Eliminar xenobióticos del patrimonio cultural:un reto para la biolimpieza

  1. Pilar Bosch-Roig 1
  2. Mercedes Sanchez Pons 1
  3. Patricia Sanmartín 2
  1. 1 Dpto. Conservación y Restauración del Patrimonio, Instituto Universitario de Restauración del Patrimonio-Universidad Politécnica de Valencia
  2. 2 Dpto. Edafoloxía e Química Agrícola, U. de Santiago de Compostela
Revista:
PH: Boletín del Instituto Andaluz del Patrimonio Histórico

ISSN: 2340-7565

Ano de publicación: 2023

Título do exemplar: (especial monográfico) Tecnologías verdes aplicadas a la caracterización, diagnóstico y conservación del patrimonio cultural

Ano: 31

Número: 110

Páxinas: 236-250

Tipo: Artigo

DOI: 10.33349/2023.110.5387 DIALNET GOOGLE SCHOLAR lock_openAcceso aberto editor

Outras publicacións en: PH: Boletín del Instituto Andaluz del Patrimonio Histórico

Resumo

La biolimpieza utiliza enzimas y microorganismos vivos para eliminar sustancias indeseadas de materiales de alto valor patrimonial. En los últimos treinta años, ha mostrado avances y aplicaciones exitosas en obras de pequeño, medio y gran tamaño, y de distinta naturaleza, como esculturas en piedra, pinturas murales y lienzos, demostrando que es una interesante y útil tecnología verde, no invasiva, no tóxica y sostenible para la restauración, alternativa a métodos químicos y mecánicos tradicionales. Su validez sobre sustancias naturales inorgánicas (nitratos y sulfatos) y orgánicas (colas animales) ha quedado demostrada, mientras que frente a sustancias sintéticas (xenobióticas) su recorrido es menor e inconcluso. Tradicionalmente los xenobióticos son eliminados empleando procedimientos mecánicos y disolventes, con los consiguientes riesgos de erosión en el material original y toxicidad para el trabajador y el medio ambiente, además de con limitaciones para actuar en materiales porosos, con fisuras y grietas. Su eliminación mediante biolimpieza se presenta como la alternativa necesaria, atóxica y eco-sostenible. En este artículo revisamos el estado del arte en la biolimpieza de sustancias xenobióticas, comenzando por las que pueden ser consideradas más simples, como son las resinas sintéticas, y continuando por grafitis y bitúmenes, que añaden la complejidad de la inclusión de otros elementos, como pigmentos, extendedores y aditivos. Para a continuación presentar el proyecto recién concedido BIOXEN (PID2021-123329NA-I00), en el que las autoras son las principales responsables y con el que se pretende abordar de manera definitiva la biolimpieza de restos de materiales xenobióticos del patrimonio.

Referencias bibliográficas

  • Alcalá, S., Baglioni, M., Alderson, S., Neiman, M., Tallio, S. C., y Giorgi, R. (2022) The use of nanostructured fluids for the removal of polymer coatings from a Nuxalk monumental carving-exploring the cleaning mechanism. Journal of Cultural Heritage, vol. 55, pp. 18-29
  • Alisi, C., Musella, R., Tasso, F., Ubaldi, C., Manzo, S., Cremisini, C. y Sprocati, A.R. (2009) Bioremediation of diesel oil in a co-contaminated soil by bioaugmentation with a microbial formula tailored with native strains selected for heavy metals resistance. Science of the Total Environment, vol. 407, pp. 3024-3032
  • Alisi, C., Magrini, D., Vettori, S., Salvadori, B., Vincenti, M., Manna, D., Bietti, M. y Sprocati, A.R. (2022) Sustainable Restoration Guided by Scientific and Archival Investigations: The Bio-Cleaning of Lorenzo Duke of Urbino’s Sarcophagus, a Michelangelo’s Masterpiece in the Medici Chapels. Heritage, vol. 5, pp. 3359-3373. Disponible en: https://doi. org/10.3390/heritage5040172 [Consulta: 06/07/2023]
  • Alfano, G., Lustrato, G., Belli, C., Zanardini, E., Cappitelli, F., Mello, E., Sorlini, C. y Ranalli, G. (2011) The bioremoval of nitrate and sulfate alterations on artistic stonework: The case-study of Matera Cathedral after six years from the treatment, International Biodeterioration and Biodegradation, vol. 65, n.º 7, pp. 1004-1011. Disponible en: https://doi.org/10.1016/j.ibiod.2011.07.010 [Consulta: 06/07/2023]
  • Atlas, R.M., Chowdhury, A.N. y Gauri, K.L. (1988) Microbial calcification of gypsum-rock and sulfated marble. Studies in Conservation, vol. 33, pp. 149-153
  • Balloi, A., Lombardi, E., Troiano, F., Polo, A., Cappitelli, F., Gulotta, D., Toniolo, L., Lucchini, A. y Daffonchio, D. (2015) Sulfate reducing bacteria as bio-cleaning agents: development of new methodologies and study cases. Conservation Science in Cultural Heritage, vol. 15, pp. 109- 119
  • Baglioni, M., Benavides, Y.J., Desprat-Drapela, A. y Giorgi, R. (2015) Amphiphile-based nanofludis for the removal of styrene/acrylate coatings: Cleaning of stucco decoration in the Uaxactun archeological site (Guatemala). Journal of Cultural Heritage, vol. 16, n.º 6, pp. 862-868
  • Baglioni, M., Poggi, G., Benavides, Y.J., Camacho, F.M., Giorgi, R. y Baglioni, P. (2018) Nanostructuredfluids for the removal of graffiti-A survey on 17 commercial spray-can paints. Journal of Cultural Heritage, vol. 34, pp. 218-226
  • Baglioni, M., Poggi, G., Chelazzi, D. y Baglioni, P. (2021a) Advanced Materials in Cultural Heritage Conservation. Molecules, vol. 26, n.º 13, pp. 3967. Disponible en: https:// doi.org/10.3390/molecules26133967 [Consulta: 10/07/2023]
  • Baglioni, M., Poggi, G., Giorgi, R., Rivella, P., Ogura, T. y Baglioni, P. (2021b) Selective removal of over-paintings from “Street Art” using an environmentally friendly nanostructured fluid loaded in highly retentive hydrogels. Journal of Colloid and Interface Science, vol. 595, pp. 187-201
  • Barbabietola, N., Grimaldi, M., Tasso, F., Alisi, C. Marconi, P., Sprocati, A.R. (2011) Development of microbial-based restoration techniques. Contribution to the “Italy in Japan 2011” initiative Science, Technology and Innovation, pp. 1-8
  • Bellucci, R., Cremonesi, P. y Pignagnoli, G (1999) A preliminary note on the use of enzymes in conservation: the removal of aged acrylic resin coatings with lipase. Studies in Conservation, vol. 44, n.º 4, pp. 278-281. Disponible en: https://doi.org/10.2307/1506657 [Consulta: 10/07/2023]
  • Bentley, J. y Turner, G.P.A. (1998) Introduction to paint chemistry and principles of paint technology. 4.ª ed. Londres: Editorial Chapman & Hall
  • Borgioli, L. y Cremonesi, P. (2005) Le resine sintetiche usate nel trattamento delle opere policrome, collana “I talenti”. Ed. Il Prato
  • Bonomi, R. (1998) Enzimi e Resine scambiatrici; Casi applicativi. En: Symposium Prospettive nell’utilizzo di Nuove Tecnologie per la Pulitura di Manufatti Artistici. Villa Gualino, Torino: Fondazione per le Biotecnologie
  • Bosch-Roig, P., Regidor-Ros, J.L. y Montes-Estellés, R.M. (2013) Biocleaning of nitrate alterations on wall paintings by Pseudomonas stutzeri. International Biodeterioration and Biodegradation, n.º 84, pp. 266-274. Disponible en: https:// doi.org/10.1016/j.ibiod.2012.09.009 [Consulta: 10/07/2023]
  • Bosch-Roig, P. y Ranalli, G. (2014) The safety of biocleaning technologies for cultural heritage. Frontiers in Microbiology, n.º 5, pp. 155
  • Bosch-Roig, P., Lustrato, G., Zanardini, E. y Ranalli, G. (2014) Biocleaning of Cultural Heritage stone surfaces and frescoes: Which delivery system can be the most appropriate? Annals of Microbiology, n.º 65, pp. 1227-1241
  • Bosch-Roig, P., Decorosi, F., Giovannetti, L., Ranalli, G. y Viti, C. (2016) Connecting phenome to genome in Pseudomonas stutzeri 5190: an artwork biocleaning bacterium. Research in Microbiology, n.º 167, pp. 757-765
  • Bosch-Roig, P., Allegue, H. y Bosch, I. (2019) Granite pavement nitrate desalination: traditional methods vs. biocleaning methods. Sustainability, vol. 11, n.º 15, pp. 4227. Disponible en: https://doi.org/10.3390/su11154227 [Consulta: 10/08/2023]
  • Bosch-Roig, P. y Sanmartín, P. (2021) Bioremoval of Graffiti in the Context of Current Biocleaning Research. En: Joseph, E. (ed.) Microorganisms in the Deterioration and Preservation of Cultural Heritage. Springer, Cham. Disponible en: https://doi.org/10.1007/978-3-030-69411- 1_8 [Consulta: 11/07/2023]
  • Bosch-Roig, P., Pérez-Castro, L., Fernández-Santiago, A. y Bosch, I. (2021a) High Dimension Granite Pavement Bio-Desalination Practical Implementation. Applied Sciences, vol. 11, n.º 14, pp. 6458. Disponible en: https:// doi.org/10.3390/app11146458 [Consulta: 11/07/2023]
  • Bosch-Roig, P., Pozo-Antonio, J.S. y Sanmartín, P. (2021b) Identification of the best- performing novel microbial strains from naturally-aged graffiti for biocleaning research. International Biodeterioration and Biodegradation, n.º 159, pp. 105-206
  • Bosi, A., Ciccola, A., Serafini, I., Guiso, M., Ripanti, F., Postorino, P., Curini, R. y Bianco, A. (2020) Street art graffiti: Discovering their composition and alteration by FTIR and micro-Raman spectroscopy. Spectrochimica Acta, Part A: Molecular and Biomolecular Spectroscopy, n.º 225
  • Campana, R., Sabatini, L., Giorgi, L., Pettinari, G., Valentini, L. y Gobbi, P. (2022) A Multidisciplinary Approach in Examining the Susceptibility to Microbial Attack of Polyacrylic and Polyurethane Resins Used in Art Restoration. International Journal of Molecular Sciences, vol. 23, n.º 19, pp. 11725. Disponible en: https://doi. org//ijms231911725 [Consulta: 10/07/2023]
  • Cappitelli, F., Zanardini, E., Toniolo, L., Abbruscato, P., Ranalli, G. y Sorlini, C. (2005a) Bioconservation of the marble base of the Pietà Rondanini by Michelangelo Buonarroti. Geophysical Research Abstracts, n.º 7, pp. 06675-00676
  • Cappitelli, F., Vicini, S., Piaggio, P., Abbruscato, P., Princi, E., Casadevall, A., Nosanchuk, J.D. y Zanardini, E. (2005b) Investigation of fungal deterioration of synthetic paint binders using vibrational spectroscopic techniques. Macromolecular Bioscience, n.º 5, pp. 49-57
  • Cappitelli, F., Zanardini, E., Ranalli, G., Mello, E., Daffonchio, D. y Sorlini, C. (2006) Improved methodology for bioremoval of black crusts on historical stone artworks by use of sulfate-reducing bacteria. Applied and Environmental Microbiology, n.º 72, pp. 3733-3737
  • Cappitelli, F., Toniolo, L., Sansonetti, A., Gulotta, D., Ranalli, G., Zanardini, E. y Sorlini, C. (2007a) Advantages of using microbial technology over traditional chemical technology in removal of black crusts from stone surfaces of historical monuments. Applied and Environmental Microbiology, vol. 73, n.º 17, pp. 5671-5675
  • Cappitelli, F., Principi, P., Pedrazzani, R., Toniolo, L. y Sorlini, C. (2007b) Bacterial and fungal deterioration of the Milan Cathedral marble treated with protective synthetic resins. Science of The Total Environment, n.º 385, pp. 172-181
  • Cappitelli, F. y Sorlini, C. (2008) Microorganisms attack synthetic polymers in items representing our cultural heritage. Applied and Environmental Microbiology, vol. 74, n.º 3, pp. 564-569
  • Cappitelli, F., Villa, F. y Sorlini, C. (2009) Biodeterioramento di consolidanti e adesivi naturali e sintetici. En: L’attenzione alle superfici pittoriche: materiali e metodi per il consolidamento e metodi scientifici per valutarne l’efficacia. Padova: Ed. Il Prato, pp. 33-37
  • Cappitelli, F., Villa, F. y Sanmartín, P. (2021) Interactions of microorganisms and synthetic polymers in cultural heritage conservation. International Biodeterioration and Biodegradation, n.º 163105282
  • Cattò, C., Sanmartín, P., Gulotta, D., Troiano, F. y Cappitelli, F. (2021) Bioremoval of graffiti using novel commercial strains of bacteria. Science of The Total Environment, n.º 756, pp. 144075
  • Chiara, A., Musella, R., Tasso, F., Ubaldi, C., Manzo, S., Cremisini, C. y Sprocati, A.R. (2009) Bioremediation of diesel oil in a co-contaminated soil by bioaugmentation with a microbial formula tailored with native strains selected for heavy metals resistance. Science of The Total Environment, vol. 407, n.º 8, pp. 3024-3032. Disponible en: https://doi. org/10.1016/j.scitotenv.2009.01.011 [Consulta: 06/07/2023]
  • Cremonesi, P. (2000) L’uso dei solventi organici nella pulitura di opere policrome. Padova: Il Prato
  • Cremonesi, P. (2002) L’uso degli enzimi nella pulitura di opere policrome. 2ª ed. Padova: Pl Prato
  • Cremonesi, P. y Casoli, A. (2021) Enzymes as tools for conservation of works of art. Journal of Cultural Heritage, vol. 50, pp.73-87. Disponible en: https://doi.org/10.1016/j. culher.2021.06.005 [Consulta: 06/07/2023]
  • Cortea, J.M., Ratoiu, L. y Rădvan, R. (2020) Characterization of spray paints used in street art graffiti by a non-destructive multi-analytical approach. Color Research and Application, vol. 46, n.º 1, pp. 183-194. Disponible en: https://doi.org/10.1002/col.22561 [Consulta: 17/07/2023]
  • Doehne, E. y Price, C.A. (2010) Stone Conservation-An Overview of Current Research. 2.ª ed. Los Angeles, CA, USA: The Getty Conservation Institute
  • Favaro, M., Mendichi, R., Ossola, F., Russo, U., Simon, S., Tomasin, P. y Vigato, P. A. (2006) Evaluation of polymers for conservation treatments of outdoor exposed stone monuments. Part I: Photo-oxidative weathering. Polymer Degradation and Stability, vol. 91, n.º 12, pp. 3083-3096
  • Gauri, K.L., Chowdhury, A.N., Kulshreshtha, N.P. y Punuru, A.R. (1989) The sulfation of marble and the treatment of gypsum crusts. Studies in Conservation, n.º 34, pp. 201-206
  • Gauri, K.L., Parks, L., Jaynes, J. y Atlas, R. (1992) Removal of sulfated-crust from marble using sulfatereducing bacteria. En: Proceedings of the International Conference on Stone Cleaning and the Nature, Soiling and Decay Mechanisms of Stone, Edinburgh, UK, 14-16 April, pp. 160-165. London:Donhead Publishing
  • Geminario, G., Van Der Werf, I.D. y Sabbatini, L. (2016) Chemical characterization of spray paints by a multi-analythical (Py-GC/MS, FTIR, uRaman) approach. Microchemical Journal, n.º 124, pp. 929-939
  • Giacomucci, L., Toja, F., Sanmartín, P., Toniolo, L., Prieto, B., Villa, F. y Cappitelli, F. (2012) Degradation of nitrocellulose-based paint by Desulfovibrio desulfuricans ATCC 13541. Biodegradation, n.º 23, pp. 705-716
  • Gioventù, E., Lorenzi, P.F., Villa, F., Sorlini, C., Rizzi, M., Cagnini, A., Griffo, A. y Cappitelli, F. (2011) Comparing the bioremoval of black crusts on colored artistic lithotypes of the Cathedral of Florence with chemical and laser treatment. Int. Biodeterior. Biodegrad, n.º 65, pp. 832-839
  • Gioventù, E., Ranalli, G. y Vittorini, E. (2020) Il biorestauro. Batteri per la conservazione dell’ opere d’arte. Biopulitura e bioconsolidamento. Florencia: Nardini Editore
  • Giusti, C., Colombini, M. P., Lluveras-Tenorio, A., La Nasa, J., Striova, J. y Salvadori, B. (2020) Graphic vandalism: Multi-analytical evaluation of laser and chemical methods for the removal of spray paints. Journal of Cultural Heritage, n.º 44, pp. 260-274
  • Gu, J.D. (2003) Microbiological deterioration and degradation of synthetic polymeric materials: Recent research advances Int. Biodeterior. Biodegrad, vol. 52, pp. 69-91
  • Heselmeyer, K., Fischer, U., Krumbein, K.E. y Warscheid, T. (1991) Application of Desulfovibrio vulgaris for the bioconversion of rock gypsum crusts into calcite. BIOforum, n.º 1/2, p. 89
  • Izzo, F.C., Vitale, V., Fabbro, C. y Van Keulen, H. (2016) Multi-analytical investigation on felt-tip pen inks: formulation and preliminary photo-degradation study. Microchemical Journal, n.º 124, pp. 919-928
  • Lustrato, G., Alfano, G., Andreotti, A., Colombini, M.P. y Ranalli, G. (2012) Fast biocleaning of mediaeval frescoes using viable bacterial cells. International Biodeterioration and Biodegradation, n.º 69, pp. 51-61
  • Marazioti, V., Douvas, A.M., Katsaros, F., Koralli, P., Chochos, C., Gregoriou, V., Boyatzis, S., y Facorellis, Y. (2023) Chemical characterisation of artists’ spray-paints: A diagnostic tool for urban art conservation. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, vol. 291, pp. 122375. Disponible en: https://doi.org/10.1016/j. saa.2023.122375 [Consulta: 06/07/2023]
  • Mazzoni, M., Alisi, C., Tasso, F., Cecchini, A., Marconi, P. y Sprocati, A.R. (2014) Laponite micro-packs for the selective cleaning of multiple coherent deposits on wall paintings: the case study of Casina Farnese on the Palatine Hill (Rome-Italy). Int. Biodeterior. Biodegrad, n.º 94, pp. 1-11
  • Okunye, O.L., Morakinyo, K.O. y Ayedun, J.S. (2013) Isolation and characterization of fungi associated with incan degradation of paint. Environmental Earth Sciences, vol. 3, n.º 12, pp. 142-145
  • Panella, E., Giovannone, C., Bartolini, M. y Fondi, V. (2019) Biotechnology in the conservation field: removal of sulphates using bacteria and bioconsolidation of paintings and stuccos. Conservation Science in Cultural Heritage, n.º 19, pp. 157-175
  • Pellis, G., Bertasa, M., Ricci, C., Scarcella, A.; Croveri, P., Poli, T. y Scalarone, D. (2022) A multi-analytical approach for precise identification of alkyd spray paints and for a better understanding of their ageing behaviour in graffiti and urban artworks. Journal of Analytical and Applied Pyrolysis, vol. 165, pp. 105576. Disponible en: https://doi.org/10.1016/j. jaap.2022.105576 [Consulta: 06/07/2023]
  • Pereira-Pardo, L. y Korenberg, C. (2018)The use of erbium lasers for the conservation of cultural heritage. A review. Journal of Cultural Heritage, n.º 31, pp. 236-247. Disponible en: https://www.sciencedirect.com/science/ article/pii/S129620741730287X [Consulta: 04/07/2023]
  • Pereira-Pardo, L., Melita, L.N. y Korenberg, C. (2020) Tackling conservation challenges using erbium lasers: case studies at the British Museum. Journal of the Institute of Conservation, vol. 43, n.º 1, pp. 25-43. Disponible en: https://doi.org/10.1080/19455224.2019.1706591 [Consulta: 04/07/2023]
  • Polo, A., Cappitelli, F., Brusetti, L., Principi, P., Villa, F., Giacomucci, L., Ranalli, G. y Sorlini, C. (2010) Feasibility of removing surface deposits on stone using biological and chemical remediation methods. Microbial Ecology, n.º 60, pp. 1-14
  • Pozo-Antonio, S., Rivas, T., Fiorucci, M.P., López, A.J. y Ramil, A. (2016) Effectiveness and harmfulness evaluation of graffiti cleaning by mechanical, chemical and laser procedures on granite. Microchemical Journal, vol. 125, pp. 1-9. Disponible en: https://www.sciencedirect.com/science/ article/pii/S0026265X15002714 [Consulta: 04/07/2023]
  • Pozo-Antonio, S., Rivas, T., González, N. y Alonso-Villar, E.M. (2022) Deterioration of graffiti spray paints applied on granite after a decade of natural environment. Science of The Total Environment, vol. 826, pp. 154169. Disponible en: https://www.sciencedirect.com/science/article/pii/ S004896972201261X [Consulta: 4/7/2023]
  • Ramírez, J.L., Santana, M.A., Galindo-Castro, I. y González, A. (2005) The role of biotechnology in art preservation. Trends in Biotechnology, n.º 23, pp.584-588
  • Ranalli, G., Chiavarini, M., Guidetti, V., Marsala, F., Matteini, M., Zanardini, E. y Sorlini, C. (1996) The use of microorganisms for the removal of nitrates and organic substances on artistic stoneworks. En: Proceedings of the 8th Int. Congress on Deterioration and Conservation of Stone, Berlin, Alemania, 30 Septiembre-4 Octubre 1996
  • Ranalli, G., Chiavarini, M., Guidetti, V., Marsala, F., Matteini, M., Zanardini, E. y Sorlini, C. (1997) The use of microorganisms for the removal of sulphates on artistic stoneworks. International Biodeterioration and Biodegradation, n.º 40, pp. 255-261
  • Ranalli, G., Alfano, G., Belli, C., Lustrato, G., Colombini, M.P., Bonaduce, I., Zanardini, E., Abbruscato, P. et ál. (2004) Biotechnology applied to cultural heritage: biorestoration of frescoes using viable bacterial cells and enzymes. Journal of Applied Microbiology, vol. 98, n.º 1, pp. 73-83
  • Ranalli, G., Alfano, G., Belli, C., Lustrato, G., Colombini, M.P., Bonaduce, I., Zanardini, E., Abbruscato, P., Cappitelli, F. y Sorlini, C. (2005) Biotechnology applied to cultural heritage: biorestoration of frescoes using viable bacterial cells and enzymes. Journal of Applied Microbiology, vol. 98, n.º 1, pp. 73-83
  • Ranalli, G., Zanardini, E., Andreotti, A., Colombini, M.P., Corti, C., Bosch-Roig, P., De Nuntiis, P., Lustrato, G., Mandrioli, P., Rampazzi, L., Giantomassi, C. y Zari, D. (2018) Hi-tech restoration by two-steps biocleaning process of triumph of death fresco at the Camposanto Monumental Cemetery (Pisa, Italy). Journal of Applied Microbiology, vol. 125, n.º 3, pp. 800-812
  • Ranalli, G., Zanardini, E., Rampazzi, L., Corti, C., Andreotti, A., Colombini, M.P., Bosch-Roig, P., Lustrato, G., Giantomassi, C., Zari, D. y Virilli, P. (2019) Onsite advanced biocleaning system for historical wall paintings using new agar-gauze bacteria gel. Journal of Applied Microbiology, vol. 126, n.º 6, pp. 1785-1796
  • Ranalli, G. y Zanardini, E. (2021) Biocleaning on Cultural Heritage: new frontiers of microbial biotechnologies. Journal of Applied Microbiology, vol. 131, n.º 2, pp. 583-603
  • Saiz-Mauleón, M.B., Bosch-Roig, P. y Montes-Estellés, M.R. (2017). Tecnologías especiales de limpieza láser y biolimpieza. En: Intervención Arquitectónica y Pictórico Ornamental en la Iglesia Parroquial de San Nicolás Obispo y San Pedro Mártir de Valencia. Valencia: Parroquia de San Nicolás, pp. 139-14
  • Sanmartín, P., DeAraujo, A., Vasanthakumar, A. y Mitchell, R. (2015) Feasibility study involving the search for natural strains of microorganisms capable of degrading graffiti from heritage materials. International Biodeterioration and Biodegradation, n.º 103, pp. 186-190
  • Sanmartín, P. y Bosch-Roig, P. (2019) Biocleaning to Remove Graffiti: A Real Possibility? Advances towards a Complete Protocol of Action. Coatings, 9(2), p. 104. Disponible en: https://doi.org/10.3390/coatings9020104 [Consulta: 04/07/2023]
  • Sanmartín, P., Bosch-Roig, P., Gulotta, D., Fort, R., Bosch, I. y Cappitelli, F. (2021) Klebsiella aerogenes and Comamonas testosteroni as bioremoval agents on graffiticoated concrete and granite: Impact assessment through surface analysis. International Biodeterioration and Biodegradation, vol. 161, 105244. Disponible en: https:// doi.org/10.1016/j.ibiod.2021.105244 [Consulta: 24/07/2023]
  • Sánchez-Pons, M. (2016) Acercamiento a la evolución histórica y tecnológica de los materiales pictóricos empleados en el grafiti y arte urbano. Ge-Conservacion, n.º 10, pp. 146-159. Disponible en: https://doi.org/10.37558/ gec.v10i0.408 [Consulta: 04/07/2023]
  • Snethlage, R. y Sterflinger, K. (2010) Stone conservation. En: Stone in architecture: properties, durability. Berlin, Heidelberg: Springer Berlin Heidelberg, pp. 411-544
  • Stulik, D., Miller, D., Khanjian, H., Khandekar, N., Wolbers, R., Carlson, J. y Petersen, C. (2004) Solvent gels for the cleaning of works of art: the residue question. Getty Publications
  • Troiano, F., Gulotta, D., Balloi, A., Polo, A., Toniolo, L., Lombardi, E., Daffonchio, D., Sorlini, C. y Cappitelli, F. (2013) Successful combination of chemical and biological treatments for the cleaning of stone artworks. International Biodeterioration and Biodegradation, n.º 85, pp. 294-304
  • Troiano, F., Vicini, S., Gioventù, E., Lorenzi, P.F., Improta, C. M. y Cappitelli, F. (2014) A methodology to select bacteria able to remove synthetic polymers. Polymer Degradation and Stability, vol. 107, pp. 321-327. Disponible en: https:// doi.org/10.1016/j.polymdegradstab.2013.12.029 [Consulta: 04/07/2023]
  • Upadhyay, H, Chhabra, V. y Singh, J. (2020) Role of Bacterial Communities to Prevent the Microbial Growth on Cultural Heritage. En: Yadav A., Rastegari A., Gupta V. Yadav N. (ed.) Microbial Biotechnology Approaches to Monuments of Cultural Heritage. Singapore: Springer
  • Varas-Muriel, M.J., Pérez-Monserrat, E.M., VázquezCalvo, C. y Fort, R. (2015) Effect of conservation treatments on heritage stone. Characterisation of decay processes in a case study. Construction and Building Materials, n.º 95, pp. 611-622
  • Villarquide, A. (2005) La pintura sobre tela II: alteraciones, materiales y tratamientos de restauración. San Sebastián: Ed. Nerea
  • Webster, A. y May, E. (2006) Bioremediation of weathered-building stone surface. Trends in Biotechnology, n.º 24, pp. 25-260
  • Weyer, A., Roig Picazo, P., Pop, D., Cassar, J., Özköse, A., Vallet, J.M. y Srša, I. (ed.) (2015) EwaGlos-European Illustrated Glossary of Conservation Terms for Wall Paintings and Architectural Surfaces. HAWK Hildesheim/Holzminden/ Göttinge. Disponible en: https://www.hornema ectural Surfaces. HAWK Hildesheim/Holzminden/ Göttinge. Disponible en: https://www.hornemann-institut. de/doi/234.php [Consulta: 24/07/2023
Fonte de datos: Dialnet