Integrated chemo and bio-catalyzed synthesis of 2,5-furandicarboxylic acid from fructose derived 5-hydroxymethylfurfural

被引:9
作者
Parate, Roopa D. [1 ,2 ]
Dharne, Mahesh S. [2 ,3 ]
Rode, Chandrashekhar, V [1 ,2 ]
机构
[1] Natl Chem Lab, Chem Engn & Proc Dev Div, CSIR, Pune 411008, Maharashtra, India
[2] Acad Sci & Innovat Res AcSIR, Ghaziabad 201002, India
[3] Natl Chem Lab, Natl Collect Ind Microorganisms, Biochem Sci Div, CSIR, Pune 411008, Maharashtra, India
关键词
Biomass; Platform chemical; Biocatalysis; Biodegradable polyester; Sustainability metrics; 5-HYDROXYMETHYL-2-FURANCARBOXYLIC ACID; BIOCATALYTIC PRODUCTION; KLEBSIELLA-PNEUMONIAE; GREEN CHEMISTRY; 2-FUROIC ACID; OXIDATION; BIOMASS; BIOTRANSFORMATION; CONVERSION; CARBON;
D O I
10.1016/j.biombioe.2022.106474
中图分类号
S2 [农业工程];
学科分类号
0828 ;
摘要
Biomass being a renewable source of energy, has emerged as an attractive target for manufacturing valuable products. These possibilities can be explored to meet the current need for degradable plastic, 2,5-furandicarboxylic acid (FDCA). Integration of chemical and biological approaches for direct biomass conversion into FDCA was evaluated in this study. 5-hydroxymethylfurfural (5-HMF) was chemo-catalytically obtained from fructose using recyclable amberlyte IR-120 as a catalyst with >98% purity. Klebsiella oxytoca NCIM 2694 bacterial strain showed the potential of converting 98% of 5-HMF into FDCA with 58% selectivity at 96 h. With optimized conditions of pH 7, 37 degrees C, 2 g whole cells, we reported 99% 5-HMF conversion to FDCA with 95% selectivity at 72 h and 2667 mg L-1 yield, with 39 mg L-1 h-1 productivity. This is the highest yield obtained with the substrate concentration as high as 3000 mg L-1 reported till date. While the bacterial tolerance to 5-HMF observed was for the highest 5-HMF concentration of 4000 mg L-1, with 99% conversion however, compromising the FDCA yield to 2447 mg L-1 and 32 mg L-1 h-1 productivity. Atom economy of 85% and E factor of 17.71 g g-1 was obtained as a measure of its efficiency and sustainability of the process. The developed process will decrease the cost by excluding any extra nutrient supplement, complete substrate utilization, highest FDCA selectivity/productivity and higher tolerance by K. oxytoca, sequentially catalyzing the oxidations by a single route for FDCA synthesis from renewables.
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页数:10
相关论文
共 74 条
[1]   Metabolic effects of furaldehydes and impacts on biotechnological processes [J].
Almeida, Joao R. M. ;
Bertilsson, Magnus ;
Gorwa-Grauslund, Marie F. ;
Gorsich, Steven ;
Liden, Gunnar .
APPLIED MICROBIOLOGY AND BIOTECHNOLOGY, 2009, 82 (04) :625-638
[2]  
Anastas P., 1998, GREEN CHEM THEORY PR
[3]   Static microplate fermentation and automated growth analysis approaches identified a highly-aldehyde resistant Saccharomyces cerevisiae strain [J].
Bezerra de Mello, Fellipe da Silveira ;
Venega Coradini, Alessandro Luis ;
Galvao Tizei, Pedro Augusto ;
Carazzolle, Marcelo Falsarella ;
Guimaraes Pereira, Goncalo Amarante ;
Teixeira, Gleidson Silva .
BIOMASS & BIOENERGY, 2019, 120 :49-58
[4]   Catalytic hydrodeoxygenation of biomass-derived pyrolysis oil over alloyed bimetallic Ni3Fe nanocatalyst for high-grade biofuel production [J].
Bharath, G. ;
Rambabu, K. ;
Hai, Abdul ;
Banat, Fawzi ;
Taher, Hanifa ;
Schmidt, Jens Ejbye ;
Show, Pau Loke .
ENERGY CONVERSION AND MANAGEMENT, 2020, 213
[5]   Systematic production and characterization of pyrolysis-oil from date tree wastes for bio-fuel applications [J].
Bharath, G. ;
Hai, Abdul ;
Rambabu, K. ;
Banat, Fawzi ;
Jayaraman, Raja ;
Taher, Hanifa ;
Bastidas-Oyanedel, Juan-Rodrigo ;
Ashraf, Muhammad Tahir ;
Schmidt, Jens Ejbye .
BIOMASS & BIOENERGY, 2020, 135
[6]   Highly selective etherification of fructose and 5-hydroxymethylfurfural over a novel Pd-Ru/MXene catalyst for sustainable liquid fuel production [J].
Bharath, Govindan ;
Rambabu, Krishnamoorthy ;
Hai, Abdul ;
Morajkar, Pranay P. ;
Salkar, Akshay, V ;
Hasan, Shadi W. ;
Show, Pau Loke ;
Banat, Fawzi .
INTERNATIONAL JOURNAL OF ENERGY RESEARCH, 2021, 45 (10) :14680-14691
[7]   Process integration for the conversion of glucose to 2,5-furandicarboxylic acid [J].
Boisen, A. ;
Christensen, T. B. ;
Fu, W. ;
Gorbanev, Y. Y. ;
Hansen, T. S. ;
Jensen, J. S. ;
Klitgaard, S. K. ;
Pedersen, S. ;
Riisager, A. ;
Stahlberg, T. ;
Woodley, J. M. .
CHEMICAL ENGINEERING RESEARCH & DESIGN, 2009, 87 (9A) :1318-1327
[8]   BIOTRANSFORMATION OF FURFURAL AND 5-HYDROXYMETHYL FURFURAL BY ENTERIC BACTERIA [J].
BOOPATHY, R ;
BOKANG, H ;
DANIELS, L .
JOURNAL OF INDUSTRIAL MICROBIOLOGY, 1993, 11 (03) :147-150
[9]   Enzymatic conversion reactions of 5-hydroxymethylfurfural (HMF) to bio-based 2,5-diformylfuran (DFF) and 2,5-furandicarboxylic acid (FDCA) with air: mechanisms, pathways and synthesis selectivity [J].
Cajnko, Misa Mojca ;
Novak, Uros ;
Grilc, Miha ;
Likozar, Blaz .
BIOTECHNOLOGY FOR BIOFUELS, 2020, 13 (01)
[10]   A two-step approach for the catalytic conversion of glucose to 2,5-dimethylfuran in ionic liquids [J].
Chidambaram, Mandan ;
Bell, Alexis T. .
GREEN CHEMISTRY, 2010, 12 (07) :1253-1262