Multimodal Soft Robotic Actuation and Locomotion

Yao, Dickson R.; Kim, Inho; Yin, Shukun; Gao, Wei

doi:10.1002/adma.202308829

Cited by 7 publications

(2 citation statements)

References 289 publications

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“…The past few decades have witnessed cardiovascular and cerebrovascular diseases caused by thrombus formation becoming a major threat to human life [1,2]. Continuous robots with active guidance functions have shown great potential to revolutionize the field of interventional surgery, since they can change their shape and bending stiffness to adapt to complex surroundings [3,4]. However, most of the existing continuous robots have proven unavailable for interventional catheters functioning in blood vessels that possess complicated vascular lumens with diameters at the millimeter scale [5][6][7].…”

Section: Introductionmentioning

confidence: 99%

Design, Modeling, and Experimental Validation of an Active Microcatheter Driven by Shape Memory Effects

Li,

Zhang,

Ren

et al. 2024

Micromachines

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Microcatheters capable of active guidance have been proven to be effective and efficient solutions to interventional surgeries for cardiovascular and cerebrovascular diseases. Herein, a novel microcatheter made of two biocompatible materials, shape memory alloy (SMA) and polyethylene (PE), is proposed. It consists of a reconfigurable distal actuator and a separate polyethylene catheter. The distal actuator is created via embedding U-shape SMA wires into the PE base, and its reconfigurability is mainly dominated by the shape memory effect (SME) of SMA wires, as well as the effect of thermal mismatch between the SMA and PE base. A mathematical model was established to predict the distal actuator’s deformation, and the analytical solutions show great agreement with the finite element results. Structural optimization of such microcatheters was carried out using the verified analytical model, followed by fabrication of some typical prototypes. Experimental testing of their mechanical behaviors demonstrates the feasibility of the structural designs, and the reliability and accuracy of the mathematical model. The active microcatheter, together with the prediction model, will lay a solid foundation for rapid development and optimization of active navigation strategies for vascular interventions.

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Section: Introductionmentioning

confidence: 99%

Design, Modeling, and Experimental Validation of an Active Microcatheter Driven by Shape Memory Effects

Li,

Zhang,

Ren

et al. 2024

Micromachines

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“…The advances in manufacturing technologies have led to a proliferation of programmable, magnetically driven robots. This progress encompasses innovations in materials, − magnetic field applications, − structural analysis, and practical applications. − As a result, a variety of soft robots capable of complex tasks such as grasping, locomotion, and exploration have emerged. − Yet, a critical challenge remains: these robots lack feedback mechanisms for their deformation states, which has hindered their development into intelligent, integrated systems.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Magnetic Soft Robotics: Integrating Fiber Optics and 3D Printing for Rapid Actuation and Precision Sensing

Han,

Gao,

Wang

2024

ACS Appl. Mater. Interfaces

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Timely, accurate, and rapid grasping of dynamic change information in magnetic actuation soft robots is essential for advancing their evolution toward intelligent, integrated, and multifunctional systems. However, existing magnetic-actuation soft robots lack effective functions for integrating sensing and actuation. Herein, we demonstrate the integration of distributed fiber optics technology with advanced-programming 3D printing techniques. This integration provides our soft robots unique capabilities such as integrated sensing, precise shape reconstruction, controlled deformation, and sophisticated magnetic navigation. By utilizing an improved magneto-mechanical coupling model and an advanced inversion algorithm, we successfully achieved real-time reconstruction of complex structures, such as ‘V’, ‘N’, and ‘M’ shapes and gripper designs, with a notable response time of 34 ms. Additionally, our robots demonstrate proficiency in magnetic navigation and closed-loop deformation control, making them ideal for operation in confined or obscured environments. This work thus provides a transformative strategy to meet unmet demands in the rapidly growing field of soft robotics, especially in establishing the theoretical and technological foundation for constructing digitized robots.

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Laser‐Printed All‐Carbon Responsive Material and Soft Robot

Yu,

Zhao,

Zhu

et al. 2024

Advanced Materials

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Responsive materials and actuators are the basis for the development of various leading‐edge technologies but have so far mostly been designed based on polymers, incurring key limitations related to sensitivity and environmental tolerance. This work reports a new responsive material, laser‐printed carbon film (LPCF), produced via direct laser transformation of a liquid organic precursor and consists of graphitic and amorphous carbons. The high activity of amorphous carbon combined with the dual‐gradient structure enables the LPCF to have a actuation speed of 9400° s−1 in response to the stimulus of organic vapor. LPCF exhibits a conductivity of 950 S m−1 and excellent resistance to various extreme environmental conditions, which are unachievable for polymer‐based materials. Additionally, an LPCF‐based all‐carbon soft robot that can mimic the complex continuous backward somersaulting motions without manual intervention is constructed. The locomotion velocity of the robot reaches a value of 1.19 BL s−1, which is almost one to two orders of magnitude faster than that of reported soft robots. This work not only offers a new paradigm for highly responsive materials but also provides a great design and engineering example for the next generation of biomimetic robots with life‐like performance.

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Multimodal Soft Robotic Actuation and Locomotion

Cited by 7 publications

References 289 publications

Design, Modeling, and Experimental Validation of an Active Microcatheter Driven by Shape Memory Effects

Design, Modeling, and Experimental Validation of an Active Microcatheter Driven by Shape Memory Effects

Enhanced Magnetic Soft Robotics: Integrating Fiber Optics and 3D Printing for Rapid Actuation and Precision Sensing

Laser‐Printed All‐Carbon Responsive Material and Soft Robot

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