Physical, Rheological and Mechanical Properties of Alkali Activated Hydrogels Based on Nanofibrillated Cellulose

Hydrogels are classified as a three-dimensional network system, capable of retaining large amounts of water while preserving their shape and dimensional stability. Due to their natural origin and biocompatibility with human tissue, cellulose nanofibrils are often considered to be promising candidate...

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Published inJournal of natural fibers Vol. 19; no. 17; pp. 16040 - 16052
Main Authors Žepič, Vesna, Oven, Primož, Čop, Matjaž, Vek, Viljem, Janković, Biljana, Poljanšek, Ida
Format Journal Article
LanguageEnglish
Published Abingdon Taylor & Francis 02.12.2022
Taylor & Francis Ltd
Taylor & Francis Group
Subjects
Aerogels
Biocompatibility
Cellulose
compression
Cyclic loads
Dimensional stability
Human tissues
hydrogel
Hydrogels
Mechanical properties
mercerization
Nanofibrillated cellulose
Neutralization
Porosity
Rheological properties
Rheology
shear properties
Sodium hydroxide
water absorption
丝光化
剪切特性
压缩
吸水率
水凝胶
纳米原纤化纤维素
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Summary:Hydrogels are classified as a three-dimensional network system, capable of retaining large amounts of water while preserving their shape and dimensional stability. Due to their natural origin and biocompatibility with human tissue, cellulose nanofibrils are often considered to be promising candidates for bioactive hydrogels preparation. For such applications, their responsiveness under different types of mechanical load, including multiple cyclic compressions, is of crucial importance. In the present study, cellulose nanofibril-based hydrogels were initiated though a simple alkali neutralization treatment. Structural, rheological and compressive features were investigated as a function of elevated NaOH concentration and physical gelling conditions. It was found that a sufficiently concentrated alkaline solution allows the formation of mechanically robust cellulose nanofibril hydrogels, which can be dried to the state of ultralight material, aerogel, of low density (0.057 g cm −3 ), superior porosity (96.2%), super water absorbant capacity (1200%), and exceptional shear and compressive load resilience with elasticity modulus of 9.3 kPa. These outstanding characteristics can be predominantly attributed to the polymorphic conversion of cellulose I to cellulose II, which results from the mercerization of cellulose nanofibrils and creates a stable and firm hydrogels texture.
ISSN:1544-0478
1544-046X
DOI:10.1080/15440478.2022.2123879