Abstract
Lignin-carbohydrate complexes (LCCs) in the plant cell wall are responsible for providing resistance against biomass-degrading enzymes produced by microorganisms. Four major types of lignin-carbohydrate bonds are reported in the literature, namely, benzyl ethers, benzyl esters, phenyl glycosides, and acetyl ester linkages. Ester’s linkages in the plant cell wall are labile to alkaline pretreatments, such as ammonia fiber expansion (AFEX), which uses liquid or gaseous ammonia to cleave those linkages in the plant cell wall and reduce biomass recalcitrance. Two competing reactions, notably hydrolysis and ammonolysis, take place during AFEX pretreatment process, producing different aliphatic and aromatic acids, as well as their amide counterparts. AFEX pretreated grasses and agricultural residues are known to increase conversion of biomass to sugars by four- to five-fold when subjected to commercial enzyme hydrolysis, yielding a sustainable feedstock for producing biofuels, biomaterials, and animal feed. Animal feed trials on dairy cows have demonstrated a 27% increase in milk production when compared to a control feedstock. However, the presence of carboxamides in feedstocks could promote neurotoxicity in animals if consumed beyond a certain concentration. Thus, there is the need to overcome regulatory hurdles associated with commercializing AFEX pretreated biomass as animal feed in the United States. This manuscript demonstrates a modified pretreatment for increasing the digestibility of industrial byproducts such as Brewer’s spent grains (BSG) and high-fiber meal (HFM) produced from BSG and dry distillers grains with soluble (DDGS), while avoiding the production of carboxamides. The three industrial byproducts were first treated with calculated amounts of alkali such as NaOH, Ca(OH)2, or KOH followed by AFEX pretreatment. We found that 4% alkali was able to de-esterify BSG and DDGS more efficiently than using 2% alkali at both 10 and 20% solids loading. AFEX pretreatment of de-esterified BSG, HFM, and DDGS produced twofold higher glucan conversion than respective untreated biomass. This new discovery can help overcome potential regulatory issues associated with the presence of carboxamides in ammonia-pretreated animal feeds and is expected to benefit several farmers around the world.
Highlights
Industrial lignocellulosic biomass byproducts such as Brewer’s spent grains (BSG) and high-fiber meal (HFM) produced in distilleries and dry distillers grains and soluble (DDGS) produced in corn ethanol plant are sustainable feedstocks for producing fuels, chemicals, biomaterials, and animal feed
A large-scale North American brewery will produce over 100,000 tons of wet BSG per year, and more than three million tons of BSG/year are available in the US alone
We demonstrated a two-step pretreatment process that was an effective method for reducing or eliminating acetamide formation in lignocellulosic biomass, such as BSG, HFM, and DDGS
Summary
Industrial lignocellulosic biomass byproducts such as Brewer’s spent grains (BSG) and high-fiber meal (HFM) produced in distilleries and dry distillers grains and soluble (DDGS) produced in corn ethanol plant are sustainable feedstocks for producing fuels, chemicals, biomaterials, and animal feed. Both BSG and DDGS are extensively used as ruminant animal feed. PCA is mostly acylated to the lignin polymer at the γ-carbon of the side chain region, in syringyl moieties and to a lesser extent on arabinosyl side chains of arabinoxylan (Hatfield et al, 2008) These linkages make the lignocellulosic biomass highly recalcitrant and less digestible in ruminant animals
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