Pascal, Joris
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- PublicationTracking of a magnetically navigated millirobot with a magnetic-field camera(IEEE, 10.04.2024) Vergne, Céline; Pinto Inácio, José Miguel; Quirin, Thomas; Sargent, David; Madec, Morgan; Pascal, Joris [in: IEEE Sensors Journal]A significant progress has been made in the development of magnetic micromanipulation for minimally invasive surgery. The development of systems to localize millimeter-sized robots during magnetic manipulation without line-of-sight detection remains, however, a challenging task. In this study, we focused on the development of a tracking system aiming to fill this gap. A robot, which consists of a cylindrical magnet of 1-mm diameter, is localized using a 2-D array of 3-D magnetoresistive sensors. The system, also called magnetic-field camera (MFC), provides tracking of the robot with a refresh rate of 2 Hz. The developed tracking algorithm reaches a mean absolute error (MAE) for the position and the orientation of, respectively, 0.56 mm and 5.13° in 2-D. This system can be added to the existing magnetic manipulation systems (MMSs) allowing closed-loop control of the navigation. The performances of the MFC are not affected by an exposure to strong magnetic fields. Exposures up to 3 T have been validated. Increasing the integrability of the MFC into MMSs. The presented tracking system makes it possible to target applications, such as minimally invasive eye surgery or drug delivery. The high spatial and magnetic resolutions allow the tracking of magnetic particles, down to 200- μm diameter, when placed close to the surface. The system could also be suitable for the localization of small objects for 2-D biomanipulation.01A - Beitrag in wissenschaftlicher Zeitschrift
- PublicationLow-field electromagnetic tracking using 3-D magnetometer for assisted surgery(IEEE, 02/2023) Vergne, Céline; Féry, Corentin; Quirin, Thomas; Nicolas, Hugo; Madec, Morgan; Hemm-Ode, Simone; Pascal, Joris [in: IEEE Transactions on Magnetics]01A - Beitrag in wissenschaftlicher Zeitschrift
- PublicationMonitoring the exposure to magnetic fields of MRI workers using goggles integrating magnetometers(2023) Jeker, Dominic; Quirin, Thomas; Pascal, Joris [in: 2023 IEEE International Symposium on Medical Measurements and Applications (MeMeA)]04B - Beitrag Konferenzschrift
- PublicationGradiometer-based magnetic localization for medical tools(IEEE, 2023) Fischer, Cedric; Quirin, Thomas; Chautems, Christophe; Boehler, Quentin; Pascal, Joris; Nelson, Bradley J. [in: IEEE Transactions on Magnetics]01A - Beitrag in wissenschaftlicher Zeitschrift
- PublicationMagnetic field interactions of smartwatches and portable electronic devices with CIEDs. Did we open a Pandora’s box?(Elsevier, 12/2022) Badertscher, Patrick; Vergne, Céline; Féry, Corentin; Mannhart, Diego; Quirin, Thomas; Osswald, Stefan; Kühne, Michael; Sticherling, Christian; Knecht, Stefan; Pascal, Joris [in: International Journal of Cardiology Heart & Vasculature]Magnetic interaction of portable electronic devices (PEDs), such as state-of-the art mobile phones, with cardiovascular implantable electronic devices (CIEDs) has been reported. The aim of the study was to quantify the magnetic fields of latest generation smartwatches and other PEDs and to evaluate and predict their risk of CIED interactions.01A - Beitrag in wissenschaftlicher Zeitschrift
- PublicationA magnetic camera to assess the risk of magnetic interaction between portable electronics and cardiac implantable electronic devices(IEEE, 06/2022) Quirin, Thomas; Vergne, Céline; Féry, Corentin; Badertscher, Patrick; Nicolas, Hugo; Mannhart, Diego; Osswald, Stefan; Kuhne, Michael; Sticherling, Christian; Madec, Morgan; Hébrard, Luc; Knecht, Sven; Pascal, Joris [in: IEEE International Symposium on Medical Measurements and Applications (MeMeA)]04B - Beitrag Konferenzschrift
- PublicationMagnetic field measurements of portable electronic devices. The risk inside pockets for patients with cardiovascular implantable devices(American Heart Association, 15.03.2022) Féry, Corentin; Desombre, Adrien; Quirin, Thomas; Badertscher, Patrick; Sticherling, Christian; Knecht, Sven; Pascal, Joris [in: Circulation. Arrhythmia and Electrophysiology]01A - Beitrag in wissenschaftlicher Zeitschrift
- PublicationMillirobot magnetic manipulation for ocular drug delivery with sub millimeter precision(IEEE, 2022) Vergne, Céline; Ignacio, Jose; Quirin, Thomas; Sargent, David; Pascal, Joris [in: 2022 IEEE Sensors]Significant progress has been made in the development of magnetic micromanipulation for minimally invasive surgery. The development of systems to localize millimetric size robots during magnetic navigation and without line of sight remains however a challenging task. In this study, we focused on the development of a tracking system aiming to fill this gap. A robot which consists of a cylindrical magnet of 1 mm diameter is localized using a 2D array of 3D magneto resistive sensors. The system provides a tracking of the robot with a refreshing rate of 2 Hz. The developed tracking algorithm reaches a mean absolute error for the position and the orientation of, respectively 0.56 mm and 5.13° in 2D. This system can be added to existing magnetic navigation systems allowing closed loop control of the navigation. The presented tracking system makes it possible to target applications such as minimally invasive ocular drug delivery.04B - Beitrag Konferenzschrift
- PublicationTowards tracking of deep brain stimulation electrodes using an integrated magnetometer(MDPI, 10.04.2021) Quirin, Thomas; Féry, Corentin; Vogel, Dorian; Vergne, Céline; Sarracanie, Mathieu; Salameh, Najat; Madec, Morgan; Hemm-Ode, Simone; Hebrard, Luc; Pascal, Joris [in: Sensors]This paper presents a tracking system using magnetometers, possibly integrable in a deep brain stimulation (DBS) electrode. DBS is a treatment for movement disorders where the position of the implant is of prime importance. Positioning challenges during the surgery could be addressed thanks to a magnetic tracking. The system proposed in this paper, complementary to existing procedures, has been designed to bridge preoperative clinical imaging with DBS surgery, allowing the surgeon to increase his/her control on the implantation trajectory. Here the magnetic source required for tracking consists of three coils, and is experimentally mapped. This mapping has been performed with an in-house three-dimensional magnetic camera. The system demonstrates how magnetometers integrated directly at the tip of a DBS electrode, might improve treatment by monitoring the position during and after the surgery. The three-dimensional operation without line of sight has been demonstrated using a reference obtained with magnetic resonance imaging (MRI) of a simplified brain model. We observed experimentally a mean absolute error of 1.35 mm and an Euclidean error of 3.07 mm. Several areas of improvement to target errors below 1 mm are also discussed.01A - Beitrag in wissenschaftlicher Zeitschrift
- PublicationTowards tracking of deep brain stimulation electrodes using an integrated magnetometer(MDPI, 04/2021) Quirin, Thomas; Féry, Corentin; Vogel, Dorian; Vergne, Céline; Sarracanie, Mathieu; Salameh, Najat; Madec, Morgan; Hemm-Ode, Simone; Hébrard, Luc; Pascal, Joris [in: Sensors]This paper presents a tracking system using magnetometers, possibly integrable in a deep brain stimulation (DBS) electrode. DBS is a treatment for movement disorders where the position of the implant is of prime importance. Positioning challenges during the surgery could be addressed thanks to a magnetic tracking. The system proposed in this paper, complementary to existing procedures, has been designed to bridge preoperative clinical imaging with DBS surgery, allowing the surgeon to increase his/her control on the implantation trajectory. Here the magnetic source required for tracking consists of three coils, and is experimentally mapped. This mapping has been performed with an in-house three-dimensional magnetic camera. The system demonstrates how magnetometers integrated directly at the tip of a DBS electrode, might improve treatment by monitoring the position during and after the surgery. The three-dimensional operation without line of sight has been demonstrated using a reference obtained with magnetic resonance imaging (MRI) of a simplified brain model. We observed experimentally a mean absolute error of 1.35 mm and an Euclidean error of 3.07 mm. Several areas of improvement to target errors below 1 mm are also discussed.01A - Beitrag in wissenschaftlicher Zeitschrift