Tough and recoverable triple‐network hydrogels based on multiple pairs of toughing mechanisms with excellent ionic conductivity as stable strain sensors

Li, Shuai; Bu, Ximan; Wu, Linlin; Ma, Xiaofeng; Diao, Wenjing; Zhuang, Zhenzhen; Zhou, Yongmin

doi:10.1002/pen.25164

Cited by 22 publications

(13 citation statements)

References 43 publications

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“…A,B) Plots of the compressive versus tensile strength and modulus for BC–PVA–PAMPS (this work) and other strong hydrogels (see Table S1 in the Supporting Information for data and references). [ 13–35 ] The multiple data points for BC–PVA–PAMPS are for different compositions. C) BC–PVA–PAMPS easily bears the weight of a 100 lb.…”

Section: Introductionmentioning

confidence: 99%

A Synthetic Hydrogel Composite with the Mechanical Behavior and Durability of Cartilage

Yang

Zhao

Koshut

et al. 2020

Adv Funct Materials

216

178

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This article reports the first hydrogel with the strength and modulus of cartilage in both tension and compression, and the first to exhibit cartilage‐equivalent tensile fatigue strength at 100 000 cycles. These properties are achieved by infiltrating a bacterial cellulose (BC) nanofiber network with a poly(vinyl alcohol) (PVA)–poly(2‐acrylamido‐2‐methyl‐1‐propanesulfonic acid sodium salt) (PAMPS) double network hydrogel. The BC provides tensile strength in a manner analogous to collagen in cartilage, while the PAMPS provides a fixed negative charge and osmotic restoring force similar to the role of aggrecan in cartilage. The hydrogel has the same aggregate modulus and permeability as cartilage, resulting in the same time‐dependent deformation under confined compression. The hydrogel is not cytotoxic, has a coefficient of friction 45% lower than cartilage, and is 4.4 times more wear‐resistant than a PVA hydrogel. The properties of this hydrogel make it an excellent candidate material for replacement of damaged cartilage.

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Section: Introductionmentioning

confidence: 99%

A Synthetic Hydrogel Composite with the Mechanical Behavior and Durability of Cartilage

Yang

Zhao

Koshut

et al. 2020

Adv Funct Materials

216

178

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“…Among DC hydrogels, DPC hydrogels [38] attract much more attention due to their excellent stiffness, toughness, anti-fatigue, and selfrecoverability. Diverse physical interactions could be utilized to construct DPC hydrogels, such as hydrogen bonding, [39,40] hostguest interaction, [41,42] ionic coordination (IC), [43,44] HA, [45,46] crystallization, [47,48] chain entanglement, [49,50] and dipole-dipole interaction. [51,52] Inspired by the synergistic enhancement of rigid and flexible networks in DN hydrogels, the synergistic effect of strong and weak interactions is anticipated to endow DPC hydrogels with outstanding mechanical performances.…”

Section: Introductionmentioning

confidence: 99%

A Dual Physical Cross‐Linking Strategy to Construct Tough Hydrogels with High Strength, Excellent Fatigue Resistance, and Stretching‐Induced Strengthening Effect

Yang

Gao

Tsou

et al. 2021

Macro Materials & Eng

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Hydrogels with excellent stiffness, toughness, anti‐fatigue, and self‐recovery properties are regarded as promising water‐containing materials. In this work, a dual physically cross‐linked (DPC) sodium alginate (SA)/poly[acrylamide (AAm)‐acrylic acid (AAc)‐octadecyl methacrylate (OMA)]‐Fe3+ hydrogel is reported, which is constructed by hydrophobic association (HA) and ionic coordination (IC). The optimal DPC hydrogel demonstrates excellent mechanical performance: tensile modulus of 0.65 MPa, tensile strength of 3.31 MPa, elongation at break of 1547%, and toughness of 27.8 MJ m–3. SA/P(AAm‐AAc‐OMA)‐Fe3+ DPC hydrogels also exhibit prominent anti‐fatigue and self‐recovery performance (99.1–109.7% modulus recovery and 90.4–108.9% dissipated energy recovery after resting for 5 min without additional stimuli at ambient temperature) through the reconstruction of reversible physical cross‐linking. Some of the SA/P(AAm‐AAc‐OMA)‐Fe3+ DPC hydrogels even exhibit a stretching‐induced strengthening effect, which is similar to the performance of muscle—“the more training, the more strength.” Hence, the combination of HA and IC will provide an effective approach to design DPC hydrogels with desirable mechanical performances and a longer service life for wider applications of soft materials.

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“…This low strain level is in part due Gels 2021, 7,101 to the fact that common cytocompatible polymer hydrogels such as alginate and gelatin methacryloyl (GelMA), along with certain explanted soft tissues, typically fail at or below 50% compressive strain [22][23][24]. In contrast, existing hydrogels optimized for very high toughness and strain tolerance are frequently unsuitable for cell encapsulation due to toxic components or inhospitable gelation conditions [25][26][27]. This limitation presents a need for hydrogel scaffolds optimized for bulk compression of encapsulated cells at very high strain.…”

Section: Introductionmentioning

confidence: 99%

Biocompatible and Enzymatically Degradable Gels for 3D Cellular Encapsulation under Extreme Compressive Strain

Clapacs

Neal

Schuftan

et al. 2021

Gels

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Cell encapsulating scaffolds are necessary for the study of cellular mechanosensing of cultured cells. However, conventional scaffolds used for loading cells in bulk generally fail at low compressive strain, while hydrogels designed for high toughness and strain resistance are generally unsuitable for cell encapsulation. Here we describe an alginate/gelatin methacryloyl interpenetrating network with multiple crosslinking modes that is robust to compressive strains greater than 70%, highly biocompatible, enzymatically degradable and able to effectively transfer strain to encapsulated cells. In future studies, this gel formula may allow researchers to probe cellular mechanosensing in bulk at levels of compressive strain previously difficult to investigate.

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Tough and recoverable triple‐network hydrogels based on multiple pairs of toughing mechanisms with excellent ionic conductivity as stable strain sensors

Cited by 22 publications

References 43 publications

A Synthetic Hydrogel Composite with the Mechanical Behavior and Durability of Cartilage

A Synthetic Hydrogel Composite with the Mechanical Behavior and Durability of Cartilage

A Dual Physical Cross‐Linking Strategy to Construct Tough Hydrogels with High Strength, Excellent Fatigue Resistance, and Stretching‐Induced Strengthening Effect

Biocompatible and Enzymatically Degradable Gels for 3D Cellular Encapsulation under Extreme Compressive Strain

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