Self‐Folded Hydrogel Tubes for Implantable Muscular Tissue Scaffolds

Vannozzi, Lorenzo; Yasa, Immihan Ceren; Ceylan, Hakan; Menciassi, Arianna; Ricotti, Leonardo; Sitti, Metin

doi:10.1002/mabi.201700377

Cited by 58 publications

(62 citation statements)

References 36 publications

(60 reference statements)

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“…In contrast, to the gradient crosslinking approach, the multilayer heterogeneous structures (Figure c) containing swelling and reinforcing layers can be prepared with a great deal of control using mass fabrication techniques . Application of stimuli responsive hydrogel materials, such as thermally and pH sensitive films, reinforced with rigid nonswelling polymeric layers allows for a reversible self‐assembly of the structure upon temperature or pH change that then triggers the swelling or de‐swelling of the polymers . Patterned hydrophobic reinforcing layers, can be introduced below, inside, or on top of the hydrogel layer, resulting in nontrivial transformations (Figures and d) of the geometry during the swelling/shrinking process after being released from the substrate .…”

Section: Self‐assembly Driving Mechanisms and Materials Platformsmentioning

confidence: 99%

Shapeable Material Technologies for 3D Self‐Assembly of Mesoscale Electronics

Karnaushenko

Kang

Schmidt

2019

Adv Materials Technologies

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simple transistors and logics to highly integrated microcontrollers and displays, the latter of which utilizes some of the most technologically advanced processes available in the industry. [3] The success of these technologies has been achieved through enhanced integration of various active functional blocks such as transistors, digital logics, and analog circuits, along with advances in miniaturization and simplification of the overall manufacturing process, eventually leading to large scale, parallel fabrication of silicon chip-based microelectronic components and systems. [4,5] However, many of the manufacturing steps in assembling these electronic components remain either semiparallel or sequential in nature, including processes as dicing, pick and place, packaging, and final assembly of the device. Each additional sequential step increases costs and should ideally be avoided, however substantial streamlining is not always feasible in complex manufacturing processes. [6] More critically, highly integrated silicon-based devices still require several external supporting components for their operation such as wiring, powering, sensing, and communications that cannot be easily integrated within the planar surface of a silicon die. Thus, sensors, actuators, capacitors, coils, antennas, and optics, each crucial for the complete system, are typically placed separately from the silicon chip onto a printed circuit board (PCB), or integrated within another package (Figure 1a). While the need for ever decreasing sizes has demanded tremendous investments and efforts in the manufacture of completed assemblies, the miniaturizing of 3D electronic components (Figure 1b) and systems has nevertheless reached the range of mesoscopic sizes (<1 mm) where the manufacture and assembly of components experience challenges with respect to yield, costs, and reliability. [7] As a result, these issues limit the fabrication potential and commercial viability of components and systems to scales around 1 mm, [8] and despite efforts to improve the planar construction of mesoscopic 3D devices, the results are seen as inefficient and experience difficulties in achieving high performances while maintaining reasonable complexity. Despite the great success in manufacturing active electronics, such concerns are strongly related to the fabrication of passive electronic components like inductors, capacitors, antennas, and resonators where material properties (e.g., mechanical, magnetic, and electrical) and geometry play a crucial role. [8,9] In order to downscale these devices further and improve integration with active electronics, novel fabrication strategies are required.Electronic devices and their components are continually evolving to offer improved performance, smaller sizes, lower weight, and reduced costs, often requiring the state-of-the-art manufacturing and materials to do so. An emerging class of materials and fabrication techniques inspired by self-assembling biological systems shows promise as an alternative to the more traditional m...

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Section: Self‐assembly Driving Mechanisms and Materials Platformsmentioning

confidence: 99%

Shapeable Material Technologies for 3D Self‐Assembly of Mesoscale Electronics

Karnaushenko

Kang

Schmidt

2019

Adv Materials Technologies

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“…Also, compared to the fabrication strategy of bilayer-based soft grippers and self-folded actuators, which have a soft and stiff layer with heterogeneous swelling degrees to fold into 3D shape, our method avoids further alignment processes of secondary materials. [50,51] From the materials point-of-view, compared to the previously presented actuators, including polyurethane-based elastomeric films embedded with SPION chains, [37] our hydrogel milli-gripper is composed of fully biodegradable material, which addresses one of the main challenges of small-scale untethered magnetic robots toward the pursuit of clinical relevance. www.afm-journal.de www.advancedsciencenews.com…”

Section: Design and Fabrication Of The Hydrogel Milli-grippers With 3mentioning

confidence: 99%

Biodegradable Untethered Magnetic Hydrogel Milli‐Grippers

Goudu

Yasa

et al. 2020

Adv Funct Materials

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129

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Small-scale magnetic soft-bodied robots based on biocompatible and biodegradable materials are essential for their potential high-impact minimally invasive medical applications inside the human body. Therefore, a strategy for fully biodegradable untethered soft millirobots with encoded 3D magnetic anisotropy for their static or dynamic shape programming is presented. Such a robot body is comprised of a porcine extracellular matrix-derived collagenbased hydrogel network with embedded superparamagnetic iron oxide nanoparticles (SPIONs). 3D magnetization programming inside the hydrogel body is achieved by directionally self-assembled SPION chains using an external permanent magnet. As a proof-of-concept demonstration, a hydrogel milligripper that can undergo flexible and reversible shape deformations inside glycerol and biologically relevant liquid media is presented. The gripper can perform cargo grabbing, transportation by rolling, and release by controlling magnetic field inputs. These milli-grippers can be completely degraded by the matrix metalloproteinase-2 enzyme in physiologically relevant concentrations. Furthermore, biocompatibility tests using human umbilical cord vein endothelial cells with the degradation products of the grippers demonstrate no acute toxicity. The approach offers a facile fabrication strategy for designing biocompatible and biodegradable soft robots using nanocomposite materials with programmable 3D magnetic anisotropy toward future medical applications.

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“…Torsion, bending, and buckling can be generated by the residual stress and eventually lead to the shape transformation from a two-dimensional (2D) to a three-dimensional (3D) structure [4,5]. Hybrid bilayers have various applications including cell encapsulation [6][7][8], drug delivery [9], micro robots [10], actuators [11][12][13], and flexible electronics [14][15][16][17][18].…”

Section: Introductionmentioning

confidence: 99%

“…Metallic bilayer actuators [19,20] have a long history in sensing, but exhibit small shape changes and usually are responsive only to temperature change. In contrast, hydrogels can respond to various stimuli, including temperature, pH, light, chemicals, and electrical field [21] and have a larger extent of shape change [8]. When hydrogel is constrained by the passive layer with a different swelling property, the swell or de-swell of the hydrogel can induce internal residual stress and result in shape transformation.…”

Section: Introductionmentioning

confidence: 99%

Shape Morphable Hydrogel/Elastomer Bilayer for Implanted Retinal Electronics

et al. 2020

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Direct fabrication of a three-dimensional (3D) structure using soft materials has been challenging. The hybrid bilayer is a promising approach to address this challenge because of its programable shape-transformation ability when responding to various stimuli. The goals of this study are to experimentally and theoretically establish a rational design principle of a hydrogel/elastomer bilayer system and further optimize the programed 3D structures that can serve as substrates for multi-electrode arrays. The hydrogel/elastomer bilayer consists of a hygroscopic polyacrylamide (PAAm) layer cofacially laminated with a water-insensitive polydimethylsiloxane (PDMS) layer. The asymmetric volume change in the PAAm hydrogel can bend the bilayer into a curvature. We manipulate the initial monomer concentrations of the pre-gel solutions of PAAm to experimentally and theoretically investigate the effect of intrinsic mechanical properties of the hydrogel on the resulting curvature. By using the obtained results as a design guideline, we demonstrated stimuli-responsive transformation of a PAAm/PDMS flower-shaped bilayer from a flat bilayer film to a curved 3D structure that can serve as a substrate for a wide-field retinal electrode array.

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Self‐Folded Hydrogel Tubes for Implantable Muscular Tissue Scaffolds

Cited by 58 publications

References 36 publications

Shapeable Material Technologies for 3D Self‐Assembly of Mesoscale Electronics

Shapeable Material Technologies for 3D Self‐Assembly of Mesoscale Electronics

Biodegradable Untethered Magnetic Hydrogel Milli‐Grippers

Shape Morphable Hydrogel/Elastomer Bilayer for Implanted Retinal Electronics

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