Title: Bridging Neural Dynamics to Goal-Directed Behavior Across Species and Timescales
Abstract:
Humans and animals exhibit a range of interesting behaviors in dynamic environments, and it is unclear how the brain reformats dense sensory information to enable these behaviors. To gain traction on this problem, new recording paradigms now facilitate the ability to record and manipulate hundreds to thousands of neurons in awake, behaving animals. Consequently, a pressing need arises to distill these data into interpretable insights about how neural circuits give rise to intelligent behaviors.
To engage with these issues, I take a computational approach, known as “goal-driven modeling”, that leverages recent advancements in artificial intelligence (AI) to express hypotheses for the evolutionary constraints of neural circuits in a mathematically closed-form. These constraints guide the iterative optimization of artificial neural networks to achieve a specific behavior (“goal”). By carefully analyzing the factors that contribute to model fidelity in predicting large-scale neural response patterns, we can gain insight into why certain brain areas respond as they do, and what selective pressures over evolutionary and developmental timescales give rise to the diversity of observed neural responses.
In this talk, I apply this approach to examine the functional constraints of brain areas in adaptive behaviors across multiple timescales: 1. visual scene processing in mice (within 250 ms), and 2. visually-grounded mental simulation in primates (within several seconds). Additionally, I will briefly touch upon the identification of plasticity rules during learning over potentially longer timescales (within an organism’s lifetime). Finally, I conclude with future directions towards closing the perception-action loop shared across species. I propose building integrative, embodied agents that serve as normative accounts of how neural circuits collaborate to enable meaningful interaction with the physical world. The design of these agents would help reveal evolutionarily conserved principles of natural cognition, and lead to more common-sense, physically-grounded AI algorithms along the way.