Issue 45, 2021

Stress relaxation in tunable gels

Abstract

Hydrogels are a staple of biomaterials development. Optimizing their use in e.g. drug delivery or tissue engineering requires a solid understanding of how to adjust their mechanical properties. Here, we present a numerical study of a class of hydrogels made of 4-arm star polymers with a combination of covalent and reversible crosslinks. This design principle combines the flexibility and responsivity associated with reversible linkers with stability provided by chemical crosslinks. In molecular dynamics simulations of such hybrid gel networks, we observe that the strength of the reversible bonds can tune the material from solid to fluid. We identify at what fraction of reversible bonds this tunability is most pronounced, and find that the stress relaxation time of the gels in this tunable regime is set directly by the average lifetime of the reversible bonds. As our design is easy to realize in the already widely-used tetraPEG gel setting, our work will provide guidelines to improve the mechanical performance of biomedical gels.

Graphical abstract: Stress relaxation in tunable gels

Article information

Article type
Paper
Submitted
18 Jan 2021
Accepted
25 Mar 2021
First published
26 Mar 2021
This article is Open Access
Creative Commons BY-NC license

Soft Matter, 2021,17, 10254-10262

Stress relaxation in tunable gels

C. Raffaelli and W. G. Ellenbroek, Soft Matter, 2021, 17, 10254 DOI: 10.1039/D1SM00091H

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