Modeling Electromagnetic Navigation Systems

Charreyron, Samuel; Boehler, Quentin; Kim, Byungsoo; Weibel, Cameron; Chautems, Christophe; Nelson, Bradley J.

doi:10.1109/tro.2020.3047053

Cited by 31 publications

(28 citation statements)

References 31 publications

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“…In the future, we plan to expand our tests to 3D models. We also plan to test our localization algorithm with other field models such as the one described in Charreyron et al [1]. The use of a linear model is particularly limited when trying to set specific magnetic gradients which lead the core of the electromagnets to saturate under higher currents [1].…”

Section: Discussionmentioning

confidence: 99%

“…We also plan to test our localization algorithm with other field models such as the one described in Charreyron et al [1]. The use of a linear model is particularly limited when trying to set specific magnetic gradients which lead the core of the electromagnets to saturate under higher currents [1]. A field model that compensates for the saturation behavior is thus expected to yield better results.…”

Section: Discussionmentioning

confidence: 99%

“…Minimally invasive surgery is a primary application area of RMN. Medical tools containing magnetic material can be navigated through the human body using external magnetic fields produced by a magnetic navigation system (MNS) [1]. 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.…”

Section: Introductionmentioning

confidence: 99%

“…This work was supported by the Swiss National Science Foundation through grant numbers 200020B 185039 and 20B2-1 180861, by the ITC-InnoHK funding, and the ERC Advanced Grant 743217 Soft Micro Robotics (SOMBOT). 1 Multi-Scale Robotics Lab, ETH Zurich, Switzerland {fischece,qboehler,bnelson}@ethz.ch…”

Section: Introductionmentioning

confidence: 99%

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

Fischer

Boehler

Nelson

2022

IEEE Robot. Autom. Lett.

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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.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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

Fischer

Boehler

Nelson

2022

IEEE Robot. Autom. Lett.

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“…An m-CR is composed of permanent magnets [4] or magnetic particles [5], [6] embedded along a flexible body in which deflection is induced by the torques produced on the magnets by externally generated magnetic fields. These magnetic fields can be generated with an electromagnetic navigation system (eMNS) [7]. This distal actuation allows an m-CR to generate tip forces while having a soft body, making it safe for interactions with human tissue.…”

Section: Introductionmentioning

confidence: 99%

A Simulation Framework for Magnetic Continuum Robots

Dreyfus

Boehler

Nelson

2022

IEEE Robot. Autom. Lett.

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Remote magnetic navigation is a technology used to robotically steer magnetic medical instruments, such as magnetic catheters and guidewires, for minimally invasive surgery. The ability to model and simulate the behavior of these magnetic instruments in complex anatomies is important for their clinical use in many ways. Simulation frameworks can improve their design, characterization, and automatic control capabilities, as well as provide training simulators for physicians. In this work we introduce a new simulation framework that accounts for both magnetic actuation and interactions forces with meshed collision models. The simulations are validated experimentally in planar rigid models using a pre-clinical electromagnetic navigation system. We also demonstrate the use of our framework to build training simulators for two endovascular navigation tasks including the exploration of the aortic arch and the internal carotid artery.

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A Human‐Scale Clinically Ready Electromagnetic Navigation System for Magnetically Responsive Biomaterials and Medical Devices

Gervasoni,

Pedrini,

Rifai

et al. 2024

Advanced Materials

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Magnetic navigation systems are used to precisely manipulate magnetically responsive materials enabling the realization of new minimally invasive procedures using magnetic medical devices. Their widespread applicability has been constrained by high infrastructure demands and costs. we report on a portable electromagnetic navigation system, the Navion, which is capable of generating a large magnetic field over a large workspace. The system is easy to install in hospital operating rooms and transportable through healthcare facilities, aiding in the widespread adoption of magnetically responsive medical devices. First, we introduce our design and implementation approach for the system and characterize its performance. Next, we demonstrate in vitro navigation of different microrobot structures using magnetic field gradients and rotating magnetic fields. Spherical permanent magnets, electroplated cylindrical microrobots, microparticle swarms, and magnetic composite bacteria‐inspired helical structures are investigated. we also demonstrate the navigation of magnetic catheters in two challenging endovascular tasks: (1) an angiography procedure and (2) deep navigation within the circle of Willis. Catheter navigation is demonstrated in a porcine model in vivo to perform an angiography under magnetic guidance.This article is protected by copyright. All rights reserved

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Modeling Electromagnetic Navigation Systems

Cited by 31 publications

References 31 publications

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

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

A Simulation Framework for Magnetic Continuum Robots

A Human‐Scale Clinically Ready Electromagnetic Navigation System for Magnetically Responsive Biomaterials and Medical Devices

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