Multisensory processes are fundamental in scaffolding perception, cognition, learning, and behavior. However, the structural and functional architecture that underlies the brain’s ability to seamlessly integrate a multitude of simultaneous multisensory inputs is poorly understood. Across multiple scales – from cellular to network and systems levels – specialized mechanisms enable crossmodal processing. Previously, multisensory integration was considered to primarily occur in higher-level cortices and was examined within a theoretical framework of computational principles associated with spatiotemporal stimulus characteristics. More recently, it has become evident that (i) physical stimulus attributes do not fully account for multisensory precepts, (ii) sensory processing streams affect one another even at very early stages, and (iii) multisensory processing is plastic and dynamic. While these findings have challenged many traditional views of crossmodal integration, we still lack a coherent picture of the neural basis underlying multisensory percept formation. Fundamental questions remain unanswered. Therefore, the goal of RTG 2416 is to gain a conceptual understanding of the mechanisms that govern crossmodal integration of sensory information at multiple scales. By implementing a unique MultiSenses–MultiScales approach, we substantially advance our knowledge in several areas of multisensory neuroscience. This RTG provides in-depth expertise in sensory neurobiology, fosters the spirit of transdisciplinary collaboration, and offers hands-on training in a variety of cutting-edge techniques . The RTG consortium is ideally suited to achieve these ambitious goals. Consequently, we train expert individuals that make the transition from cells to systems and behavior, thus, preparing trainees for various career paths. A coherent, though flexible curriculum builds a solid foundation in the core concepts of neuroscience. In addition, a specialized course program is tailored to individual needs. Combined with innovative qualification elements, professional skill development and – most importantly – the opportunity to conduct independent research in a nurturing environment, we train neuroscientists that can compete at the highest international level. In summary, RTG 2416 has become a prime location for both national and international doctoral researchers interested in the mechanistic foundation of multisensory integration.

DFG Programme Research Training Groups

Applicant Institution Rheinisch-Westfälische Technische Hochschule Aachen

Participating Institution Forschungszentrum Jülich

Spokesperson Professor Dr. Marc Spehr

Participating Researchers Professor Dr. Paolo Carloni; Professor Dr. Markus Diesmann; Professorin Dr.-Ing. Janina Fels; Professorin Dr. Sonja Grün; Professorin Dr. Ute Habel; Professor Björn Michael Kampa, Ph.D.; Professorin Dr. Angelika Lampert; Professorin Dr.-Ing. Dorit Merhof; Professor Dr. Simon Musall; Professorin Giulia Rossetti, Ph.D.; Professor Dr. Jörg Bernhard Schulz; Professorin Dr. Geraldine Zimmer-Bensch