Neuronal Mechanisms of Human Episodic Memory

The rapid formation of new memories and the recall of old memories to inform decisions is essential for human cognition, but the underlying neural mechanisms remain poorly understood. The long-term goal of this research is a circuit-level understanding of human memory to enable the development of new treatments for the devastating effects of memory disorders. The study experiments utilize the rare opportunity to record in-vivo from human single neurons simultaneously in multiple brain areas in patients undergoing treatment for drug resistant epilepsy. The overall objective is to continue and expand a multi-institutional (Cedars Sinai/Caltech, Johns Hopkins, U Toronto, Children's/Harvard, UC Denver, UCSB), integrated, and multi-disciplinary team. Jointly, the investigators have the expertise and patient volume to test key predictions on the neural substrate of human memory. The study will utilize a combination of (i) in-vivo recordings in awake behaving humans assessing memory strength through confidence ratings, (ii) focal electrical stimulation to test causality, and (iii) computational analysis and modeling.

These techniques will be applied to investigate three overarching hypotheses on the mechanisms of episodic memory. First, to determine the role of persistent neuronal activity in translating working memories into longterm declarative memories (Aim 1). Second, to determine how declarative memories are translated into decisions (Aim 2). Third, to investigate how event segmentation, temporal binding and reinstatement during temporally extended experience facilitate episodic memory.

The expected outcomes of this work are an unprecedented characterization of how episodic memories are formed, retrieved and used for decisions, and how temporally extended experiences are segmented to form distinct but linked episodes. This work is significant because it moves beyond a "parts list" of neurons and brain areas by testing circuit-based hypotheses by simultaneously recording single-neurons from multiple frontal cortical and subcortical temporal lobe areas in humans who are forming, declaring and describing their memories. The proposed work is unusually innovative because it combines single-neuron recordings in multiple areas in behaving humans, develops new methods for non-invasive localization of implanted electrodes and electrical stimulation and directly test long-standing theoretical predictions on the role of evidence accumulation in memory retrieval.

A second significant innovation is the study team, which combines the patient volume and expertise of several major centers to maximally utilize the rare neurosurgical opportunities available to directly study the human nervous system. This innovative approach permits investigation of circuit-level mechanisms of human memory that cannot be studied non-invasively in humans nor in animal models. This integrated multi-disciplinary combination of human in-vivo single-neuron physiology, behavior, and modeling will contribute significantly to the understanding of the circuits and patterns of neural activity that give rise to human memory, which is a central goal of human neuroscience in general and the BRAIN initiative in particular.