Ingestible Functional Magnetic Robot with Localized Flexibility (MR‐LF)

Greenwood, Taylor E.; Cagle, Henry; Pulver, Benson; Pak, On Shun; Kong, Yong Lin

doi:10.1002/aisy.202200166

Cited by 4 publications

(3 citation statements)

References 59 publications

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“…However, how to remotely control the collection and dispersion of each functional module is the focus of research. A design of centralized compartment in magnetic robot by imparting localized flexibility was demonstrated, that enables capsule robot to be readily integrated with functional modular, such as commercial electronics and medication [76]. Furthermore, adaptive magnetic levitation is an ideal way for capsule robots to move.…”

Section: Medical Operation Of Capsule Robotsmentioning

confidence: 99%

Functional capsule robots: a review of locomotion, pose, medical operation and wireless power transmission reported in 2018–2023

Hua,

Deng,

Gołdasz

et al. 2024

Smart Mater. Struct.

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As a new type of medical equipment, capsule robots are actuated wirelessly by space magnetic field, which have important application advantages in the diagnosis and treatment of gastrointestinal diseases. Active locomotion is the basis of medical operation for capsule robots, as well as an important guarantee to avoid misdetection and retention in the body. Furthermore, the pose estimation of the capsule robots in the gastrointestinal tract can provide accurate information for medical operation and improve work efficiency. Specific medical operation is one of the ultimate goals of capsule robots, and it is the key to realize the non-invasive diagnosis and treatment technology. Moreover, replacing traditional chemical batteries with wireless power transfer technology not only reduces the dimensions of the capsule robots, but also provides unlimited possibilities for the development of medical operations. In this work, the state-of-the-art capsule robots are reviewed according to the research directions of the locomotion, pose, medical operation and wireless power transmission reported from 2018 to 2023. In light of the four main directions of the capsule robots, some important research achievements and approaches are summarized. In particular, some outstanding advances on innovative structure, efficient methodology and appropriate application of the capsule robots are introduced in details. Finally, an overview of the significant issues occurred in the capsule robots is reported, and the developing trends are discussed.

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Section: Medical Operation Of Capsule Robotsmentioning

confidence: 99%

Functional capsule robots: a review of locomotion, pose, medical operation and wireless power transmission reported in 2018–2023

Hua,

Deng,

Gołdasz

et al. 2024

Smart Mater. Struct.

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show abstract

“…In recent years, microrobots have shown great advantages in the field of biomedical applications. With the development of microrobots, various aspects such as their driving methods [ 2 , 3 , 4 , 5 , 6 ], recognition and tracking [ 7 , 8 ], biosafety [ 9 ], targeted drug delivery methods [ 10 , 11 , 12 ], and multi-functional integration [ 13 , 14 ] have attracted widespread attention. For example, a magnetically driven rotary ablation catheter robot [ 15 ] was employed to remove calcified deposits from arterial stenosis and occlusion.…”

Section: Introductionmentioning

confidence: 99%

Magnetic-Controlled Microrobot: Real-Time Detection and Tracking through Deep Learning Approaches

Li,

Yi,

Zhang

et al. 2024

Micromachines

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As one of the most significant research topics in robotics, microrobots hold great promise in biomedicine for applications such as targeted diagnosis, targeted drug delivery, and minimally invasive treatment. This paper proposes an enhanced YOLOv5 (You Only Look Once version 5) microrobot detection and tracking system (MDTS), incorporating a visual tracking algorithm to elevate the precision of small-target detection and tracking. The improved YOLOv5 network structure is used to take magnetic bodies with sizes of 3 mm and 1 mm and a magnetic microrobot with a length of 2 mm as the pretraining targets, and the training weight model is used to obtain the position information and motion information of the microrobot in real time. The experimental results show that the accuracy of the improved network model for magnetic bodies with a size of 3 mm is 95.81%, representing an increase of 2.1%; for magnetic bodies with a size of 1 mm, the accuracy is 91.03%, representing an increase of 1.33%; and for microrobots with a length of 2 mm, the accuracy is 91.7%, representing an increase of 1.5%. The combination of the improved YOLOv5 network model and the vision algorithm can effectively realize the real-time detection and tracking of magnetically controlled microrobots. Finally, 2D and 3D detection and tracking experiments relating to microrobots are designed to verify the robustness and effectiveness of the system, which provides strong support for the operation and control of microrobots in an in vivo environment.

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“…[32,33] Among various methods, applying an external magnetic field to create a torque or force on the soft actuator is one of the simplest yet effective actuation approaches. [34][35][36][37][38][39][40][41][42][43][44] More importantly, this actuation method is transparent and noninvasive, and high temporal resolution is possible by controlling the amplitude, gradient, and direction of the magnetic field. Although some interesting studies on sample capturing and trapping have been reported using soft actuator platforms, [45][46][47] their use in hot-spot engineering is still very limited.…”

Section: Introductionmentioning

confidence: 99%

Dynamic Tuning of Plasmonic Hot‐Spot Generation through Cilia‐Inspired Magnetic Actuators

Liman

Ergene

Yildiz

et al. 2023

Advanced Intelligent Systems

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Soft actuators that draw inspiration from nature are powerful and versatile tools for both technological applications and fundamental research, yet their use in hot‐spot engineering is very limited. Conventional hot‐spot engineering methods still suffer from complexity, high process cost, and static generation of hot‐spots, thus, underperforming particularly in the application side. Herein, we demonstrate a strategy based on plasmonic nanoparticles decorated cilia‐inspired magnetic actuators that enable highly accessible millimeter‐sized hot‐spot generation via bending motion under a magnetic field. The hot‐spot formation is shown to be reversible and tunable, and leads to excellent Raman signal enhancements of up to ≈120 folds compared to the unactuated platforms. Accessible electromagnetic field magnification in the platforms can be manipulated by controlling magnetic field strength, which is further supported by finite difference time domain (FDTD) simulations. As a proof‐of‐concept demonstration, a centipede‐inspired robot is fabricated and used for sample collection/analysis in a target environment. Our results demonstrate an effective strategy in soft actuator platforms for reversible and tunable large‐area hot‐spot formation, which provides a promising guidance toward studying the fundamentals of hot‐spot generation and advancing real‐life plasmonic applications.

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Ingestible Functional Magnetic Robot with Localized Flexibility (MR‐LF)

Cited by 4 publications

References 59 publications

Functional capsule robots: a review of locomotion, pose, medical operation and wireless power transmission reported in 2018–2023

Functional capsule robots: a review of locomotion, pose, medical operation and wireless power transmission reported in 2018–2023

Magnetic-Controlled Microrobot: Real-Time Detection and Tracking through Deep Learning Approaches

Dynamic Tuning of Plasmonic Hot‐Spot Generation through Cilia‐Inspired Magnetic Actuators

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