Stretchable origami robotic arm with omnidirectional bending and twisting

Wu, Shuai; Ze, Qiji; Dai, Jize; Udipi, Nupur; Paulino, Gláucio H.; Zhao, Ruike Renee

doi:10.1073/pnas.2110023118

Cited by 231 publications

(127 citation statements)

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“…Inspired by nature, patterning different smart materials of distinctive mechanical properties on a single planar sheet can create complex 3D objects by origami folding. [ 27 ] This “fabricating 2D and folding into 3D” approach facilitates fast and efficient prototyping and product iteration ( Figure 3 a ). SMA, shape memory polymers, and stimuli‐responsive polymers are often used for origami self‐folding.…”

Section: Soft Matter Materials and Design Strategiesmentioning

confidence: 99%

“…[ 34 ] It typically needs external stimuli, such as water, [ 35 , 36 , 37 , 38 , 39 , 40 , 41 , 42 , 43 , 44 , 45 ] pH, [ 46 , 47 , 48 , 49 , 50 ] heat, [ 47 , 51 , 52 , 53 , 54 , 55 , 56 , 57 ] light, [ 58 , 59 , 60 , 61 , 62 , 63 , 64 , 65 ] electricity, [ 53 , 66 , 67 , 68 , 69 , 70 , 71 ] and magnetic field to perform. [ 27 , 72 , 73 , 74 , 75 ] In recent years, soft actuators can be classified based on materials as elastomeric pneumatic actuator (PA), hydrogel actuator (HA), bio‐hybrid actuator (BHA), actuators made of DE, twisted and coiled yarns (TCY), SMA, liquid crystal elastomers (LCE), and ionic polymer‐metal composites (IPMC). [ 76 ] Extensive efforts in design and fabrication are dedicated to improving the performance of artificial mu...…”

Section: Biomimetic Functions and Potential Applicationsmentioning

confidence: 99%

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A Shift from Efficiency to Adaptability: Recent Progress in Biomimetic Interactive Soft Robotics in Wet Environments

et al. 2022

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Research field of soft robotics develops exponentially since it opens up many imaginations, such as human-interactive robot, wearable robots, and transformable robots in unpredictable environments. Wet environments such as sea and in vivo represent dynamic and unstructured environments that adaptive soft robots can reach their potentials. Recent progresses in soft hybridized robotics performing tasks underwater herald a diversity of interactive soft robotics in wet environments. Here, the development of soft robots in wet environments is reviewed. The authors recapitulate biomimetic inspirations, recent advances in soft matter materials, representative fabrication techniques, system integration, and exemplary functions for underwater soft robots. The authors consider the key challenges the field faces in engineering material, software, and hardware that can bring highly intelligent soft robots into real world.

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Section: Soft Matter Materials and Design Strategiesmentioning

confidence: 99%

Section: Biomimetic Functions and Potential Applicationsmentioning

confidence: 99%

A Shift from Efficiency to Adaptability: Recent Progress in Biomimetic Interactive Soft Robotics in Wet Environments

et al. 2022

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“…Shape-reconfigurable materials that significantly change their structure and size can potentially impact modern engineering applications, such as mechanical memory devices, [1][2][3] mechanical metamaterials, [4][5][6] bio-inspired robotics, [7][8][9] microelectronic plasticity-induced deformation contributes to a permanent origami deployment. [28,29] Despite this plasticity allowing manipulating plastically to form a drastically different origami structures, it is largely inapplicable for intrinsically guiding deformation in complex 3D origami without mold.…”

Section: Introductionmentioning

confidence: 99%

“…[14,15] An origami pattern consists of foldable and non-foldable creases with an anisotropic deformability that enables shape guiding and functionalities without molding. [7,16,17] This is fully compatible with shapereconfigurable materials because it incorporates the benefits of 2D simplicity, high throughput, and space conservation. It also provides a guided folding mechanism for shape reconfiguration.…”

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confidence: 99%

Light‐Induced Topological Patterning toward 3D Shape‐Reconfigurable Origami

Chen

et al. 2022

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devices/sensors, [10][11][12] and green architectures. [13] However, for homogenous material deformability, shape reconfiguration has relied on mold-assisted techniques that increase complexity. The ancient art of origami has been recently endowed with a new vitality with regard to 3D shape-reconfigurable materials. [14,15] An origami pattern consists of foldable and non-foldable creases with an anisotropic deformability that enables shape guiding and functionalities without molding. [7,16,17] This is fully compatible with shapereconfigurable materials because it incorporates the benefits of 2D simplicity, high throughput, and space conservation. It also provides a guided folding mechanism for shape reconfiguration. However, origamis that are based on nonrigid patterns require heavy pressurization to maintain a specific geometry. [18,19] Thus, to entirely forgo this process, an origami material must integrate two factors. First, in a predetermined origami pattern, the kinematic deformation must be solely restricted to the plastically folding creases, while the non-folding regions remain undeformed. Second, the origami material must exhibit repeatable "self-locking," where the deployed structure can be spontaneously fixed at a particular configuration without pressure. However, removal of the self-locking should enable re-shaping. By introducing the selflockable origami pattern, versatile shape-configurable materials are possible without assisting equipment.A self-lockable polymer origami that can significantly change shape along a foldable and non-foldable pattern, and spontaneously fix a specific geometry, can be fabricated via bi-and multi-layer assemblies [8,20] and lateral curing. [21] However, these structures usually suffer from delamination between layers and non-repeatable shape changes. Another method uses origami made from shape-memory polymers. [22,23] In this case, shapereconfiguration can be realized via stimuli-responsive elasticity, which subsequently eliminates stimuli that fix the geometry in a particular state. However, the elastically deforming into temporary shapes still need continuous external force load to remain its geometries, impeding the complexity of on-demand 3D shape-reconfigurability. Recent progress in covalent adaptable network polymers [24,25] offers strategies for polymeric origami that standard approaches cannot achieve. Because of bonding exchange reactions within a dynamic network topology, crosslinked polymers exhibit stimuli-responsive plasticity. [26,27] The Shape-reconfigurable materials are crucial in many engineering applications. However, because of their isotropic deformability, they often require complex molding equipment for shaping. A polymeric origami structure that follows predetermined deformed and non-deformed patterns at specific temperatures without molding is demonstrated. It is constructed with a heterogeneous (dynamic and static) network topology via light-induced programming. The corresponding spatio-selective thermal plasticity creates varied deformabili...

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“…Small-scale magnetic robotics emerged as an interdisciplinary research field several decades ago and quickly gained momentum in advancement [9][10][11][12][13][14][15][16][17][18][19][20]. Magnetic field excels other control approaches due to its abilities of simultaneously generating both forces and torques on remote objects while safely penetrating biological substances.…”

Section: Introductionmentioning

confidence: 99%

Evolving from Laboratory Toys towards Life-Savers: Small-Scale Magnetic Robotic Systems with Medical Imaging Modalities

Zhang

2021

Micromachines

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Small-scale magnetic robots are remotely actuated and controlled by an externally applied magnetic field. These robots have a characteristic size ranging from several millimetres down to a few nanometres. They are often untethered in order to access constrained and hard-to-reach space buried deep in human body. Thus, they promise to bring revolutionary improvement to minimally invasive diagnostics and therapeutics. However, existing research is still mostly limited to scenarios in over-simplified laboratory environment with unrealistic working conditions. Further advancement of this field demands researchers to consider complex unstructured biological workspace. In order to deliver its promised potentials, next-generation small-scale magnetic robotic systems need to address the constraints and meet the demands of real-world clinical tasks. In particular, integrating medical imaging modalities into the robotic systems is a critical step in their evolution from laboratory toys towards potential life-savers. This review discusses the recent efforts made in this direction to push small-scale magnetic robots towards genuine biomedical applications. This review examines the accomplishment achieved so far and sheds light on the open challenges. It is hoped that this review can offer a perspective on how next-generation robotic systems can not only effectively integrate medical imaging methods, but also take full advantage of the imaging equipments to enable additional functionalities.

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Stretchable origami robotic arm with omnidirectional bending and twisting

Cited by 231 publications

References 42 publications

A Shift from Efficiency to Adaptability: Recent Progress in Biomimetic Interactive Soft Robotics in Wet Environments

A Shift from Efficiency to Adaptability: Recent Progress in Biomimetic Interactive Soft Robotics in Wet Environments

Light‐Induced Topological Patterning toward 3D Shape‐Reconfigurable Origami

Evolving from Laboratory Toys towards Life-Savers: Small-Scale Magnetic Robotic Systems with Medical Imaging Modalities

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