Highly Efficient and Environmentally Friendly Fabrication of Robust, Programmable, and Biocompatible Anisotropic, All‐Cellulose, Wrinkle‐Patterned Hydrogels for Cell Alignment

Zou, Jie; Wu, Shyi-Kuen; Chen, Jie; Lei, Xiaojuan; Li, Yongling; Yu, Hui; Tang, Shan; Ye, Dongdong

doi:10.1002/adma.201904762

Cited by 88 publications

(83 citation statements)

References 31 publications

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“…In addition, wrinkles could also serve as graphical tags since the graphical images formed by wrinkles could be identified by naked eyes due to the light scattering caused by wrinkling pattern. Owing to the randomness, 3D topography, and nondeterministic process and unpredictability of the formation, wrinkling patterns caused by a surface mechanical instability [26][27][28][29][30][31][32] can realize a higher level of security in anticounterfeiting. Combining both responsive fluorescent behavior and the dynamic wrinkling pattern [33][34][35][36][37][38][39][40][41][42][43][44][45][46][47][48] into the same anticounterfeiting tag will undoubtedly enhance the information capacity and security.…”

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confidence: 99%

Dynamic wrinkling pattern exhibiting tunable fluorescence for anticounterfeiting applications

et al. 2020

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A dynamic surface pattern with a topography and fluorescence in response to environmental stimulus can enable information recording, hiding, and reading. Such patterns are therefore widely used in information security and anticounterfeiting. Here, we demonstrate a dynamic dual pattern using a supramolecular network comprising a copolymer containing pyridine (P4VP-nBA-S) and hydroxyl distyrylpyridine (DSP-OH) as the skin layer for bilayer wrinkling systems, in which both the wrinkle morphology and fluorescence color can be simultaneously regulated by visible light-triggered isomerization of DSP-OH, or acids. Acid-induced protonation of pyridines can dynamically regulate the cross-linking of the skin layer through hydrogen bonding, and the fluorescence of DSP-OH. On selective irradiation with 450 nm visible light or acid treatment, the resulting hierarchical patterned surface becomes smooth and wrinkled reversibly, and simultaneously its fluorescence changes dynamically from blue to orange-red. The smart surfaces with dynamic hierarchical wrinkles and fluorescence can find potential application in anticounterfeiting.

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Dynamic wrinkling pattern exhibiting tunable fluorescence for anticounterfeiting applications

et al. 2020

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“…[ 39 ] Given the importance of wrinkling structures, the merits of PDMS and the biological similarity of a hydrogel, the PDMS‐hydrogel bilayer (PHB) structure with a robust interface provides a stable and water‐rich platform to generate surface wrinkles, which is ideal for many applications requiring high hydrophilicity. [ 22,29 ]…”

Section: Figurementioning

confidence: 99%

“…[18] Coating PDMS with a hydrogel anchored by micropillars is a creative approach to generate a more stable and effective hydrophilic surface, [19][20][21] as PDMS virtually does not swell in contact with water. [1] Thus, PDMS and hydrogel act as a perfect combination, because hydrogel contains water providing a very hydrophilic surface with remarkable biocompatibility and similarity to biological tissues, [22] and PDMS serves as a more rigid substrate for the soft hydrogel film. However, the PDMS substrate needs replica micro-molding via photosensitive chemistry to produce micropillar structures, and the modified interface of the PDMS and the hydrogel is just a physical conglutination with potential instability.…”

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confidence: 99%

“…[39] Given the importance of wrinkling structures, the merits of PDMS and the biological similarity of a hydrogel, the PDMS-hydrogel bilayer (PHB) structure with a robust interface provides a stable and water-rich platform to generate surface wrinkles, which is ideal for many applications requiring high hydrophilicity. [22,29] Herein, we present a new method to prepare a covalently bonded PHB structure, which was obtained via in situ free radical copolymerization of acrylamide together with the surface alkenyl groups on α-zirconium phosphate (ZrP) nanosheets and on the surface of PDMS substrate in aqueous solution. Polyacrylamide (PAM) is chosen to build the polymer gel network as it is a widely-reported biocompatible polymer.…”

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confidence: 99%

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Transparency Change Mechanochromism Based on a Robust PDMS‐Hydrogel Bilayer Structure

Zeng

Xian

et al. 2020

Macromol. Rapid Commun.

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transparency, excellent resistance to UV radiation, high chemical stability, and reasonably low cost. [1-4] The fabrication of PDMS parts is typically a rapid-prototyping process often achieved by molding or spin-coating a viscous prepolymer with a curing agent. The cross-linking degree depends on the ratio of the prepolymer and the curing agent, which endows PDMS with tunable elastic modulus and stretchability. These characteristics make PDMS one of the most popular stretchable and transparent substrates for biomedical, mechanochromic, and photoelectric devices. [5-7,8] However, the hydrophobic nature of PDMS is a significant obstacle for its combination with hydrophilic materials requiring a strong interfacial adhesion. Various methods have been reported to improve the surface hydrophilicity of PDMS, including surface oxidization via plasma [9-11] or UV-ozone treatment, [12,13] silanization treatment, [14,15] and surface coating with hydrophilic materials. [16,17] Unfortunately, the surface hydrophilicity of PDMS generated by the above methods is typically temporary, which usually only Hydrogels and polydimethylsiloxane (PDMS) are complementary to each other, since the hydrophobic PDMS provides a more stable and rigid substrate, while the water-rich hydrogel possesses remarkable hydrophilicity, biocompatibility, and similarity to biological tissues. Herein a transparent and stretchable covalently bonded PDMS-hydrogel bilayer (PHB) structure is prepared via in situ free radical copolymerization of acrylamide and allylamineexfoliated-ZrP (AA-e-ZrP) on a functionalized PDMS surface. The AA-e-ZrP serves as cross-linking nano-patches in the polymer gel network. The covalently bonded structure is constructed through the addition reaction of vinyl groups of PDMS surface and monomers, obtaining a strong interfacial adhesion between the PDMS and the hydrogel. A mechanical-responsive wrinkle surface, which exhibs transparency change mechanochromism, is created via introducing a cross-linked polyvinyl alcohol film atop the PHB structure. A finite element model is implemented to simulate the wrinkle formation process. The implication of the present finding for the interfacial design of the PHB and PDMS-hydrogel-PVA trilayer (PHPT) structures is discussed.

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“…Accordingly, as a naturally mechanical phenomenon, wrinkled patterning on film–substrate bilayer systems [ 8 ] resulting from compressive stress provides an intriguing avenue for overcoming the abovementioned obstacles and has attracted considerable research interest owing to the distinguished optical, [ 9 ] electrical, [ 10 ] biological, [ 11 ] and mechanical [ 9b,12 ] performances of the developed patterns. To date, manipulating the progress of stress relaxation and modulus within the wrinkled topologies based on indirect or direct actuation (e.g., light, temperature, pH, and solvents) has enabled the realization of dynamically tunable smart surfaces.…”

Section: Figurementioning

confidence: 99%

Photodynamic Pattern Memory Surfaces with Responsive Wrinkled and Fluorescent Patterns

Chen

Bai

et al. 2020

Advanced Science

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Reversible pattern systems, namely pattern memory surfaces, possessing tunable morphology play an important role in the development of smart materials; however, the construction of these surfaces is still extensively challenging because of complicated methodologies or chemical reactions. Herein, a functionalized basement is strategically integrated with a multi-responsive supramolecular network based on hydrogen bonding between aggregation-induced emission luminogens (AIEgens) and copolymers containing amidogen (poly(St-co-Dm) to establish a bilayer system for near-infrared (NIR)-driven memory dual-pattern, where both the fluorescence emission and wrinkled structures can be concurrently regulated by a noninvasive NIR input. The motion of the AIEgens and photo-to-thermal expansion of the modified base allow temporal erasing of the fluorescent wrinkling patterns. Meanwhile, when exposed to 365 nm UV radiation, the fluorescent patterns can be independently regulated through photocyclization. The fluorescent wrinkling pattern presented herein is successfully demonstrated to promote the level of information security and capacity. This strategy provides a brand-new approach for the development of smart memory interfaces. Inspired by the profound comprehension of natural and living organisms, the development of patterned surfaces has become a fundamentally important element in both basic subjects and practical applications. [1] Particularly, similar to shape-memory polymers, [2] a class of pattern memory surfaces (PMSs) whose morphology can completely return to its original permanent status reversibly upon external stimulation has attracted significant attention in the last few years because the dynamic change in morphology from nano-to microscale can provide on-demand control of surface properties including switchable wetting, [3] adhesion control, [4] intelligent displays, [3b,5] and signal delivery. [6]

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Highly Efficient and Environmentally Friendly Fabrication of Robust, Programmable, and Biocompatible Anisotropic, All‐Cellulose, Wrinkle‐Patterned Hydrogels for Cell Alignment

Cited by 88 publications

References 31 publications

Dynamic wrinkling pattern exhibiting tunable fluorescence for anticounterfeiting applications

Dynamic wrinkling pattern exhibiting tunable fluorescence for anticounterfeiting applications

Transparency Change Mechanochromism Based on a Robust PDMS‐Hydrogel Bilayer Structure

Photodynamic Pattern Memory Surfaces with Responsive Wrinkled and Fluorescent Patterns

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