Oxidative treatment and nanofibrillation softwood kraft fibres with lytic polysaccharide monooxygenases from Trichoderma reesei and Podospora anserina

Cellulose oxidation and enzymatic treatments can be employed to reduce the energy consumption in production of cellulose nanofibrils (CNFs). Lytic polysaccharide monooxygenases (LPMOs) offer new biocatalytic tools for oxidative pretreatment of cellulosic fibres in this process. In this work the capa...

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Bibliographic Details
Published in:Industrial crops and products 2023-03, Vol.193, p.116243, Article 116243
Main Authors: Marjamaa, Kaisa, Lahtinen, Panu, Arola, Suvi, Maiorova, Natalia, Nygren, Heli, Aro, Nina, Koivula, Anu
Format: Article
Language:English
Subjects:
Barrier
CNF
Lytic polysaccharide monooxygenase
Oxidation
Softwood kraft
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Summary:Cellulose oxidation and enzymatic treatments can be employed to reduce the energy consumption in production of cellulose nanofibrils (CNFs). Lytic polysaccharide monooxygenases (LPMOs) offer new biocatalytic tools for oxidative pretreatment of cellulosic fibres in this process. In this work the capability of LPMO enzymes to enhance fibrillation of bleached softwood kraft fibres was studied using two LPMO enzymes, i.e. C1/C4-oxidising AA9A from Trichoderma reesei (Tr AA9A) and C1-oxidising AA9E from Podospora anserina (Pa AA9E). The enzymatic treatments were carried out after mechanical pre-refining (grinding) of the pulp, which resulted in clear reduction of the intrinsic viscosity of the refined fibres compared to the previously published work, presumably due to better access of the enzymes on the fibre polysaccharides. The Tr AA9A treatments were carried out using different enzyme dosages (0.25–10 mg/g dry fibre) and fixed reaction time (24 h), resulting in fibres characterized by increased aldehyde content, which is in line with the C1/C4 oxidising activity of this enzyme. Comparison of the Tr AA9A to Pa AA9E with fixed enzyme dosage (2 mg/g dry fibre) and reaction time (24 h), showed that no remarkable increase in total charge of the cellulosic fibres could be obtained with either of the LPMO enzymes in these conditions. All the LPMO pretreatments improved fibrillation of mechanically refined fibres in microfluidization, seen as clearly lower residual fibre content and higher proportion nanosized material. In comparison of the Pa AA9E to Tr AA9A, clearly faster fibrillation was achieved with the Pa AA9E pretreatment. The mechanical and oxygen barrier properties of CNF films prepared from LPMO pretreated fibres were very similar to the reference CNF films while water vapour transmission rate was somewhat higher. [Display omitted] •Oxidation of softwood fibres with specific enzymes (LPMOs) was studied as a pretreatment means to produce nanocellulose.•Oxidation specificity of the two LPMOs was verified using liquid chromatography combined to ion mobility-mass spectrometry•Enzymatic oxidation of pre-refined fibres resulted in remarkable reduction in intrinsic viscosity due to oxidative cleavages.•Enzymatic oxidations enhanced fibrillation, shown by decrease in residual particles and increase in nanosized material.•The usage of C1-specific LPMO resulted to faster fibrillation than that of C1/C4 oxidising LPMO.
ISSN:0926-6690
1872-633X
DOI:10.1016/j.indcrop.2023.116243