Encoding Smart Microjoints for Microcrawlers with Enhanced Locomotion

Chen, Qianying; Lv, Pengyu; Huang, Tian-Yun; Huang, Jianyong; Duan, Huiling

doi:10.1002/aisy.201900128

Cited by 25 publications

(23 citation statements)

References 44 publications

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“…Honschoten et al [ 51 ] fabricated a microstructure with a silicon nitride layer and then created hinges by photolithography and plasma etching of the layer to a thinner thickness as the crease for folding. Chen et al [ 57 ] and Jin et al [ 54 ] embedded narrow bilayer structures into micromachines for obviously fixed-point folding ( Figure 2(g) ). In general, the folding direction is predesigned, rather than random swings like chaining.…”

Section: Modes Of Shape Morphingmentioning

confidence: 99%

“…Though it is a random and unpredictable process in a static fluid, the diffusion path could be artificially controlled when the velocity of the fluid is greater than the diffusion speed. Chen et al [ 57 ] proposed a shape-morphing realization strategy to trigger a series of microcrawlers walking along a predesigned diffusion path ( Figure 3(b) ). Through controlling of injecting directions and rates of the alkaline solution into the acidic solution, the trajectories of neutralization reaction could be manipulated.…”

Section: Realizations Of Shape Morphingmentioning

confidence: 99%

“…When different regions of intelligent micromachines are triggered by different deformation degrees or stimuli, the whole micromachines realize asymmetric-response shape morphing [ 43 , 47 – 50 , 54 , 57 , 69 ]. For example, Gao et al [ 44 ] reported a synthetic hybrid wire-shaped motor at the microscale.…”

Section: Realizations Of Shape Morphingmentioning

confidence: 99%

“…Asymmetric triggering time is an effective internal asymmetric factor for the realization of shape morphing. Chen et al [ 57 ] found a sequential deformation effect of pH-response bilayer beams at the microscale. The layer with dense crosslinking density was triggered ahead of the loose one in response to the change in the ambient solution from acidic to alkaline and induced sequential swelling between two layers of the microbeam.…”

Section: Realizations Of Shape Morphingmentioning

confidence: 99%

“…Here, we list eight types of applications of intelligent micromachines which are divided into motion- and target-based micromachines, as shown in Figure 4 . The motion-based micromachines include microswimmers for swimming in the liquid [ 23 , 30 , 41 – 44 ], microcrawlers for substrate locomotion [ 57 , 64 ], microjumpers for jumping [ 64 , 86 ], and micromotors for marching [ 52 , 53 , 58 , 87 ], while the target-based micromachines include microvalves for valve control of microchannels [ 35 , 36 ], microstents for extending vessels [ 54 , 88 ], microgrippers for drugs catching [ 26 , 47 , 49 , 56 , 66 ], and microcarriers for drug carrying and delivery [ 29 , 89 , 90 ]. Each application is summarized and marked with its common strategies according to the shape-morphing dimension, shape-morphing modes, and realization methods discussed above, together with their advantages and limitations (see Table 1 for details).…”

Section: Applications Of Shape-morphing Micromachinesmentioning

confidence: 99%

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Intelligent Shape-Morphing Micromachines

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Huang

et al. 2021

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Intelligent machines are capable of switching shape configurations to adapt to changes in dynamic environments and thus have offered the potentials in many applications such as precision medicine, lab on a chip, and bioengineering. Even though the developments of smart materials and advanced micro/nanomanufacturing are flouring, how to achieve intelligent shape-morphing machines at micro/nanoscales is still significantly challenging due to the lack of design methods and strategies especially for small-scale shape transformations. This review is aimed at summarizing the principles and methods for the construction of intelligent shape-morphing micromachines by introducing the dimensions, modes, realization methods, and applications of shape-morphing micromachines. Meanwhile, this review highlights the advantages and challenges in shape transformations by comparing micromachines with the macroscale counterparts and presents the future outlines for the next generation of intelligent shape-morphing micromachines.

show abstract

Section: Modes Of Shape Morphingmentioning

confidence: 99%

Section: Realizations Of Shape Morphingmentioning

confidence: 99%

Section: Realizations Of Shape Morphingmentioning

confidence: 99%

Section: Realizations Of Shape Morphingmentioning

confidence: 99%

Section: Applications Of Shape-morphing Micromachinesmentioning

confidence: 99%

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Intelligent Shape-Morphing Micromachines

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et al. 2021

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Two‐Photon Polymerization of Sugar Responsive 4D Microstructures

Ennis

Nicdao

Kolagatla

et al. 2023

Adv Funct Materials

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Stimuli‐responsive hydrogels have attracted much attention owing to the versatility of their programmed response in offering intelligent solutions for biomimicry applications, such as soft robotics, tissue engineering, and drug delivery. To achieve the complexity of biomimetic structures, two photon polymerization (2PP) has provided a means of fabricating intricate 3D structures from stimuli‐responsive hydrogels. Rapid swelling hydrogel microstructures are advantageous for osmotically driven stimuli‐response, where actuation speed, that is reliant on the diffusion of analytes or bioanalytes, can be optimized. Herein, the flexibility of 2PP is exploited to showcase a novel sugar‐responsive, phenylboronic acid‐based photoresist. This offers a remarkable solution for achieving fast response hydrogel systems that have been often hindered by the volume‐dependent diffusion times of analytes to receptor sites. A phenylboronic acid‐based photoresist compatible with 2PP is presented to fabricate stimuli‐responsive microstructures with accelerated response times. Moreover, microstructures with programmable actuation (i.e., bending and opening) are fabricated using the same photoresist within a one‐step fabrication process. By combining the flexibility of 2PP with an easily adaptable photoresist, an accessible fabrication method is showcased for sophisticated and chemo‐responsive 3D hydrogel actuators.

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4D Direct Laser Writing for Intelligent Micromachines

Wang,

Sai,

Tang

et al. 2024

Adv Funct Materials

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Intelligent micromachines are devices with sizes ranging from submillimeters to nanometers, capable of performing complex tasks adaptively at small scales. Smart micromachines have recently been developed that exhibit shape‐morphing capability in response to various stimuli to adapt to their environment. However, for such micromachines to be effective in harsh environments, micromachines should be more than adaptive. Essentially, they must exhibit a high degree of intelligence, characterized by enhanced locomotion capability, self‐adaptability, programmability, reconfigurability, and multifunctionality. 4D direct laser writing has enabled the rapid prototyping of stimulus‐responsive adaptive micromechanisms and diverse functional microcomponents, including microscale sensors, actuators, data processors, memory structures, and power‐supply structures. This review provides a comprehensive overview of the current state of the art in 4D microprinting technology based on two‐photon polymerization for the intelligentization of micromachines. Further, it offers insights into the fabrication of intelligent micromachines via the integration of diverse functional components through the 4D direct laser writing technology.

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Encoding Smart Microjoints for Microcrawlers with Enhanced Locomotion

Cited by 25 publications

References 44 publications

Intelligent Shape-Morphing Micromachines

Intelligent Shape-Morphing Micromachines

Two‐Photon Polymerization of Sugar Responsive 4D Microstructures

4D Direct Laser Writing for Intelligent Micromachines

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