C3–C4 Platform Chemicals Bioproduction Using Biomass
作者: Emna Chaabouni , Saurabh Jyoti Sarma , Fatma Gassara , Satinder Kaur Brar
DOI: 10.1007/978-1-4614-8005-1_19
关键词:
摘要: Platform chemicals composed of 3–4 carbons are group that can be used as important precursors for making a variety and materials, including solvents, fuels, polymers, pharmaceuticals, perfumes, foods. At present, most the commercial platform produced from petroleum-based products. However, fossil-derived resources nonrenewable their amount is increasingly depleting. Additionally, application these materials has number environmental concerns. To overcome problems, increasing interest focused on development sustainable technologies producing renewable resources. Researchers have made significant progress in biological production using metabolic engineering-modified microorganisms. efficiency still needs to improved it become economically viable. Further work engineering strains exploring tolerances use low-cost substrate like biomass may increase yields green an industrial scale. In this review we current status bio-based major C3–C4 chemicals, by direct microbial bioconversion materials.
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sci-hub.st 参考文章(72)
John H. Litchfield, Microbiological production of lactic acid. Advances in Applied Microbiology. ,vol. 42, pp. 45- 95 ,(1996) , 10.1016/S0065-2164(08)70372-1
E I Garvie, Bacterial lactate dehydrogenases. Microbiological Research. ,vol. 44, pp. 106- 139 ,(1980) , 10.1128/MR.44.1.106-139.1980
D T Jones, D R Woods, Acetone-butanol fermentation revisited. Microbiological Research. ,vol. 50, pp. 484- 524 ,(1986) , 10.1128/MR.50.4.484-524.1986
Michiel Dusselier, Pieter Van Wouwe, Annelies Dewaele, Ekaterina Makshina, Bert F. Sels, Lactic acid as a platform chemical in the biobased economy: the role of chemocatalysis Energy and Environmental Science. ,vol. 6, pp. 1415- 1442 ,(2013) , 10.1039/C3EE00069A
Rathin Datta, Shih-Perng Tsai, Patrick Bonsignore, Seung-Hyeon Moon, James R. Frank, Technological and economic potential of poly(lactic acid) and lactic acid derivatives Fems Microbiology Reviews. ,vol. 16, pp. 221- 231 ,(1995) , 10.1111/J.1574-6976.1995.TB00168.X
Shota Atsumi, Anthony F. Cann, Michael R. Connor, Claire R. Shen, Kevin M. Smith, Mark P. Brynildsen, Katherine J.Y. Chou, Taizo Hanai, James C. Liao, Metabolic engineering of Escherichia coli for 1-butanol production. Metabolic Engineering. ,vol. 10, pp. 305- 311 ,(2008) , 10.1016/J.YMBEN.2007.08.003
Yongming Zhu, Y. Y. Lee, Richard T. Elander, Conversion of aqueous ammonia-treated corn stover to lactic acid by simultaneous saccharification and cofermentation. Applied Biochemistry and Biotechnology. ,vol. 137, pp. 721- 738 ,(2007) , 10.1007/S12010-007-9092-9
Rajni Hatti-Kaul, Ulrika Törnvall, Linda Gustafsson, Pål Börjesson, Industrial biotechnology for the production of bio-based chemicals – a cradle-to-grave perspective Trends in Biotechnology. ,vol. 25, pp. 119- 124 ,(2007) , 10.1016/J.TIBTECH.2007.01.001
Gernot Jäger, Jochen Büchs, Biocatalytic conversion of lignocellulose to platform chemicals. Biotechnology Journal. ,vol. 7, pp. 1122- 1136 ,(2012) , 10.1002/BIOT.201200033
Victor M. Ye, Sujata K. Bhatia, Metabolic engineering for the production of clinically important molecules: Omega‐3 fatty acids, artemisinin, and taxol Biotechnology Journal. ,vol. 7, pp. 20- 33 ,(2012) , 10.1002/BIOT.201100289