Prof. Dr. Joris Pascal is a lecturer in Life Sciences Technologies at the Institute for Medical Engineering and Medical Informatics (FHNW-IM2) in Muttenz, Switzerland. Joris holds a master’s degree in electrical engineering from the Ecole Supérieure d’Electricité (Supélec) in France and a PhD in Microelectronics from the University of Strasbourg, France. Before entering the faculty at the FHNW, Joris held Senior Scientists positions at ABB in Switzerland. Joris now focuses his energy on the development of sensor systems for Life Sciences and Medicine.
The Institute for Medical Engineering and Medical Informatics (FHNW-IM2) is active in the area of systems for diagnostic and therapeutic applications. We operate at the innovative intersection of industry, medicine and academia.
My research interests mainly focus on the investigation of new types of magnetic sensors and sensor systems and their applications in imaging, robotics and analytics. More specifically, I am active in the fields of MRI imaging, magnetic navigation and trackingOnce the resonance has been found (see Search), a continuous-wave NMR teslameter can lock onto a signal and continue measuring it, even... systems as well as in NMRNuclear Magnetic Resonance. A resonance phenomenon seen when you irradiate a sample in a magnetic field with an RF field.... spectroscopy. For all this applications, new types of sensors can help improving diagnostic or even open the way to new therapeutic solutions.
In this video, you can see a magnetic sensor network entering the tunnel of a clinical MRI. This network consists of an arrangement of nine three-dimensional magnetic field sensors based on the Metrolab MagVector™ MV2* magnetometerAn instrument to measure magnetic flux density (B) or magnetic field intensity (H).... on a chip (to my knowledge no other 3D magnetic sensor chip commercially available can measure up to 30T). The integration of a magnetic sensor module within a LEGO brick allows us to perform measurements in many geometrical configurations with a remarkable accuracyAccuracy is how close a measure conforms to reality. Even if our NMR Teslameter displays 9 digits, we claim 5... and ease to use. The video shows how the sensor network can acquire dynamic fields and the strong increase of the magnetic field as the sensor enters the tunnel. Actually, we acquire with this system the magnetic field gradients applied during imaging sequences. Unlike existing techniques, this system delivers the full magnetic field vector information.
We started the project with a general purpose. We aimed at developing a flexible magnetic field mapper, which could fit many R&D industrial applications or physics experiments besides the specific MRI application. However, the MRI application has been the first to be tested with our prototype. The inspiration came from my collaboration started many years earlier with the IADI lab at the University Hospital in Nancy, France. We needed to map the magnetic field gradients within an MRI in order to use this data set to locate objects during MRI imaging sequences. A surgical tool or an ECG electrode equipped with an MV2 chip can then be tracked during imaging.
The next step will be to make the modular sensor system even smaller and faster to be able to acquire any type of MRI magnetic field gradients. The recording of several MRI gradientIn this context, gradient refers to the spatial variation of the magnetic field.... types will allow us to locate an object in different MRI sequences. The main principle is still based on the unique relationship between magnetic field and location within the boreThe centre of a solenoidal magnet, where the magnetic field is concentrated.....
Magnetic field probes that could measure strong magnetic fields such as in a 3T MRI with several tens of kHz acquisition rate, a micro-Tesla resolutionResolution measures the ability of a magnetometer to distinguish ("resolve") two nearly identical field values. Related to precision, but not to... and parallel sampling capability for multiple probeThe actual sensor that is placed in the magnetic field. The NMR probe contains the NMR sample; the Hall probe... systems would be highly valuable. The sensing technology is there, the devices not yet commercially available.
Besides Metrolab’s team who provided their expertise as well as the MV2 chip, I worked with the IADI lab team of Prof. Jacques Felblinger, mainly Dr. Julien Oster and Benjamin Roussel. This lab located at the University Hospital in Nancy allowed us to test the system in a clinical MRI environment. Nicolas Collin from the University of Strasbourg has supported us in the software development.
1: Abstract #1759 ISMRM’18: Magnetic gradientIn this context, gradient refers to the spatial variation of the magnetic field.... mappingThe process of measuring magnetic field intensity at many different points, in order to understand the structure of the field... of a 3T MRI scanner using a modular array of novel three-axisThe magnetic field is a three-dimensional vector quantity. A single Hall element only measures one component. A three-axis Hall instrument has... Hall sensors,
Joris Pascal , Nicolas Weber , Jacques Felblinger , and Julien Oster
FHNW, University of Applied Sciences and Arts Northwestern Switzerland, Muttenz, Switzerland, U947, Inserm, Nancy, France, IADI, Université de Lorraine, Nancy, France
Try it! We promise not to flood your inbox with advertising.
Thank you for your interest in Metrolab! Please check your mailbox for an e-mail to confirm your subscription. If you don't receive it, check your spam box. Don't hesitate to contact us if you continue to have trouble.
On our social networks
Liu Yu, R&D manager at Aoxin, shares insights on the use of MFC9046 160 mm NMR probe array for extremity MRI magnet mapping.
Compact but powerful USB instruments.