Nadja Cachet scite author profile

This review is devoted to the application of MS using soft ionization methods with a special emphasis on electrospray ionization, atmospheric pressure photoionization and matrix-assisted laser desorption/ionization MS and tandem MS (MS/MS) for the elucidation of the chemical structure of native and modified lignins. We describe and critically evaluate how these soft ionization methods have contributed to the present-day knowledge of the structure of lignins. Herein, we will introduce new nomenclature concerning the chemical state of lignins, namely, virgin released lignins (VRLs) and processed modified lignins (PML). VRLs are obtained by liberation of lignins through degradation of vegetable matter by either chemical hydrolysis and/or enzymatic hydrolysis. PMLs are produced by subjecting the VRL to a series of further chemical transformations and purifications that are likely to alter their original chemical structures. We are proposing that native lignin polymers, present in the lignocellulosic biomass, are not made of macromolecules linked to cellulose fibres as has been frequently reported. Instead, we propose that the lignins are composed of vast series of linear related oligomers, having different lengths that are covalently linked in a criss-cross pattern to cellulose and hemicellulose fibres forming the network of vegetal matter. Consequently, structural elucidation of VRLs, which presumably have not been purified and processed by any other type of additional chemical treatment and purification, may reflect the structure of the native lignin. In this review, we present an introduction to a MS/MS top-down concept of lignin sequencing and how this technique may be used to address the challenge of characterizing the structure of VRLs. Finally, we offer the case that although lignins have been reported to have very high or high molecular weights, they might not exist on the basis that such polymers have never been identified by the mild ionizing techniques used in modern MS.

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Esterification of organosolv lignin under supercritical conditions

Cachet

Camy

Benjelloun-Mlayah

et al. 2014

Industrial Crops and Products

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An organosolv lignin, extracted in organic acid media, named Biolignin ™ , was acetylated with acetic anhydride in supercritical carbon dioxide (scC02). The effect of moisture and specific surface of lignin sample, temperature (50, 80, 100, 150 "C), reaction time and the use of a catalyst have been studied using analytical techniques such as FT-IR, quantitative 31 P NMR and Differential Scanning Calorimetry (DSC). The reaction appeared ta be more efficient when a dried organosolv lignin was used (97% Dry Matter) and with a specific surface of 0.645 m 2 /g. The highest degree of substitution of acetylated samples was obtained after 1 h of reaction at a temperature of 100 '((180 bar) and in the presence of pyridine as a catalyst.

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Acid-based organosolv lignin extraction from wheat straw: Kinetic and structural analysis

Labauze

Cachet

Benjelloun-Mlayah

2022

Industrial Crops and Products

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Comparison of organic acid-based organosolv lignins extracted from the residues of five annual crops

Cachet

Benjelloun-Mlayah

2021

BioRes

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Organosolv lignins were extracted from corn stover, wheat, rice straw, reed straw, and sugarcane bagasse using a mixture of acetic and formic acids, at relatively low temperature and atmospheric pressure. Lignin content, residual carbohydrates, ash levels, proteins, and molecular weights were determined in each extracted lignin. The lignin content of all samples was relatively high, confirming the performance of the pretreatment process. The low molecular weights were in a narrow range, in accordance with the organosolv lignin molar masses. However, some differences between studied lignins were highlighted, in particular in rice straw lignin, which contained the highest silica, calcium, and nitrogen contents. Nuclear magnetic resonance spectroscopies (31P and semi-quantitative Heteronuclear Single Quantum Correlation) underlined the structural similarities and differences between these organosolv lignins. Corn stover and sugarcane bagasse lignins were rich in non-methoxylated (H-Unit) or mono-methoxylated (G-Unit) phenolic units, making them the best promising candidates for production of phenolic resins. Wheat straw lignin was richer in aliphatic OH than in phenolic OH. This is an advantage for use as polyol substitute in polyurethane synthesis. Reed straw lignin was less specific, with a balanced content of OH groups. However, it contained a high concentration of β-O-4 linkages, which is favorable for depolymerization.

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Nadja Cachet

A critique on the structural analysis of lignins and application of novel tandem mass spectrometric strategies to determine lignin sequencing

Esterification of organosolv lignin under supercritical conditions

Acid-based organosolv lignin extraction from wheat straw: Kinetic and structural analysis

Comparison of organic acid-based organosolv lignins extracted from the residues of five annual crops

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