Biofunctional Silk Kirigami With Engineered Properties

Pradhan, Sayantan; Ventura, Leonardo; Agostinacchio, Francesca; Meng, Xu; Barbieri, Ettore; Motta, Antonella; Pugno, Nicola; Yadavalli, Vamsi K.

doi:10.1021/acsami.9b20691

Cited by 17 publications

(17 citation statements)

References 56 publications

(162 reference statements)

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“…The popularity of silk continues to grow, impacting virtually all areas of biomedical research. For example, the precision cutting [68] or patterning of silks has already provided the ability to influence applications, ranging from stem cell biology to the design of rewritable optical storage devices [69]. However, in light of the ongoing Covid-19 pandemic, I have picked one example where silk is having a particular impact.…”

Section: Biomedical Applicationsmentioning

confidence: 99%

Emerging Silk Material Trends: Repurposing, Phase Separation and Solution-Based Designs

Seib

2021

Materials

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Silk continues to amaze. This review unravels the most recent progress in silk science, spanning from fundamental insights to medical silks. Key advances in silk flow are examined, with specific reference to the role of metal ions in switching silk from a storage to a spinning state. Orthogonal thermoplastic silk molding is described, as is the transfer of silk flow principles for the triggering of flow-induced crystallization in other non-silk polymers. Other exciting new developments include silk-inspired liquid–liquid phase separation for non-canonical fiber formation and the creation of “silk organelles” in live cells. This review closes by examining the role of silk fabrics in fashioning facemasks in response to the SARS-CoV-2 pandemic.

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Section: Biomedical Applicationsmentioning

confidence: 99%

Emerging Silk Material Trends: Repurposing, Phase Separation and Solution-Based Designs

Seib

2021

Materials

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“…Staggered linear and Y-shape cuts (15 mm and 5 mm) [60] Photoactive silk fibroin Photolithography Staggered linear cuts (25 µm), branched Y-shape cuts, saddles, chevrons [37] Graphite electrodes on polyimide sheet Laser cutting Staggered linear cuts (over 3 cm) [61] Gold nanofilms Dual-beam focused ion beam (FIB)/SEM Arcs and 3D microdomes (sub-50-nm) [27] Gold traces embedded in thin-film Parylene C Oxygen plasma etching Serpentine cuts [62] Mono-layer MoS 2 on PDMS Molding and plasma etching Linear patterns, pyramids, out-of-plane springs with alternating C-shapes [35] PMMA-PI composite Wet etching and laser cutting 2D hierarchical designs [63] PEO-PAA composite Blade cutting Curved patterns, linear cuts [64] Multiwalled boron nitride nanotubes Pressure-induced Folded nanoribbon internal structures/pleats [65] PLA-PEDOT:PSS Laser cutting Y-shape cuts [24] Hydrogel films-carboxyl-Zr 4+ metal coordination complexes Photolithography Custom papercut designs, woven-like alternating vertical/horizontal lines [30] Graphene sandwiched between polyimide sheets Photolithography and reactive ion etching Mesh (islands connected by kirigami bridges) [66] Liquid crystal elastomer Two-photon polymerization (2PP) Linear cuts, hinged squares, [67] PET encapsulated in PDMS Laser cutting Graded kirigami (10 mm segments of increasing void area) [68] PVDF-TrFE composite (ZnO nanoparticles and MWCNTs)…”

Section: Laser Cuttingmentioning

confidence: 99%

Section: The Influence Of Kirigami Designs On Materials Propertiesmentioning

confidence: 99%

mentioning

confidence: 99%

“…Silk fibroin kirigami films (loaded with fluorescein isothiocyanate (FITC)-dextran MW 4 kDa) with adherence of C2C12 cells 7 days after seeding.Arrows indicate cytoskeletal bridges across the cuts, followed by DAPI and actin staining. Reproduced with permission [37]. Copyright 2020, American Chemical Society.…”

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Kirigami‐Inspired Biodesign for Applications in Healthcare

et al. 2022

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Mechanically flexible and conformable materials and integrated devices have found diverse applications in personalized healthcare as diagnostics and therapeutics, tissue engineering and regenerative medicine constructs, surgical tools, secure systems, and assistive technologies. In order to impart optimal mechanical properties to the (bio)materials used in these applications, various strategies have been explored—from composites to structural engineering. In recent years, geometric cuts inspired by the art of paper‐cutting, referred to as kirigami, have provided innovative opportunities for conferring precise mechanical properties via material removal. Kirigami‐based approaches have been used for device design in areas ranging from soft bioelectronics to energy storage. In this review, the principles of kirigami‐inspired engineering specifically for biomedical applications are discussed. Factors pertinent to their design, including cut geometry, materials, and fabrication, and the effect these parameters have on their properties and configurations are covered. Examples of kirigami designs in healthcare are presented, such as, various form factors of sensors (on skin, wearable), implantable devices, therapeutics, surgical procedures, and cellular scaffolds for regenerative medicine. Finally, the challenges and future scope for the successful translation of these biodesign concepts to broader deployment are discussed.

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Engineering by Cuts: How Kirigami Principle Enables Unique Mechanical Properties and Functionalities

et al. 2022

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Kirigami, the ancient art of paper cutting, has evolved into a design and fabrication framework to engineer multi‐functional materials and structures at vastly different scales. By slit cutting with carefully designed geometries, desirable mechanical behaviors—such as accurate shape morphing, tunable auxetics, super‐stretchability, buckling, and multistability—can be imparted to otherwise inflexible sheet materials. In addition, the kirigami sheet provides a versatile platform for embedding different electronic and responsive components, opening up avenues for building the next generations of metamaterials, sensors, and soft robotics. These promising potentials of kirigami‐based engineering have inspired vigorous research activities over the past few years, generating many academic publications. Therefore, this review aims to provide insights into the recent advance in this vibrant field. In particular, this paper offers the first comprehensive survey of unique mechanical properties induced by kirigami cutting, their underlying physical principles, and their corresponding applications. The synergies between design methodologies, mechanics modeling, advanced fabrication, and material science will continue to mature this promising discipline.

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Biofunctional Silk Kirigami With Engineered Properties

Cited by 17 publications

References 56 publications

Emerging Silk Material Trends: Repurposing, Phase Separation and Solution-Based Designs

Emerging Silk Material Trends: Repurposing, Phase Separation and Solution-Based Designs

Kirigami‐Inspired Biodesign for Applications in Healthcare

Engineering by Cuts: How Kirigami Principle Enables Unique Mechanical Properties and Functionalities

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