater by membrane bioreactor systems,” Water Res., vol. 145, pp. 498–508, 2018.Y. Zhu, Y. Wang, S. Zhou, X. Jiang, X. Ma, and C. Liu, “Robust performance of a membrane bioreactor for removing antibiotic resistance genes exposed to antibiotics: Role of membrane foulants,” Water Res., vol. 130, pp. 139–150, Mar. 2018.B.-J. Shi et al., “Application of membrane bioreactor for sulfamethazine-contained wastewater treatment,” Chemosphere, vol. 193, pp. 840–846, Feb. 2018Z. Xu, X. Song, G. Li, Y. Li, and W. Luo, “Removal of antibiotics by sequencing-batch membrane bioreactor for swine wastewater treatment,” Sci. Total Environ., vol. 684, pp. 23–30, Sep. 2019.W. Zhao, Q. Sui, X. Mei, and X. Cheng, “Efficient elimination of sulfonamides by an anaerobic/anoxic/oxic-membrane bioreactor process: Performance and influence of redox condition,” Sci. Total Environ., vol. 633, pp. 668–676, Aug. 2018.T. T. Nguyen et al., “Removal of antibiotics in sponge membrane bioreactors treating hospital wastewater: Comparison between hollow fiber and flat sheet membrane systems,” Bioresour. Technol. Rep., vol. 240, pp. 42–49, Sep. 2017.G. Prados Joya, “Tratamiento de aguas para la eliminación de antibióticos -nitroimidazoles- mediante adsorción sobre carbón activado y tecnologías avanzadas de oxidación”, tesis doctoral, Universidad de Granada, 2010.A. A. Basheer, “New generation nano-adsorbents for the removal of emerging contaminants in water,” J. Mol. Liq., vol. 261, pp. 583–593, Jul. 2018.S. A. Snyder et al., “Role of membranes and activated carbon in the removal of endocrine disruptors and pharmaceuticals,” Desalination, vol. 202, no. 1. pp. 156–181, 2007.M. J. Ahmed and S. K. Theydan, “Fluoroquinolones antibiotics adsorption onto microporous activated carbon from lignocellulosic biomass by microwave pyrolysis,” J. Taiwan Inst. Chem. Eng., vol. 45, no. 1, pp. 219–226, Jan. 2014.G. Nazari, H. Abolghasemi, and M. Esmaieli, “Batch adsorption of cephalexin antibiotic from aqueous solution by walnut shell-based activated carbon,” J. Taiwan Inst. Chem. Eng., vol. 58, pp. 357–365, Jan. 2016.Q. Tang, P et al., “Control of antibiotic resistance in China must not be delayed: The current state of resistance and policy suggestions for the government, medical facilities, and patients,” BioSci. Trends, vol. 10, no. 1, pp. 1-6, 2016.M. Ferech et al., “European Surveillance of Antimicrobial Consumption (ESAC): outpatient antibiotic use in Europe,” J. Antimicrob. Chemother., vol. 48, pp. 401-407, 2006.F. Reinthaler et al., “Antibiotic resistance of E. coli in sewage and sludge,” Water Res., vol. 37, no. 8, pp. 1685-1692, Abril, 2003.S. Mosquito, J. Ruiz, J. Bauer and T. Ochoa, “Mecanismos moleculares de Resistencia antibiótica en Escherichia coli asociadas a diarrea,” Rev. Peru Med. Exp. Salud Pública, vol. 28, no. 4, pp. 648-656, 2011.G. Pliego et al., “Trends in the intensification of the Fenton process for wastewater treatment -An overview,” Crit. Rev. Env. Sci. Technol., vol. 45, no. 24, pp. 2611-2692, 2015.J. Pignatello, E. Oliveros and A. MacKay, “Advanced Oxidation Processes for Organic Contaminant Destruction Based on the Fenton Reaction and Related Chemistry,” J. Hazard. Mater., vol. 36, pp. 1-84, 2006.P. Kajitvichyanukul, L. Ming-Chun, L. Chih-Hsiang, W. Wirojanagud and T. Koottateo, “Degradation and detoxification of formaline wastewater by advanced oxidation processes”, J. Hazard. Mater., vol. 135, pp. 337-343, July, 2006.A. Vorontsov, “Advancing Fenton and photo-Fenton water treatment through the catalyst design”, vol. 372, pp. 103-112, 2019. Crit. Rev. Env. Sci. Technol., vol. 45, no. 24, pp. 2611-2692, 2015.B. Feier, A. Florea, C. Cristea and R. Sandulescu, “Electrochemical detection and removal of pharmaceuticals in waste waters,” Curr. Opin. Electrochem., vol. 11, pp. 1-11, Octuber 2018.P. Liu, H. Zhang, Y. Feng, C. Shen and F. Yang, “Integrating electrochemical oxidation into forward osmosis process for removal of trace antibiotics in wastewater,” J. Hazard. Mater., vol. 296, pp. 248-255, 2015.E. Lacasa, S. Cotillas, C. Saez, J. Lobato, P. Cañizares and M. Rodrigo, “Environmental applications of electrochemical technology. What is needed to enable full-scale applications?” Curr. Opin. Electrochem., vol. 16, pp. 149-156, 2019.C. Byrne, G. Subramanian and S. Pillai, “Recent advances in photocatalysis for environmental applications”, J. Environ. Chem. Eng., vol. 6, no. 3, pp. 3531-3555, Jun, 2018.L. Garcés, E. Mejía and J. Santamaría, “La fotocatálisis como alternativa para el tratamiento de aguas residuales,” Rev. Lasallista Investig., vol. 1, no. 1, pp. 83-92, 2004.J. You, Y. Guo, R. Guo and X. Liu, “A review of visible light-active photocatalysts for water disinfection: Features and prospects,” Chem. Eng. J., vol. 373, pp. 624-641, Octubre, 2019.W. Jianlong, “Application of radiation technology to sewage sludge processing: A review,” J. Hazard. Mater., vol.143, pp. 2-7, 2007.M. Salgot and M. Folch, “Wastewater treatment and water reuse,” Curr. Opin. Environ. Sci. Health, vol. 2, pp. 64-74, Ap. 2018.H. Jo et al., “Improvement of biodegradability of industrial wastewaters by radiation treatment,” J. Radioanal. Nucl. Chem., vol. 268, no. 1, pp. 145-150, 2006.CC-LICENSElicense_rdflicense_rdfapplication/rdf+xml; charset=utf-8811https://repository.usta.edu.co/bitstream/11634/21176/4/license_rdf217700a34da79ed616c2feb68d4c5e06MD54open accessLICENSElicense.txtlicense.txttext/plain; charset=utf-8807https://repository.usta.edu.co/bitstream/11634/21176/5/license.txtf6b8c5608fa6b2f649b2d63e10c5fa73MD55open accessTHUMBNAIL2019mariazapata.pdf.jpg2019mariazapata.pdf.jpgIM Thumbnailimage/jpeg8385https://repository.usta.edu.co/bitstream/11634/21176/6/2019mariazapata.pdf.jpg2a59e8883a29d6bf88e02c7c0e9d4509MD56open accessCarta_de_aprobación_de_la_facultad.pdf.jpgCarta_de_aprobación_de_la_facultad.pdf.jpgIM Thumbnailimage/jpeg8310https://repository.usta.edu.co/bitstream/11634/21176/7/Carta_de_aprobaci%c3%b3n_de_la_facultad.pdf.jpg637a0f3de54611f1f202fbe6a9aac3d8MD57metadata only accessCarta_de_derechos_de_autor.pdf.jpgCarta_de_derechos_de_autor.pdf.jpgIM Thumbnailimage/jpeg6443https://repository.usta.edu.co/bitstream/11634/21176/8/Carta_de_derechos_de_autor.pdf.jpgc905336a15af87c71fd24b73b690f9b8MD58metadata only accessORIGINAL2019mariazapata.pdf2019mariazapata.pdfapplication/pdf1064870https://repository.usta.edu.co/bitstream/11634/21176/1/2019mariazapata.pdf79500557b562086f1cabc36f69530162MD51open accessCarta_de_aprobación_de_la_facultad.pdfCarta_de_aprobación_de_la_facultad.pdfCarta de aprobación de la facultadapplication/pdf113313https://repository.usta.edu.co/bitstream/11634/21176/2/Carta_de_aprobaci%c3%b3n_de_la_facultad.pdfaee0c64fc7adef73e29c9047a2848954MD52metadata only accessCarta_de_derechos_de_autor.pdfCarta_de_derechos_de_autor.pdfCarta de derechos de autorapplication/pdf151889https://repository.usta.edu.co/bitstream/11634/21176/3/Carta_de_derechos_de_autor.pdf94d7ce7740a7e79ef3ccf460e33e806fMD53metadata only access11634/21176oai:repository.usta.edu.co:11634/211762022-10-10 14:50:48.56open accessRepositorio Universidad Santo Tomásrepositorio@usantotomas.edu.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

Innovación en tecnologías en plantas de tratamiento de agua residual para la eliminación de antibióticos, bacterias resistentes y genes de resistencia antibiótica: una revisión

Publicaciones similares