striatal circuits

Hallucinating mice, dopamine and immunity; towards mechanistic treatment targets for psychosis

Hallucinations are a core symptom of psychotic disorders and have traditionally been difficult to study biologically. We developed a new behavioral computational approach to measure hallucinations-like perception in humans and mice alike. Using targeted neural circuit manipulations, we identified a causal role for striatal dopamine in mediating hallucination-like perception. Building on this, we currently investigate the neural and immunological upstream regulators of these dopaminergic circuits with the goal to identify new biological treatment targets for psychosis

Striatal circuits underlying sensorimotor functions

Pulvinar and striatal circuits for auditory processing and behaviors

Striatal circuits for reward learning and decision-making

How are actions linked with subsequent outcomes to guide choices? The nucleus accumbens (NAc), which is implicated in this process, receives glutamatergic inputs from the prelimbic cortex (PL) and midline regions of the thalamus (mTH). However, little is known about what is represented in PL or mTH neurons that project to NAc (PL-NAc and mTH-NAc). By comparing these inputs during a reinforcement learning task in mice, we discovered that i) PL-NAc preferentially represents actions and choices, ii) mTH-NAc preferentially represents cues, iii) choice-selective activity in PL-NAc is organized in sequences that persist beyond the outcome. Through computational modelling, we demonstrate that these sequences can support the neural implementation of temporal difference learning, a powerful algorithm to connect actions and outcomes across time. Finally, we test and confirm predictions of our circuit model by direct manipulation of PL-NAc neurons. Thus, we integrate experiment and modelling to suggest a neural solution for credit assignment.

Regionally distinct striatal circuits support broadly opponent aspects of action suppression and production

COSYNE 2022

Regionally distinct striatal circuits support broadly opponent aspects of action suppression and production

COSYNE 2022

Anatomical and functional characterization of Amygdala-Striatal circuits

LINE-1 long non-coding RNAs at striatal circuits contribute to the transition from flexible to inflexible behavioral control

Modulating and monitoring the functionality of corticostriatal circuits using an electrostimulable microfluidic device

Role of postsynaptic β2-containing nicotinic acetylcholine receptors in striatal circuits and related behavior