Source:http://ec.europa.eu/research/infocentre/article_en.cfm?id=/research/headlines/news/article_18_07_27-1_en.html?infocentre&item=Infocentre&artid=49584 Jul 27 2018Live cell imaging captures or visualizes human tissue in action. Several methods have been developed to study living cells in greater detail and with less effort, helping scientists gain a better grasp of biological functions. But the sort of super-resolution required to make fundamental medical discoveries comes with a trade-off between resolution, speed and exposure to too much light using current imaging methods.As technology and resolution improves, more and more detail can be detected showing even tiny changes to structures within the body. Now, the EU-funded HISTO-MRI project is taking that even further, developing technologies enabling non-invasive visualization of individual human cells in real time based on a radical new application for magnetic resonance imaging called high-frequency pulsed MRI.Groundbreaking tech neededRelated StoriesSlug serves as ‘command central’ for determining breast stem cell healthNew study reveals ‘clutch’ proteins responsible for putting T cell activation ‘into gear’Mathematical model helps quantify metastatic cell behaviorFirst, project scientists need to develop new methods for producing magnet coils based on 3D printing technology. The coils need to be able to withstand very high currents at high frequencies.Novel high-frequency, high-voltage pulsed power sources are also essential to the project’s work. In addition, new pulse sequencing and computer algorithms are needed to deal with, and analyze, the enormous amount of data collected.The team plans to ‘visualize’ a mouse brain at the neuron level as a proof of concept. Successfully implemented, this new technology could pave the way for transformational research in the neuroscience, bioengineering, biophysics and experimental oncology fields.The project is establishing the foundations for a new field of research – pulsed MRI in the high-frequency regime – which has the potential to radically advance MRI performance to micron resolution.