Monitor Neural Activity

Project Summary This proposal seeks to investigate sex hormone effects on reward and aversion-related behaviors through mapping of Lateral Habenula (LHb) circuits. The LHb is a central hub important for encoding aversive information and coordinating motivated behaviors, actions critical for survival. Dysfunction in LHb-dependent circuits contribute to a diverse set of disordered behaviors, such as aberrant processing of positive and negative valence, anhedonia, depressive symptomology, and maladaptive stress response, to name a few.

PROJECT SUMMARY To flexibly execute behavior, choices are made based on previous outcomes that will maximize reward. Crucially, learning the value of each action to obtain a reward is thought to drive this decision making process. In a value-based decision making framework, these values are first computed and then used to select and execute actions. Dysfunction in this decision making process is evident in many neuropsychiatric disorders including addiction and in patients with frontal cortical damage who show an inability to flexibly adjust or adapt their behavior.

The brain uses the combined physiology of many cells to transform incoming sensory signals into internal representations. This process is critical for the animal’s survival because it underlies the animal’s ability to identify environmental cues and associate them with the condition of their situation. While sensory representation at the somatic level is well-studied, exploration of this phenomenon at the synaptic level is lacking.

Project Summary/Abstract Learning how spontaneous neuronal activity shapes embryonic brain development is critical for understanding neurodevelopmental processes, with implications in neurological or neuropsychiatric disorders. Early sporadic activity is essential for the formation of mature correlated neuronal networks. To date, we have had success in identifying the motor circuit as the first circuit to function in a developing zebrafish embryo. In addition, a few neurons, the “leader cells”, are the first neurons to obtain spontaneous neuronal activity.

PROJECT SUMMARY Serotonin has been long been recognized as an important modulator of mood and behavior, yet it projection- specific dynamics are little understood. While serotonin has been well studied in anxiolytic contexts, activity of certain serotonin projections works to increase stress behaviors. In particular, serotonergic projections from dorsal raphe to the anterodorsal bed nucleus of the stria terminalis have been shown to be anxiogenic.

PROJECT SUMMARY A core feature of a number of psychiatric illnesses is the disordered estimation of the predictive relationship between a given cue and an outcome. This failure to appraise and generate appropriate behavioral responses is true for cues that both are rewarding and aversive. For example, in post-traumatic stress disorders innocuous stimuli can elicit intense aversive motivational responses even though these were encountered in a safe and familiar context.

Project Summary/Abstract Electromagnetic brain stimulation is a safe and proven way of controlling neural activity non-invasively with no implanted hardware or injected biochemical agents. Transcranial magnetic stimulation (TMS) is FDA approved for treatment of drug resistant depression and obsessive compulsory disorder with a range of other clinical applications under investigation.

PROJECT SUMMARY Living organisms interact with complex environments that are inherently multisensory. Within these environments, the brain must integrate information from multiple sensory modalities, including the auditory and olfactory systems, for perception and behavior. However, despite the ubiquity and importance of multisensory integration, there is a critical gap in our understanding of how the brain integrates auditory and olfactory stimuli. This proposal will fill this knowledge gap by revealing the mechanisms underlying auditory-olfactory integration in the auditory cortex.

Project Summary / Abstract Astrocytes are pervasive throughout the CNS and are the most abundant non-neuronal cell type. They are an essential component of neural circuits, and increasing evidence demonstrates they are specialized for specific brain regions. For example, proteomic, transcriptomic, and electrophysiology experiments show that hippocampal and striatal astrocytes are distinct. However, it is unknown if astrocytes are heterogeneous within brain regions such as the striatum where neuronal subtypes are largely uniform.

The Brain Research through Advancing Innovative Neurotechnologies (BRAIN) Initiative promotes the development and application of technologies to describe the temporal and spatial dynamics of cell types and neural circuits in the brain.