Structural changes of lignin in biorefinery pretreatments and consequences to enzyme-lignin interactions - OPEN ACCESS

Sipponen, Mika H.; Rahikainen, Jenni; Leskinen, Timo; Pihlajaniemi, Ville; Mattinen, Maija‐Liisa; Lange, Heiko; Crestini, Claudia; Österberg, Monika

doi:10.3183/npprj-2017-32-04-p550-571

Cited by 40 publications

(20 citation statements)

References 182 publications

(284 reference statements)

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“…The efficient valorization of lignin has been hampered by its complex and varying chemical structure partly arising from chemical reactions during these pulping [1][2][3] and biomass pretreatment processes. 4 In effect, cleavage of the inter-unit linkages of native lignin (Fig. 1c-h) and associated formation of new covalent bonds leads to technical lignins with complex and incompletely elucidated structures.…”

Section: Monika öSterbergmentioning

confidence: 99%

“…Nevertheless, one needs to be critical as to when the energy input and solvents used for the production of LNPs is compensated by the added value of the products. Other issues that are not always addressed are (1) to what extent the processes are preventing the formation of waste, especially wastewater, (2) what is the atom efficiency of the process, (3) are all materials incorporated in the product, and (4) to what extent could LNPs be designed for degradation?…”

Section: Monika öSterbergmentioning

confidence: 99%

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Spherical lignin particles: a review on their sustainability and applications

et al. 2020

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Section: Monika öSterbergmentioning

confidence: 99%

Section: Monika öSterbergmentioning

confidence: 99%

Spherical lignin particles: a review on their sustainability and applications

et al. 2020

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“…The structure of a specific lignin material strongly depends on the botanical origin and the isolation process. Especially the harsh thermochemical processes used to separate cellulose from other cell‐wall components cause fragmentation, functional group eliminations, and process‐typical chemical functionalization of lignin . In recent years, apart from its combustion for energy, isolation of lignin originating from industrial kraft pulping processes as well as biorefinery plants producing ethanol as biofuel has seen a steady increase.…”

Section: Introductionmentioning

confidence: 99%

Lignin for Nano‐ and Microscaled Carrier Systems: Applications, Trends, and Challenges

et al. 2019

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To liberate society from its dependence on fossil‐based fuels and materials it is pivotal to explore components of renewable plant biomass in applications that benefit from their intrinsic biodegradability, safety, and sustainability. Lignin, a byproduct of the pulp and paper industry, is a plausible material for carrying various types of cargo in small‐ and large‐scale applications. Herein, possibilities and constraints regarding the physical–chemical properties of the lignin source as well as modifications and processing required to render lignins suitable for the loading and release of pesticides, pharmaceuticals, and biological macromolecules is reviewed. In addition, the technical challenges, regulatory and toxicological aspects, and future research needed to realize some of the promises that nano‐ and microscaled lignin materials hold for a sustainable future are critically discussed.

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“…Lignin has been considered as one of the major obstructions in biorefinery operations aiming at enzymatically converting cellulose in lignocellulosic biomass into glucose before further downstream processing (Li, Pu, & Ragauskas, ). Nonproductive adsorption of cellulases onto lignin is considered an important mechanism behind retardation of enzymatic cellulose degradation in lignocellulose‐based processes (Liu, Sun, Leu, & Chen, ; Saini, Patel, Adsul, & Singhania, ; Sipponen et al, ). Studies have reported adsorption of cellulases onto lignin isolated from various biomass feedstocks and have correlated such adsorption with the observed retardation of enzymatic degradation of pure model cellulose in the presence of the isolated lignin (Kellock, Rahikainen, Marjamaa, & Kruus, ; Rahikainen et al, ; Tu, Pan, & Saddler, ).…”

Section: Introductionmentioning

confidence: 99%

“…Hydrophobic interaction (Sammond et al, ; Tu et al, ), electrostatic interaction (Lan, Lou, & Zhu, ; Yarbrough et al, ), and hydrogen bonding (Sewalt, Glasser, & Beauchemin, ; Yu et al, ) have been regarded as the cause of the nonproductive binding of cellulases to lignin. However, more recently, it has been recognized that several interactions between the different chemical groups in the lignin and in the enzymes may be occurring simultaneously (Liu et al, ; Nakagame, Chandra, Kadla, & Saddler, ; Rahikainen, Evans et al, ; Sipponen et al, ).…”

Section: Introductionmentioning

confidence: 99%

Cellulases adsorb reversibly on biomass lignin

Djajadi

Pihlajaniemi

Rahikainen

et al. 2018

Biotech & Bioengineering

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Adsorption of cellulases onto lignin is considered a major factor in retarding enzymatic cellulose degradation of lignocellulosic biomass. However, the adsorption mechanisms and kinetics are not well understood for individual types of cellulases. This study examines the binding affinity, kinetics of adsorption, and competition of four monocomponent cellulases of Trichoderma reesei during adsorption onto lignin. TrCel7A, TrCel6A, TrCel7B, and TrCel5A were radiolabeled for adsorption experiments on lignin‐rich residues (LRRs) isolated from hydrothermally pretreated spruce (L‐HPS) and wheat straw (L‐HPWS), respectively. On the basis of adsorption isotherms fitted to the Langmuir model, the ranking of binding affinities was TrCel5A > TrCel6A > TrCel7B > TrCel7A on both types of LRRs. The enzymes had a higher affinity to the L‐HPS than to the L‐HPWS. Adsorption experiments with dilution after 1 and 24 hr and kinetic modeling were performed to quantify any irreversible binding over time. Models with reversible binding parameters fitted well and can explain the results obtained. The adsorption constants obtained from the reversible models agreed with the fitted Langmuir isotherms and suggested that reversible adsorption–desorption existed at equilibrium. Competitive binding experiments showed that individual types of cellulases competed for binding sites on the lignin and the adsorption data fitted the Langmuir adsorption model. Overall, the data strongly indicate that the adsorption of cellulases onto lignin is reversible and the findings have implications for the development of more efficient cellulose degrading enzymes.

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Structural changes of lignin in biorefinery pretreatments and consequences to enzyme-lignin interactions - OPEN ACCESS

Cited by 40 publications

References 182 publications

Spherical lignin particles: a review on their sustainability and applications

Spherical lignin particles: a review on their sustainability and applications

Lignin for Nano‐ and Microscaled Carrier Systems: Applications, Trends, and Challenges

Cellulases adsorb reversibly on biomass lignin

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