Supramolecular dissipative self‐assembly systems: Approaches and applications

Hou, Xiao‐Fang; Chen, Xiao; Wei, Jia‐Hao; Xu, Yang; Chen, Xu‐Man; Li, Quan

doi:10.1002/rpm.20230016

Cited by 9 publications

(3 citation statements)

References 219 publications

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“… In recent decades, the explosive development of dynamic chemistry, for example, supramolecular chemistry, [5‐8] dynamic covalent chemistry, [9–13] molecular machines, [14–16] and molecular switches, [17–20] give rise to a variety of stimuli‐responsive dynamic soft materials, [21–24] including stimuli‐responsive hydrogels, which undergo macroscopic changes in response to certain external stimulistim. Schematic representation of (a) fluorescent organic hydrogel P(DMA‐DEAN)/P(SMA‐9‐ANA) and its (b) information coding/decoding process; (c) information‐coding, dual‐encryption, and dynamic fluorescent decryption procedures; (d) shape memorizing/recovering process [110] .…”

Section: Applications Of Stimuli‐responsive Fluorescent Hydrogelsmentioning

confidence: 99%

“…Hydrogels are highly hydrated, functional materials with a three‐dimensional (3D) network structure formed by cross‐linking hydrophilic gelators, [1–3] with mechanical flexibility, biocompatibility, and hydrophilicity [4] . In recent decades, the explosive development of dynamic chemistry, for example, supramolecular chemistry, [5–8] dynamic covalent chemistry, [9–13] molecular machines, [14–16] and molecular switches, [17–20] give rise to a variety of dynamic soft materials, [21–24] including stimuli‐responsive hydrogels, that can undergo macroscopic changes in response to certain external stimuli (e.g., light, heating/cooling, acid/base, mechanical forces, and one or more conditions in parallel). Some of them can mimic the adaptation of organisms to the environment in nature and have artificially controllable properties [25–27] .…”

Section: Introductionmentioning

confidence: 99%

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Stimuli‐responsive fluorescent hydrogels: Strategies and applications

Lei,

Wang,

et al. 2024

Responsive Materials

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Stimuli‐responsive fluorescent hydrogels are three‐dimensional networked polymeric materials with tunable luminescence and dynamic properties, which play an important role as a water‐rich soft material in the fields of information encryption, bionic actuation, bioimaging, environmental monitoring, and luminescent materials. Compared with conventional hydrogels, their unique luminescent properties allow the visualization of microscopic dynamics within the polymer network. By rational inclusion of dynamic motifs, such as photoswitches, AIEgens, lanthanide complexes, and host–guest complexes, these materials are endowed with tunability of emission, shape, and phase in time and space in response to environmental effectors. In this review, we summarize the fabrication strategies that are mainly used by recently reported stimuli‐responsive fluorescent hydrogels and the applications of these materials.

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Section: Applications Of Stimuli‐responsive Fluorescent Hydrogelsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Stimuli‐responsive fluorescent hydrogels: Strategies and applications

Lei,

Wang,

et al. 2024

Responsive Materials

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“…Until now, this strategy mostly focused on controlling the lifetime and nature of the transient assembly or kinetically trapped intermediates without adding any external energy forces. − Performing an inherently dissociative assembly process in the presence of an external physical energy source can bring further complexity in the outcome. − In this paper, we report on dissipative self-assembly and the corresponding spatiotemporally nonequilibrium patterning behavior in the presence of an external electric field. Herein, we use histone as the chemical fuel, which interacts with DNA (building block) and results in assembly of DNA-histone to generate chromatin-like condensates (coacervate in nature) (Figure ).…”

Section: Introductionmentioning

confidence: 99%

Enzymatic Dissociation of DNA-Histone Condensates in an Electrophoretic Setting: Modulating DNA Patterning and Hydrogel Viscoelasticity

Sivoria,

Mahato,

Priyanka

et al. 2024

Langmuir

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Closed‐Loop Recyclable Poly(ester‐disulfide)s for Potential Alternatives to Engineering Plastic

Chen,

Yang,

et al. 2024

Angewandte Chemie

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Facile fabrication, low material complexity and closed‐loop recycling are essential for polymer plastics to alter their linear product economy towards a cradle‐to‐cradle one. Covalent adaptable networks (CANs) are one way to achieve that, which intrinsically exhibit decent mechanical properties of the thermosets but could also be easily recycled like the thermoplastics. In this work, we introduce rigid ester structural motifs into dynamic poly(disulfide)s to form a series of dual polymer networks. Owning to the coherence of soft/rigid segments and the reversible sacrificial crosslinking, they exhibit tailorable properties and good resistance towards different chemicals. Their closed‐loop recycling is achieved via mild solvolysis, maintaining materials’ mechanical integrities. It offers a solution as a sustainable replacement for engineering plastics which are massively under production but hard to be recycled.

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Supramolecular dissipative self‐assembly systems: Approaches and applications

Cited by 9 publications

References 219 publications

Stimuli‐responsive fluorescent hydrogels: Strategies and applications

Stimuli‐responsive fluorescent hydrogels: Strategies and applications

Enzymatic Dissociation of DNA-Histone Condensates in an Electrophoretic Setting: Modulating DNA Patterning and Hydrogel Viscoelasticity

Closed‐Loop Recyclable Poly(ester‐disulfide)s for Potential Alternatives to Engineering Plastic

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