In this project, we have developed a novel and unique imaging tool that helps visualizing pivotal physiological processes, which are important for human health, in vivo. In particular, our imaging technology allows extracting information on electrophysiological processes that underlie, for instance, heart beat in a non-invasive way. We believe that this is directly related to important societal challenges since cardiovascular disease is responsible for the majority of all deaths worldwide. Along these lines, we were able to demonstrate the translational potential of our invention for human heart failure, which is a live-threatening condition that currently lacks efficient diagnosis and treatment. Furthermore, we were able to elucidate an unexpected role of pain medication in a poorly understood part of the central nervous system. Finally, we made first steps in identifying additional potential of our new tool for impacting breast cancer diagnosis. Therefore, we can conclude that we have successfully achieve the overall objective of developing a novel translational imaging tool, which potentially improves patient outcomes. Noteworthy, the major indication fields of cardiovascular disease, pain, and cancer represent all-important and critical challenges of societies in Europe and worldwide.
The overall educational objective was to provide training in chemical synthesis, small molecule analytics, radiochemistry, and molecular imaging to the researcher. These training goals were efficiently achieved by the mentorship and hands-on training at the partner institutions as well as attendance to educational workshops.