Formation, characterization, and chemical reactions of free radicals in lignin

Hon, Nyok-Sai

January 1985

Free radicals are produced in lignin during mechanical treatment and irradiation with light of various wavelengths. During mechanical treatment, the lignin macromolecule is degraded severely as revealed by ESR and viscosity measurements. Several types of mechano-radicals are produced in lignin during the mechanical process. Among these the phenoxy radicals are rather stable, where carbon-radicals are labile at ambient conditions. Transient mechano-radicals reacted readily with oxygen molecules to produce peroxy radicals even at 77°K, but they decayed rapidly at ambient temperature. Photodegradation of lignin was observed when macromolecule was irradiated with light of λ<3500 Å as revealed by ESR, viscosity, and weight loss. Phenoxy radicals are the predominant intermediates in the photoirradiated lignin as shown by ESR studies. Elimination of side chains of lignin phenyl propane units took effect in α-carbonyl group bearing molecules. By contrast, β aryl ether substituents adjacent to α-carbonyl groups caused ether cleavage under identical conditions of photoirradiation. This is attributed to energy transferred from excited α-carbonyl groups to the ether bonds. The α-carbonyl groups also functioned as photosensitizers accelerating photochemical reactions of lignin. Termination and decomposition reactions of mechano-radicals and photoinduced free radicals in lignin ultimately lead to the formation of para- and ortho-quinones, carbonyl groups, and double bonds which cause the color of lignin. These potential choromophoric groups can be partially removed from lignin by using ultraviolet light of λ> 4000 Å; and they can be completely removed by irradiation of lignin in the presence of dioxane-water with light of λ>3500 Å. Experimental findings suggest chat chromophoric groups in lignin were being trapped or blocked by dioxanyl radicals resulting in brightening. However, the photoreduced lignin-adduct suffered color reversion. This adverse effect can be prevented by using 2-hydroxy-4-methoxy-benzophenone as a photostabilizer. The feasibility of applying photoreduction techniques to high- yield pulps was demonstrated. However, optimal experimental conditions for photoreduction of lignin in high-yield pulps have not been established yet. / Ph. D.

LD5655.V856 1985.H66

Lignin

Wood -- Chemistry

Cellulose -- Chemistry

Free radicals (Chemistry)

Free radical reactions

Synthesis and characterization of novel cellulosics

Dash, Rajalaxmi

30 August 2012

The search for alternatives to the fossil-based products has dramatically surged during past few decades primarily due to the problems associated with the scarcity of these sources and global environmental concerns. Among those many alternatives, exploitation of cellulose, as a raw material to develop novel products has been a constant attempt since it has never lost its both economic and industrial impact. Cellulose is known for its significant contribution as a raw material and as a fascinating sustainable macromolecule, which exhibits wide availability and versatile chemical reactivity to discover novel derivatives for broad range of applications. Conversion of cellulose C2/C3 secondary hydroxyl groups to dialdehyde groups in the presence of periodate is an extremely useful method for regioselective oxidation of cellulose and to activate the polymer for further derivatization. This thesis is primarily focused on synthesis and characterization of wide range of cellulose derivatives exploiting facile periodate oxidation methodology. The first study investigated the use of periodate oxidation as a potential method to synthesize a novel water soluble derivative of cellulose from bleached hardwood Kraft pulp. The work focused on the effect of periodate oxidation and sulfonation reaction on water solubility, morphology and structure of cellulose fibers. The results showed a significant increase in water solubility (2.85 -28.5 g/L) and complete change in surface morphology of the fibers due to the introduction of sulfonic acid groups. In the second study, the same reaction scheme was employed on bead cellulose to prepare anionic 2,3-disulfonated beads. Due to the presence of negatively charged sulfonic acid groups, the beads were found to be agglomerated in presence of cationic starch, exhibiting their future application in chromatographic separation. In the third study, model primary amine compounds such as methyl and butyl amines were grafted to nanowhisker surfaces following periodate oxidation and reductive amination. Then, based on the grafting procedure, in the following study, gamma aminobutyric acid (spacer) and syringyl alcohol (linker) was attached to periodate oxidized nanowhiskers to synthesize a novel drug delivery system. The final study investigated the application of periodate oxidized nanowhiskers as chemical cross-linkers to stabilize gelatin gels. It was concluded that the chemical cross-linking has a significant effect on relative increase in percentage of rigid protons, reduced water uptake ability and reduced pore size of the gels. Not only did the chemical cross-linking improve the storage modulus of the gels (150%) and but it also increased the thermal resistance until 50 oC.

Water soluble cellulose

Periodate oxidation

Reductive amination

Cross-linked hydrogels

Bead cellulose

Cellulose nanowhiskers

Cellulose

Wood Chemistry

Cellulose Chemistry

Biodegradable products

Biodegradation

Molecular design, construction, and characterization of a xylanosome: a protein nanostructure for biomass utilization

McClendon, Shara Demetria

21 February 2011

Lignocellulosic biomass is an abundant renewable resource targeted for biofuel production. Cellulose and hemicellulose from biomass both contain fermentable sugars and other moieties that can be converted to biofuels or other commodity chemicals. Enzymatic hydrolysis of these biopolymers is a critical step in the liberation of sugars for fermentation into desired products. In nature, anaerobic microbes produce protein nanostructures called cellulosomes that efficiently degrade cellulose substrates by combining multiple enzyme activities onto a scaffolding protein. However, current enzyme cocktails used in industry contain secretomes of aerobic microbes and are not efficient enough to be highly economical. Furthermore, most bio-processes focus on cellulose, rendering hemicellulose under-utilized. The three main objectives of this dissertation are to 1) develop multi-functional, self-assembling protein nanostructures for hemicellulose degradation using the architecture provided by cellulosomes, 2) understand the self-assembly mechanism at conditions for consolidated bioprocessing applications, and 3) compare the effectiveness of structured to non-structured hemicellulases in the hydrolysis of biomass. Xylan is a major type of hemicellulose in biomass feedstocks targeted for biofuel production. Six different xylanosomes were designed for hydrolysis of xylan within multiple biomass substrates using the cohesin-dockerin domain systems from Clostridium thermocellum, Clostridium cellulovorans, and Clostridium cellulolyticum. Each two-unit structure contained a xylanase for internal cleavage of the xylan backbone and one side-chain acting enzyme, either a ferulic acid esterase or bi-functional arabinofuranosidase/xylosidase. Expansion to three-unit xylanosomes included a family 10 or 11 xylanase, a bi-functional arabinofuranosidase/xylosidase, and bi-functional ferulic acid esterase/acetylxylan esterase. These multi-functional biocatalysts were used to degrade hemicellulose-rich wheat arabinoxylan and cellulose-containing destarched corn bran. Synergistic release of soluble sugars and ferulic acid was observed with select xylanosomes and in some cases required addition of an endoglucanase and cellobiohydrolase for enhanced hydrolysis. Furthermore, a putative ferulic acid esterase gene from the soil bacterium Cellvibrio japonicus was characterized and its role in xylan hydrolysis investigated. Information for the development of stable and functional cellulosome-like biocatalysts in metabolically-engineered microbes was collected using surface plasmon resonance. The protein-protein interaction of cohesin and dockerin domains for xylanosome self-assembly was examined at various temperatures and in the presence of ethanol to mimic different hydrolysis and fermentation processes and found to retain high affinities at the selected conditions. Moreover, the high-affinity interaction of cohesin and dockerin domains in the presence of non-specific proteins eliminated the need for protein purification for xylanosome construction. In addition to development of the first cellulosome-like biocatalysts targeted for hemicellulose degradation, this dissertation provides insight on possible improvements for the enzymatic hydrolysis of biomass, as well as the applicability of xylanosomes in consolidated bioprocessing.

Cellulosomes

Cohesin-dockerin interaction

Xylan hydroysis

Consolidated bioprocessing

Ferulic acid esterase

Cellulose Chemistry

Cellulose

Cellulose Biodegradation

Biomass

Renewable energy sources

Renewable natural resources