Development and Verification of Mechanism for Enhancement of Steering Angle and Active Locomotion for Magnetic Micro Active-Guidewire

Jeon, Guk-Hong; Kim, Sung Hoon

doi:10.1109/access.2020.2973341

Cited by 12 publications

(6 citation statements)

References 27 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The concept of the experiments is the penetration of the clot by the programmed magnetic soft robot under the action of the rotating magnetic field (the field amplitude is 10 mT, the field frequency is 40 Hz in X and Z directions), using the screwing technique, ,, and then the unaided extraction of the swimmer with the clot from the vein-mimicking system due to the self-propelled nature of the material (see the SI Section: Thrombus Extraction Experiments). The snapshot in Figure E and Movie S5 demonstrates the main steps of the thromboextraction without thrombolytics: the insertion of the robot into the vein-mimicking tube (0 min), penetration and hook of the model fibrin clot (3 min), and further extraction of the clot from the vessel by self-propulsion of the swimmer with the hooked clot (5 and 7 min).…”

Section: Resultsmentioning

confidence: 99%

Reprogrammable Soft Swimmers for Minimally Invasive Thrombus Extraction

Pozhitkova

Kladko

Винник

et al. 2022

ACS Appl. Mater. Interfaces

View full text Add to dashboard Cite

Thrombosis-related diseases are the primary cause of death in the world. Despite recent advances in thrombosis treatment methods, their invasive nature remains a crucial factor, which leads to considerable deadly consequences. Soft magnetic robots are attracting widespread interest due to their fast response, remote actuation, and shape reprogrammability and can potentially avoid the side effects of conventional approaches. This paper outlines a new approach to the thrombosis treatment via reprogrammable magnetic soft robots that penetrate, hook, and extract the plasma clots in a vein-mimicking system under applied rotating magnetic fields. We present shape-switching bioinspired soft swimmers, capable of locomotion by different mechanisms in vein-mimicking flow conditions and whose swimming efficiency is similar to animals. Further, we demonstrate the potential of a developed robot for minimally invasive thromboextraction with and without fibrinolytic usage, including hooking the plasma clot for 3.1 ± 1.1 min and extracting it from the vein-mimicking system under the applied magnetic fields. We consider an interesting solution for thrombosis treatment to avoid substantial drawbacks of the existing methods.

show abstract

Section: Resultsmentioning

confidence: 99%

Reprogrammable Soft Swimmers for Minimally Invasive Thrombus Extraction

Pozhitkova

Kladko

Винник

et al. 2022

ACS Appl. Mater. Interfaces

View full text Add to dashboard Cite

show abstract

“…Drilling motion is one of the widely studied functionalities. [70,72,81,[162][163][164][165] For example, Yang et al developed a driller-tipped magnetic guidewire for peripheral vascular disease (PVD) treatment. The guidewire consisted of a magnetic driller tip, elastic neck, and base shaft (Figure 11a).…”

Section: Mcr With Medical Treatmentmentioning

confidence: 99%

“…Jeon et al proposed a magnetic micro active‐guidewire composed of a ball joint and spiral‐type magnetic microrobot. [ 164 ] The designed ball joint could provide an additional joint angle of up to 45° without wire deformation, providing a larger steering angle that was the sum of the joint and wire angles. Both directional magnetic field‐driven and rotating magnetic field‐driven modalities were analyzed and experimentally validated.…”

Section: Magnetic Continuum Robotmentioning

confidence: 99%

Magnetically Actuated Continuum Medical Robots: A Review

Yang

Cao

et al. 2023

Advanced Intelligent Systems

View full text Add to dashboard Cite

The magnetic field has unique advantages in manipulating miniature robots working inside the human body, such as high transparency to biological tissue and good controllability for field generation. Generally, the actuated magnetic robot can be classified into two categories: tethered devices like intravascular microcatheters and untethered devices like helical swimmers. Among these, the tethered devices have a long history and good clinical application prospects, considering their high‐dose delivery and easy removal after the procedure. As an evolution of traditional continuum medical devices, the integration with magnetic actuation provides them with better scalability and improved dexterity. Although rapidly developed in the last two decades, the field of tethered magnetic robots requires further advancements in terms of design, fabrication, modeling, and control, especially for clinical applications. Herein, the recent progress of magnetically actuated continuum medical robots is focused on, intending to offer readers a comprehensive survey of the state‐of‐the‐art technologies and an information collection for future system design.

show abstract

“…Magnetic actuation systems can be used to precisely manipulate magnetic microrobots [25]- [28]. Hoshiar et al used a steering algorithm to control a flexible guidewire microrobot along a complex arbitrary path, spelling out the letters "BMR" [29].…”

Section: Introductionmentioning

confidence: 99%

Electromagnetic Manipulation System for Semi-Autonomous Control of Small-Scale Magnetic Objects With Sequential Programming

et al. 2023

View full text Add to dashboard Cite

In this study, an electromagnetic coil system was developed for semi-autonomous manipulation of microrobots in three-dimensional (3D) space with sequential programming. Cylindricalshaped cores were used for the electromagnetic coils; the coils were arranged in a hemispherical configuration to allow open access to the workspace for imaging tools. The system consisted of four main parts: the electromagnetic coils, an electronic control unit, optical cameras, and a direct-manipulation graphical user interface (GUI). The system was capable of producing a magnetic field of up to 18 mT with a maximum current of 8 A current. Using this system, magnetic force and torque can be applied for semi-autonomous manipulation of magnetic objects, with different time intervals, by instantly inputting the required fields and gradients via the GUI. Sequential programming of the magnetic field allowed for better controllability and enhanced the repeatability of the system. The versatility of the system was demonstrated by moving a magnetic guidewire, micromagnet, and nanoparticles to their intended targets to assess the potential application of the system in biomedical fields.

show abstract

Development and Verification of Mechanism for Enhancement of Steering Angle and Active Locomotion for Magnetic Micro Active-Guidewire

Cited by 12 publications

References 27 publications

Reprogrammable Soft Swimmers for Minimally Invasive Thrombus Extraction

Reprogrammable Soft Swimmers for Minimally Invasive Thrombus Extraction

Magnetically Actuated Continuum Medical Robots: A Review

Electromagnetic Manipulation System for Semi-Autonomous Control of Small-Scale Magnetic Objects With Sequential Programming

Contact Info

Product

Resources

About