Revealing the mechanisms of hydrogel formation by laccase crosslinking and regeneration of feruloylated arabinoxylan from wheat bran
Journal article, 2022

Feruloylated arabinoxylan (FAX) from cereal brans has large potential to generate multifunctional materials with customized macromolecular and nanostructural architectures and techno-functional properties. Here we investigate the chemical and structural mechanisms of hydrogel formation of wheat bran FAX following enzymatic crosslinking by laccase and a subsequent regeneration procedure involving freeze-drying and resuspension of the crosslinked FAX in different pH buffers, using a battery of biochemical, rheological and physical techniques. The laccase crosslinking induced the conversion of ferulic acid units into a wide diversity of dimeric forms, leading to an increased molecular weight and a closer-packing of the FAX chains. The regeneration step resulted in a remarkable increase in the viscosity and viscoelasticity for all tested pH values. The amount of crystallinity of FAX increased by enzymatic crosslinking, it was however decreased by the regeneration step. The structural characterization revealed that enzymatic crosslinking, in addition to the formation of covalent crosslinks, influences the physical intermolecular interactions between adjacent FAX domains, and the regeneration forms larger clusters with higher dynamic moduli. Our results reveal that both chemical and physical mechanisms influence the network formation and multiscale assembly of wheat bran FAX hydrogels, thus modulating their rheological properties fundamental for their use in food and biomedical applications.

Arabinoxylan

Hydrogel nanostructure

Oxidative gelation

Ferulic acid

Crystallinity

Author

Secil Yilmaz-Turan

AlbaNova University Center

Patricia Lopez-Sanchez

Chalmers, Biology and Biological Engineering, Food and Nutrition Science

Amparo Jiménez-Quero

AlbaNova University Center

Tomás S. Plivelic

Lund University

francisco Vilaplana

AlbaNova University Center

Food Hydrocolloids

0268-005X (ISSN)

Vol. 128 107575

Subject Categories

Polymer Chemistry

Polymer Technologies

Other Chemistry Topics

DOI

10.1016/j.foodhyd.2022.107575

More information

Latest update

2/22/2022