Surface Nanopatterned Shape Memory Alloy (SMA)‐Based Photosensitive Artificial Muscle

Kim, Min‐Soo; Lee, Hye‐Sung; Cho, Younggyun; Heo, Jae Kyung; Quan, Ying‐Jun; Lee, Seung Woo; Pahk, Heui Jae; Ahn, Sung‐Hoon

doi:10.1002/adom.202102024

Cited by 13 publications

(4 citation statements)

References 43 publications

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“…As shown in Figure 6A and Movie S1 of the Supporting Information, we realized a temporary motion of the "fingers". The bilayer hydrogel fingers that were immersed in the BrO 3− − Fe(CN) 6 4− mixture gradually bent upon the addition of H 2 SO 4 and subsequently self-recovered without any external modulation. Furthermore, we prepared a bird claw-like bilayer actuator.…”

Section: Temporary Ph Decrease Of the H + −Bromentioning

confidence: 99%

“…For the manufacturing of such robots, artificial soft actuators that can mimic the biological functions of animal muscles are crucial. Thus far, many materials or devices have been developed to reach this goal, including pneumatic artificial muscles, , hydraulic artificial muscles, , shape-memory materials, − twisted polymer fibers, − etc. In recent years, hydrogel actuators, − which can deform by the control of external stimuli, have been widely reported as candidates for mimicking natural muscles.…”

Section: Introductionmentioning

confidence: 99%

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Novel Acid-Driven Bioinspired Self-Resettable Bilayer Hydrogel Actuator Mimicking Natural Muscles

Nan,

Guo,

Jia

et al. 2024

ACS Appl. Mater. Interfaces

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Soft robots have great potential applications in manufacturing, disaster rescue, medical treatment, etc. Artificial muscle is one of the most important components of a soft robot. In previous years, hydrogel actuators that can be controllably deformed by the stimuli of external signals have been developed as good candidates for muscle-like materials. In this article, we successfully prepared a chemical fuel-driven self-resettable bilayer hydrogel actuator mimicking natural muscles with the aid of a new negative feedback reaction network. The actuator can temporarily deform upon the addition of H + (chemical fuel). Subsequently, H + accelerated the reaction between BrO 3 − and Fe(CN) 6 4− , which consume H + . It resulted in the spontaneous recovery of the pH as well as the shape of the actuator. Such an actuator exhibits a great similarity with natural muscles in actuation mechanisms and automaticity in the manipulation compared to the widely reported stimuli-responsive hydrogel actuators. This illustrates that fueldriven self-resettable hydrogel is a promising dynamic material for mimicking the functions of living creatures.

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Section: Temporary Ph Decrease Of the H + −Bromentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Novel Acid-Driven Bioinspired Self-Resettable Bilayer Hydrogel Actuator Mimicking Natural Muscles

Nan,

Guo,

Jia

et al. 2024

ACS Appl. Mater. Interfaces

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show abstract

“…Cases of muscle mimicry in humans also exist. Kim et al developed an SMA actuator that responds to infrared (IR) light utilizing the plasmonic effect, showing responses like the pupil reflex of iris muscles [42]. Wearable robots using artificial muscles have been developed.…”

Section: Introductionmentioning

confidence: 99%

Shape Memory Alloys Patches to Mimic Rolling, Sliding, and Spinning Movements of the Knee

Seo,

Kang,

Han

2024

Biomimetics

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Every year, almost 4 million patients received medical care for knee osteoarthritis. Osteoarthritis involves progressive deterioration or degenerative changes in the cartilage, leading to inflammation and pain as the bones and ligaments are affected. To enhance treatment and surgical outcomes, various studies analyzing the biomechanics of the human skeletal system by fabricating simulated bones, particularly those reflecting the characteristics of patients with knee osteoarthritis, are underway. In this study, we fabricated replicated bones that mirror the bone characteristics of patients with knee osteoarthritis and developed a skeletal model that mimics the actual movement of the knee. To create patient-specific replicated bones, models were extracted from computerized tomography (CT) scans of knee osteoarthritis patients. Utilizing 3D printing technology, we replicated the femur and tibia, which bear the weight of the body and support movement, and manufactured cartilage capable of absorbing and dispersing the impact of knee joint loads using flexible polymers. Furthermore, to implement knee movement in the skeletal model, we developed artificial muscles based on shape memory alloys (SMAs) and used them to mimic the rolling, sliding, and spinning motions of knee flexion. The knee movement was investigated by changing the SMA spring’s position, the number of coils, and the applied voltage. Additionally, we developed a knee-joint-mimicking system to analyze the movement of the femur. The proposed artificial-skeletal-model-based knee-joint-mimicking system appears to be applicable for analyzing skeletal models of knee patients and developing surgical simulation equipment for artificial joint replacement surgery.

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“…Micro-hand, a flexible actuator, most of which is made of rubber materials, with the characteristics of low cost, flexible movement, high efficiency, safety and simple operation. Therefore, since 1989, the flexible actuators with various driving modes have been developed, [1][2][3][4] such as the miniature pneumatic curling rubber actuators, [5][6][7] the pneumatic artificial muscle micro actuators 8 and so on. The pneumatic actuators generate bidirectional curling motion by providing pneumatic pressure that can simulate biological behaviors such as peristaltic movement, jumping and grasping.…”

Section: Introductionmentioning

confidence: 99%

Robust tracking control for uncertain micro‐hand actuator with Prandtl‐Ishlinskii hysteresis

Zhang

2023

Intl J Robust & Nonlinear

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This article is concerned with the robust tracking control for an uncertain micro‐hand actuator with Prandtl‐Ishlinskii hysteresis (PI hysteresis) by robust right coprime factorization (RRCF). Firstly, the PI hysteresis is modeled into the rubber micro‐hand actuator and a new hysteretic micro‐hand system is obtained. Secondly, by compensating the hysteresis part into the isomorphic subspace, the effect of hysteresis on micro‐hand system is transferred and the operator‐based robust controllers are designed to ensure that the robust stability of the whole system. Thirdly, the RRCF and terminal sliding mode control are combined for tracking control, and the nonsingular terminal sliding mode surface with integral terms is designed, which shorten the convergence time and improve the tracking performance. Finally, the effectiveness of the method is tested by the simulation of the micro‐hand system.

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Surface Nanopatterned Shape Memory Alloy (SMA)‐Based Photosensitive Artificial Muscle

Cited by 13 publications

References 43 publications

Novel Acid-Driven Bioinspired Self-Resettable Bilayer Hydrogel Actuator Mimicking Natural Muscles

Novel Acid-Driven Bioinspired Self-Resettable Bilayer Hydrogel Actuator Mimicking Natural Muscles

Shape Memory Alloys Patches to Mimic Rolling, Sliding, and Spinning Movements of the Knee

Robust tracking control for uncertain micro‐hand actuator with Prandtl‐Ishlinskii hysteresis

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