Understanding Gel-Powers: Exploring Rheological Marvels of Acrylamide/Sodium Alginate Double-Network Hydrogels

Shi Chang Wang; Shu Tong Du; Saud Hashmi; Shu Ming Cui; Ling Li; Stephan Handschuh-Wang; Xuechang Zhou; Florian J. Stadler

doi:10.3390/molecules28124868

Understanding Gel-Powers: Exploring Rheological Marvels of Acrylamide/Sodium Alginate Double-Network Hydrogels

Shi Chang Wang
, Shu Tong Du
, Saud Hashmi
, Shu Ming Cui
, Ling Li
, Stephan Handschuh-Wang
, Xuechang Zhou
, Florian J. Stadler^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

20 Scopus citations

Abstract

This study investigates the rheological properties of dual-network hydrogels based on acrylamide and sodium alginate under large deformations. The concentration of calcium ions affects the nonlinear behavior, and all gel samples exhibit strain hardening, shear thickening, and shear densification. The paper focuses on systematic variation of the alginate concentration—which serves as second network building blocks—and the Ca²⁺-concentration—which shows how strongly they are connected. The precursor solutions show a typical viscoelastic solution behavior depending on alginate content and pH. The gels are highly elastic solids with only relatively small viscoelastic components, i.e., their creep and creep recovery behavior are indicative of the solid state after only a very short time while the linear viscoelastic phase angles are very small. The onset of the nonlinear regime decreases significantly when closing the second network (alginate) upon adding Ca²⁺, while at the same time the nonlinearity parameters (Q₀, I₃/I₁, S, T, e₃/e₁, and v₃/v₁) increase significantly. Further, the tensile properties are significantly improved by closing the alginate network by Ca²⁺ at intermediate concentrations.

Original language	English
Article number	4868
Journal	Molecules
Volume	28
Issue number	12
DOIs	https://doi.org/10.3390/molecules28124868
State	Published - Jun 2023
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2023 by the authors.

Keywords

Fourier transform rheology
acrylamide
double network hydrogel
large amplitude oscillatory shear
sodium alginate

ASJC Scopus subject areas

Analytical Chemistry
Chemistry (miscellaneous)
Molecular Medicine
Pharmaceutical Science
Drug Discovery
Physical and Theoretical Chemistry
Organic Chemistry

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@article{446994ce3ae2434da42582e396f5698a,

title = "Understanding Gel-Powers: Exploring Rheological Marvels of Acrylamide/Sodium Alginate Double-Network Hydrogels",

abstract = "This study investigates the rheological properties of dual-network hydrogels based on acrylamide and sodium alginate under large deformations. The concentration of calcium ions affects the nonlinear behavior, and all gel samples exhibit strain hardening, shear thickening, and shear densification. The paper focuses on systematic variation of the alginate concentration—which serves as second network building blocks—and the Ca2+-concentration—which shows how strongly they are connected. The precursor solutions show a typical viscoelastic solution behavior depending on alginate content and pH. The gels are highly elastic solids with only relatively small viscoelastic components, i.e., their creep and creep recovery behavior are indicative of the solid state after only a very short time while the linear viscoelastic phase angles are very small. The onset of the nonlinear regime decreases significantly when closing the second network (alginate) upon adding Ca2+, while at the same time the nonlinearity parameters (Q0, I3/I1, S, T, e3/e1, and v3/v1) increase significantly. Further, the tensile properties are significantly improved by closing the alginate network by Ca2+ at intermediate concentrations.",

keywords = "Fourier transform rheology, acrylamide, double network hydrogel, large amplitude oscillatory shear, sodium alginate",

author = "Wang, \{Shi Chang\} and Du, \{Shu Tong\} and Saud Hashmi and Cui, \{Shu Ming\} and Ling Li and Stephan Handschuh-Wang and Xuechang Zhou and Stadler, \{Florian J.\}",

note = "Publisher Copyright: {\textcopyright} 2023 by the authors.",

year = "2023",

month = jun,

doi = "10.3390/molecules28124868",

language = "English",

volume = "28",

journal = "Molecules",

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T2 - Exploring Rheological Marvels of Acrylamide/Sodium Alginate Double-Network Hydrogels

AU - Wang, Shi Chang

AU - Du, Shu Tong

AU - Hashmi, Saud

AU - Cui, Shu Ming

AU - Li, Ling

AU - Handschuh-Wang, Stephan

AU - Zhou, Xuechang

AU - Stadler, Florian J.

PY - 2023/6

Y1 - 2023/6

N2 - This study investigates the rheological properties of dual-network hydrogels based on acrylamide and sodium alginate under large deformations. The concentration of calcium ions affects the nonlinear behavior, and all gel samples exhibit strain hardening, shear thickening, and shear densification. The paper focuses on systematic variation of the alginate concentration—which serves as second network building blocks—and the Ca2+-concentration—which shows how strongly they are connected. The precursor solutions show a typical viscoelastic solution behavior depending on alginate content and pH. The gels are highly elastic solids with only relatively small viscoelastic components, i.e., their creep and creep recovery behavior are indicative of the solid state after only a very short time while the linear viscoelastic phase angles are very small. The onset of the nonlinear regime decreases significantly when closing the second network (alginate) upon adding Ca2+, while at the same time the nonlinearity parameters (Q0, I3/I1, S, T, e3/e1, and v3/v1) increase significantly. Further, the tensile properties are significantly improved by closing the alginate network by Ca2+ at intermediate concentrations.

AB - This study investigates the rheological properties of dual-network hydrogels based on acrylamide and sodium alginate under large deformations. The concentration of calcium ions affects the nonlinear behavior, and all gel samples exhibit strain hardening, shear thickening, and shear densification. The paper focuses on systematic variation of the alginate concentration—which serves as second network building blocks—and the Ca2+-concentration—which shows how strongly they are connected. The precursor solutions show a typical viscoelastic solution behavior depending on alginate content and pH. The gels are highly elastic solids with only relatively small viscoelastic components, i.e., their creep and creep recovery behavior are indicative of the solid state after only a very short time while the linear viscoelastic phase angles are very small. The onset of the nonlinear regime decreases significantly when closing the second network (alginate) upon adding Ca2+, while at the same time the nonlinearity parameters (Q0, I3/I1, S, T, e3/e1, and v3/v1) increase significantly. Further, the tensile properties are significantly improved by closing the alginate network by Ca2+ at intermediate concentrations.

KW - Fourier transform rheology

KW - acrylamide

KW - double network hydrogel

KW - large amplitude oscillatory shear

KW - sodium alginate

UR - https://www.scopus.com/pages/publications/85163573841

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DO - 10.3390/molecules28124868

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AN - SCOPUS:85163573841

SN - 1420-3049

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JF - Molecules

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M1 - 4868

ER -

Understanding Gel-Powers: Exploring Rheological Marvels of Acrylamide/Sodium Alginate Double-Network Hydrogels

Abstract

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Keywords

ASJC Scopus subject areas

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