Reconfigurable Printed Liquids

Forth, Joe; Liu, Xubo; Hasnain, Jaffar; Toor, Anju; Miszta, Karol; Shi, Shaowei; Geissler, Phillip L.; Emrick, Todd; Helms, Brett A.; Russell, Thomas P.

doi:10.1002/adma.201707603

Cited by 150 publications

(221 citation statements)

References 51 publications

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“…Different from gel‐in‐gel or gel‐in‐solution DIW, Russell et al. developed a unique liquid‐in‐liquid 3D printing method by chemical control of the liquid/liquid interface (Figure c) . This method is based on their discovery that non‐spherical fluid drops could be obtained by stabilizing the liquid/liquid interface through interfacial jamming of nanoparticles .…”

Section: Facilitating 3d Printability To Polymersmentioning

confidence: 99%

“…Different from gel-in-gel or gel-in-solution DIW,R ussell et al developed au nique liquid-in-liquid 3D printing methodb y chemicalc ontrol of the liquid/liquid interface (Figure 8c). [111] This methodi sb ased on their discovery that non-spherical fluid drops could be obtained by stabilizing the liquid/liquid interface through interfacial jamming of nanoparticles. [112] When an aqueous solution of carboxylic acid-functionalized nanoparticles was extruded into am ono-aminopropyl-poly(dimethylsiloxane) (PMDS-NH 2 )-containing silicone oil bath, [111] the negativelyc harged carboxylic acid-functionalized nanoparticles bind the PMDS-NH 2 at the oil/water interface, forming elastic assemblies of nanoparticle surfactants (NPSs) that stabilized the extruded filament shape.…”

Section: Printing Enabled By the Externalenvironmentmentioning

confidence: 99%

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Advanced Polymer Designs for Direct‐Ink‐Write 3D Printing

Lin

Tang

et al. 2019

Chemistry A European J

190

161

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The rapid development of additive manufacturing techniques, also known as three‐dimensional (3D) printing, is driving innovations in polymer chemistry, materials science, and engineering. Among current 3D printing techniques, direct ink writing (DIW) employs viscoelastic materials as inks, which are capable of constructing sophisticated 3D architectures at ambient conditions. In this perspective, polymer designs that meet the rheological requirements for direct ink writing are outlined and successful examples are summarized, which include the development of polymer micelles, co‐assembled hydrogels, supramolecularly cross‐linked systems, polymer liquids with microcrystalline domains, and hydrogels with dynamic covalent cross‐links. Furthermore, advanced polymer designs that reinforce the mechanical properties of these 3D printing materials, as well as the integration of functional moieties to these materials are discussed to inspire new polymer designs for direct ink writing and broadly 3D printing.

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Section: Facilitating 3d Printability To Polymersmentioning

confidence: 99%

Section: Printing Enabled By the Externalenvironmentmentioning

confidence: 99%

Advanced Polymer Designs for Direct‐Ink‐Write 3D Printing

Lin

Tang

et al. 2019

Chemistry A European J

190

161

View full text Add to dashboard Cite

show abstract

“…[2,[22][23][24][25][26] Here,u nlike in colloidosomes, [1,27] colloidal capsules, [28][29][30] or Pickering emulsions, [31][32][33][34] which are stabilized with micronsized particles (Scheme 1a), functionalized nanoparticles dispersed in an aqueous phase interact with end-functionalized oligomeric ligands dissolved in an oil phase at the interface to form nanoparticle surfactants (NP-surfactants; Scheme 1b), where the number of ligands anchored to the NPs is self-regulated to minimize the energy holding each NPsurfactant at the interface. [2,[22][23][24][25][26] Here,u nlike in colloidosomes, [1,27] colloidal capsules, [28][29][30] or Pickering emulsions, [31][32][33][34] which are stabilized with micronsized particles (Scheme 1a), functionalized nanoparticles dispersed in an aqueous phase interact with end-functionalized oligomeric ligands dissolved in an oil phase at the interface to form nanoparticle surfactants (NP-surfactants; Scheme 1b), where the number of ligands anchored to the NPs is self-regulated to minimize the energy holding each NPsurfactant at the interface.…”

Section: Nanoparticle Assemblies At Liquid-liquid Interfaces Openmentioning

confidence: 99%

Interfacial Activity of Amine‐Functionalized Polyhedral Oligomeric Silsesquioxanes (POSS): A Simple Strategy To Structure Liquids

Hou

et al. 2019

Angew Chem Int Ed

Self Cite

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“…[1,2,7,8,12,15,16,[23][24][25][26][27] The surrounding matrices that help to support the printed arbitrary 3D architectures include viscous oils, elastomers, self-healing hydrogels, and granular gel suspensions. For instance, aqueous architectures suspended in oils can be stabilized by the jamming of interfacial nanoparticles; [3,[28][29][30] but their functionality remains to be explored. For instance, aqueous architectures suspended in oils can be stabilized by the jamming of interfacial nanoparticles; [3,[28][29][30] but their functionality remains to be explored.…”

Section: Doi: 101002/adma201904631mentioning

confidence: 99%

Freeform, Reconfigurable Embedded Printing of All‐Aqueous 3D Architectures

Luo

Yuan

et al. 2019

Advanced Materials

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Aqueous microstructures are challenging to create, handle, and preserve since their surfaces tend to shrink into spherical shapes with minimum surface areas. The creation of freeform aqueous architectures will significantly advance the bioprinting of complex tissue‐like constructs, such as arteries, urinary catheters, and tracheae. The generation of complex, freeform, three‐dimensional (3D) all‐liquid architectures using formulated aqueous two‐phase systems (ATPSs) is demonstrated. These all‐liquid microconstructs are formed by printing aqueous bioinks in an immiscible aqueous environment, which functions as a biocompatible support and pregel solution. By exploiting the hydrogen bonding interaction between polymers in ATPS, the printed aqueous‐in‐aqueous reconfigurable 3D architectures can be stabilized for weeks by the noncovalent membrane at the interface. Different cells can be separately combined with compartmentalized bioinks and matrices to obtain tailor‐designed microconstructs with perfusable vascular networks. The freeform, reconfigurable embedded printing of all‐liquid architectures by ATPSs offers unique opportunities and powerful tools since limitless formulations can be designed from among a breadth of natural and synthetic hydrophilic polymers to mimic tissues. This printing approach may be useful to engineer biomimetic, dynamic tissue‐like constructs for potential applications in drug screening, in vitro tissue models, and regenerative medicine.

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Reconfigurable Printed Liquids

Cited by 150 publications

References 51 publications

Advanced Polymer Designs for Direct‐Ink‐Write 3D Printing

Advanced Polymer Designs for Direct‐Ink‐Write 3D Printing

Interfacial Activity of Amine‐Functionalized Polyhedral Oligomeric Silsesquioxanes (POSS): A Simple Strategy To Structure Liquids

Freeform, Reconfigurable Embedded Printing of All‐Aqueous 3D Architectures

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