A pH, glucose, and dopamine triple-responsive, self-healable adhesive hydrogel formed by phenylborate–catechol complexation

Meng, Shuxian; Gong, Chu; Li, Bingqiang; Wu, Guolin

doi:10.1039/c7py00519a

Cited by 125 publications

(81 citation statements)

References 53 publications

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“…This kind of physical adsorption‐based adhesion may also be applicable for various dry surfaces (e.g., metals, ceramics, and plastics) and wet surfaces (e.g., hydrogels and biotissues); however, future extensive studies should be carried out to further clarify this. The adhesive property of our system is comparable to commonly used mussel‐inspired catechol‐based hydrogels and other recently developed adhesive hydrogels that rely on supramolecular interactions for adhesion (Table S1, Supporting Information) . Notably, while most adhesive hydrogels (apart from nanoparticle adhesives) require internal modification of the chemical structure—which ultimately changes the properties compared to the original unmodified hydrogel—our strategy only alters the surface structure.…”

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confidence: 62%

“…The adhesive property of our system is comparable to commonly used mussel-inspired catechol-based hydrogels and other recently developed adhesive hydrogels that rely on supramolecular interactions for adhesion (Table S1, Supporting Information). [26][27][28][29][30][31] Notably, while most adhesive hydrogels (apart from nanoparticle adhesives) require internal modification of the chemical structure-which ultimately changes the properties compared to the original unmodified hydrogel-our strategy only alters the surface structure. Hence, this approach could be used to easily turn various nonadhesive hydrogels into adhesive hydrogels, while retaining the original bulk properties.…”

mentioning

confidence: 99%

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Double‐Hydrophobic‐Coating through Quenching for Hydrogels with Strong Resistance to Both Drying and Swelling

Mredha

Cui

et al. 2020

Advanced Science

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In recent years, various hydrogels with a wide range of functionalities have been developed. However, owing to the two major drawbacks of hydrogels—air‐drying and water‐swelling—hydrogels developed thus far have yet to achieve most of their potential applications. Herein, a bioinspired, facile, and versatile method for fabricating hydrogels with high stability in both air and water is reported. This method includes the creation of a bioinspired homogeneous fusion layer of a hydrophobic polymer and oil in the outermost surface layer of the hydrogel via a double‐hydrophobic‐coating produced through quenching. As a proof‐of‐concept, this method is applied to a polyacrylamide hydrogel without compromising its mechanical properties. The coated hydrogel exhibits strong resistance to both drying in air and swelling in multiple aqueous environments. Furthermore, the versatility of this method is demonstrated using different types of hydrogels and oils. Because this method is easy to apply and is not dependent on hydrogel surface chemistry, it can significantly broaden the scope of next‐generation hydrogels for real‐world applications in both wet and dry environments.

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confidence: 62%

mentioning

confidence: 99%

Double‐Hydrophobic‐Coating through Quenching for Hydrogels with Strong Resistance to Both Drying and Swelling

Mredha

Cui

et al. 2020

Advanced Science

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“…Finally, we demonstrate that these materials can be used as bulk cell encapsulants for cell delivery applications aimed to soft tissue engineering applications, [69][70][71][72] owing to the mild mixing and recovery conditions for their preparation and reconstruction. Such functionalities in terms of multi-responsiveness and healability, combined with excellent cytocompatible properties, have not been extensively exploited in previous boronic acid-based studies, 33,60,64,73 and hence, we anticipate that our study will be inspirational towards the development of functionally more complex, yet synthetically accessible, materials for the biomedical field.…”

Section: Introductionmentioning

confidence: 99%

“…The cytotoxicity of the constructs was assessed by an extraction test according to ISO 10993-5 standard as described by previously published studies. 64,75,76 The gels were immersed in DMEM at an extrac- …”

Section: Cytotoxicity Assaysmentioning

confidence: 99%

“…59,60 Recently, soft healable gels based on the reversible bonding of boronic acids with diols have also emerged in the form of multi-responsive polymer blends. [61][62][63][64] Inspired by these studies and our previous work on boronate ester constructs for chemical logic operations 65 and cell surface engineering, 66,67 we designed a simple boronic acidbased nanocomposite that exhibits complex, albeit predictable, physicochemical and mechanical behaviour as a multihealable model platform for cell encapsulation. Our proposed system comprises a synthetic thermoresponsive boronic acid copolymer that is crosslinked with poly(vinyl alcohol) (PVA) to form cytocompatible hydrogels within seconds under physiological conditions (Fig.…”

Section: Introductionmentioning

confidence: 99%

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Transiently malleable multi-healable hydrogel nanocomposites based on responsive boronic acid copolymers

2018

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The design of materials that mimic aspects of self-healing, as observed in nature, is of paramount importance as they could solve a number of problems in the biomedical field, such as the elimination of (bio-) material failure after prolonged use, improved integration at the interface with living tissues and more robust biomechanical performance. In this report, we propose the fabrication of soft hydrogels comprising a polymer matrix of poly(vinyl alcohol) mixed with a thermoresponsive boronic acid copolymer that is subsequently impregnated with poly(vinyl pyrrolidone) coated gold nanoparticles. The gels are crosslinked by the formation of reversible boronate ester bonds that can be remotely disrupted by a thermal or optical stimulus, endowing the gels with thermally-induced transient malleability that is optically trackable. It is demonstrated that the gels exhibit excellent healing properties within minutes even without the application of external stimuli. The rapid formation of the gels in concert with their fast and mild gel-sol phase transition under biologically relevant conditions is demonstrated by the encapsulation and release of cells in vitro. The proposed materials constitute a versatile cytocompatible platform for the construction of remotely healable soft gels for biomedical applications.

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Bioadhesive Hydrogels and Their Applications

Chopra

Kumar²,

Singh

2020

Bioadhesives in Drug Delivery

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A pH, glucose, and dopamine triple-responsive, self-healable adhesive hydrogel formed by phenylborate–catechol complexation

Abstract: A pH, glucose, and dopamine triple-responsive, self-healable and adhesive polyethylene glycol hydrogel was developed via the formation of phenylborate–catechol complexation.

Cited by 125 publications

References 53 publications

Double‐Hydrophobic‐Coating through Quenching for Hydrogels with Strong Resistance to Both Drying and Swelling

Double‐Hydrophobic‐Coating through Quenching for Hydrogels with Strong Resistance to Both Drying and Swelling

Transiently malleable multi-healable hydrogel nanocomposites based on responsive boronic acid copolymers

Bioadhesive Hydrogels and Their Applications

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