Chen-Loung Chen scite author profile

Comparative studies on the structures of residual and dissolved lignins isolated from pine kraft pulp and pulping liquor have been undertaken using the (1)H-(13)C HMQC NMR technique, GPC, and sugar analysis to elucidate the reaction mechanisms in kraft pulping and the lignin reactivity. A modified procedure for the isolation of enzymatic residual lignins has resulted in an appreciable decrease in protein contaminants in the residual lignin preparations (N content < 0.2%). The very high dispersion of HMQC spectra allows identification of different lignin moieties, which signals appear overlapped in 1D (13)C NMR spectra. Elucidation of the role of condensation reactions indicates that an increase in the degree of lignin condensation during pulping results from accumulation of original condensed lignin moieties rather than from the formation of new alkyl-aryl structures. Among aryl-vinyl type moieties, only stilbene structures are accumulated in lignin in appreciable amounts. Benzyl ether lignin-carbohydrate bonds involving primary hydroxyl groups of carbohydrates have been detected in residual and dissolved lignin preparations. Structures of the alpha-hydroxyacid type have been postulated to be among the important lignin degradation products in kraft pulping. The effect of the isolation method on the lignin structure and differences between the residual and dissolved lignins are discussed.

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The role of of laccase in lignification

O’Malley¹,

Whetten²,

Bao³

et al. 1993

The Plant Journal

186

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The enzymatic mechanism of monolignol polymerization in lignin biosynthesis is not known, although it has been the subject of significant interest for more than 60 years. Peroxidase had been considered to be the exclusive plant enzyme involved in the oxidative polymerization of lignin precursors. Recently, laccase and laccase‐like oxidase activities have been associated with lignification. Laccase is bound to lignifying plant cell walls and can polymerize lignin precursors in vitro. Strong circumstantial evidence from different species implicates this enzyme in the polymerization of lignin precursors. Lignin has a complex structure and it has been difficult to analyze the heterogeneity of lignin by chemical and physical techniques. If lignin precursors are polymerized by enzymes that differ in their catalytic properties, then lignin heterogeneity could be produced by differential expression of multiple enzymes during plant development. When laccase genes are correctly identified, these ideas can be tested in genetic experiments where gain or loss of function can be predicted by the presence or absence of the functional gene.

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Characterization of lignin by 1H and 13C NMR spectroscopy

Chen¹,

Robert²

1988

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Structural Analysis of Residual and Technical Lignins by 1H-13C Correlation 2D NMR-Spectroscopy

Capanema¹,

Balakshin²,

Chen³

et al. 2001

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Summary Structural analysis was conducted on residual lignin from pine Kraft AQ pulp, Eucalyptus Kraft lignin from Eucalyptus globulus and Repap Organosolv lignin by 2D 13C-1H correlation NMR spectroscopic techniques such as HMQC sequence. These lignins contain a rather wide variety of saturated aliphatic groups. The HMQC NMR spectra of the lignins do not verify the presence of diarylmethane moieties in any lignin investigated. The type and amount of other condensed structures depend on the nature of lignin preparation. All the lignins investigated still contained β-O-4′, pino- and syringayresinol (β-β′) and phenylcoumarane (β-5′) structures. Stilbene structures were also identified. Vinyl ether structures were present only in Eucalyptus Kraft lignin. All the lignins contain α-carbonyl groups conjugated to aromatic moieties as terminal side chains rather than involving β-O-4′ structures. No coniferyl alcohol and coniferyl aldehyde type structures are detected in the lignins after pulping. The spectra of kraft lignins show some new signals, the origin of which is discussed.

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Characterization of Milled Wood Lignins and Dehydrogenative Polymerisates from Monolignols by Carbon-13 NMR Spectroscopy

Chen

1998

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Chen-Loung Chen

Elucidation of the Structures of Residual and Dissolved Pine Kraft Lignins Using an HMQC NMR Technique

The role of of laccase in lignification

Characterization of lignin by 1H and 13C NMR spectroscopy

Structural Analysis of Residual and Technical Lignins by 1H-13C Correlation 2D NMR-Spectroscopy

Characterization of Milled Wood Lignins and Dehydrogenative Polymerisates from Monolignols by Carbon-13 NMR Spectroscopy

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