This blog post presents an example of using GIRF-corrected k-t trajectories for FID (free induction decay) MR spectroscopic imaging (MRSI) using rosette k-space sampling.

Mobile electronic devices face various potential conditions depending on their placement and orientation around the MRI magnet. To guarantee their proper functionality, we use sensors: magnetometers detect stray fields, accelerometers prevent vibration issues, and thermocouples control heating. This whitepaper proposes equipping such mobile devices with sensors to monitor environmental conditions in real-time, ensuring optimal operation and alerting operators when necessary. This same technology has been deployed in the NYOX base unit.

Learn about the technical architecture implemented in Skope’s latest innovation – the NYOX platform. The whitepaper details why the RF signal digitization occurs in the base unit and the main processing happens in the controller unit, while the high-speed interface between these two is done over the optical line using the standard JESD204B Subclass 1 protocol. 

Explore the hidden complexities of magnetic field encoding in MRI, from imperfect gradients to spherical harmonics, and learn how new techniques are enhancing image clarity and diagnostic precision.

Learn how Skope’s field cameras were used in the Iseult 11.7 T project, which was recently highlighted in Nature Methods, detailing the path to obtaining the most precise in vivo images of the human brain.

Read GIRF tutorial and access related material such as references, scripts and demo data. The demos were presented at the Skope User Meeting 2024, held in Tübingen, September 3.

Ever wondered how skope-i transforms field monitoring data into precise neuroscience images? Discover answers to three key questions about this image reconstruction engine in our blog post.

Discover the hidden dynamics of MR imaging with Skope tools. From enhancing neuroimaging to refining sequence development, delve into real-time field monitoring. Unveil the potential for sharper images and groundbreaking research.

Novel MR sequences have been introduced to improve and expand the applications of diffusion MRI in healthcare and neurosciences.

Ultra-high-field MRI has finally found its way into clinical practice. Despite large efforts in the ultra-high-field research, its full potential has yet to be realized.