Seeing Biomass Recalcitrance Through Fluorescence

Overview

Journal Sci Rep

Specialty Science

Date 2017 Aug 20

PMID 28821835

Citations 13

Authors

Thomas Auxenfans

Christine Terryn

Gabriel Paes

Affiliations

Soon will be listed here.

Abstract

Lignocellulosic biomass is the only renewable carbon resource available in sufficient amount on Earth to go beyond the fossil-based carbon economy. Its transformation requires controlled breakdown of polymers into a set of molecules to make fuels, chemicals and materials. But biomass is a network of various inter-connected polymers which are very difficult to deconstruct optimally. In particular, saccharification potential of lignocellulosic biomass depends on several complex chemical and physical factors. For the first time, an easily measurable fluorescence properties of steam-exploded biomass samples from miscanthus, poplar and wheat straw was shown to be directly correlated to their saccharification potential. Fluorescence can thus be advantageously used as a predictive method of biomass saccharification. The loss in fluorescence occurring after the steam explosion pretreatment and increasing with pretreatment severity does not originate from the loss in lignin content, but rather from a decrease of the lignin β-aryl-ether linkage content. Fluorescence lifetime analysis demonstrates that monolignols making lignin become highly conjugated after steam explosion pretreatment. These results reveal that lignin chemical composition is a more important feature to consider than its content to understand and to predict biomass saccharification.

Citing Articles

Cinnamyl alcohol dehydrogenase downregulation in poplar wood increases saccharification after dilute acid pretreatment: a key role for lignin revealed by a multimodal investigation.

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Unraveling lignin degradation in fibre cement via multidimensional fluorometry.

Hoque M, Kamal S, Raghunath S, Foster E Sci Rep. 2023; 13(1):8385.

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Automated quantification of fluorescence and morphological changes in pretreated wood cells by fluorescence macroscopy.

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Experimental and computational studies of cellulases as bioethanol enzymes.

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Fluorescence Microscopy Methods for the Analysis and Characterization of Lignin.

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