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Motor reorganization after stroke: From pathophysiology to treatment strategies
Caroline TscherpelDone
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Introduction
Sebastian CarstensDone
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EEG based triage of stroke patients in the ambulance
Dr. Wouter PottersDone
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Measuring the Effects of Amazonian Ayahuasca Retreats with EEG: The Challenges and Rewards of Naturalistic Neuroscience
Caspar MontgomeryDone
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Opening address
Martijn SchreuderDone
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Brain sources of the theta EEG rhythm underlying inhibitory control and replanning in active navigation in the Virtual House Locomotor Maze
Prof. Dr. Guy CheronDone
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The Neurocognition of Liveness
Dr. Guido OrgsDone
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Neural bases of individual differences in sensorimotor plasticity
Prof. Dr. Jacinta O'SheaDone
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EEG microstates as a tool to capture brain network dynamics
Prof. Dr. Christoph M. MichelDone
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A Lower-Dimensional Parameter?: Searching for Brain/Body electrophysiological metrics for individual and hyperscanning recordings
Prof. Francisco ParadaDone
Surjo R. Soekadar, MD, studied medicine in Mainz, Heidelberg and Baltimore. After a Research Fellowship at the Human Cortical Physiology and Stroke Neurorehabilitation Section (HCPS) at the National Institute of Neurological Disorders and Stroke (NINDS, NIH, USA), he continued his work at the University Hospital of Tübingen, Germany, where he became head of the Applied Neurotechnology Laboratory. In 2018, he transitioned his group to the Charité - Universitätsmedizin Berlin, where is became Germany’s first Professor of Clinical Neurotechnology. He is currently head of the research division ‘Translation and Neurotechnology’ and medical head of the Center for Translational Neuromodulation. Dr. Soekadar received various prizes and awards such as the NIH-DFG Research Career Transition Award, the NIH Fellows’ Award for Research Excellence, the International BCI Research Award as well as the BIOMAG and NARSAD Young Investigator Awards. Most recently, he received the ERC PoC and Consolidator Grant to develop a bidirectional quantum-BCI.
Non-invasive brain stimulation (NIBS) is increasingly used to treat neurological and psychiatric disorders, but its underlying mechanisms are still not fully understood. Combinations with advanced neuroimaging methods and implementation of closed-loop approaches allow now to draw a more precise picture of these mechanisms and may result in more robust and efficient protocols. This talk will introduce the latest advances in establishing such closed-loop approaches and outline possible clinical applications. Moreover, implementation of these protocols in bidirectional brain-computer interfaces (BCI) will be discussed.