Anyone needing a tomography gets the clearest possible images of an organ or other body structure slice by slice. But the further inside the potential problem lies, the more difficult it is to obtain high-resolution images in magnetic resonance imaging. An international team of scientists led by the University of Duisburg-Essen (UDE) has developed a high-frequency coil that allows for much better range inside the body – among other advantages.
The scientific journal Nature Communications covers the topic.
The leaky wave antenna is built of periodic metamaterial structures.
Products and exhibitors around imaging
Exhibitors and products related to this topic can be found in the database of MEDICA 2020:
Magnetic resonance imaging (MRI) at 7 tesla is the latest generation of this technology and offers images with a significantly higher-resolution than the classic devices, working with a maximum magnetic flux density of 3 tesla. However, the high-frequency magnetic fields at 7 tesla in particular are strongly absorbed by body tissue and therefore only poorly reach organs that are located far inside, such as the heart or prostate.
Dr. Jan Taro Svejda from the Department of General and Theoretical Electrical Engineering (ATE) and the Center for Nanointegration (CENIDE) – together with colleagues from the ITMO University of St. Petersburg (Russia), the Technical University of Eindhoven and the University Hospital of Utrecht (both in the Netherlands) – has developed a new high-frequency coil with three decisive properties: The composite made of periodic metamaterial structures directs the energy into the radiated magnetic field as effectively as possible. This avoids an intense magnetic field directly around the antenna – and thus also on the body under examination. At the same time, this leads to a greater range because less energy is absorbed by the tissue.
The third advantage comes with the possibilities offered by this new type of leaky wave antenna: Conventional MRI antennas excite the resonance of hydrogen atomic nuclei in the body. Cartilage, however, could be better represented using the resonance of sodium nuclei, for example; but to date, this would require a different antenna with the appropriate operating frequency. "Our coil, on the other hand, can also generate such alternative magnetic resonances," Svejda explains. "In other words, complementary MRI images, which additionally highlight tissue structures containing sodium, such as cartilage, can be produced with only one antenna."
As a next step, the team is now working on a new version of the metamaterial structure that can further enhance the image quality from inside the body.
MEDICA-tradefair.com; Source: University of Duisburg-Essen (UDE)