Bioinspired Self-Healing of Kinetically Inert Hydrogels Mediated by Chemical Nutrient Supply

Zhong, Yuanbo; Li, Panpan; Hao, Jingcheng; Xu, Weifeng

doi:10.1021/acsami.9b20445

Cited by 50 publications

(80 citation statements)

References 46 publications

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“…S4, † than compound 3. 51 Because of this, gelation occurs rapidly at low pH as compared to that at high pH. These observations are quite similar to the polymer system reported by Wang group, where the formation of acylhydrazone bonds was efficient at a low initial pH of 4 and further activation of the acylhydrazone bonds through protonation not only led to rapid hydrogelation but also allowed good healing capability under acidic condition.…”

Section: Resultssupporting

confidence: 87%

“…These observations are quite similar to the polymer system reported by Wang group, where the formation of acylhydrazone bonds was efficient at a low initial pH of 4 and further activation of the acylhydrazone bonds through protonation not only led to rapid hydrogelation but also allowed good healing capability under acidic condition. 51 However, when the pH is sufficiently low, all the molecules of 3 become protonated and we assume destroy the hydrogen bonded network through electrostatic repulsion. The increased polarity of the compound then aids the dissolution of the gel.…”

Section: Resultsmentioning

confidence: 99%

“…S4 †), leading to an orange coloured transient hydrogel. 51 In presence of base, no such seeding-induced self-assembly occurs. Rather, the system spontaneously drives to a thermodynamically stable yet kinetically trapped yellow coloured hydrogel over time.…”

Section: Resultsmentioning

confidence: 99%

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Programming properties of transient hydrogels by an enzymatic reaction

et al. 2020

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Section: Resultssupporting

confidence: 87%

Section: Resultsmentioning

confidence: 99%

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Programming properties of transient hydrogels by an enzymatic reaction

et al. 2020

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“…Reprinted with permissions. 5 , 15 , 32 , 60 , 63 , 70 , 73 Copyright Wiley-VCH, American Chemical Society, and Royal Society of Chemistry.…”

Section: Introductionmentioning

confidence: 99%

“… 32 , 60 − 62 The initial use of enzymatic reactions in polymeric hydrogels is for material construction, 63 − 65 and then followed by enzymatic fabrication of healable polymeric hydrogels 60 , 66 − 70 and enzymatically regulated healing of polymeric hydrogels. 32 , 71 , 72 The latest progress of this field is to use the enzymatic reaction to mediate the transient healing ability of polymeric hydrogels, 73 , 74 which not only enables the fabrication of thermodynamically stable and kinetically inert hydrogels but also endows such hydrogels with an intrinsic healing ability on demand.…”

Section: Introductionmentioning

confidence: 99%

Enzyme-Regulated Healable Polymeric Hydrogels

Zhong

et al. 2020

ACS Cent. Sci.

Self Cite

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The enzyme-regulated healable polymeric hydrogels are a kind of emerging soft material capable of repairing the structural defects and recovering the hydrogel properties, wherein their fabrication, self-healing, or degradation is mediated by enzymatic reactions. Despite achievements that have been made in controllable cross-linking and de-cross-linking of hydrogels by utilizing enzyme-catalyzed reactions in the past few years, this substrate-specific strategy for regulating healable polymeric hydrogels remains in its infancy, because both the intelligence and practicality of current man-made enzyme-regulated healable materials are far below the levels of living organisms. A systematic summary of current achievements and a reasonable prospect at this point can play positive roles for the future development in this field. This Outlook focuses on the emerging and rapidly developing research area of bioinspired enzyme-regulated self-healing polymeric hydrogel systems. The enzymatic fabrication and degradation of healable polymeric hydrogels, as well as the enzymatically regulated self-healing of polymeric hydrogels, are reviewed. The functions and applications of the enzyme-regulated healable polymeric hydrogels are discussed.

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Environmentally Adaptive Polymer Hydrogels: Maintaining Wet‐Soft Features in Extreme Conditions

Lei

Chen

Guo

et al. 2023

Adv Funct Materials

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Hydrogels have been widely explored to adapt to different application circumstances. As typical wet‐soft materials, the high‐water content of hydrogels is beneficial to their wide biomedical applications. Moreover, hydrogels have been displaying considerable application potential in some high‐tech areas, like brain‐computer interface, intelligent actuator, flexible sensor, etc. However, traditional hydrogel is susceptive to freezing below zero, dehydration, performance swelling‐induced deformation, and suffers from mechanical damage in extremely mechanical environments, which result in the loss of wet‐soft peculiarities (e.g., flexibility, structure integrity, transparency), greatly limiting their applications. Therefore, reducing the freezing point, improving the dehydration/solution resistance, and designing mechanical adaptability are effective strategies to endow hydrogels with the extreme environmental adaptability, thus broadening their application fields. This review systematically summarizes research advances of environmentally adaptive hydrogels (EAHs), comprising anti‐freezing, dehydration‐resistant, acid/base/swelling deformation‐resistant, and mechanical environment adaptive hydrogels (MEAHs). Firstly, fabrication methods are presented, including the deep eutectic solvent/ionic liquid substituent, the addition of salts, organogel, polymer network modification, and double network (DN) complex/nanocomposite strategy, etc. Meanwhile, the features of different approaches are overviewed. The mechanisms, properties, and applications (e.g., intelligent actuator, wound dressing, flexible sensor) of EAHs are demonstrated. Finally, the issues and future perspectives for EAHs’ researches are demonstrated.

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Bioinspired Self-Healing of Kinetically Inert Hydrogels Mediated by Chemical Nutrient Supply

Cited by 50 publications

References 46 publications

Programming properties of transient hydrogels by an enzymatic reaction

Programming properties of transient hydrogels by an enzymatic reaction

Enzyme-Regulated Healable Polymeric Hydrogels

Environmentally Adaptive Polymer Hydrogels: Maintaining Wet‐Soft Features in Extreme Conditions

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