Influence of nickel on butanol production by Clostridium beijerinckii using hydrolyzate from green coconut shell

Petrúcia Karine Santos de Brito Bezerra; Beatriz Meneghetti Costa de Araújo; Otávio Lima da Silva; Beatriz de Azevedo; Stephanie Caroline Bivar Matias; Everaldo Silvino dos Santos

doi:10.13083/reveng.v29i1.12620

Autores

Petrúcia Karine Santos de Brito Bezerra Federal University of Rio Grande do Norte https://orcid.org/0000-0002-3939-5682
Beatriz Meneghetti Costa de Araújo Federal University of Rio Grande do Norte https://orcid.org/0000-0003-2130-0646
Otávio Lima da Silva Federal University of Rio Grande do Norte https://orcid.org/0000-0002-6937-6159
Beatriz de Azevedo Federal University of Rio Grande do Norte https://orcid.org/0000-0002-6517-1762
Stephanie Caroline Bivar Matias Federal University of Rio Grande do Norte https://orcid.org/0000-0002-6517-1762
Everaldo Silvino dos Santos Federal University of Rio Grande do Norte https://orcid.org/0000-0001-7384-1140

DOI:

https://doi.org/10.13083/reveng.v29i1.12620

Palavras-chave:

Agro-industrial wastes, Hydrolysis, Ni catalyst, ABE fermentation

Resumo

The improvement of biotechnological processes capable of transforming agro-industrial waste into products with high added value has stood out in the area of renewable energies, promoting positive impacts to the environment. Thus, the present work evaluated the influence of nickel on the conversion of fermentable sugars, present in the green coconut shell hydrolyzate (GCSH), into butanol and other products. Fermentation assays were performed at 37 °C, starting with 19.4 g.L^-1 of sugars and 1.0 g.L^-1 of inoculum (C. beijerinckii). The GCSH was supplemented with tryptone, yeast extract, ammonium acetate, minerals and phosphate buffer. Two conditions were tested: with and without addition of nickel. Concentrations of sugars (glucose and xylose), intermediate products (organic acids), acetone, butanol, and ethanol were determined by high performance liquid chromatography (HPLC). The results show that the butanol production was higher from GCSH without addition of nickel, reaching a concentration of 2.14 g.L^-1 of butanol. Therefore, the presence of nickel in the hydrolyzate was not favorable in the production of butanol under the studied process conditions.

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AMIRI, H.; KARIMI, K. Pretreatment and hydrolysis of lignocellulosic wastes for butanol production: Challenges and perspectives. Bioresource Technology, v. 270, p. 702-721, 2018.

BURHANI, D.; TRIWAHYUNI, E.; SETIAWAN, R. Second-Generation Biobutanol: An Update. Reaktor, v. 19, n. 3, p. 101-110, 2019.

EITINGER, T.; MANDRAND-BERTHELOT, M-A. Nickel transport systems in microorganisms – Mini Review. Archives of Microbiology, v. 173, p. 1-9, 2000.

FAOSTAT - Food and Agriculture Organization of the United Nations. World Production. 2019. Available in: <http://faostat.fao.org/site/342/default.aspx> Access on 24 fev. 2021.

GHOSE, T. K. Measurement of cellulose activities. Pure Applied Chemistry, v. 59, n. 2, p. 257-268, 1987.

KETABCHI, E.; PASTOR-PÉREZ, L.; REINA, T. R.; ARELLANO-GARCÍA, H. Catalytic upgrading of acetone, butanol and ethanol (ABE): A step ahead for the production of added value chemicals in bio-refineries. Renewable Energy, v. 156, p. 1065-1075, 2020a.

KETABCHI, E.; PASTOR-PÉREZ, L.; ARELLANO-GARCIA, H.; REINA, T.R. Influence of Reaction Parameters on the Catalytic Upgrading of an Acetone, Butanol, and Ethanol (ABE) Mixture: Exploring New Routes for Modern Biorefineries. Frontiers in Chemistry, v.7, p. 906, 2020b.

LI, Y.; ZHANG, Z.; LEI, Z.; YANG, Y., UTSUMI, M., SUGIURA, N. Influence of metal addition on ethanol production with Pichia stipitis ATCC 58784. Journal of Industrial Microbiology and Biotechnology, v. 36, n. 4, p. 491-497, 2009.

MAGALHÃES, B.L. Otimização da produção de butanol por cepas de Clostridium spp. utilizando hidrolisado lignocelulósico. 2015. 111f. Dissertação de mestrado, Universidade Estadual de Campinas, Campinas, SP, 2015.

MAGALHÃES, B. L.; GRASSI, M. C. B.; PEREIRA, G. A.; BROCCHI, M. Improved n-butanol production from lignocellulosic hydrolysate by Clostridium strain screening and culture-medium optimization. Biomass and Bioenergy, v. 108, p. 157-166, 2018.

NOGUEIRA, C.C.; PADILHA, C.E.A.; LEITÃO, A.; ROCHA, L.S.; MACEDO, P.M.; MACEDO, G. R.; SANTOS, E. S. Enhancing enzymatic hydrolysis of green coconut fiber – Pretreatment assisted by tween 80 and water effect on the post-washing. Industrial Crops and Products, v. 112, p. 734-740, 2018.

NOGUEIRA, C.C.; PADILHA, C.E.A.; JESUS, A.A. SOUZA, D.F.S.; ASSIS, C.F.; SOUZA JUNIOR, F.C.; SANTOS, E. S. Pressurized pretreatment and simultaneous saccharification and fermentation with in situ detoxification to increase bioethanol production from green coconut fibers. Industrial Crops and Products, v. 130, p. 259-266, 2019.

QURESHI, N.; BLASCHEK, H. Butanol recovery from model solution/fermentation broth by pervaporation: evaluation of membrane performance. Biomass and Bioenergy, v. 17, n. 2, p. 175-184, 1999.

OLIVEIRA, S.D., PADILHA, C.E.A., ASEVEDO, E.A., PIMENTEL, V.C., ARAÚJO, F.R., MACEDO, G.R., SANTOS, E.S. Utilization of agroindustrial residues for producing cellulases by Aspergillus fumigatus on Semi-Solid Fermentation. Journal of Environmental Chemical Engineering, 6(1), p. 937-944, 2018.

PADILHA, C.E.A; NOGUEIRA, C.C.; SOUZA, D.F.S.; OLIVEIRA, J. A.; SANTOS, E. S. Valorization of green coconut fibre: Use of the black liquor of organolsolv pretreatment for ethanol production and the washing water for production of rhamnolipids by Pseudomonas aeruginosa ATCC 27583. Industrial Crops and Products, v. 140, p. 111604, 2019.

SÁ, L. R. V.; CAMMAROTA, M. C.; FERREIRA-LEITÃO, V.S. Produção de hidrogênio via fermentação anaeróbia – aspectos gerais e possibilidade de utilização de resíduos agroindustriais brasileiros. Química Nova, v. 37, n. 5, p. 857-867, 2014.

SOARES, J.; DEMEKE, M. M.; VAN DE VELDE, M.; FOULQUIÉ-MORENO, M. R.; KERSTENS, D.; SELS, B. F.; VERPLAETSE, A.; FERNANDES, A.A.R.; THEVELEIN, J.M.; FERNANDES, P. M. B. Fed-batch production of green coconut hydrolysates for high-gravity second-generation bioethanol fermentation with cellulosic yeast. Bioresource technology, 244, p. 234-242, 2017.

TRAN, P. D.; BARBER, J. Proton reduction to hydrogen in biological and chemical systems. Physical Chemistry Chemical Physics, 14(40), p. 13772-13784, 2012

TRCHOUNIAN, K.; MÜLLER, N.; SCHINK, B.; TRCHOUNIAN, A. Glycerol and mixture of carbon sources conversion to hydrogen by Clostridium beijerinckii DSM791 and effects of various heavy metals on hydrogenase activity. International Journal of Hydrogen Energy, 42(12), p. 7875-7882, 2017.

ZETTY-ARENAS, A. M.; ALVES, R. F.; PORTELA, C. A. F.; MARIANO, A. P.; BASSO, T. O.; TOVAR, L. P.; MACIEL FILHO, R.; FREITAS, S. Towards enhanced n-butanol production from sugarcane bagasse hemicellulosic hydrolysate: Strain screening, and the effects of sugar concentration and butanol tolerance. Biomass and Bioenergy, v. 126, p. 190-198, 2019.

ZHEN, X.; WANG, Y.; LIU, D. Bio-butanol as a new generation of clean alternative fuel for SI (spark ignition) and CI (compression ignition) engines. Renewable Energy, v. 147, p. 2494-2521, 2020.

Influence of nickel on butanol production by Clostridium beijerinckii using hydrolyzate from green coconut shell

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