Causal power of cortical neural ensembles: mechanisms and utility for brain perturbations

皮质神经元的因果力：大脑扰动的机制和效用

• 批准号: 10590631
• 负责人: Roozbeh Kiani
• 金额: $ 60.01万
• 依托单位: NEW YORK UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2022
• 资助国家: 美国
• 起止时间: 2022-04-01 至 2027-01-31
• 项目状态: 未结题
• 来源: https://reporter.nih.gov/project-details/10590631
• 关键词: Acceleration; Behavior; Behavior Control; Behavioral; Brain; Chronic; Classification; Cognition; Cognitive; Cortical Column; Data; Decision Making; Development; Dimensions; Electrodes; Ethics; Future; Genetic; Goals; Human; Impaired cognition; Individual; Investigation; Learning; Maps; Memory; Methods; Modeling; Monitor; Monkeys; Movement; Neurons; Neurosciences; Output; Pattern; Population; Prefrontal Cortex; Primates; Property; Protocols documentation; Pupil; Rest; Saccades; Sampling; Space Models; Statistical Methods; Statistical Models; Structure; System; Techniques; Technology; Testing; Therapeutic Intervention; Time; awake; brain machine interface; cognitive control; cognitive function; cognitive performance; gaze; improved; innovation; interdisciplinary approach; microstimulation; neural; neural circuit; novel; response; simulation; tool

PROJECT SUMMARY Understanding the causal interactions in large neural ensembles is key for developing techniques to alter cognitive behavior through targeted manipulation of the brain. This is a challenging goal because commonly used methods for recording neural responses in the human brain do not provide information about physical connections of neurons and allow only extremely sparse sampling of neurons in a circuit (typically <1%). Here, we develop an innovative path forward using a multi-disciplinary approach that combines recent theoretical and experimental advances by the two PIs (Kiani and Mazzucato). In Aim 1, we introduce a novel theoretical framework to infer a map of causal functional connectivity (CFC) based on sparse sampling from neurons in a circuit. Our framework successfully recovers the structure of functional interactions, identifies hub neurons in the circuit, and has multi-scale properties that make it applicable on a variety of data, ranging from spiking of individual neurons to aggregated spiking of clusters of neighboring neurons to local field potentials. In Aim 2, we test if the CFC inferred from a population of simultaneously recorded prefrontal neurons successfully predicts how microstimulation perturbs neural activity in the circuit. Specifically, we show the existence of hub neural clusters, identified through CFC, whose microstimulation has large and predictable impacts on the population response dynamics. Finally, in Aim 3, we explore if the CFC and perturbation effects at rest predict how microstimulation alters behavior during a perceptual decision-making task. We hypothesize that resting CFC combined with the population activity prior to microstimulation successfully predicts the effect of microstimulation both on the circuit activity and the behavior. The approach, data and analyses proposed in each of these aims are novel and the combination will provide a practical solution for a long-standing problem in systems neuroscience.

项目概要 了解大型神经系统中的因果相互作用是开发改变神经网络的技术的关键 通过有针对性地操纵大脑的认知行为。这是一个具有挑战性的目标，因为通常 用于记录人脑神经反应的方法不能提供有关物理的信​​息 神经元的连接，并且只允许对电路中的神经元进行极其稀疏的采样（通常<1%）。这里， 我们使用结合了最新理论和技术的多学科方法开发了一条创新的前进道路 两位 PI（Kiani 和 Mazzucato）的实验进展。在目标 1 中，我们引入了一种新颖的理论 框架根据神经元的稀疏采样推断因果功能连接（CFC）图 电路。我们的框架成功地恢复了功能相互作用的结构，识别了中枢神经元 该电路，并具有多尺度特性，使其适用于各种数据，范围从尖峰 单个神经元到相邻神经元簇的聚集尖峰到局部场电位。在目标 2 中， 我们测试 CFC 是否成功地从同时记录的前额叶神经元群体中推断出来 预测微刺激如何扰乱回路中的神经活动。具体来说，我们展示了 hub 的存在 通过 CFC 识别的神经簇，其微刺激对 人口反应动态。最后，在目标 3 中，我们探讨了静止时的 CFC 和扰动效应是否可以预测 微刺激如何在感知决策任务中改变行为。我们假设休息 CFC 与微刺激前的群体活动相结合，成功预测了 对电路活动和行为的微刺激。中提出的方法、数据和分析 这些目标中的每一个都是新颖的，结合起来将为长期存在的问题提供实用的解决方案 在系统神经科学中。