{"id":63,"date":"2020-11-11T17:18:39","date_gmt":"2020-11-11T17:18:39","guid":{"rendered":"https:\/\/www.itba.edu.ar\/centros\/cima\/?page_id=63"},"modified":"2020-12-01T12:22:18","modified_gmt":"2020-12-01T12:22:18","slug":"publicaciones","status":"publish","type":"page","link":"https:\/\/www.itba.edu.ar\/centros\/cima\/publicaciones\/","title":{"rendered":"Publicaciones"},"content":{"rendered":"

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Publicaciones<\/h1>\n

Centro de Ingenier\u00eda en Medio Ambiente <\/span><\/h2>\n

[\/et_pb_text][\/et_pb_column][et_pb_column type=\u00bb1_3″ _builder_version=\u00bb3.25″ custom_padding=\u00bb|||\u00bb custom_padding__hover=\u00bb|||\u00bb][\/et_pb_column][\/et_pb_row][\/et_pb_section][et_pb_section fb_built=\u00bb1″ admin_label=\u00bb Get a Quote\u00bb _builder_version=\u00bb4.6.6″ background_color=\u00bb#f5f5f5″ custom_padding=\u00bb|||\u00bb animation_style=\u00bbslide\u00bb animation_direction=\u00bbtop\u00bb animation_intensity_slide=\u00bb10%\u00bb box_shadow_style=\u00bbpreset3″ box_shadow_vertical=\u00bb10px\u00bb box_shadow_blur=\u00bb105px\u00bb box_shadow_spread=\u00bb0px\u00bb box_shadow_color=\u00bbrgba(0,0,0,0.12)\u00bb][et_pb_row column_structure=\u00bb1_3,1_3,1_3″ _builder_version=\u00bb4.6.6″ background_color=\u00bb#f5f5f5″ max_width=\u00bb80%\u00bb custom_margin=\u00bb|||\u00bb use_custom_width=\u00bbon\u00bb width_unit=\u00bboff\u00bb][et_pb_column type=\u00bb1_3″ _builder_version=\u00bb4.6.6″ background_color=\u00bb#f5f5f5″ custom_padding=\u00bb|||\u00bb custom_padding__hover=\u00bb|||\u00bb][et_pb_blurb use_icon=\u00bbon\u00bb icon_placement=\u00bbleft\u00bb content_max_width=\u00bb1100px\u00bb content_max_width_tablet=\u00bb1100px\u00bb content_max_width_last_edited=\u00bboff|desktop\u00bb _builder_version=\u00bb4.6.6″ header_font=\u00bbRubik|700|||||||\u00bb header_line_height=\u00bb1.4em\u00bb body_font=\u00bb||||||||\u00bb body_font_size=\u00bb15px\u00bb body_line_height=\u00bb1.8em\u00bb custom_margin=\u00bb||20px||false|false\u00bb custom_padding=\u00bb||0px|||\u00bb animation_style=\u00bbslide\u00bb animation_direction=\u00bbright\u00bb animation_intensity_slide=\u00bb10%\u00bb animation=\u00bboff\u00bb locked=\u00bboff\u00bb]<\/p>\n

Applying the monitoring breakdown structure model to trace metal content in edible biomonitors: An eight-year survey in the Beagle Channel (southern Patagonia), Conti, M.E., Tudino, M.B., Finoia, M.G., Simone, C., Stripeikis, J.2020 Food Research International<\/p>\n

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Managing complexity of marine ecosystems: From the monitoring breakdown structure (MBS) to the baseline assessment. Trace metal concentrations in biomonitors of the Beagle Channel, Patagonia (2005\u20132012), Conti, M.E., Tudino, M.B., Finoia, M.G., Simone, C., Stripeikis, J.2019 Ecological Indicators<\/p>\n

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Performance of two Patagonian molluscs as trace metal biomonitors: The overlap bioaccumulation index (OBI) as an integrative tool for the management of marine ecosystems , Conti, M.E., Tudino, M.B., Finoia, M.G., Simone, C., Stripeikis, J. 2019 Ecological Indicators<\/p>\n

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Enhancement of the Fouling Resistance of Zwitterion Coated Ceramic Membranes. Max Storms, Abbas J. Kadhem, Shuting Xiang, Matthew Bernards, Guillermina J. Gentile, Mar\u00eda M. Fidalgo de Cortalezzi. Membranes, Volume 10 (2020), 210.<\/p>\n

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Chapter 2 – Nanotechnology and the environment. In Harnessing Nanoscale Surface Interactions. Guillermina J. Gentile, Mar\u00eda M. Fidalgo de Cortalezzi. Editor: David J. Henry. Editorial: Elsevier. 2019; 41\u201376.<\/p>\n

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Electrostatic interactions in virus removal by ultrafiltration membranes. Guillermina Jos\u00e9 Gentile, Mercedes Cecilia Cruz, Ver\u00f3nica Beatriz Rajal, Mar\u00eda Marta Fidalgo de Cortalezzi. Journal of Environmental Chemical Engineering, Volume 6 (2018) 1314\u20131321.<\/p>\n

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Enhanced retention of bacteria by TiO2 nanoparticles in saturated porous media. Guillermina J. Gentile, Mar\u00eda M. Fidalgo de Cortalezzi. Journal of Contaminant Hydrology, Volume 191 (2016) 66\u201375.<\/p>\n

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Virus removal by iron oxide ceramic membranes. Maria M. Fidalgo de Cortalezzi, Maria V. Gallardo, Fernando Yrazu, Guillermina J. Gentile, Oscar Opezzo, Ramon Pizarro, Hugo R. Poma, Ver\u00f3nica B. Rajal. Journal of Environmental Chemical Engineering, Volume 2 (2014) 1831\u20131840.<\/p>\n

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Preparation and Characterization of Nanoencapsulated Synthetic Soybean Oil Derivative-an Abundant and Environmentally Friendly Phase Change Material-Heat Transfer Analysis and Applications, Jorge Bergamo, Ezequiel Rossi, Juan Mart\u00edn Maffi, Laura De Angelis, Mar\u00eda In\u00e9s Errea Sustainable Energy Technologies and Assessments, 41, 100794 (2020);<\/p>\n

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Preparation of an environmentally friendly lead adsorbent. A contribution to the rational design of heavy metal adsorbentsEzequiel Rossi, Jhon Alejandro \u00c1vila Ramirez, Mar\u00eda In\u00e9s Errea Journal of Environmental Chemical Engineering, 8 (5), 104210 (2020);<\/p>\n

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Trielectrode Plasma Reactor for Water Treatment Leandro Giuliani, Laura De Angelis, Gema, Diaz Bukvic, M. Zanini, F. Minotti, Mar\u00eda I. Errea, Diana Grondona Journal of Applied Physics, 127, 223303 (2020);<\/p>\n

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Development of poly(lactic acid) nanocomposites reinforced with hydrophobized bacterial cellulose Jhon Alejandro \u00c1vila Ram\u00edrez, Jimena Bovib, Celina Bernal, Mar\u00eda In\u00e9s Errea, Mar\u00eda Laura Foresti, Journal of Polymers and the Environment 28, 61\u201373 (2020)<\/p>\n

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Nanocomposites Based on Poly(lactic acid) and Bacterial Cellulose Acetylated by an &alpha;-Hydroxyacid Catalyzed Route Jhon A. Avila, Ursula Montoya Rojo, Patricia Cerruti, Celina Bernal, Mar\u00eda I. Errea, Mar\u00eda L. Foresti Journal of Polymers and the Environment 27 (3), 510-520 (2019)<\/p>\n

[\/et_pb_blurb][\/et_pb_column][et_pb_column type=\u00bb1_3″ _builder_version=\u00bb3.25″ custom_padding=\u00bb|||\u00bb custom_padding__hover=\u00bb|||\u00bb][et_pb_blurb use_icon=\u00bbon\u00bb icon_placement=\u00bbleft\u00bb content_max_width=\u00bb1100px\u00bb content_max_width_tablet=\u00bb1100px\u00bb content_max_width_last_edited=\u00bboff|desktop\u00bb _builder_version=\u00bb4.6.6″ header_font=\u00bbRubik|700|||||||\u00bb header_line_height=\u00bb1.4em\u00bb body_font=\u00bb||||||||\u00bb body_font_size=\u00bb15px\u00bb body_line_height=\u00bb1.8em\u00bb custom_margin=\u00bb||20px||false|false\u00bb custom_padding=\u00bb|||\u00bb animation_style=\u00bbslide\u00bb animation_direction=\u00bbright\u00bb animation_delay=\u00bb100ms\u00bb animation_intensity_slide=\u00bb10%\u00bb animation=\u00bboff\u00bb locked=\u00bboff\u00bb]<\/p>\n

Carboxymethylated bacterial cellulose: An environmentally friendly adsorbent for lead removal from water Ezequiel Rossi, Ursula Montoya Rojo, Patricia Cerruti, Mar\u00eda L. Foresti, Mar\u00eda I. Errea Journal of Environmental Chemical Engineering 6, 6844-6852 (2018)<\/p>\n

[\/et_pb_blurb][\/et_pb_column][et_pb_column type=\u00bb1_3″ _builder_version=\u00bb3.25″ custom_padding=\u00bb|||\u00bb custom_padding__hover=\u00bb|||\u00bb][et_pb_blurb use_icon=\u00bbon\u00bb icon_placement=\u00bbleft\u00bb content_max_width=\u00bb1100px\u00bb content_max_width_tablet=\u00bb1100px\u00bb content_max_width_last_edited=\u00bboff|desktop\u00bb _builder_version=\u00bb4.6.6″ header_font=\u00bbRubik|700|||||||\u00bb header_line_height=\u00bb1.4em\u00bb body_font=\u00bb||||||||\u00bb body_font_size=\u00bb15px\u00bb body_line_height=\u00bb1.8em\u00bb custom_margin=\u00bb||20px||false|false\u00bb custom_padding=\u00bb|||\u00bb animation_style=\u00bbslide\u00bb animation_direction=\u00bbright\u00bb animation_delay=\u00bb200ms\u00bb animation_intensity_slide=\u00bb10%\u00bb animation=\u00bboff\u00bb locked=\u00bboff\u00bb]<\/p>\n

Sulfated Polysaccharides in the Freshwater Green Macroalga Cladophora surera not Linked to Salinity AdaptationPaula X. Arata, Josefina Alberghina, Viviana Confalonieri, Mar\u00eda I. Errea, Jos\u00e9 M. Estevez, Marina Ciancia Frontiers in Plant Science<\/p>\n

[\/et_pb_blurb][et_pb_button button_url=\u00bbhttps:\/\/doi.org\/10.3389\/fpls.2017.01927″ url_new_window=\u00bbon\u00bb button_text=\u00bb+\u00bb _builder_version=\u00bb4.6.6″ _module_preset=\u00bbdefault\u00bb custom_button=\u00bbon\u00bb button_text_size=\u00bb13px\u00bb button_text_color=\u00bb#000000″ custom_margin=\u00bb|||19px|false|false\u00bb][\/et_pb_button][\/et_pb_column][\/et_pb_row][et_pb_row column_structure=\u00bb1_3,1_3,1_3″ _builder_version=\u00bb4.6.6″ background_color=\u00bb#f5f5f5″ max_width=\u00bb80%\u00bb custom_margin=\u00bb|||\u00bb use_custom_width=\u00bbon\u00bb width_unit=\u00bboff\u00bb][et_pb_column type=\u00bb1_3″ _builder_version=\u00bb4.6.6″ background_color=\u00bb#f5f5f5″ custom_padding=\u00bb|||\u00bb custom_padding__hover=\u00bb|||\u00bb][et_pb_blurb use_icon=\u00bbon\u00bb icon_placement=\u00bbleft\u00bb content_max_width=\u00bb1100px\u00bb content_max_width_tablet=\u00bb1100px\u00bb content_max_width_last_edited=\u00bboff|desktop\u00bb _builder_version=\u00bb4.6.6″ header_font=\u00bbRubik|700|||||||\u00bb header_line_height=\u00bb1.4em\u00bb body_font=\u00bb||||||||\u00bb body_font_size=\u00bb15px\u00bb body_line_height=\u00bb1.8em\u00bb custom_margin=\u00bb||20px||false|false\u00bb custom_padding=\u00bb|||\u00bb animation_style=\u00bbslide\u00bb animation_direction=\u00bbright\u00bb animation_intensity_slide=\u00bb10%\u00bb animation=\u00bboff\u00bb locked=\u00bboff\u00bb]<\/p>\n

Absorption of Siderite Within a Chemically Modified Poly(lactic acid) Based Composite Material for Agricultural ApplicationsNancy L., Mirta Fascio, Mar\u00eda I. Errea, Silvia Goyanes, Norma D\u00b4Accorso Journal of Polymers and the Environment (2017).<\/p>\n

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Selective Determination of Cr (VI) by On- Line Solid Phase Extraction FI-SPE-FAAS Using an Ion Exchanger Resin as Sorbent: An Improvement Treatment of the Analytical Signal Ezequiel Rossi, Mar\u00eda I. Errea, Mar\u00eda M. Fidalgo de Cortalezzi, Jorge Stripeikis Microchemical Journal 130, 88 (2017)<\/p>\n

[\/et_pb_blurb][\/et_pb_column][et_pb_column type=\u00bb1_3″ _builder_version=\u00bb3.25″ custom_padding=\u00bb|||\u00bb custom_padding__hover=\u00bb|||\u00bb][et_pb_blurb use_icon=\u00bbon\u00bb icon_placement=\u00bbleft\u00bb content_max_width=\u00bb1100px\u00bb content_max_width_tablet=\u00bb1100px\u00bb content_max_width_last_edited=\u00bboff|desktop\u00bb _builder_version=\u00bb4.6.6″ header_font=\u00bbRubik|700|||||||\u00bb header_line_height=\u00bb1.4em\u00bb body_font=\u00bb||||||||\u00bb body_font_size=\u00bb15px\u00bb body_line_height=\u00bb1.8em\u00bb custom_margin=\u00bb||20px||false|false\u00bb custom_padding=\u00bb|||\u00bb animation_style=\u00bbslide\u00bb animation_direction=\u00bbright\u00bb animation_delay=\u00bb200ms\u00bb animation_intensity_slide=\u00bb10%\u00bb animation=\u00bboff\u00bb locked=\u00bboff\u00bb]<\/p>\n

V. E. Aude Luppi and M. M. Fidalgo de Cortalezzi, \u00abInhibitory effects of titanium dioxide, silver and fullerene nanoparticles on activated sludge from a municipal wastewater treatment plant.,\u00bb in Technical Proceedings of the 2013 NSTI Nanotechnology Conference and Expo, NSTI-Nanotech 2013, vol. 3: CRC Press, 2013, pp. 489-492.<\/p>\n

[\/et_pb_blurb][\/et_pb_column][\/et_pb_row][et_pb_row column_structure=\u00bb1_3,1_3,1_3″ _builder_version=\u00bb4.6.6″ background_color=\u00bb#f5f5f5″ max_width=\u00bb80%\u00bb custom_margin=\u00bb|||\u00bb use_custom_width=\u00bbon\u00bb width_unit=\u00bboff\u00bb][et_pb_column type=\u00bb1_3″ _builder_version=\u00bb4.6.6″ background_color=\u00bb#f5f5f5″ custom_padding=\u00bb|||\u00bb custom_padding__hover=\u00bb|||\u00bb][et_pb_blurb use_icon=\u00bbon\u00bb icon_placement=\u00bbleft\u00bb content_max_width=\u00bb1100px\u00bb content_max_width_tablet=\u00bb1100px\u00bb content_max_width_last_edited=\u00bboff|desktop\u00bb _builder_version=\u00bb4.6.6″ header_font=\u00bbRubik|700|||||||\u00bb header_line_height=\u00bb1.4em\u00bb body_font=\u00bb||||||||\u00bb body_font_size=\u00bb15px\u00bb body_line_height=\u00bb1.8em\u00bb custom_margin=\u00bb||20px||false|false\u00bb custom_padding=\u00bb|||\u00bb animation_style=\u00bbslide\u00bb animation_direction=\u00bbright\u00bb animation_intensity_slide=\u00bb10%\u00bb animation=\u00bboff\u00bb locked=\u00bboff\u00bb]<\/p>\n

M. B. Romanello, L. Bertini, V. E. Aude Luppi, and M. M. Fidalgo de Cortalezzi, \u00abAn investigation on the aggregation phenomena of Titanium dioxide nanoparticles in natural waters: role of ionic strength, organic matter and natural colloidal particles,\u00bb in Technical Proceedings of the 2012 NSTI Nanotechnology Conference and Expo, NSTI-Nanotech 2012, vol. 3: CRC Press, 2012, pp. 281-284.<\/p>\n

[\/et_pb_blurb][\/et_pb_column][et_pb_column type=\u00bb1_3″ _builder_version=\u00bb3.25″ custom_padding=\u00bb|||\u00bb custom_padding__hover=\u00bb|||\u00bb][et_pb_blurb use_icon=\u00bbon\u00bb icon_placement=\u00bbleft\u00bb content_max_width=\u00bb1100px\u00bb content_max_width_tablet=\u00bb1100px\u00bb content_max_width_last_edited=\u00bboff|desktop\u00bb _builder_version=\u00bb4.6.6″ header_font=\u00bbRubik|700|||||||\u00bb header_line_height=\u00bb1.4em\u00bb body_font=\u00bb||||||||\u00bb body_font_size=\u00bb15px\u00bb body_line_height=\u00bb1.8em\u00bb custom_margin=\u00bb||20px||false|false\u00bb custom_padding=\u00bb|||\u00bb animation_style=\u00bbslide\u00bb animation_direction=\u00bbright\u00bb animation_delay=\u00bb100ms\u00bb animation_intensity_slide=\u00bb10%\u00bb animation=\u00bboff\u00bb locked=\u00bboff\u00bb]<\/p>\n

M. M. Fidalgo de Cortalezzi, L. Bertini, and V. E. Aude Luppi, \u00abNanotecnolog\u00eda y Medio Ambiente: \u00bfAvances o Amenazas?,\u00bb in Memorias de las Jornadas de Capacitaci\u00f3n Ambiental MetropolitanasBuenos Aires: Rubinzal Culzoni, 2010.<\/p>\n

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Glyphosate and AMPA removal from water by solar induced processes using low Fe(III) or Fe(II) concentrations\u201d . Serra-Clusellas, A., De Angelis, L., et.al. Environmental Science: Water Research & Technology (2019) http:\/\/dx.doi.org\/10.1039\/C9EW00442D<\/p>\n

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\u201cAbatement of 2,4-D by H2O2 solar photolysis and solar photo-Fenton-like process with minute Fe(III) concentrations\u201d. Serra-Clusellas, A., De Angelis, L., et.al. Water Research (2018) 144, 572-580.<\/p>\n

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\u201cAdsorption with catalytic oxidation in a recirculating bed reactor for contaminated groundwater.\u201d Russo, A. V., De Angelis, L. E., & Jacobo, S. E. Journal of Water Process Engineering (2018) 23, 129-133<\/p>\n

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\u201cAdsorption and catalytic oxidation of organic pollutants using Fe-zeolite\u201d. Russo, A. V., Andrade, C. V., De Angelis, L. E., & Jacobo, S. E., Water Science and Technology (2017) 77(4), 939-947.<\/p>\n

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\u201cImproved membrane flux recovery by Fenton-type reactions\u201d De Angelis, L.; Fidalgo, M. Journal of Membrane Science, 500, 255-264, (2016)<\/p>\n

[\/et_pb_blurb][et_pb_button button_url=\u00bbhttps:\/\/doi.org\/10.1016\/j.memsci.2015.11.042″ url_new_window=\u00bbon\u00bb button_text=\u00bb+\u00bb _builder_version=\u00bb4.6.6″ _module_preset=\u00bbdefault\u00bb custom_button=\u00bbon\u00bb button_text_size=\u00bb13px\u00bb button_text_color=\u00bb#000000″ custom_margin=\u00bb|||19px|false|false\u00bb][\/et_pb_button][\/et_pb_column][et_pb_column type=\u00bb1_3″ _builder_version=\u00bb3.25″ custom_padding=\u00bb|||\u00bb custom_padding__hover=\u00bb|||\u00bb][et_pb_blurb use_icon=\u00bbon\u00bb icon_placement=\u00bbleft\u00bb content_max_width=\u00bb1100px\u00bb content_max_width_tablet=\u00bb1100px\u00bb content_max_width_last_edited=\u00bboff|desktop\u00bb _builder_version=\u00bb4.6.6″ header_font=\u00bbRubik|700|||||||\u00bb header_line_height=\u00bb1.4em\u00bb body_font=\u00bb||||||||\u00bb body_font_size=\u00bb15px\u00bb body_line_height=\u00bb1.8em\u00bb custom_margin=\u00bb||20px||false|false\u00bb custom_padding=\u00bb|||\u00bb animation_style=\u00bbslide\u00bb animation_direction=\u00bbright\u00bb animation_delay=\u00bb100ms\u00bb animation_intensity_slide=\u00bb10%\u00bb animation=\u00bboff\u00bb locked=\u00bboff\u00bb]<\/p>\n

\u201cCeramic membrane filtration of organic compounds: Effect of concentration, pH, and mixtures interactions on fouling\u201d. De Angelis, L.; Fidalgo de Cortalezzi, M. Separation and Purification Technology, (2013). 118(0): p. 762-775.<\/p>\n

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\u201cComparative assessment of fouling of iron oxide ceramic membranes by model organic compounds\u201d. De Angelis, L., Fidalgo De Cortalezzi, M. (2009). In 2009 AWWA Membrane Technology Conference and Exposition.<\/p>\n

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Publicaciones Centro de Ingenier\u00eda en Medio Ambiente Applying the monitoring breakdown structure model to trace metal content in edible biomonitors: An eight-year survey in the Beagle Channel (southern Patagonia), Conti, M.E., Tudino, M.B., Finoia, M.G., Simone, C., Stripeikis, J.2020 Food Research InternationalManaging complexity of marine ecosystems: From the monitoring breakdown structure (MBS) to the baseline […]<\/p>\n","protected":false},"author":7,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"_et_pb_use_builder":"on","_et_pb_old_content":"","_et_gb_content_width":"","footnotes":""},"class_list":["post-63","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/www.itba.edu.ar\/centros\/cima\/wp-json\/wp\/v2\/pages\/63","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/www.itba.edu.ar\/centros\/cima\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/www.itba.edu.ar\/centros\/cima\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/www.itba.edu.ar\/centros\/cima\/wp-json\/wp\/v2\/users\/7"}],"replies":[{"embeddable":true,"href":"https:\/\/www.itba.edu.ar\/centros\/cima\/wp-json\/wp\/v2\/comments?post=63"}],"version-history":[{"count":22,"href":"https:\/\/www.itba.edu.ar\/centros\/cima\/wp-json\/wp\/v2\/pages\/63\/revisions"}],"predecessor-version":[{"id":152,"href":"https:\/\/www.itba.edu.ar\/centros\/cima\/wp-json\/wp\/v2\/pages\/63\/revisions\/152"}],"wp:attachment":[{"href":"https:\/\/www.itba.edu.ar\/centros\/cima\/wp-json\/wp\/v2\/media?parent=63"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}