Highly Stretchable and Highly Resilient Polymer–Clay Nanocomposite Hydrogels with Low Hysteresis

Su, Xing; Muthusubramanian, Shanmugam; Edirisinghe, Mohan; Chen, Biqiong

doi:10.1021/acsami.7b05261

Cited by 77 publications

(102 citation statements)

References 69 publications

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“…Not only this, the cross‐linking density and inter‐crosslinking molecular weight cannot be controlled separately. When the concentration of the cross‐linker is high, heterogeneous aggregation of the cross‐linking points occurs . Hydrogels that have been chemically cross‐linked are thus limited in terms of their morphology, mechanical strength, and optical transparency .…”

Section: Applicationsmentioning

confidence: 99%

“…When the concentration of the cross-linker is high, heterogeneous aggregation of the crosslinking points occurs. [95] Hydrogels that have been chemically cross-linked are thus limited in terms of their morphology, mechanical strength, and optical transparency. [96] Although ultra-stretchable, self-healing, and tough hydrogels can be synthesized through physically cross-linking, for example, from polyacrylamide-montmorillonite (PAM-MMT), it is difficult to achieve low hysteresis, and therefore optimum mechanical properties, as some of the organic-inorganic cross-links will break.…”

Section: Hydrogelsmentioning

confidence: 99%

“…Our laboratory, in association with Chen and coworkers, used PG to fabricate PAM-clay nanocomposite hydrogel fibers, exhibiting low hysteresis. [95] To do this, in situ polymerization of acrylamide (AM) in the presence of MMT or chitosan− treated MMT (CHI−MMT) was conducted at 60 °C, instead of with a catalyst, to allow for chain grafting and branching. The radical initiator attacked the hydroxyl groups of the polysaccharide chains to generate alkoxy radicals, initiating polymerization of AM.…”

Section: Hydrogelsmentioning

confidence: 99%

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Developments in Pressurized Gyration for the Mass Production of Polymeric Fibers

Heseltine

Ahmed

Edirisinghe

2018

Macro Materials & Eng

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107

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In this invited feature article, the invention of pressurized gyration in 2013 and its subsequent development into sister processes such as pressurized melt gyration, infusion gyration, and pressure‐coupled infusion gyration is elucidated. The fundamentals of these processes are discussed, elucidating how these novel methods can be used to facilitate mass production of polymeric fibers and other morphologies. The effects of the main system parameters: rotational speed and gas pressure, are discussed along with the influence of solution parameters such as viscosity and polymer chain entanglement. The effect of flow of material into the gyrator in infused gyration is also illustrated. Examples of many polymers that have been subjected to these processes are discussed and the applications of resulting products are illustrated under several different research themes such as, tissue engineering, drug delivery, diagnostics, hydrogels, filtration, and wound healing.

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Section: Applicationsmentioning

confidence: 99%

Section: Hydrogelsmentioning

confidence: 99%

Section: Hydrogelsmentioning

confidence: 99%

See 1 more Smart Citation

Developments in Pressurized Gyration for the Mass Production of Polymeric Fibers

Heseltine

Ahmed

Edirisinghe

2018

Macro Materials & Eng

Self Cite

119

107

View full text Add to dashboard Cite

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“…And then the in situ polymerizations of hydrogels were occurred to obtain hydrogels with stable structure and excellent mechanical properties. In situ growth of NC gels is usually suitable for NPs with intrinsic functions but hardly surface modified, for example, polyaniline NPs, metal and metal‐oxide NPs . Physical mixing is a simple route to compound NC gels by polymer and NPs directly.…”

Section: Nps For Nanocomposite Hydrogelsmentioning

confidence: 99%

“…Typically, due to the reversible physical interactions between polymers and NPs, the overload mechanical stress on the NC gels could be effectively dissipated by spreading along with the polymer chains mutually rather than concentrated. As a result, the NC gel is less likely to form micro cracks under mechanical stress, which avoids widespread failure and endows the NC gel with good mechanical properties …”

Section: Properties Of Nanocomposite Hydrogelsmentioning

confidence: 99%

Nanoparticle–Polymer Synergies in Nanocomposite Hydrogels: From Design to Application

Chen

Hou

Ren

et al. 2018

Macromol. Rapid Commun.

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Hydrogels are an important class of soft materials with high water retention that exhibit intelligent and elastic properties and have promising applications in the fields of biomaterials, soft machines, and artificial tissue. However, the low mechanical strength and limited functions of traditional chemically cross-linked hydrogels restrict their further applications. Natural materials that consist of stiff and soft components exhibit high mechanical strength and functionality. Among artificial soft materials, nanocomposite hydrogels are analogous to these natural materials because of the synergistic effects of nanoparticle (NP) polymers in hydrogels construction. In this article, the structural design and properties of nanocomposite hydrogels are summarized. Furthermore, along with the development of nanocomposite hydrogel-based devices, the shaping and potential applications of hydrogel devices in recent years are highlighted. The influence of the interactions between NPs and polymers on the dispersion as well as the structural stability of nanocomposite hydrogels is discussed, and the novel stimuli-responsive properties induced by the synergies between functional NPs and polymeric networks are reviewed. Finally, recent progress in the preparation and applications of nanocomposite hydrogels is highlighted. Interest in this field is growing, and the future and prospects of nanocomposite hydrogels are also reviewed.

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Spatiotemporally Controlled Photoresponsive Hydrogels: Design and Predictive Modeling from Processing through Application

Zhu

Yang

et al. 2020

Adv Funct Materials

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Photoresponsive hydrogels (PRHs) are soft materials whose mechanical and chemical properties can be tuned spatially and temporally with relative ease. Both photo‐crosslinkable and photodegradable hydrogels find utility in a range of biomedical applications that require tissue‐like properties or programmable responses. Progress in engineering with PRHs is facilitated by the development of theoretical tools that enable optimization of their photochemistry, polymer matrices, nanofillers, and architecture. This review brings together models and design principles that enable key applications of PRHs in tissue engineering, drug delivery, and soft robotics, and highlights ongoing challenges in both modeling and application.

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Highly Stretchable and Highly Resilient Polymer–Clay Nanocomposite Hydrogels with Low Hysteresis

Cited by 77 publications

References 69 publications

Developments in Pressurized Gyration for the Mass Production of Polymeric Fibers

Developments in Pressurized Gyration for the Mass Production of Polymeric Fibers

Nanoparticle–Polymer Synergies in Nanocomposite Hydrogels: From Design to Application

Spatiotemporally Controlled Photoresponsive Hydrogels: Design and Predictive Modeling from Processing through Application

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