Design of integrated processes for a second generation biorefinery using mixed agricultural waste

Dlangamandla, Nkosikho

January 2018

Thesis (Doctor of Engineering in Chemical Engineering)--Cape Peninsula University of Technology, 2018. / Lignocellulosic biomass (agro-waste) has been recommended as the most promising feedstock for the production of bioalcohols, in the biofuel industry. Furthermore, agro-waste is well-known as the most abundant organic matter in the agricultural and forestry product processing industry. However, the challenge with utilizing agro-waste as a feedstock is its highly recalcitrant structure, which limits hydrolysis to convert the holocelluloses into fermentable sugars. Conventional pre-treatment methods such as dilute acid, alkaline, thermal, hot water and enzymatic, have been used in previous studies. The challenge with these conventional methods is the generation of residual toxicants during the pretreatment process, which inhibits a high bioalcohol yield, by reducing the microbial populations’ (fermenter) ability to be metabolically proficient during fermentation. Numerous studies have been developed to improve the engineered strains, which have shown to have an ability to reduce the inhibition and toxicity of the bioalcohols produced or by-products produced during pre-treatment, while enhancing the bioalcohol production. In the present study (chapter 5), evaluation of common conventional methods for the pretreatment of the mixed agro-waste, i.e. (˃45µm to <100µm) constituted by Citrus sinensis, Malus domestica peels, corn cobs from Zea mays and Quercus robur (oak) yard waste without a pre-rinsing step at a ratio of 1:1 at 25% (w/w) for each waste material, was undertaken, focusing on hot water pre treatment followed by dilute acid (H2SO4) pre-treatment. To further pretreat the mixed agro-waste residue, cellulases were used to further hydrolyse the pre-treated agro-waste in a single pot (batch) multi-reaction process. The TRS concentration of 0.12, 1.43 and 3.22 g/L was achieved with hot water, dilute acid and cellulases hydrolysis as sequential pretreatment steps, respectively, in a single pot multi-reaction system. Furthermore, a commercial strain was used to ascertain low (C1 to C3) and high carbon content (C4+) bioalcohol production under aerobic conditions. Multiple bioproducts were obtained within 48 to 72 h, including bioethanol and 1-Butanol, 3-methyl, which were major products for this study. However, undesirable bio-compounds such as phenolics, were detected post fermentation. Since multiple process units characterised by chemical usage and high energy intensivity have been utilized to overcome delignification and cellulolysis, a sustainable, environmental benign pretreatment process was proposed using N. mirabilis “monkey cup” fluids (extracts) to also reduce fermenter inhibitors from the delignification of mixed agrowaste; a process with minimal thermo physical chemical inputs for which a single pot multi-reaction system strategy was used. Nepenthes mirabilis extracts shown to have ligninolytic, cellulolytic and xylanolytic activities, were used as an enzyme cocktail to pretreat mixed agro-waste, subsequent to the furtherance of TRS production from the agro-waste, by further using cellulase for further hydrolysis. N. mirabilis pod extracts were determined to contained carboxylesterases (529.41±30.50 U/L), β-glucosidases (251.94±11.48 U/L) and xylanases (36.09±18.04 U/L), constituting an enzymatic cocktail with a significant potential for the reduction in total residual phenolic compounds (TRPCs). Furthermore, the results indicated that maximum concentration of TRS obtainable was 310±5.19 mg/L within 168 h, while the TRPCs were reduced from 6.25±0.18 to 4.26 ±0.09 mg/L, which was lower than that observed when conventional methods were used. Overall N. mirabilis extracts were demonstrated to have an ability to support biocatalytic processes for the conversion of agro-waste to produce fermentable TRS in a single unit facilitating multiple reactions with minimised interference with cellulase hydrolysis. Therefore, the digestive enzymes in N. mirabilis pods can be used in an integrated system for a second generation biorefinery.

Agricultural wastes

Biomass energy

Bioalcohol

β-Glucosidases

Carboxylesterases

Cellulases

Holocelluloses

Nepenthes mirabilis

Total reducing sugars

Kinetic models

Saccharomyces cerevisiae

Estudos de inibição de β-glicosidases bacterianas por fenóis solúveis

Barbosa, Mariana de Almeida

January 2019

Orientador: Mario de Oliveira Neto / Resumo: A biomassa lignocelulósica pode ser usada para a produção de energia ou de novos bioprodutos potenciais substitutos de químicos convencionais. Porém a conversão dos polissacarídeos estruturais presentes na parede celular vegetal das células que compõe a biomassa não é simples. Isto se deve principalmente pela presença da lignina, que juntamente com a hemicelulose, formam uma estrutura coesa de microfibrilas que entrelaçam a celulose. Compostos que inibem as enzimas celulolíticas, incluindo fenólicos solúveis (derivados da lignina), açúcares solúveis, aldeídos de furano e ácidos fracos são gerados durante os diversos pré-tratamentos utilizados atualmente. Neste estudo, observamos como os fenólicos solúveis interagem com -glicosidases. Para isso, combinamos simulações de ensaio enzimático, docking molecular e dinâmica molecular para descrever o processo de ligação. Notavelmente, o ácido tânico, um dos fenólicos solúveis estudados, foi a molécula com maior poder inibitório em comparação com todos os demais fenólicos. Possivelmente devido ao seu comprimento e suas substituições de grupos químicos. A alta presença de anéis aromáticos e grupos hidroxilas no ácido tânico, leva a maior interação entre as moléculas e consequente inibição/desativação das β-glicosidases bacterianas, enquanto os grupos carboxílicos presentes nos demais fenólicos alteram os efeitos físico-químicos aumentando a hidrofobicidade; criando cargas eletrostáticas e aumentando a ligação de hidrogênio, afetando a... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: Lignocellulosic biomass can be transformed to chemicals or energy products. However converting polysaccharides present on the cell wall can be limitated due to the high recalcitrance caused by the presence of lignin. Compounds that inhibit enzymes, including lignin-derived phenolics, soluble sugars, furan aldehydes, and weak acids, are generated during the various pre-treatments currently used. In this study was observed how the soluble phenolics generated significantly impede the enzymatic hydrolysis of cellulose. For this were combine enzymatic assay, molecular docking and molecular dynamics simulations to describe the binding process between soluble phenolics and bacterial β-glycosidases. Notably, tannic acid, one of the soluble phenolics generated, was the strongest inhibitory molecule in comparison with all phenolics studied. Possibly because of its length and its substitutions of chemical groups. The high presence of aromatic rings and hydroxyl groups in tannic acid leads to greater interaction between the molecules and consequent inhibition / deactivation of bacterial β-glycosidases. Taken together, our studies of the interaction suggest that there is a high correlation between exposed hydrophobic surface areas and the number of binding sites on the inhibition of βglucosidases. These data may provide a useful basis for future biotechnological applications of microbial β-glucosidases, especially in the field of biofuel production. / Doutor

Biomassa lignocelulósica

inibição enzimática

β-glicosidases bacterianas

Fenóis.

ácido tânico

Lignocellulosic biomass

inhibit enzymes

bacterial β-glucosidases

Fenóis.

tannic acid