Synthesis of poly(acrylic acid)–Fe<sup>3+</sup>/gelatin/poly(vinyl alcohol) triple‐network supramolecular hydrogels with high toughness, high strength and self‐healing properties

Jing, Zhanxin; Zhang, Qiangshan; Liang, Yan‐Qiu; Zhang, Zhaoxia; Hong, Pengzhi; Li, Yong

doi:10.1002/pi.5876

Cited by 33 publications

(16 citation statements)

References 41 publications

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“…The tensile curves clearly showed that with the increasing self-healing time, the recovery degree of mechanical properties became higher, and the sample could be recovered almost entirely after 48 h of contact at RT (Figure 4C), which could be a synergic effect of metal migration and coordination, hydrogen bonding, and electrostatic interactions between the two polymer networks. 38 In addition, Figure 4D showed the healing of electrical conductivity after putting two separated pieces of gels together in which the conductivity could be rapidly recovered within seconds. Both the mechanical and electrical self-healing performance could satisfy the demand of fabricating self-healing stretchable devices, in which the healing could be accelerated with external heat activation according to previous literatures.…”

Section: ■ Results and Discussionmentioning

confidence: 97%

“…Both the mechanical and electrical self-healing performance could satisfy the demand of fabricating self-healing stretchable devices, in which the healing could be accelerated with external heat activation according to previous literatures. 7,38,41 Regarding the degradation performance, unlike single-network gelatin organohydrogel 7 or Fe 3+ -cross-linked PAA hydrogel 24 that could turn into the liquid state in DI water after a few days, the GEL/PAA-GL organohydrogels were found to be stable in water for at least 1 week owing to the stronger interactions between gelatin and PAA networks. However, by elevating the temperature or adding other reagents such as glycerol or sodium citrate to dissociate the metal ions from carboxyl groups, the degradation time of GEL/PAA-GL could be remarkably reduced.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

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Stretchable, Healable, and Degradable Soft Ionic Microdevices Based on Multifunctional Soaking-Toughened Dual-Dynamic-Network Organohydrogel Electrolytes

Fang

Zhang

Wang

et al. 2020

ACS Appl. Mater. Interfaces

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Electronic materials and devices that can mimic biological systems featured with elasticity, toughness, self-healing, degradability, and environmental friendliness drive the technological developments in fields spanning from bioelectronics, biomedical diagnosis and therapy, electronic skin, and soft robotics to Internetof-Things with "green" electronics. Among them, ionic devices based on gel electrolytes have emerged as attractive candidates for biomimetic systems. Herein, we presented a straightforward approach to demonstrate soft ionic microdevices based on a versatile organohydrogel platform acting as both a free-standing, stretchable, adhesive, healable, and entirely degradable support and a highly conductive, dehydration-and freezing-tolerant electrolyte. This is achieved by forming a gelatin/ferric-ion-cross-linked polyacrylic acid (GEL/PAA) dual dynamic supramolecular network followed by soaking into a NaCl glycerol/water solution to further toughen the gelatin network via solvent displacement, thus obtaining a high toughness of 1.34 MJ•cm −3 and a high ionic conductivity (>7 mS•cm −1 ). Highly stretchable and multifunctional ionic microdevices are then fabricated based on the organohydrogel electrolytes by simple transfer printing of carbon-based microelectrodes onto the prestretched gel surface. Proof-of-concept microdevices including resistive strain sensors and microsupercapacitors are demonstrated, which displayed outstanding stretchability to 300% strain, resistance to dehydration for >6 months, autonomous self-healing, and rapid room-temperature degradation within hours. The present material design and fabrication approach for the organohydrogel-based ionic microdevices will provide promising scope for life-like and sustainable electronic systems.

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Section: ■ Results and Discussionmentioning

confidence: 97%

Section: ■ Results and Discussionmentioning

confidence: 99%

Stretchable, Healable, and Degradable Soft Ionic Microdevices Based on Multifunctional Soaking-Toughened Dual-Dynamic-Network Organohydrogel Electrolytes

Fang

Zhang

Wang

et al. 2020

ACS Appl. Mater. Interfaces

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“…At the same time, gelatin molecules were entrapped in the network of PMAA and, after cooling down to 4°C, formed physical cross‐links due to triple helices formation. [ 32 ] Water entrapped in the structure of hydrogels acted as a porogen, contributing to the high porosity of the hydrogels. The resulting materials were constituted from highly porous interpenetrating networks of covalently cross‐linked PMAA and physically cross‐linked gelatin.…”

Section: Resultsmentioning

confidence: 99%

Strong and tough, pH sensible, interpenetrating network hydrogels based on gelatin and poly(methacrylic acid)

Ugrinović

Panic

Spasojević

et al. 2021

Polymer Engineering & Sci

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Hydrogels are promising materials for biomedical applications due to highly hydrated, porous, permeable structure with possibility to accommodate living cells, drugs, or bioactive factors. In this paper, we reported poly(methacrylic acid) (PMAA)/gelatin IPN hydrogels, synthesized by free-radical polymerization, with adjustable mechanical, structural, physicochemical, and biological characteristics. The influence of methacrylic acid (MAA), gelatin, and crosslinker in the precursor solution on hydrogels properties was investigated. The increasing concentration of MAA, gelatin, and cross-linker led to better mechanical properties, lower porosity, and water content. The compressive mechanical properties of hydrogels were significantly better in comparison to a single-network PMAA hydrogel, while the obtained compressive strength values up to 16 MPa were comparable with tough hydrogels. The increasing concentration of MAA and cross-linker reduced fatigue resistance and degradability, while the increase in gelatin content acted in the opposite way. Swelling tests in different pH conditions demonstrated strong pH-sensibility of the hydrogels, which was more pronounced as MAA concentration was higher, and gelatin and cross-linker concentrations were lower. In addition, the hydrogels strongly promoted the proliferation of human periodontal ligament stem cells and MRC-5 cells as assayed by MTT assay.

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“…Tensile tests of the composite hydrogels were conducted with reference to the ASTM D638 standard, with slight modification [45]. Uniaxial tensile tests on rectangular hydrogel strips (50 mm × 10 mm × 1.0 mm) were performed on an Instron 5567 universal testing machine at a crosshead speed of 10 mm/min.…”

Section: Physical Properties Of Sipc Hydrogelsmentioning

confidence: 99%

Supramolecular ionic polymer/carbon nanotube composite hydrogels with enhanced electromechanical performance

Zhang

Chen

et al. 2020

Nanotechnology Reviews

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AbstractElectroactive hydrogels have received increasing attention due to the possibility of being used in biomimetics, such as for soft robotics and artificial muscles. However, the applications are hindered by the poor mechanical properties and slow response time. To address these issues, in this study, supramolecular ionic polymer–carbon nanotube (SIPC) composite hydrogels were fabricated via in situ free radical polymerization. The polymer matrix consisted of carbon nanotubes (CNTs), styrene sulfonic sodium (SSNa), β-cyclodextrin (β-CD)-grafted acrylamide, and ferrocene (Fc)-grafted acrylamide, with the incorporation of SSNa serving as the ionic source. On applying an external voltage, the ions accumulate on one side of the matrix, leading to localized swelling and bending of the structure. Therefore, a controllable and reversible actuation can be achieved by changing the applied voltage. The tensile strength of the SIPC was improved by over 300%, from 12 to 49 kPa, due to the reinforcement effect of the CNTs and the supramolecular host–guest interactions between the β-CD and Fc moieties. The inclusion of CNTs not only improved the tensile properties but also enhanced the ion mobility, which lead to a faster electromechanical response. The presented electro-responsive composite hydrogel shows a high potential for the development of robotic devices and soft smart components for sensing and actuating applications.

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Synthesis of poly(acrylic acid)–Fe³⁺/gelatin/poly(vinyl alcohol) triple‐network supramolecular hydrogels with high toughness, high strength and self‐healing properties

Cited by 33 publications

References 41 publications

Stretchable, Healable, and Degradable Soft Ionic Microdevices Based on Multifunctional Soaking-Toughened Dual-Dynamic-Network Organohydrogel Electrolytes

Stretchable, Healable, and Degradable Soft Ionic Microdevices Based on Multifunctional Soaking-Toughened Dual-Dynamic-Network Organohydrogel Electrolytes

Strong and tough, pH sensible, interpenetrating network hydrogels based on gelatin and poly(methacrylic acid)

Supramolecular ionic polymer/carbon nanotube composite hydrogels with enhanced electromechanical performance

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Synthesis of poly(acrylic acid)–Fe3+/gelatin/poly(vinyl alcohol) triple‐network supramolecular hydrogels with high toughness, high strength and self‐healing properties

Cited by 33 publications

References 41 publications

Stretchable, Healable, and Degradable Soft Ionic Microdevices Based on Multifunctional Soaking-Toughened Dual-Dynamic-Network Organohydrogel Electrolytes

Stretchable, Healable, and Degradable Soft Ionic Microdevices Based on Multifunctional Soaking-Toughened Dual-Dynamic-Network Organohydrogel Electrolytes

Strong and tough, pH sensible, interpenetrating network hydrogels based on gelatin and poly(methacrylic acid)

Supramolecular ionic polymer/carbon nanotube composite hydrogels with enhanced electromechanical performance

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Product

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Synthesis of poly(acrylic acid)–Fe³⁺/gelatin/poly(vinyl alcohol) triple‐network supramolecular hydrogels with high toughness, high strength and self‐healing properties