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Assessing the Viability of Recovery of Hydroxycinnamic Acids from Lignocellulosic Biorefinery Alkaline Pretreatment Waste Streams

Steven D. Karlen, Peyman Fasahati, Mona Mazaheri, José Serate, Rebecca A. Smith, Sirisha Sirobhushanam, Mingjie Chen, Vitaliy I. Tymokhin, Cynthia L. Cass, Sarah Liu, Dharshana Padmakshan, Dan Xie, Yaoping Zhang, Mick McGee, Jason D. Russell, Joshua J. Coon, Heidi F. Kaeppler, Natalia de León, Christos T. Maravelias, Troy Runge, Shawn M. Kaeppler, John C. Sedbrook, John Ralph

2020ChemSusChem76 citationsDOIOpen Access PDF

Abstract

Abstract The hydroxycinnamic acids p ‐coumaric acid ( p CA) and ferulic acid (FA) add diversity to the portfolio of products produced by using grass‐fed lignocellulosic biorefineries. The level of lignin‐bound p CA in Zea mays was modified by the alteration of p ‐coumaroyl‐CoA monolignol transferase expression. The biomass was processed in a lab‐scale alkaline‐pretreatment biorefinery process and the data were used for a baseline technoeconomic analysis to determine where to direct future research efforts to couple plant design to biomass utilization processes. It is concluded that future plant engineering efforts should focus on strategies that ramp up accumulation of one type of hydroxycinnamate ( p CA or FA) predominantly and suppress that of the other. Technoeconomic analysis indicates that target extraction titers of one hydroxycinnamic acid need to be >50 g kg −1 biomass, at least five times higher than observed titers for the impure p CA/FA product mixture from wild‐type maize. The technical challenge for process engineers is to develop a viable process that requires more than 80 % reduction of the isolation costs.

Topics & Concepts

BiorefineryChemistrySTREAMSPulp and paper industryWaste managementWaste streamBioenergyEnvironmental scienceBiofuelOrganic chemistryEngineeringRaw materialComputer scienceComputer networkLignin and Wood ChemistryBiofuel production and bioconversionEnzyme-mediated dye degradation