Telerobotic neurovascular interventions with magnetic manipulation

Kim, Yoonho; Genevriere, Emily; Harker, Pablo; Choe, Jaehun; Balicki, Marcin; Regenhardt, Robert W; Vranic, Justin E; Dmytriw, Adam A; Patel, Aman B.; Zhao, Xuanhe

doi:10.1126/scirobotics.abg9907

Cited by 164 publications

(127 citation statements)

References 62 publications

Supporting

Mentioning

103

Contrasting

Order By: Relevance

“…Then, the magnetic soft robots are cut out from the double-sided adhesive, after which they are powered by a spatially nonuniform magnetic field. Within the actuating magnetic field, the 3D deformation of a soft robot is primarily driven by magnetic torques that align the local magnetization with the field direction, and then the magnetic forces increase or decrease the robot’s deformation depending on the relationship between the reoriented magnetization of the initially torque-driven deformation with the direction of magnetic field gradient ( 44 , 45 ). The magnetic response of the robot will either involve folding or continuous structural changes depending on whether it is programmed with uniform or nonuniform magnetization profiles, respectively.…”

Section: Resultsmentioning

confidence: 99%

Untethered small-scale magnetic soft robot with programmable magnetization and integrated multifunctional modules

et al. 2022

View full text Add to dashboard Cite

Intelligent magnetic soft robots capable of programmable structural changes and multifunctionality modalities depend on material architectures and methods for controlling magnetization profiles. While some efforts have been made, there are still key challenges in achieving programmable magnetization profile and creating heterogeneous architectures. Here, we directly embed programmed magnetization patterns (magnetization modules) into the adhesive sticker layers to construct soft robots with programmable magnetization profiles and geometries and then integrate spatially distributed functional modules. Functional modules including temperature and ultraviolet light sensing particles, pH sensing sheets, oil sensing foams, positioning electronic component, circuit foils, and therapy patch films are integrated into soft robots. These test beds are used to explore multimodal robot locomotion and various applications related to environmental sensing and detection, circuit repairing, and gastric ulcer coating, respectively. This proposed approach to engineering modular soft material systems has the potential to expand the functionality, versatility, and adaptability of soft robots.

show abstract

Section: Resultsmentioning

confidence: 99%

Untethered small-scale magnetic soft robot with programmable magnetization and integrated multifunctional modules

et al. 2022

View full text Add to dashboard Cite

show abstract

“…One of the common application areas of RMN is minimally invasive surgery. The high dexterity and precise tip control of magnetic catheters allow surgeons to successfully accomplish tasks that are otherwise very difficult to perform using their manually steered counterparts [1]- [4]. RMN also offers an ideal platform for automating various surgical procedures [5].…”

Section: Introductionmentioning

confidence: 99%

Gradiometer-Based Magnetic Localization for Medical Tools

Fischer¹,

Quirin

Chautems³

et al. 2023

IEEE Trans. Magn.

View full text Add to dashboard Cite

Remote magnetic navigation offers various possibilities for medical interventions. Magnetic catheters can be wirelessly steered with high precision and accuracy through complex structures, as they are generally more dexterous and flexible than their manually steered counterparts. Position feedback is essential for many tasks. However, most commercially available systems do not integrate well with the magnetic navigation systems. As a result, fluoroscopy is still widely used in many interventions despite the known associated health risks.In this study, we propose a localization method that uses multiple Hall sensors to measure the magnetic fields produced by the magnetic navigation system and estimate the full sensor pose without the need for a separate dedicated mapping system. This makes the magnetic navigation system a 2-in-1 system that can be used for simultaneous navigation and localization of a medical tool.We perform an optimization of the sensors' array design in simulation and investigate the influence of the magnetic fields and gradients on the localization accuracy to provide information on the minimal requirements for a magnetic navigation system for this task.

show abstract

“…Magnetic actuation allows the catheters to be generally softer and more flexible than their manual counterparts thus reducing the risk of tissue damage during procedures. Forces can be directly applied to the magnetic tip of the catheter offering high dexterity and precision to navigate through complex structures [2], [3]. Hong et al [4], [5] demonstrated the benefits of a magnetically steered needle for deep brain stimulation by avoiding obstacles along the path.…”

Section: Introductionmentioning

confidence: 99%

Using Magnetic Fields to Navigate and Simultaneously Localize Catheters in Endoluminal Environments

Fischer

Boehler

Nelson

2022

IEEE Robot. Autom. Lett.

View full text Add to dashboard Cite

Remote magnetic navigation offers an ideal platform for automated catheter navigation. Magnetically guided catheters show great dexterity and can reach locations that are otherwise challenging to access. By automating aspects of catheterization procedures, we can simplify and expedite the procedure to allow surgeons to focus on other critical tasks during the surgery. In this article, we describe an automation strategy that is based on the center line of extracted and registered vascular geometries. Position feedback is accomplished with a Hall-effect sensor embedded near the distal end of the catheter. Sensor measurements are compared to the magnetic field predicted by a linear model of the electromagnetic navigation system. By defining specific magnetic field gradients and applying the known vascular geometry, the magnetic fields can be utilized for the simultaneous navigation and localization of the catheter. This eliminates the need for other external, dedicated mapping systems, and the use of fluoroscopy imaging is minimized. The concept is tested in 2d vascular models and the accuracy of the localization is assessed with overhead camera tracking.

show abstract

Telerobotic neurovascular interventions with magnetic manipulation

Cited by 164 publications

References 62 publications

Untethered small-scale magnetic soft robot with programmable magnetization and integrated multifunctional modules

Untethered small-scale magnetic soft robot with programmable magnetization and integrated multifunctional modules

Gradiometer-Based Magnetic Localization for Medical Tools

Using Magnetic Fields to Navigate and Simultaneously Localize Catheters in Endoluminal Environments

Contact Info

Product

Resources

About