Tobias K. F. Dier scite author profile

High resolution mass spectrometry was utilized to study the highly complex product mixtures resulting from electrochemical breakdown of lignin. As most of the chemical structures of the degradation products were unknown, enhanced mass defect filtering techniques were implemented to simplify the characterization of the mixtures. It was shown that the implemented ionization techniques had a major impact on the range of detectable breakdown products, with atmospheric pressure photoionization in negative ionization mode providing the widest coverage in our experiments. Different modified Kendrick mass plots were used as a basis for mass defect filtering, where Kendrick mass defect and the mass defect of the lignin-specific guaiacol (C7H7O2) monomeric unit were utilized, readily allowing class assignments independent of the oligomeric state of the product. The enhanced mass defect filtering strategy therefore provided rapid characterization of the sample composition. In addition, the structural similarities between the compounds within a degradation sequence were determined by comparison to a tentatively identified product of this compound series. In general, our analyses revealed that primarily breakdown products with low oxygen content were formed under electrochemical conditions using protic ionic liquids as solvent for lignin.

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Sustainable Electrochemical Depolymerization of Lignin in Reusable Ionic Liquids

Dier

Rauber

Durneata

et al. 2017

Sci Rep

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Lignin’s aromatic building blocks provide a chemical resource that is, in theory, ideal for substitution of aromatic petrochemicals. Moreover, degradation and valorization of lignin has the potential to generate many high-value chemicals for technical applications. In this study, electrochemical degradation of alkali and Organosolv lignin was performed using the ionic liquids 1-ethyl-3-methylimidazolium trifluoromethanesulfonate and triethylammonium methanesulfonate. The extensive degradation of the investigated lignins with simultaneous almost full recovery of the electrolyte materials provided a sustainable alternative to more common lignin degradation processes. We demonstrate here that both the presence (and the absence) of water during electrolysis and proton transport reactions had significant impact on the degradation efficiency. Hydrogen peroxide radical formation promoted certain electrochemical mechanisms in electrolyte systems “contaminated” with water and increased yields of low molecular weight products significantly. The proposed mechanisms were tentatively confirmed by determining product distributions using a combination of liquid chromatography-mass spectrometry and gas-chromatography-mass spectrometry, allowing measurement of both polar versus non-polar as well as volatile versus non-volatile components in the mixtures.

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Electrochemical Lignin Degradation in Ionic Liquids on Ternary Mixed Metal Electrodes

Rauber

Dier

Volmer

2017

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Lignin is the second most abundant natural polymer and a promissing feedstock for the generation of renewable aromatic chemicals. We present an fundamental approach for the electrocatalytic cleavage of lignin dissolved in a recoverable, inexpensive ionic liquid using mixed metal oxide electrodes of different compositions. The distribution of depolymerization products generated by electrochemical oxidation were analyzed by means of mass spectrometry. The distribution and yield of the cracked species was found to depended strongly on the implemented metal catalyst and therefore offers the potential to tailor the amount and composition of the low molecular weight cleavage products. This approach could help to provide a more sustainable valorization of lignin for the potential production of high value aromatic compounds due to synergistic effects.

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Two-color emissive probes for click reactions

et al. 2014

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Comparison of CYP106A1 and CYP106A2 from Bacillus megaterium – identification of a novel 11-oxidase activity

Kiss

Schmitz

Zapp

et al. 2015

Appl Microbiol Biotechnol

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The CYP106A subfamily hydroxylates steroids, diterpenes, and triterpenes in a regioselective and stereoselective manner, which is a challenging task for synthetic chemistry. The well-studied CYP106A2 enzyme, from the Bacillus megaterium strain ATCC 13368, is a highly promising candidate for the pharmaceutical industry. It shares 63 % amino acid sequence identity with CYP106A1 from B. megaterium DSM319, which was recently characterized. A focused steroid library was screened with both CYP106A1 and CYP106A2. Out of the 23 tested steroids, 19 were successfully converted by both enzymes during in vitro and in vivo reactions. Thirteen new substrates were identified for CYP106A1, while the substrate spectrum of CYP106A2 was extended by seven new members. Finally, six chosen steroids were further studied on a preparative scale employing a recombinant B. megaterium MS941 whole-cell system, yielding sufficient amounts of product for structure characterization by nuclear magnetic resonance. The hydroxylase activity was confirmed at positons 6β, 7β, 9α, and 15β. In addition, the CYP106A subfamily showed unprecedented 11-oxidase activity, converting 11β-hydroxysteroids to their 11-keto derivatives. This novel reaction and the diverse hydroxylation positions on pharmaceutically relevant compounds underline the role of the CYP106A subfamily in drug development and production.

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Tobias K. F. Dier

Enhanced Mass Defect Filtering To Simplify and Classify Complex Mixtures of Lignin Degradation Products

Sustainable Electrochemical Depolymerization of Lignin in Reusable Ionic Liquids

Electrochemical Lignin Degradation in Ionic Liquids on Ternary Mixed Metal Electrodes

Two-color emissive probes for click reactions

Comparison of CYP106A1 and CYP106A2 from Bacillus megaterium – identification of a novel 11-oxidase activity

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