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Clean Technologies and Environmental Policy

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04.07.2018 | Original Paper

An overview of biorefinery-derived platform chemicals from a cellulose and hemicellulose biorefinery

verfasst von: Sudhakar Takkellapati, Tao Li, Michael A. Gonzalez

Erschienen in: Clean Technologies and Environmental Policy | Ausgabe 7/2018

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Abstract

Until recently, most of energy and industrially produced chemicals were derived from fossil fuel-based resources. This along with the continued depletion of finite fossil resources and their attributed adverse environmental impacts, alternatively sourced and more sustainable resources are being pursued as feedstock replacements. Thus, biomass has been identified as an alternate renewable and more sustainable resource as a means to reduce this sector’s dependence on fossil fuel-based resources and to alleviate their environmental impacts. As such, lignocellulosic biomass has been further identified and demonstrated as an abundant renewable resource for the production of biofuels, platform chemicals, and their respective value-added products. This review article provides an overview of the techniques developed for the valorization of biomass in the production of platform chemicals within a biorefinery and the status for commercialization.

Vorheriger Artikel Analysis of bioenergy production at different levels of integration in energy-driven biorefineries

Nächster Artikel Multiplicities in dividing wall distillation columns in the purification of bioethanol: energy considerations

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Abad S, Turon X (2012) Valorization of biodiesel derived glycerol as a carbon source to obtain added-value metabolites: focus on polyunsaturated fatty acids. Biotechnol Adv 30:733–741CrossRef

Abubackar HN, Veiga MC, Kennes C (2011) Biological conversion of carbon monoxide: rich syngas or waste gases to bioethanol. Biofuels Bioprod Bioref 5:93–114CrossRef

Adkins J, Pugh S, McKenna R, Nielsen DR (2012) Engineering microbial chemical factories to produce renewable “biomonomers”. Front Microbiol 3:313CrossRef

Agbor VB, Cicek N, Sparling R, Berlin A, Levin DB (2011) Biomass pretreatment: fundamentals toward application. Biotechnol Adv 29:675–685CrossRef

Almeida JRM, Favaro LCL, Quirino BF (2012) Biodiesel biorefinery: opportunities and challenges for microbial production of fuels and chemicals from glycerol waste. Biotechnol Biofuels 5:48CrossRef

Alonso DM, Bond JQ, Dumesic JA (2010) Catalytic conversion of biomass to biofuels. Green Chem 12:1493–1513CrossRef

Altaras NE, Cameron DC (1999) Metabolic engineering of a 1,2-propanediol pathway in Escherichia coli. Appl Environ Microbiol 65:1180–1185

Amyris. https://amyris.com/products/isoprene/. Accessed 22 June 2017

Arena U (2012) Process and technological aspects of municipal solid waste gasification. Rev Waste Manag 32:625–639CrossRef

Avantium (2016) Press release. https://www.avantium.com/press-releases/synvina-joint-venture-basf-avantium-established/

Avantium. https://www.avantium.com/yxy/products-applications/. Accessed 22 June 2017

Bai R, Zhang H, Mei F, Wang S, Li T, Gu Y, Li G (2013) One-pot synthesis of glycidol from glycerol and dimethyl carbonate over a highly efficient and easily available solid catalyst NaAlO₂. Green Chem 15:2929–2934CrossRef

Banu M, Venuvanalingam P, Shanmugam R, Viswanathan B, Sivasanker S (2012) Sorbitol hydrogenolysis over Ni, Pt and Ru supported on NaY. Top Catal 55:897–907CrossRef

Barbosa BM, Colodette JL, Longue D Jr, Gomes FJB, Martino DC (2014) Preliminary studies on furfural production from lignocellulosics. J Wood Chem Technol 34:178–190CrossRef

Behr A, Eilting J, Irawadi K, Leschinski J, Lindner F (2008) Improved utilisation of renewable resources: new important derivatives of glycerol. Green Chem 10:13–30CrossRef

Bell BM, Briggs JR, Campbell RM, Chambers SM, Gaarenstroom PD, Hippler JG, Hook BD, Kearns H, Kenney JM, Kruper WJ, Schreck DJ, Theriault CN, Wolfe CP (2008) Glycerin as a renewable feedstock for epichlorohydrin production. The GTE process. Clean 36:657–661

BIO (2016). Advancing the biobased economy: renewable chemical biorefinery commercialization, progress and market opportunities and beyond. https://www.bio.org/advancing-biobased-economy-renewable-chemical-biorefinery-commercialization-progress-and-market. Accessed 22 June 2017

Bioamber (2015) Press release. https://www.bio-amber.com/bioamber/en/news/2015/bioamber-now-shipping-bio-succinic-acid-to-customers

Bozell JJ, Petersen GR (2010) Technology development for the production of biobased products from biorefinery carbohydrates-the US Department of Energy’s “Top 10” revisited. Green Chem 12:539–554CrossRef

Brethauer S, Studer MH (2015) Biochemical conversion processes of lignocellulosic biomass to fuels and chemicals—a review. Chimia 69:572–581CrossRef

Cargill (2006). http://www.foodingredientsfirst.com/news/Cargill-to-Commercialize-Renewable-Propylene-Glycol-from-Glycerin.html/ Accessed 30 June 2017

Chatterjee C, Pong F, Sen A (2015) Chemical conversion pathways for carbohydrates. Green Chem 17:40–71CrossRef

Chen X, Jiang Z, Chen S, Qin W (2010) Microbial and bioconversion production of d-xylitol and its detection and application. Int J Biol Sci 6:834–844CrossRef

Chen J, Wang S, Huang J, Chen L, Ma L, Huang X (2013) Conversion of cellulose and cellobiose into sorbitol catalyzed by ruthenium supported on a polyoxometalate/metal–organic framework hybrid. Chemsuschem 6:1545–1555CrossRef

Cherubini F, Jungmeier G, Wellisch M, Willke T, Skiadas I, Van Ree R, de Jong E (2009) Toward a common classification approach for biorefinery systems. Biofuels Bioprod Bioref 3:534–546CrossRef

Chiu CW, Dasari MA, Suppes GJ, Sutterlin WR (2006) Dehydration of glycerol to acetol via catalytic reactive distillation. AIChE J 52:3543–3548CrossRef

Ciriminna R, Pagliaro M (2003) One-pot homogeneous and heterogeneous oxidation of glycerol to ketomalonic acid mediated by TEMPO. Adv Synth Catal 345:383–388CrossRef

Clark JH, Deswarte FEI (2008) The biorefinery concept–an integrated approach. In: Clark JH, Deswarte FEI (eds) Introduction to chemicals from biomass. Wiley, Chichester, pp 1–20. https://doi.org/10.1002/9780470697474 CrossRef

Clomburg JM, Gonzalez R (2013) Anaerobic fermentation of glycerol: a platform for renewable fuels and chemicals. Trends Biotechnol 31:20–28CrossRef

Corbion. http://www.corbion.com/biochemicals/pharma/brands/purac. Accessed 22 June 2017

Corma A, Iborra S, Velty A (2007) Chemical routes for the transformation of biomass into chemicals. Chem Rev 107:2411–2502CrossRef

Craciun L, Benn GP, Dewing J, Schriver GW (2009), US Pat, 7,538,247

Dasari MA, Kiatsimkul PP, Sutterlin WR, Suppes GJ (2005) Low-pressure hydrogenolysis of glycerol to propylene glycol. Appl Catal A 281:225–231CrossRef

Datta R, Henry M (2006) Lactic acid: recent advances in products, processes and technologies-a review. J Chem Technol Biotechnol 81:1119–1129CrossRef

de Jong E, Jungmeier G (2015) Biorefinery concepts in comparison to petrochemical refineries. In: Pandey A, Hofer R, Taherzadeh M, Nampoothiri M, Larroche C (eds) Industrial biorefineries and white biotechnology, 1st edn. Elsevier, Amsterdam

de Jong E, Higson A, Walsh P, Wellissch M (2013) Bio-based chemicals, value added products from biorefineries. In: IEA Bioenergy Task 42 report 2012. www.ieabioenergy.com/wp-content/uploads/2013/10/Task-42-Biobased-Chemicals-value-added-products-from-biorefineries.pdf. Accessed 12 March 2018

Delhomme C, Weuster-Botz D, Kuhn FE (2009) Succinic acid from renewable resources as a C₄ building-block chemical—a review of the catalytic possibilities in aqueous media. Green Chem 11:13–26CrossRef

Demirbas A (2011) Competitive liquid biofuels from biomass. Appl Energy 88:17–28CrossRef

Direvo press release. http://www.direvo.com/uploads/media/DIREVO-PressRelease_No6_2013.pdf Accessed 22 June 2017

Dietrich K, Hernandez-Mejia C, Verschuren P, Rothenberg G, Shiju NR (2017) One-pot selective conversion of hemicellulose to xylitol. Org Process Res Dev 21:165–170CrossRef

Dow press release (2007). http://www.dow.com/propyleneglycol/news/20070315b.htm. Accessed 30 June 2017

DuPont press release (2016). http://www.dupont.com/products-and-services/industrial-biotechnology/press-releases/dupont-adm-announce-platform-technology-for-long-sought-after-molecule.html. Accessed 22 June 2017

DuPont. http://biosciences.dupont.com/about-us/collaborations/goodyear/. Accessed 22 June 2017

Dutta S, De S, Saha B (2012a) A brief summary of the synthesis of polyester building-block chemicals and Biofuels from 5-hydroxymethylfurfural. ChemPlusChem 77:259–272CrossRef

Dutta S, De S, Saha B, Alam MdI (2012b) Advances in conversion of hemicellulosic biomass to furfural and upgrading to biofuels. Catal Sci Technol 2:2025–2036CrossRef

Erickson B, Nelson JE, Winters P (2012) Perspective on opportunities in industrial biotechnology in renewable chemicals. Biotechnol J 7:176–185CrossRef

Esposito D, Antonietti M (2015) Redefining biorefinery: the search for unconventional building blocks for materials. Chem Soc Rev 44:5821–5835CrossRef

Fernando S, Adhikari S, Chandrapal C, Murali N (2006) Biorefineries: current status, challenges and future direction. Energy Fuels 20:1727–1737CrossRef

Genencor. http://www.genencor.com/uploads/tx_tcdaniscofiles/GENC-10053_BioIsoprene_Backgrounder_prt.pdf. Accessed 22 June 2017

GF Biochemicals press release (2015) http://www.gfbiochemicals.com/news/2015/07/gfbiochemicals-announces-production-start-up/. Accessed 22 June 2017

Ghaffar T, Irshad M, Anwar Z, Aqil T, Zulifqar Z, Tariq A, Kamran M, Ehsan N, Mehmood S (2014) Recent trends in lactic acid biotechnology: a brief review on production to purification. J Radiat Res Appl Sci 7:222–229CrossRef

Gil S, Cuenca N, Romero A, Valverde JL, Sáchez-Silva L (2014) Optimization of the synthesis procedure of microparticles containing gold for the selective oxidation of glycerol. Appl Catal A 472:11–20CrossRef

Gonzalez-Pajuelo M, Meynial-Salles I, Mendes F, Soucaille P, Vasconcelos I (2006) Microbial conversion of glycerol to 1,3-propanediol: physiological comparison of a natural producer, Clostridium butyricum VPI 3266, and an engineered strain, Clostridium acetobutylicum DG1(pSPD5). Appl Environ Microbiol 72:96–101CrossRef

Gravitis J, Vedernikov N, Zandersons J, Kokorevics A (2001) Furfural and levoglucosan production from deciduous wood and agricultural wastes. Chemicals and materials from renewable resources, vol 784. Am Chem Soc, Washington, DC, pp 110–122CrossRef

Guo Y, Li K, Yu X, Clark JH (2008) Mesoporous H₃PW₁₂O₄₀–silica composite: efficient and reusable solid acid catalyst for the synthesis of diphenolic acid from levulinic acid. Appl Catal B 81:182–191CrossRef

Hayes DJ (2009) An examination of biorefining processes, catalysts and challenges. Catal Today 145:138–151CrossRef

Huang SY, Lipp DW, Farinato RS (2001) Acrylamide polymers. In: Encyclopedia of polyer science and technology. Wiley. https://doi.org/10.1002/0471440264

Huntsman news (2006). http://www.huntsman.com/performance_products/Applications/itemrenderer?p_item_id=230137714&p_item_caid=1143. Accessed 30 June 2017

Ilmen M, Koivuranta K, Ruohonen L, Suominen P, Penttila M (2007) Efficient production of l-lactic acid from xylose by Pichia stipites. Appl Environ Microbiol 73:117–123CrossRef

Isikgor FH, Becer CR (2015) Lignocellulosic biomass: a sustainable platform for the production of bio-based chemicals and polymers. Poly Chem 6:4497–4559CrossRef

John RP, Nampoothiri KM, Pandey A (2007) Fermentative production of lactic acid from biomass: an overview on process developments and future perspectives. Appl Microbiol Biotechnol 74:524–534CrossRef

Jorgensen H, Kirstensen JB, Felby C (2007) Enzymatic conversion of lignocellulose into fermentable sugars: challenges and opportunities. Biofuels Bioprod Bioref 1:119–134CrossRef

Kamm B (2007) Production of platform chemicals and synthesis gas from biomass. Angew Chem Int Ed 46:5056–5058CrossRef

Kamm B, Kamm M (2004) Principles of biorefineries. Appl Microbiol Biotechnol 64:137–145CrossRef

Kamm B, Gruber PR, Kamm M (2006) Biorefineries-industrial processes and products. Wiley-VCH Verlag GmbH & Co. K GaA, Weinheim

Kildegaard KR, Wang Z, Chen Y, Nielsen J, Borodina I (2015) Production of 3-hydroxypropionic acid from glucose and xylose by metabolically engineered Saccharomyces cerevisiae. Metab Eng Commun 2:132–136CrossRef

Kim HJ, Lee J, Green SK, Huber GW, Kim WB (2014) Selective glycerol oxidation by electrocatalytic dehydrogenation. ChemSusChem 7:1051–1054CrossRef

Kobayashi H, Fukuoka A (2013) Synthesis and utilisation of sugar compounds derived from lignocellulosic biomass. Green Chem 15:1740–1763CrossRef

Kondamudi N, Misra M, Banerjee S, Mohapatra S (2012) Simultaneous production of glyceric acid and hydrogen from the photooxidation of crude glycerol using TiSi₂. Appl Catal B 126:180–185CrossRef

Kumar P, Barrett DM, Delwiche MJ, Stroeve P (2009) Methods for pretreatment of lignocellulosic biomass for efficient hydrolysis and biofuel production. Ind Eng Chem Res 48:3713–3729CrossRef

Kumar V, Ashok S, Park S (2013) Recent advances in biological production of 3-hydroxypropionic acid. Biotechnol Adv 31:945–961CrossRef

Li H, Yang S, Riisager A, Pandey A, Sangwan RS, Saravanamurugan S, Luque R (2016) Zeolite and zeotype-catalysed transformations of biofuranic compounds. Green Chem 18:5701–5735CrossRef

Lugani Y, Oberoi S, Sooch BS (2017) Xylitol: a sugar substitute for patients of diabetes mellitus. World J Pharm Pharm Sci 6:741–749

Luque R, Clark JH, Yoshida K, Gai PL (2009) Efficient aqueous hydrogenation of biomass platform molecules using supported metal nanoparticles on Starbons. Chem Commun 35:5305–5307CrossRef

Ma J, Song J, Liu H, Liu J, Zhang Z, Jiang T, Fan H, Han B (2012) One-pot conversion of CO₂ and glycerol to value-added products using propylene oxide as the coupling agent. Green Chem 14:1743–1748CrossRef

Machado G, Leon S, Santos F, Lourega R, Dellius J, Mollmann ME, Eichler P (2016) Literature review on furfural production from lignocellulosic biomass. Nat Resour 7:115–129

Magrini-Bair KA, Jablonski WS, Parent YO, Yung MM (2012) Bench and pilot scale studies of reaction and regeneration of Ni–Mg–K/Al₂O3 for catalytic conditioning of biomass-derived syngas. Top Catal 55:209–217CrossRef

Maki-Arvela P, Salmi T, Holmbom B, Willfor S, Murzin DY (2011) Synthesis of sugars by hydrolysis of hemicelluloses—a review. Chem Rev 111:5638–5666CrossRef

Maki-Arvela P, Simakova IL, Salmi T, Murzin DY (2014) Production of lactic acid/lactates from biomass and their catalytictransformations to commodities. Chem Rev 114:1909–1971CrossRef

Maris EP, Ketchie WC, Murayama M, Davis RJ (2007) Glycerol hydrogenolysis on carbon-supported PtRu and AuRu bimetallic catalysts. J Catal 251:281–294CrossRef

Mariscal R, Maireles-Torres P, Ojeda M, Sadaba I, Lopez Granados M (2016) Furfural: a renewable and versatile platform molecule for the synthesis of chemicals and fuels. Energy Environ Sci 9:1144–1189CrossRef

McKendry P (2002) Energy production from biomass (part 3): gasification technologies. Bioresour Technol 83:55–63CrossRef

McMillan JD (1994) Pretreatment of lignocellulosic biomass. In: Jimmel ME, Baker JO, Overend RP (eds) Enzymatic conversion of biomass for fuels production. American Chemical Society, Washington, DC, pp 292–324CrossRef

Mohammadi M, Najafpour GD, Younesi H, Lahijani P, Uzir MH, Mohamed AR (2011) Bioconversion of synthesis gas to second generation biofuels. A review. Renew Sustain Energy Rev 15:4255–4273CrossRef

Naik SN, Goud VV, Rout PK, Dalai AK (2010) Production of first and second generation biofuels: a comprehensive review. Renew Sustain Energy Rev 14:578–597CrossRef

Nakagawa Y, Tamura M, Tomishige K (2014) Catalytic materials for the hydrogenolysis of glycerol to 1,3-propanediol. J Mater Chem A 2:6688–6702CrossRef

Nanda S, Azargohar R, Dalai AK, Kozinski JA (2015) An assessment on the sustainability of lignocellulosic biomass for biorefining. Renew Sustain Energy Rev 50:925–941CrossRef

NREL. https://www.nrel.gov/workingwithus/re-biomass.html. Accessed 22 June 2017

Octave S, Thomas D (2009) Biorefinery: toward an industrial metabolism. Biochimie 91:659–664CrossRef

Okoye PU, Hameed BH (2016) Review on recent progress in catalytic carboxylation and acetylation of glycerol as a byproduct of biodiesel production. Renew Sustain Energy Rev 53:558–574CrossRef

Ortiz ME, Bleckwedel J, Raya RR, Mozzi F (2013) Biotechnological and in situ food production of polyols by lactic acid bacteria. Appl Microbiol Biotechnol 97:4713–4726CrossRef

Pagliaro M, Ciriminna R, Kimura H, Rossi M, Pina CD (2007) From glycerol to value-added product. Angew Chem Int Ed 46:4434–4440CrossRef

Pandey A (ed) (2011) Biofuels: alternative feedstocks and conversion processes. Academic Press, Kidlington ISBN-13: 978-0123850997

Pereira CSM, Silva VMTM, Rodrigues AE (2011) Ethyl lactate as a solvent: properties, applications and production processes—a review. Green Chem 13:2658–2671CrossRef

Pileidis FD, Titirici M-M (2016) Levulinic acid biorefineries: new challenges for efficient utilization of biomass. Chem Sus Chem 9:562–582CrossRef

Rafiqul ISM, Sakinah AMM (2013) Processes for the production of xylitol—a review. Food Rev Int 29:127–156CrossRef

Ragauskas AJ, Beckham GT, Biddy MJ, Chandra R, Chen F, Davis MF, Davison BH, Dixon RA, Gilna P, Keller M, Langan P, Naskar AK, Saddler JN, Tschaplinski TJ, Tuskan GA, Wyman C (2014) Lignin valorization: Improving lignin processing in the biorefinery. Science 344:1246843CrossRef

Rass HA, Essayem N, Besson M (2013) Selective aqueous phase oxidation of 5-hydroxymethylfurfural to 2,5-furandicarboxylic acid over Pt/C catalysts: influence of the base and effect of bismuth promotion. Green Chem 15:2240–2251CrossRef

Ribeiro LS, Órfão JJM, Pereira MFR (2015) Enhanced direct production of sorbitol by cellulose ball-milling. Green Chem 17:2973–2980CrossRef

Ribeiro LS, Delgado JJ, de Melo Órfão JJ, Pereira MFR (2016) A one-pot method for the enhanced production of xylitol directly from hemicellulose (corncob xylan). RSC Adv 6:95320–95327CrossRef

Roquette/DSM (2008) Press release. https://www.dsm.com/corporate/about/business-entities/dsm-biobased-productsandservices/reverdia.html. Accessed 22 June 2017

Roquette. https://www.roquette.com/industries/performance-materials/polycarbonates/. Accessed 22 June 2017

Rose M, Palkovits R (2011) Cellulose-based sustainable polymers: state of the art and future trends. Macromol Rapid Commun 32:1299–1311CrossRef

Rose M, Palkovits R (2012) Isosorbide as a renewable platform chemical for versatile applications—quo vadis? ChemSusChem 5:167–176CrossRef

Rout PK, Nannaware AD, Prakash O, Kalra A, Rajasekharan R (2016) Synthesis of hydroxymethylfurfural from cellulose using green processes: a promising biochemical and biofuel feedstock. Chem Eng Sci 142:318–346CrossRef

Saha B, Abu-Omar MM (2014) Advances in 5-hydroxymethylfurfural production from biomass in biphasic solvents. Green Chem 16:24–38CrossRef

Santacesaria E, Tesser R, Di Serio M, Casale L, Verde D (2010) New process for producing epichlorohydrin via glycerol chlorination. Ind Eng Chem Res 49:964–970CrossRef

Sarkar N, Ghosh SK, Bannerjee S, Aikat K (2012) Bioethanol production from agricultural wastes: an overview. Renew Energ 37:19–27CrossRef

Schultz EL, de Souza DT, Damaso MCT (2014) The glycerol biorefinery: a purpose for Brazilian biodiesel production. Chem Biol Technol Agric 1:7CrossRef

Schwab A, Warner E, Lewis J (2016) Survey of non-starch ethanol and renewable hydrocarbon biofuels producers. NREL/TP- 6A10-65519. www.nrel.gov/publications

Serrano-Ruiz JC, Dumesic JA (2011) Catalytic routes for the conversion of biomass into liquid hydrocarbon transportation fuels. Energy Environ Sci 4:83–99CrossRef

Singh J, Suhag M, Dhaka A (2015) Augmented digestion of lignocellulose by steam explosion, acid and alkaline pretreatment methods: a review. Carbohydr Polym 117:624–631CrossRef

Subramani V, Gangwal SK (2008) A review of recent literature to search for an efficient catalytic process for the conversion of syngas to ethanol. Energy Fuels 22:814–839CrossRef

Talebnia F, Karakashev D, Angelidaki I (2010) Production of bioethanol from wheat straw: an overview on pretreatment, hydrolysis and fermentation. Bioresour Technol 101:4744–4753CrossRef

Transparency Market Research. http://www.transparencymarketresearch.com/glycerol.market.html. Accessed June 6, 2017

US EPA (2016) Advancing sustainable material management: Facts and figures report. https://www.epa.gov/smm/advancing-sustainable-materials-management-facts-and-figures-report. Accessed 22 June 2017

US Department of Energy, Biomass Resources. Available from https://energy.gov/eere/bioenergy/biomass-resources. Accessed 22 June 2017

Van Putten R-J, van der Waal JC, de Jong E, Rasrendra CB, Heeres HJ, de Vries JG (2013) Hydroxymethylfurfural, a versatile platform chemical made from renewable resources. Chem Rev 113:1499–1597CrossRef

Verma S, Baig RBN, Nadagouda MN, Len C, Varma RS (2017) Sustainable pathway to furanics from biomass via heterogeneous organo-catalysis. Green Chem 19:164–168CrossRef

Wang T, Nolte MW, Shanks BH (2014) Catalytic dehydration of C6 carbohydrates for the production of hydroxymethylfurfural (HMF) as a versatile platform chemical. Green Chem 16:548–572CrossRef

Wang G, Tan X, Lv H, Zhao M, Wu M, Zhou J, Zhang X, Zhang L (2016) Highly selective conversion of cellobiose and cellulose to hexitols by ru-based homogeneous catalyst under acidic conditions. Ind Eng Chem Res 55:5263–5270CrossRef

Werpy T, Petersen G, Aden A, Bozell J, Holladay J, White J, Manheim A et al (2004) In: Werpy T, Petersen G (eds) Top value added chemicals from biomass—vol. 1: results of screening for potential candidates from sugars and synthesis gas. Pacific Northwest National Laboratory, National Renewable Energy Laboratory and Department of Energy, Washington, DC

Whited GM, Feher FJ, Benko DA, Cervin MA, Chotani GK, McAuliffe JC, LaDuca RJ, Ben-Shoshan EA, Sanford KJ (2010) Technology update: development of a gas-phase bioprocess for isoprene-monomer production using metabolic pathway engineering. Ind Biotechnol 6:152–163CrossRef

Yan K, Wu G, Lafleur T, Jarvis C (2014) Production, properties and catalytic hydrogenation of furfural to fuel additives and value-added chemicals. Renew Sust Energy Rev 38:663–676CrossRef

Yang F, Hanna MA, Sun R (2012) Value-added uses for crude glycerol–a byproduct of biodiesel production. Biotechnol Biofuels 5:13CrossRef

Yao K, Tang C (2013) Controlled polymerization of next-generation renewable monomers and beyond. Macromolecules 46:1689–1712CrossRef

Zhang J, Li J, Wu S, Liu Y (2013) Advances in the catalytic production and utilization of sorbitol. Ind Eng Chem Res 52:11799–11815CrossRef

Zhang X, Durndell LJ, Isaacs MA, Parlett CMA, Lee AF, Wilson K (2016) Platinum-catalyzed aqueous-phase hydrogenation of d-glucose to d-sorbitol. ACS Catal 6:7409–7417CrossRef

Zheng P, Wereath K, Sun JB, van den Heuvel J, Zeng A (2006) Overexpression of genes of the dha regulon and its effects on cell growth, glycerol fermentation to 1,3-propanediol and plasmid stability in Klebsiella pneumoniae. Process Biochem 41:2160–2169CrossRef

Zhu W, Yang H, Chen J, Chen C, Guo L, Gan H, Zhao X, Hou Z (2014) Efficient hydrogenolysis of cellulose into sorbitol catalyzed by a bifunctional catalyst. Green Chem 16:1534–1542CrossRef

Titel: An overview of biorefinery-derived platform chemicals from a cellulose and hemicellulose biorefinery
verfasst von: Sudhakar Takkellapati
Tao Li
Michael A. Gonzalez
Publikationsdatum: 04.07.2018
Verlag: Springer Berlin Heidelberg
Erschienen in: Clean Technologies and Environmental Policy / Ausgabe 7/2018
Print ISSN: 1618-954X
Elektronische ISSN: 1618-9558
DOI: https://doi.org/10.1007/s10098-018-1568-5

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