SubsidieMeestersMechanisms of memory formation in cortical networks during learning of goal-directed behaviors
This project aims to map and manipulate causal connectivity in vivo between neurons during memory learning in mice using novel optical methods to understand network dynamics and memory mechanisms.
Projectdetails
Introduction
A central hypothesis in neuroscience is that changes in connectivity patterns between neurons support learning and memory formation. Most methods for examining connectivity between individual neurons rely on ex vivo experiments (e.g., in brain slices).
In Vivo Measurements
However, in vivo measurements are required to study how neurons causally influence each other's activity ('causal connectivity') in the living brain, and how these causal interactions change over time. Thus, while brain networks are among the most studied biological networks, the cellular-level patterns and dynamics of causal connectivity in vivo remain unknown.
Research Proposal
Here, I propose to study how causal connectivity between individual neurons and across entire brain areas changes over time during learning of memory-guided behaviors. To this end, we will use novel causal optical methods to longitudinally map causal connectivity and neural activity at cell resolution in vivo, focusing on the motor cortex and related areas.
Methodology
We will combine these methods with a novel goal-directed behavior in mice that does not require pretraining, which will serve as a baseline to study learning mechanisms of more complex behaviors that rely on short-term memory.
Specific Aims
- Aim 1: Map changes in causal connectivity during learning within the motor cortex.
- Aim 2: Map changes in causal connectivity across cortical areas and relate it to the computational functions of the network.
- Aim 3: Perturb neurons based on their connectivity and coding properties to identify changes in network mechanisms for short-term memory and action selection at various learning stages.
Optogenetic Induction
Finally, we will work towards identifying constraints on memory formation via optogenetic induction of artificial connectivity patterns.
Conclusion
Taken together, this research will enable for the first time to causally study dynamics in network interactions across time on different spatial scales, and to test fundamental mechanisms of memory formation and representation in cortical networks.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 2.110.000 |
| Totale projectbegroting | € 2.110.000 |
Tijdlijn
| Startdatum | 1-11-2024 |
| Einddatum | 31-10-2029 |
| Subsidiejaar | 2024 |
Partners & Locaties
Projectpartners
- TEL AVIV UNIVERSITYpenvoerder
Land(en)
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Creating Knowledge
This project aims to test a new theory on experience-dependent learning by investigating how knowledge networks are built and updated across species using innovative behavioral and neuroimaging techniques.
Connectome cost conservation model of skill learning
This project aims to model brain connectomes before and after skill learning to predict neuroplasticity and behavioral outcomes, bridging neuropsychology and neurobiology.
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This project aims to investigate the circuit and neuromodulatory mechanisms of sensory prediction learning in the visual cortex, enhancing understanding of self-generated feedback processing and its implications for neurodevelopmental conditions and AI.
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This project aims to test the dendrite assembly hypothesis in the mouse motor cortex to understand memory representation and its implications for Parkinson's disease and AI architectures.
Delineating Convergent and Divergent Cortico-Cerebellar pathways in motor Control
The CODI-MAP project investigates the cooperative mechanisms of cortico-cerebellar circuits in motor control and learning, aiming to reveal their complex interconnectivity and functional integration.