15:30-18:00
Opening Ceremony
Keynote Lecture
Is the future of computing biological? This lecture explores the development of the “living processor”—replacing transistors with neural organoids.
18:00-18:30
Break
18:30-19:30
Projects listed here:
- Project 1: Recognition of cognitive load and resting state in motion using mobilae optical tomography (DOT-fNIRS)
- Project 2: Genomic background effects in psychiatric disorders
- Project 3: Brainrot vs Brain
- Project 4: A Digital Tool for Tracking Neuropsychiatric Symptoms in Patients with Systemic Autoimmune Diseases
- Project 5: A local interface for the exploration and analysis of large connectomics datasets
- Project 6: How Fast Can the Brain Adapt? – Measuring Rapid Neuroplasticity with Eye Tracking and EEG using Python
- Project 7: An open‑source interface for preprocessing, anonymizing, and securing multi‑source training data for humanoid robots
- Project 8: Embedding the Mind: Mapping Psychological Constructs from Language
- Project 9: Rethinking cerebrospinal fluid (CSF) dynamics: a multimodal framework for brain network organization
- Project 10: Simulating Storytime – Neural Dynamics of Parent–Child Brain Synchrony
- Proeject 11: Time-Resolved Decoding of Perspective and Subjective Pain in EEG
- Project 12: Predicting Image Quality and Aesthetics from EEG
- Project 13: HyPhi: Information-Geometric Hyperscanning for Inter-Brain Alignment
09:00-13:00
Brainhacking
13:00-14:00
Lunch
14:00-19:00
Brainhacking
19:00-20:00
Dinner
20:00-23:00
Brainhacking
09:00-13:00
Brainhacking
13:00-14:00
Lunch
14:00-15:30
Presentation preparation
15:30-17:00
Projects listed here:
- Project 1: Recognition of cognitive load and resting state in motion using mobilae optical tomography (DOT-fNIRS)
- Project 3: Brainrot vs Brain
- Project 4: A Digital Tool for Tracking Neuropsychiatric Symptoms in Patients with Systemic Autoimmune Diseases
- Project 5: A local interface for the exploration and analysis of large connectomics datasets
- Project 6: How Fast Can the Brain Adapt? – Measuring Rapid Neuroplasticity with Eye Tracking and EEG using Python
- Project 7: An open‑source interface for preprocessing, anonymizing, and securing multi‑source training data for humanoid robots
- Project 8: Embedding the Mind: Mapping Psychological Constructs from Language
- Project 9: Rethinking cerebrospinal fluid (CSF) dynamics: a multimodal framework for brain network organization
- Project 10: Simulating Storytime – Neural Dynamics of Parent–Child Brain Synchrony
- Proeject 11: Time-Resolved Decoding of Perspective and Subjective Pain in EEG
- Project 12: Predicting Image Quality and Aesthetics from EEG
- Project 13: HyPhi: Information-Geometric Hyperscanning for Inter-Brain Alignment
17:00-18:15
Closing Ceremony
Keynote Lecture
How do 80,000 spiking neurons collapse into a single coherent thought? Join us to discover a groundbreaking mathematical bridge between microscopic neural noise and the large-scale brain activity we measure with EEG