Biocatálisis y biotransformaciones I (2000-2012): Una alternativa eco-sustentable en química fina en Ecuador / Bio catalysis and biotransformation I (2000-2012): An eco-sustainable alternative in fine chemistry in Ecuador

Resumen En este estudio se desarrolló una búsqueda bibliográfica básica que abarca unos 15 años, desde el 2000 hasta 2015 sobre algunos aspectos conceptuales y metodológicos relacionados con procesos de biocatálisis y biotransformaciones, desde la perspectiva de química eco-sustentable o química ver...

Full description

Bibliographic Details
Main Authors: Sigüenza, Joseph Cruel, Canchingre, Elizabeth, Villavicencio, Carla Bernal, Morales, Juan Enrique Tacoronte
Format: Article in Journal/Newspaper
Language:Spanish
Published: Zenodo 2021
Subjects:
Tecnología química verde
Catálisis
Biocatálisis
Green Chemistry Techology
Catalysis
Biocatalysis
Argentina
Moreno
Petersen
Tapia
Gonzalez
Augusto
Fernandez
Williamson
Perez
Aranda
Ferreira
Navarro
Rubin
Estrada
Hult
Llorente
Porro
Saenz
Becerra
Vidal
Antarc*
Antarctica
Online Access:https://dx.doi.org/10.5281/zenodo.5866646
https://zenodo.org/record/5866646
_version_ 1821613080623185920
author Sigüenza, Joseph Cruel
Canchingre, Elizabeth
Villavicencio, Carla Bernal
Morales, Juan Enrique Tacoronte
author_facet Sigüenza, Joseph Cruel
Canchingre, Elizabeth
Villavicencio, Carla Bernal
Morales, Juan Enrique Tacoronte
author_sort Sigüenza, Joseph Cruel
collection DataCite
description Resumen En este estudio se desarrolló una búsqueda bibliográfica básica que abarca unos 15 años, desde el 2000 hasta 2015 sobre algunos aspectos conceptuales y metodológicos relacionados con procesos de biocatálisis y biotransformaciones, desde la perspectiva de química eco-sustentable o química verde. Se consideran los principios básicos de la química sustentable y su aplicabilidad en el campo de la quimio-catálisis, biocatálisis y de implementación de sistemas biocatalíticos (enzimas, células completas, sistemas soportados), así como ventajas y desventajas de la utilización de los diversos sistemas biocatalíticos en la química fina. Se destacan conceptos fundamentales y algunas aplicaciones, hoy clásicas y con relevante significación conceptual y metodológica de las biotransformaciones, incluyendo una visión estructural-funcional de mínimo impacto ambiental. Se analiza la aplicabilidad de la biocatálisis en la química fina y otros procesos tecnológicos tales como desulfurización, biooxidación avanzada, etc., y en el desarrollo de estrategias para el fortalecimiento de esta línea de investigación, en Biotransformaciones, a escala nacional y en laboratorios universitarios. Abstract In this study, a basic bibliographic search was developed that covers about 15 years, from 2000 to 2015 on some conceptual and methodological aspects related to bio catalysis and biotransformation processes, from the perspective of eco-sustainable chemistry or green chemistry. The basic principles of sustainable chemistry and their applicability in the field of chemo-catalysis, bio catalysis and the implementation of biocatalytic systems (enzymes, whole cells, supported systems) are considered, as well as advantages and disadvantages of the use of the various systems. biocatalysts in fine chemistry. Fundamental concepts and some applications, now classic and with relevant conceptual and methodological significance, of biotransformation are highlighted, including a structural-functional vision of minimal environmental impact. The applicability of bio catalysis in fine chemistry and other technological processes such as desulfurization, advanced bio-oxidation, etc., and in the development of strategies to strengthen this line of research, in Biotransformation, on a national scale and in university laboratories is analyzed. : {"references": ["Aranda, G., Moreno, L., Cortes, M., Prange, T., Maurs, M., & Azerad, R. (2001). A new example of 1a-hydroxylation of drimanic terpenes through combined microbial and chemical processes. Tetrahedron, (57), 6051-6056.", "Arroyo, M., Acebal, C., y De-la-Mata, I. (2014). Biocat\u00e1lisis y biotecnolog\u00eda. Arbor, 190(768), a156. https://doi.org/hb6d", "Baldessari, A., & Mangone, C. P. (2001). One-pot biocatalyzed preparation of substituted amides as intermediates of pharmaceuticals.\u00a0Journal of Molecular Catalysis - B Enzymatic,\u00a011(4-6), 335-341. https://doi.org/fk8zpc", "Baldessari, A., Bruttomesso, A. C., & Gros, E. G. (1996, June 26). Lipase-Catalysed Regioselective Deacetylation of androstane derivatives. Helvetica Chimica Acta, 79(4), 999-1004.\u00a0https://doi.org/bkxh5q", "Baldessari, A., Maier, M. S., & Gros, E. G. (1995). Enzymatic deacetylation of steroids bearing labile functions.\u00a0Tetrahedron Letters,\u00a036(25), 4349-4352. https://doi.org/fvvbtp", "Brena, B., Gonz\u00e1lez-Pombo, P., & Batista-Viera, F. (2013). Immobilization of enzymes: a literature survey.\u00a0Methods in molecular biology (Clifton, N.J.),\u00a01051, 15\u201331. https://doi.org/f5ck6h", "Cagnon, J. R., Porto, A. L., Marsaioli, A. J., Manfio, G. P., & Eguchi, S. Y. (1999). First evaluation of the Brazilian microorganisms biocatalytic potential.\u00a0Chemosphere,\u00a038(10), 2237\u20132242. https://doi.org/bj8crp", "Castellanos, O., Ram\u00edrez, D., y Monta\u00f1ez, V. (2006, mayo/agosto). Perspectiva en el desarrollo de las enzimas industriales a partir de la inteligencia tecnol\u00f3gica. Ingenier\u00eda e Investigaci\u00f3n, 26(2), 52-67. https://bit.ly/3qO5aSc", "De-Conti, R., Porto, A., Augusto, J., Rodrigues, R., Moran, P., Manfio, G., & Marsaioli, A. (2001, January 22). Microbial reduction of cyclohexanones. Journal of Molecular Catalysis B: Enzymatic, 11(4-6), 233-236. https://doi.org/dk552p", "De-Lima, C., Da-Silva, P., Nascimento, M., & Rezende, M. (1996). The use of immobilized lipases on chrysotile for esterification reactions. Journal of the Brazilian Chemical Society, 7(3), 173-175. https://bit.ly/3t6eHH0", "Enviromental Protection Agency. (1999). Green Chemistry: Frontiers in Benign Chemical Synthesis & Processes (P. Anastas & T. Williamson, Eds). Oxford University Press.", "Faber, K. (2004). Biocatalytic Applications. Biotransformations in organic chemistry (pp. 29-176). Springer.", "Fernandez-Llorente, G., Fernandez-Lafuente, R., Palomo, J. M., Mateo, C., Bastida, A., Coca, J., Haramboure, T., Hern\u00e1ndez-Justiz, O., Terreni, M., & Guisan, J. M. (2001, Januray 22). Biocatalyst engineering exerts a dramatic effect on selectivity of hydrolysis catalyzed by immobilized lipases in aqueous medium.\u00a0Journal of Molecular Catalysis B: Enzymatic, 11(4-6), 649-656. https://doi.org/c4nhhx", "Gamenara, D., Seoane, G., Saenz, P., & Dom\u00ednguez, P. (2013).\u00a0Redox Biocatalysis. Fundamentals and Applications. Wiley.", "Garc\u00eda-Garibay, M, L\u00f3pez-Mungu\u00eda, A., & Barzana, E. (2000, October 24). Effect of \u03b2-galactosidase hydration on alcoholysis reaction in organic one-phase liquid systems. Biotechnology and Bioengineering, 70(6), 647-653. https://doi.org/frp672", "Gavrilescu, M., & Chisti, Y. (2005). Biotechnology-a sustainable alternative for chemical industry.\u00a0Biotechnology advances,\u00a023(7-8), 471\u2013499. https://doi.org/bbp6zg", "Gonzalez, D., Schapiro, V., Seoane, G., & Hudlicky, T. (1997). New metabolites from toluene dioxygenase dihydroxylation of oxygenated biphenyls. Tetrahedron: Asymmetry, 8(7), 975-977. https://bit.ly/3q48j0Q", "Hudlicky, T., D. Gonzalez, & D. T. Gibson. (1999). Enzymatic dihydroxylation of aromatics in enantioselective synthesis: Expanding asymmetric methodology. Thetrahedron Letter, 32(2), 35-62. EPA Number:\u00a0R826113", "Klibanov A. M. (1983). Immobilized enzymes and cells as practical catalysts.\u00a0Science (New York, N.Y.),\u00a0219(4585), 722\u2013727. https://doi.org/c67n2p", "Lancaster, M. (2016, August 6). Green Chemistry: And Introductory Text (3rd ed.). Royal Society of Chemistry. (Original work published 2002).", "Leise, A., Seelbach, K., & Wandrey, C. (Eds). (2006, March). Industrial Biotransformations (2nd ed.). Wiley,", "Limberger, R. P., Ferreira, L., Castilhos, T., Aleixo, A. M., Petersen, R. Z., Germani, J. C., Zuanazzi, J. A., Fett-Neto, A. G., & Henriques, A. T. (2003). The ability of Bipolaris sorokiniana to modify geraniol and (-)-alpha-bisabolol as exogenous substrates.\u00a0Applied microbiology and biotechnology,\u00a061(5-6), 552\u2013555. https://doi.org/b7dd9c", "Luna, H. (2004). Aplicaci\u00f3n de la biocat\u00e1lisis a la preparaci\u00f3n de intermediarios para la s\u00edntesis de f\u00e1rmacos. Journal of the Mexican Chemical Society, 48(3), 211-219. https://bit.ly/3HFK1QW", "Magasanik, B., & chargaff, E. (1948). The structure of a new cyclohexose produced from d-inositol by biological oxidation.\u00a0The Journal of Biological Chemistry,\u00a0175(2), 929-937. https://bit.ly/3f0G5y2", "Mancera, O., Zaffaroni, A., Rubin, B., Sondheimer, F., Rosenkranz G., & Djerassi, C. (1952, July 20). Steroids. XXXVII. A ten step conversion of progesterone to cortisone. Journal of the American Chemical Society, 74(14), 3711-3712.", "Martinelle, M., Holmquist, M., & Hult, K. (1995). On the interfacial activation of Candida antarctica lipase A and B as compared with Humicola lanuginosa lipase.\u00a0Biochimica et biophysica acta,\u00a01258(3), 272\u2013276. https://doi.org/czwnw9", "Men\u00e9ndez, P., Garc\u00eda C., Rodr\u00edguez, P., Moyna, P., & Heinzen, H. (2002, June). Enzymatic systems involved in D-limonene biooxidation. Brazilian Archives of Biology and Technology, 45(2), 111-114. https://bit.ly/3q096js", "Monsalve, L. (2009). Biocat\u00e1lisis aplicada a reacciones de esteroides, terpenos y dicetonas y a la s\u00edntesis de poliamidoaminas lineales (Tesis doctoral, Universidad de Buenos Aires, Argentina). https://bit.ly/3q3QcZg", "Monteiro, J. B., Nascimento, M. G., & Ninow, J. L. (2003). Lipase-catalyzed synthesis of monoacylglycerol in a homogeneous system.\u00a0Biotechnology letters,\u00a025(8), 641\u2013644. https://doi.org/dvnjfw", "Navarro-Oca\u00f1a, A., Olgu\u00edn, L., Luna, H., Jim\u00e9nez-Estrada, M., & B\u00e1rzana, E. (2001). Reductive cyclization with baker's yeast of 4-alkyl-2-nitro-acetanilides to 6-alkylbenzimidazoles and 1-hydroxy-2-methyl-6-alkylbenzimidazoles [Abstract]. Journal of the Chemical Society, Perkin Transactions 1, (21), 2754-2756. https://rsc.li/3f0gANi", "Neuberg, C., & Lewite, A. (1918). XIV. Hydrogenation of a ketone by yeast. Transformation of methylheptenone into methylheptenol. Biochem. Z., 91, 257-266.", "Ogawa, J., & Shimizu, S. (1999). Microbial enzymes: new industrial applications from traditional screening methods.\u00a0Trends in biotechnology,\u00a017(1), 13\u201321. https://doi.org/bd6c3t", "Ovsejevi, K., Grazu, V., & Batista-Viera, D. (1998). \u03b2-Galactosidase from\u00a0Kluyveromyces lactis\u00a0immobilized on to thiosulfinate/thiosulfonate\u00a0supports for lactose hydrolysis in milk and dairy by-products. Biotechnology Techniques, 12, 143-148.", "Patel, R. (2001). Enzymatic preparations of chiral pharmaceutical intermediates by lipases. Journal. Liposome Research, (11), 355-393.", "Pessagno, R., & Baldessari, A. (2000). Lipase-Catalyzed Polymerization of Glycerol and Dicarboxylic Acids in an Organic Medium.\u00a0Molecules,\u00a05(12), 372\u2013373. MDPI AG. https://doi.org/bz44mc", "Peterson, D., & Murray, H. (1952, April 5). Microbiological oxygenation of steroids at carbon 11. Journal of the American Chemical Society, 74(7), 1871-1872. https://doi.org/bc4kzb", "Pilli, R., & Riatto, V. (1998, December). A Chemoenzymatic Synthesis of the Sex Pheromone of Lasioderma serricorne F. Journal of Brazilian Chemical Society, 9(6), 571-576. https://bit.ly/3eWprzh", "Porto, A., Cassiola, F., Dias, S., Joekes, I., Gushikem, Y., Rodrigues, J., Moran, P., Manfio, G., & Marsaioli, A. (2002). Aspergillus terreus CCT 3320 immobilized on chrysotile or cellulose/TiO2 for sulfide oxidation. Journal of Molecular Catalysis B: Enzymatic, 19-20, 327-334. https://bit.ly/32OeJJ3", "Ram\u00edrez, N., Serrano, J., & Sandoval, H. (2006). Microorganismos extrem\u00f3filos. Actinomicetos hal\u00f3filos en M\u00e9xico. Revista Mexicana de Ciencias Farmac\u00e9uticas, 37(3), 56-71. https://bit.ly/3F2vn4B", "Roberts, S., Davies, H., Green, R., Kelly, D., (1992). Biotransformations in preparative organic chemistry. The use of isolated enzymes and whole cell systems in synthesis. Academic Press.", "Rodr\u00edguez, S., Kayser, M. M., & Stewart, J. D. (2001). Highly stereoselective reagents for beta-keto ester reductions by genetic engineering of baker's yeast.\u00a0Journal of the American Chemical Society,\u00a0123(8), 1547\u20131555. https://doi.org/df5qjv", "Rogert, M., Trelles, J., Porro, S., Lewkowicz, E., & Iribarren, A., (2002). Microbial Synthesis of Antiviral Nucleosides Using Escherichia coli BL21 as Biocatalyst. Biocatalysis and Biotransformation, 20(5), 347-351. https://doi.org/dsvx77", "Santos, A., Pereira, N., Da Silva, I., Sarquis, M., & Antunes, O. (2003). Microbiologic Oxidation of Isosafrole into Piperonal [Abstract]. Biotechnology for Fuels and Chemicals, 105, 649-657. https://bit.ly/3eWnRxt", "Schapiro, V., Cavalli, G., Seoane, G., Faccio, R., & Mombru, A. (2002, November 13). Chemoenzymatic synthesis of chiral enones from aromatic compounds. Tetrahedron: Asymmetry, 13(22), 2453-2459. https://doi.org/c7vmfx", "Schmid, A., Dordick, J. S., Hauer, B., Kiener, A., Wubbolts, M., & Witholt, B. (2001). Industrial biocatalysis today and tomorrow.\u00a0Nature,\u00a0409(6817), 258\u2013268. https://doi.org/bqxgv7", "Seeger, M., Gonz\u00e1lez, M., C\u00e1mara, B., Mu\u00f1oz, L., Ponce, E., Mej\u00edas, L., Mascayano, C., V\u00e1squez, Y., & Sep\u00falveda-Boza, S. (2003). Biotransformation of natural and synthetic isoflavonoids by two recombinant microbial enzymes.\u00a0Applied and environmental microbiology,\u00a069(9), 5045\u20135050. https://doi.org/djgk32", "Sierra, A., Mel\u00e9ndez, L., Ram\u00edrez-Monroy, A., y Arroyo, M. (2014, julio/diciembre). La qu\u00edmica verde y el desarrollo sustentable RIDE Revista Iberoamericana para la Investigaci\u00f3n y el Desarrollo Educativo, 5(9), 1-15. https://bit.ly/3pZNKmr", "Solis, A., Luna, H., Perez, H., Manjarrez, N., S\u00e1nchez, R., Albores-Velasco, M., & Castillo, R. (1998). New sources of (R)-oxynitrilase: capulin (Prunnus capuli) and mamey (Mammea americana). Biotechnology Letters, 20(12), 1183-1185.", "Souza, E., & Nogueira, J. (2003). Stereoselective acylations of 1,2-azidoalcohols with vinyl acetate catalyzed by lipase Amano PS. Tetrahedron: Asymmetry, 14(10), 1255-1259. https://bit.ly/3eXH163", "Straathof, A. J., Panke, S., & Schmid, A. (2002). The production of fine chemicals by biotransformations.\u00a0Current opinion in biotechnology,\u00a013(6), 548\u2013556. https://doi.org/dsk9mv", "Tapia, A. A., Vallejo, M. D., Gouiric, S. C., Feresin, G. E., Rossomando, P. C., & Bustos, D. A. (1997). Hydroxylation of dehydroabietic acid by Fusarium species.\u00a0Phytochemistry,\u00a046(1), 131\u2013133. https://doi.org/djhjmj", "Trelles, J., Fern\u00e1ndez, M., Lewkowicz, E., Iribarren, A., & Sinisterra, J. (2003, March). Purine nucleoside synthesis from uridine using immobilized Enterobacter gergoviae CECT 875 whole cells. Tetrahedron Letter, 44(12), 2605-2609. https://doi.org/cg36b7", "Velasco, R., Montenegro, D., V\u00e9lez, J., Garc\u00eda, C., & Durango, D. (2009, enero/marzo). Biotransformaci\u00f3n de compuestos arom\u00e1ticos sustituidos mediante hongos filamentosos fitopat\u00f3genos de los g\u00e9neros Botryodiplodia y Colletotrichum. Revista de la Sociedad Qu\u00edmica del Per\u00fa, 75(1), 94-111. https://bit.ly/3zxf6DF", "Vidal, M., Becerra, J., Mondaca, M. A., & Silva, M. (2001). Selection of Mycobacterium sp. strains with capacity to biotransform high concentrations of beta-sitosterol.\u00a0Applied microbiology and biotechnology,\u00a057(3), 385\u2013389. https://doi.org/fmrjkz", "Vieira, H. S., Takahashi, J. A., & Boaventura, M. A. (2002). Novel derivatives of ent-17,19-dihydroxy-16betaH-kaurane obtained by biotransformation with Verticillium lecanii.\u00a0Journal of agricultural and food chemistry,\u00a050(13), 3704\u20133707. https://doi.org/d5thpr", "Zaks, A., & Klibanov, A. M. (1984). Enzymatic catalysis in organic media at 100 degrees C.\u00a0Science (New York, N.Y.),\u00a0224(4654), 1249\u20131251. https://doi.org/cxrp4t", "Zaks, A., & Klibanov, A. M. (1985). Enzyme-catalyzed processes in organic solvents.\u00a0Proceedings of the National Academy of Sciences of the United States of America,\u00a082(10), 3192\u20133196. https://doi.org/ftq4dc"]}
format Article in Journal/Newspaper
genre Antarc*
Antarctica
genre_facet Antarc*
Antarctica
geographic Argentina
Moreno
Petersen
Tapia
Gonzalez
Augusto
Fernandez
Williamson
Perez
Aranda
Ferreira
Navarro
Rubin
Estrada
Hult
Llorente
Porro
Saenz
Becerra
Vidal
geographic_facet Argentina
Moreno
Petersen
Tapia
Gonzalez
Augusto
Fernandez
Williamson
Perez
Aranda
Ferreira
Navarro
Rubin
Estrada
Hult
Llorente
Porro
Saenz
Becerra
Vidal
id ftdatacite:10.5281/zenodo.5866646
institution Open Polar
language Spanish
long_lat ENVELOPE(-62.300,-62.300,-64.083,-64.083)
ENVELOPE(-101.250,-101.250,-71.917,-71.917)
ENVELOPE(-62.050,-62.050,-64.083,-64.083)
ENVELOPE(-58.250,-58.250,-63.917,-63.917)
ENVELOPE(-61.613,-61.613,-64.054,-64.054)
ENVELOPE(-62.233,-62.233,-63.250,-63.250)
ENVELOPE(-65.383,-65.383,-67.717,-67.717)
ENVELOPE(-69.117,-69.117,-68.517,-68.517)
ENVELOPE(-60.783,-60.783,-62.467,-62.467)
ENVELOPE(-62.050,-62.050,-64.600,-64.600)
ENVELOPE(-62.167,-62.167,-64.650,-64.650)
ENVELOPE(65.493,65.493,-73.438,-73.438)
ENVELOPE(-61.100,-61.100,-66.000,-66.000)
ENVELOPE(-13.688,-13.688,65.101,65.101)
ENVELOPE(-58.367,-58.367,-63.700,-63.700)
ENVELOPE(23.567,23.567,65.517,65.517)
ENVELOPE(-60.967,-60.967,-66.000,-66.000)
ENVELOPE(-58.900,-58.900,-62.200,-62.200)
ENVELOPE(19.625,19.625,69.461,69.461)
op_collection_id ftdatacite
op_doi https://doi.org/10.5281/zenodo.5866646
https://doi.org/10.5281/zenodo.5866647
https://doi.org/10.5281/zenodo.5908386
op_relation https://zenodo.org/communities/manglareditores
https://dx.doi.org/10.5281/zenodo.5866647
https://dx.doi.org/10.5281/zenodo.5908386
https://zenodo.org/communities/manglareditores
op_rights Open Access
Creative Commons Attribution 4.0 International
https://creativecommons.org/licenses/by/4.0/legalcode
cc-by-4.0
info:eu-repo/semantics/openAccess
op_rightsnorm CC-BY
publishDate 2021
publisher Zenodo
record_format openpolar
spelling ftdatacite:10.5281/zenodo.5866646 2025-01-16T19:09:36+00:00 Biocatálisis y biotransformaciones I (2000-2012): Una alternativa eco-sustentable en química fina en Ecuador / Bio catalysis and biotransformation I (2000-2012): An eco-sustainable alternative in fine chemistry in Ecuador Sigüenza, Joseph Cruel Canchingre, Elizabeth Villavicencio, Carla Bernal Morales, Juan Enrique Tacoronte 2021 https://dx.doi.org/10.5281/zenodo.5866646 https://zenodo.org/record/5866646 es spa Zenodo https://zenodo.org/communities/manglareditores https://dx.doi.org/10.5281/zenodo.5866647 https://dx.doi.org/10.5281/zenodo.5908386 https://zenodo.org/communities/manglareditores Open Access Creative Commons Attribution 4.0 International https://creativecommons.org/licenses/by/4.0/legalcode cc-by-4.0 info:eu-repo/semantics/openAccess CC-BY Tecnología química verde Catálisis Biocatálisis Green Chemistry Techology Catalysis Biocatalysis article Chapter BookChapter 2021 ftdatacite https://doi.org/10.5281/zenodo.5866646 https://doi.org/10.5281/zenodo.5866647 https://doi.org/10.5281/zenodo.5908386 2022-02-09T13:51:44Z Resumen En este estudio se desarrolló una búsqueda bibliográfica básica que abarca unos 15 años, desde el 2000 hasta 2015 sobre algunos aspectos conceptuales y metodológicos relacionados con procesos de biocatálisis y biotransformaciones, desde la perspectiva de química eco-sustentable o química verde. Se consideran los principios básicos de la química sustentable y su aplicabilidad en el campo de la quimio-catálisis, biocatálisis y de implementación de sistemas biocatalíticos (enzimas, células completas, sistemas soportados), así como ventajas y desventajas de la utilización de los diversos sistemas biocatalíticos en la química fina. Se destacan conceptos fundamentales y algunas aplicaciones, hoy clásicas y con relevante significación conceptual y metodológica de las biotransformaciones, incluyendo una visión estructural-funcional de mínimo impacto ambiental. Se analiza la aplicabilidad de la biocatálisis en la química fina y otros procesos tecnológicos tales como desulfurización, biooxidación avanzada, etc., y en el desarrollo de estrategias para el fortalecimiento de esta línea de investigación, en Biotransformaciones, a escala nacional y en laboratorios universitarios. Abstract In this study, a basic bibliographic search was developed that covers about 15 years, from 2000 to 2015 on some conceptual and methodological aspects related to bio catalysis and biotransformation processes, from the perspective of eco-sustainable chemistry or green chemistry. The basic principles of sustainable chemistry and their applicability in the field of chemo-catalysis, bio catalysis and the implementation of biocatalytic systems (enzymes, whole cells, supported systems) are considered, as well as advantages and disadvantages of the use of the various systems. biocatalysts in fine chemistry. Fundamental concepts and some applications, now classic and with relevant conceptual and methodological significance, of biotransformation are highlighted, including a structural-functional vision of minimal environmental impact. The applicability of bio catalysis in fine chemistry and other technological processes such as desulfurization, advanced bio-oxidation, etc., and in the development of strategies to strengthen this line of research, in Biotransformation, on a national scale and in university laboratories is analyzed. : {"references": ["Aranda, G., Moreno, L., Cortes, M., Prange, T., Maurs, M., & Azerad, R. (2001). A new example of 1a-hydroxylation of drimanic terpenes through combined microbial and chemical processes. Tetrahedron, (57), 6051-6056.", "Arroyo, M., Acebal, C., y De-la-Mata, I. (2014). Biocat\u00e1lisis y biotecnolog\u00eda. Arbor, 190(768), a156. https://doi.org/hb6d", "Baldessari, A., & Mangone, C. P. (2001). One-pot biocatalyzed preparation of substituted amides as intermediates of pharmaceuticals.\u00a0Journal of Molecular Catalysis - B Enzymatic,\u00a011(4-6), 335-341. https://doi.org/fk8zpc", "Baldessari, A., Bruttomesso, A. C., & Gros, E. G. (1996, June 26). Lipase-Catalysed Regioselective Deacetylation of androstane derivatives. Helvetica Chimica Acta, 79(4), 999-1004.\u00a0https://doi.org/bkxh5q", "Baldessari, A., Maier, M. S., & Gros, E. G. (1995). Enzymatic deacetylation of steroids bearing labile functions.\u00a0Tetrahedron Letters,\u00a036(25), 4349-4352. https://doi.org/fvvbtp", "Brena, B., Gonz\u00e1lez-Pombo, P., & Batista-Viera, F. (2013). Immobilization of enzymes: a literature survey.\u00a0Methods in molecular biology (Clifton, N.J.),\u00a01051, 15\u201331. https://doi.org/f5ck6h", "Cagnon, J. R., Porto, A. L., Marsaioli, A. J., Manfio, G. P., & Eguchi, S. Y. (1999). First evaluation of the Brazilian microorganisms biocatalytic potential.\u00a0Chemosphere,\u00a038(10), 2237\u20132242. https://doi.org/bj8crp", "Castellanos, O., Ram\u00edrez, D., y Monta\u00f1ez, V. (2006, mayo/agosto). Perspectiva en el desarrollo de las enzimas industriales a partir de la inteligencia tecnol\u00f3gica. Ingenier\u00eda e Investigaci\u00f3n, 26(2), 52-67. https://bit.ly/3qO5aSc", "De-Conti, R., Porto, A., Augusto, J., Rodrigues, R., Moran, P., Manfio, G., & Marsaioli, A. (2001, January 22). Microbial reduction of cyclohexanones. Journal of Molecular Catalysis B: Enzymatic, 11(4-6), 233-236. https://doi.org/dk552p", "De-Lima, C., Da-Silva, P., Nascimento, M., & Rezende, M. (1996). The use of immobilized lipases on chrysotile for esterification reactions. Journal of the Brazilian Chemical Society, 7(3), 173-175. https://bit.ly/3t6eHH0", "Enviromental Protection Agency. (1999). Green Chemistry: Frontiers in Benign Chemical Synthesis & Processes (P. Anastas & T. Williamson, Eds). Oxford University Press.", "Faber, K. (2004). Biocatalytic Applications. Biotransformations in organic chemistry (pp. 29-176). Springer.", "Fernandez-Llorente, G., Fernandez-Lafuente, R., Palomo, J. M., Mateo, C., Bastida, A., Coca, J., Haramboure, T., Hern\u00e1ndez-Justiz, O., Terreni, M., & Guisan, J. M. (2001, Januray 22). Biocatalyst engineering exerts a dramatic effect on selectivity of hydrolysis catalyzed by immobilized lipases in aqueous medium.\u00a0Journal of Molecular Catalysis B: Enzymatic, 11(4-6), 649-656. https://doi.org/c4nhhx", "Gamenara, D., Seoane, G., Saenz, P., & Dom\u00ednguez, P. (2013).\u00a0Redox Biocatalysis. Fundamentals and Applications. Wiley.", "Garc\u00eda-Garibay, M, L\u00f3pez-Mungu\u00eda, A., & Barzana, E. (2000, October 24). Effect of \u03b2-galactosidase hydration on alcoholysis reaction in organic one-phase liquid systems. Biotechnology and Bioengineering, 70(6), 647-653. https://doi.org/frp672", "Gavrilescu, M., & Chisti, Y. (2005). Biotechnology-a sustainable alternative for chemical industry.\u00a0Biotechnology advances,\u00a023(7-8), 471\u2013499. https://doi.org/bbp6zg", "Gonzalez, D., Schapiro, V., Seoane, G., & Hudlicky, T. (1997). New metabolites from toluene dioxygenase dihydroxylation of oxygenated biphenyls. Tetrahedron: Asymmetry, 8(7), 975-977. https://bit.ly/3q48j0Q", "Hudlicky, T., D. Gonzalez, & D. T. Gibson. (1999). Enzymatic dihydroxylation of aromatics in enantioselective synthesis: Expanding asymmetric methodology. Thetrahedron Letter, 32(2), 35-62. EPA Number:\u00a0R826113", "Klibanov A. M. (1983). Immobilized enzymes and cells as practical catalysts.\u00a0Science (New York, N.Y.),\u00a0219(4585), 722\u2013727. https://doi.org/c67n2p", "Lancaster, M. (2016, August 6). Green Chemistry: And Introductory Text (3rd ed.). Royal Society of Chemistry. (Original work published 2002).", "Leise, A., Seelbach, K., & Wandrey, C. (Eds). (2006, March). Industrial Biotransformations (2nd ed.). Wiley,", "Limberger, R. P., Ferreira, L., Castilhos, T., Aleixo, A. M., Petersen, R. Z., Germani, J. C., Zuanazzi, J. A., Fett-Neto, A. G., & Henriques, A. T. (2003). The ability of Bipolaris sorokiniana to modify geraniol and (-)-alpha-bisabolol as exogenous substrates.\u00a0Applied microbiology and biotechnology,\u00a061(5-6), 552\u2013555. https://doi.org/b7dd9c", "Luna, H. (2004). Aplicaci\u00f3n de la biocat\u00e1lisis a la preparaci\u00f3n de intermediarios para la s\u00edntesis de f\u00e1rmacos. Journal of the Mexican Chemical Society, 48(3), 211-219. https://bit.ly/3HFK1QW", "Magasanik, B., & chargaff, E. (1948). The structure of a new cyclohexose produced from d-inositol by biological oxidation.\u00a0The Journal of Biological Chemistry,\u00a0175(2), 929-937. https://bit.ly/3f0G5y2", "Mancera, O., Zaffaroni, A., Rubin, B., Sondheimer, F., Rosenkranz G., & Djerassi, C. (1952, July 20). Steroids. XXXVII. A ten step conversion of progesterone to cortisone. Journal of the American Chemical Society, 74(14), 3711-3712.", "Martinelle, M., Holmquist, M., & Hult, K. (1995). On the interfacial activation of Candida antarctica lipase A and B as compared with Humicola lanuginosa lipase.\u00a0Biochimica et biophysica acta,\u00a01258(3), 272\u2013276. https://doi.org/czwnw9", "Men\u00e9ndez, P., Garc\u00eda C., Rodr\u00edguez, P., Moyna, P., & Heinzen, H. (2002, June). Enzymatic systems involved in D-limonene biooxidation. Brazilian Archives of Biology and Technology, 45(2), 111-114. https://bit.ly/3q096js", "Monsalve, L. (2009). Biocat\u00e1lisis aplicada a reacciones de esteroides, terpenos y dicetonas y a la s\u00edntesis de poliamidoaminas lineales (Tesis doctoral, Universidad de Buenos Aires, Argentina). https://bit.ly/3q3QcZg", "Monteiro, J. B., Nascimento, M. G., & Ninow, J. L. (2003). Lipase-catalyzed synthesis of monoacylglycerol in a homogeneous system.\u00a0Biotechnology letters,\u00a025(8), 641\u2013644. https://doi.org/dvnjfw", "Navarro-Oca\u00f1a, A., Olgu\u00edn, L., Luna, H., Jim\u00e9nez-Estrada, M., & B\u00e1rzana, E. (2001). Reductive cyclization with baker's yeast of 4-alkyl-2-nitro-acetanilides to 6-alkylbenzimidazoles and 1-hydroxy-2-methyl-6-alkylbenzimidazoles [Abstract]. Journal of the Chemical Society, Perkin Transactions 1, (21), 2754-2756. https://rsc.li/3f0gANi", "Neuberg, C., & Lewite, A. (1918). XIV. Hydrogenation of a ketone by yeast. Transformation of methylheptenone into methylheptenol. Biochem. Z., 91, 257-266.", "Ogawa, J., & Shimizu, S. (1999). Microbial enzymes: new industrial applications from traditional screening methods.\u00a0Trends in biotechnology,\u00a017(1), 13\u201321. https://doi.org/bd6c3t", "Ovsejevi, K., Grazu, V., & Batista-Viera, D. (1998). \u03b2-Galactosidase from\u00a0Kluyveromyces lactis\u00a0immobilized on to thiosulfinate/thiosulfonate\u00a0supports for lactose hydrolysis in milk and dairy by-products. Biotechnology Techniques, 12, 143-148.", "Patel, R. (2001). Enzymatic preparations of chiral pharmaceutical intermediates by lipases. Journal. Liposome Research, (11), 355-393.", "Pessagno, R., & Baldessari, A. (2000). Lipase-Catalyzed Polymerization of Glycerol and Dicarboxylic Acids in an Organic Medium.\u00a0Molecules,\u00a05(12), 372\u2013373. MDPI AG. https://doi.org/bz44mc", "Peterson, D., & Murray, H. (1952, April 5). Microbiological oxygenation of steroids at carbon 11. Journal of the American Chemical Society, 74(7), 1871-1872. https://doi.org/bc4kzb", "Pilli, R., & Riatto, V. (1998, December). A Chemoenzymatic Synthesis of the Sex Pheromone of Lasioderma serricorne F. Journal of Brazilian Chemical Society, 9(6), 571-576. https://bit.ly/3eWprzh", "Porto, A., Cassiola, F., Dias, S., Joekes, I., Gushikem, Y., Rodrigues, J., Moran, P., Manfio, G., & Marsaioli, A. (2002). Aspergillus terreus CCT 3320 immobilized on chrysotile or cellulose/TiO2 for sulfide oxidation. Journal of Molecular Catalysis B: Enzymatic, 19-20, 327-334. https://bit.ly/32OeJJ3", "Ram\u00edrez, N., Serrano, J., & Sandoval, H. (2006). Microorganismos extrem\u00f3filos. Actinomicetos hal\u00f3filos en M\u00e9xico. Revista Mexicana de Ciencias Farmac\u00e9uticas, 37(3), 56-71. https://bit.ly/3F2vn4B", "Roberts, S., Davies, H., Green, R., Kelly, D., (1992). Biotransformations in preparative organic chemistry. The use of isolated enzymes and whole cell systems in synthesis. Academic Press.", "Rodr\u00edguez, S., Kayser, M. M., & Stewart, J. D. (2001). Highly stereoselective reagents for beta-keto ester reductions by genetic engineering of baker's yeast.\u00a0Journal of the American Chemical Society,\u00a0123(8), 1547\u20131555. https://doi.org/df5qjv", "Rogert, M., Trelles, J., Porro, S., Lewkowicz, E., & Iribarren, A., (2002). Microbial Synthesis of Antiviral Nucleosides Using Escherichia coli BL21 as Biocatalyst. Biocatalysis and Biotransformation, 20(5), 347-351. https://doi.org/dsvx77", "Santos, A., Pereira, N., Da Silva, I., Sarquis, M., & Antunes, O. (2003). Microbiologic Oxidation of Isosafrole into Piperonal [Abstract]. Biotechnology for Fuels and Chemicals, 105, 649-657. https://bit.ly/3eWnRxt", "Schapiro, V., Cavalli, G., Seoane, G., Faccio, R., & Mombru, A. (2002, November 13). Chemoenzymatic synthesis of chiral enones from aromatic compounds. Tetrahedron: Asymmetry, 13(22), 2453-2459. https://doi.org/c7vmfx", "Schmid, A., Dordick, J. S., Hauer, B., Kiener, A., Wubbolts, M., & Witholt, B. (2001). Industrial biocatalysis today and tomorrow.\u00a0Nature,\u00a0409(6817), 258\u2013268. https://doi.org/bqxgv7", "Seeger, M., Gonz\u00e1lez, M., C\u00e1mara, B., Mu\u00f1oz, L., Ponce, E., Mej\u00edas, L., Mascayano, C., V\u00e1squez, Y., & Sep\u00falveda-Boza, S. (2003). Biotransformation of natural and synthetic isoflavonoids by two recombinant microbial enzymes.\u00a0Applied and environmental microbiology,\u00a069(9), 5045\u20135050. https://doi.org/djgk32", "Sierra, A., Mel\u00e9ndez, L., Ram\u00edrez-Monroy, A., y Arroyo, M. (2014, julio/diciembre). La qu\u00edmica verde y el desarrollo sustentable RIDE Revista Iberoamericana para la Investigaci\u00f3n y el Desarrollo Educativo, 5(9), 1-15. https://bit.ly/3pZNKmr", "Solis, A., Luna, H., Perez, H., Manjarrez, N., S\u00e1nchez, R., Albores-Velasco, M., & Castillo, R. (1998). New sources of (R)-oxynitrilase: capulin (Prunnus capuli) and mamey (Mammea americana). Biotechnology Letters, 20(12), 1183-1185.", "Souza, E., & Nogueira, J. (2003). Stereoselective acylations of 1,2-azidoalcohols with vinyl acetate catalyzed by lipase Amano PS. Tetrahedron: Asymmetry, 14(10), 1255-1259. https://bit.ly/3eXH163", "Straathof, A. J., Panke, S., & Schmid, A. (2002). The production of fine chemicals by biotransformations.\u00a0Current opinion in biotechnology,\u00a013(6), 548\u2013556. https://doi.org/dsk9mv", "Tapia, A. A., Vallejo, M. D., Gouiric, S. C., Feresin, G. E., Rossomando, P. C., & Bustos, D. A. (1997). Hydroxylation of dehydroabietic acid by Fusarium species.\u00a0Phytochemistry,\u00a046(1), 131\u2013133. https://doi.org/djhjmj", "Trelles, J., Fern\u00e1ndez, M., Lewkowicz, E., Iribarren, A., & Sinisterra, J. (2003, March). Purine nucleoside synthesis from uridine using immobilized Enterobacter gergoviae CECT 875 whole cells. Tetrahedron Letter, 44(12), 2605-2609. https://doi.org/cg36b7", "Velasco, R., Montenegro, D., V\u00e9lez, J., Garc\u00eda, C., & Durango, D. (2009, enero/marzo). Biotransformaci\u00f3n de compuestos arom\u00e1ticos sustituidos mediante hongos filamentosos fitopat\u00f3genos de los g\u00e9neros Botryodiplodia y Colletotrichum. Revista de la Sociedad Qu\u00edmica del Per\u00fa, 75(1), 94-111. https://bit.ly/3zxf6DF", "Vidal, M., Becerra, J., Mondaca, M. A., & Silva, M. (2001). Selection of Mycobacterium sp. strains with capacity to biotransform high concentrations of beta-sitosterol.\u00a0Applied microbiology and biotechnology,\u00a057(3), 385\u2013389. https://doi.org/fmrjkz", "Vieira, H. S., Takahashi, J. A., & Boaventura, M. A. (2002). Novel derivatives of ent-17,19-dihydroxy-16betaH-kaurane obtained by biotransformation with Verticillium lecanii.\u00a0Journal of agricultural and food chemistry,\u00a050(13), 3704\u20133707. https://doi.org/d5thpr", "Zaks, A., & Klibanov, A. M. (1984). Enzymatic catalysis in organic media at 100 degrees C.\u00a0Science (New York, N.Y.),\u00a0224(4654), 1249\u20131251. https://doi.org/cxrp4t", "Zaks, A., & Klibanov, A. M. (1985). Enzyme-catalyzed processes in organic solvents.\u00a0Proceedings of the National Academy of Sciences of the United States of America,\u00a082(10), 3192\u20133196. https://doi.org/ftq4dc"]} Article in Journal/Newspaper Antarc* Antarctica DataCite Argentina Moreno ENVELOPE(-62.300,-62.300,-64.083,-64.083) Petersen ENVELOPE(-101.250,-101.250,-71.917,-71.917) Tapia ENVELOPE(-62.050,-62.050,-64.083,-64.083) Gonzalez ENVELOPE(-58.250,-58.250,-63.917,-63.917) Augusto ENVELOPE(-61.613,-61.613,-64.054,-64.054) Fernandez ENVELOPE(-62.233,-62.233,-63.250,-63.250) Williamson ENVELOPE(-65.383,-65.383,-67.717,-67.717) Perez ENVELOPE(-69.117,-69.117,-68.517,-68.517) Aranda ENVELOPE(-60.783,-60.783,-62.467,-62.467) Ferreira ENVELOPE(-62.050,-62.050,-64.600,-64.600) Navarro ENVELOPE(-62.167,-62.167,-64.650,-64.650) Rubin ENVELOPE(65.493,65.493,-73.438,-73.438) Estrada ENVELOPE(-61.100,-61.100,-66.000,-66.000) Hult ENVELOPE(-13.688,-13.688,65.101,65.101) Llorente ENVELOPE(-58.367,-58.367,-63.700,-63.700) Porro ENVELOPE(23.567,23.567,65.517,65.517) Saenz ENVELOPE(-60.967,-60.967,-66.000,-66.000) Becerra ENVELOPE(-58.900,-58.900,-62.200,-62.200) Vidal ENVELOPE(19.625,19.625,69.461,69.461)
spellingShingle Tecnología química verde
Catálisis
Biocatálisis
Green Chemistry Techology
Catalysis
Biocatalysis
Sigüenza, Joseph Cruel
Canchingre, Elizabeth
Villavicencio, Carla Bernal
Morales, Juan Enrique Tacoronte
Biocatálisis y biotransformaciones I (2000-2012): Una alternativa eco-sustentable en química fina en Ecuador / Bio catalysis and biotransformation I (2000-2012): An eco-sustainable alternative in fine chemistry in Ecuador
title Biocatálisis y biotransformaciones I (2000-2012): Una alternativa eco-sustentable en química fina en Ecuador / Bio catalysis and biotransformation I (2000-2012): An eco-sustainable alternative in fine chemistry in Ecuador
title_full Biocatálisis y biotransformaciones I (2000-2012): Una alternativa eco-sustentable en química fina en Ecuador / Bio catalysis and biotransformation I (2000-2012): An eco-sustainable alternative in fine chemistry in Ecuador
title_fullStr Biocatálisis y biotransformaciones I (2000-2012): Una alternativa eco-sustentable en química fina en Ecuador / Bio catalysis and biotransformation I (2000-2012): An eco-sustainable alternative in fine chemistry in Ecuador
title_full_unstemmed Biocatálisis y biotransformaciones I (2000-2012): Una alternativa eco-sustentable en química fina en Ecuador / Bio catalysis and biotransformation I (2000-2012): An eco-sustainable alternative in fine chemistry in Ecuador
title_short Biocatálisis y biotransformaciones I (2000-2012): Una alternativa eco-sustentable en química fina en Ecuador / Bio catalysis and biotransformation I (2000-2012): An eco-sustainable alternative in fine chemistry in Ecuador
title_sort biocatálisis y biotransformaciones i (2000-2012): una alternativa eco-sustentable en química fina en ecuador / bio catalysis and biotransformation i (2000-2012): an eco-sustainable alternative in fine chemistry in ecuador
topic Tecnología química verde
Catálisis
Biocatálisis
Green Chemistry Techology
Catalysis
Biocatalysis
topic_facet Tecnología química verde
Catálisis
Biocatálisis
Green Chemistry Techology
Catalysis
Biocatalysis
url https://dx.doi.org/10.5281/zenodo.5866646
https://zenodo.org/record/5866646

Similar Items