Protein aggregation and large complex formation are known to be fundamental for the progression of many neurological disorders. Studying such dynamic processes is therefore key for developing new drugs
and treatments to tackle imminent challenges in neuroscience and medicine. Despite the wide range of applications that benefit from the accurate readout of molecular interactions and dynamics, methods to unveil such processes in the native context and at high throughput
are scarce . This technological void forces researchers to use laborious methods to infer information on said mechanisms, frequently resorting to simplified model systems. This not only hinders the pace of
research and escalates costs but also runs the risk of overlooking potential interferences inherent in the native systems. Developing technologies and assays able to reveal protein-protein interaction and aggregation as
well as other types of structural alterations in a direct, robust, and cheap way inside relevant biological environments should therefore be a key focus of future neuroscience research.
In this project we provide a technological solution capable of measuring protein interactions directly in live neuronal cells and tissues, revealing selected protein n-meric states from oligomers to large complex aggregates.