State-dependent Decision-making in Brainwide Neural Circuits

全脑神经回路中的状态相关决策

基本信息

批准号：
10461991
负责人：
ANNE KATHRYN CHURCHLAND
金额：
$ 365.01万
依托单位：
COLUMBIA UNIV NEW YORK MORNINGSIDE
依托单位国家：
美国
项目类别：
财政年份：
2021
资助国家：
美国
起止时间：
2021-08-15 至 2026-07-31
项目状态：
未结题

来源：
https://reporter.nih.gov/project-details/10461991
关键词：
Affect Anatomy Animals Area Axon Bar Codes Behavior Behavioral Biological Assay Brain Brain region Collaborations Collection Communication Computer Models Computing Methodologies Data Analyses Data Collection Data Science Core Data Set Decision Making Development Disease Environment Etiology Food Gene Expression Genetic Goals Histology Impairment Individual Infrastructure International Laboratories Learning Maps Measurement Measures Methods Modeling Molecular Mus Mutation Neurons Pattern Population Protocols documentation Reproducibility Research Research Personnel Rewards Schizophrenia Standardization Structure Testing Training Ultrasonography Wild Type Mouse Work addiction autism spectrum disorder cell type data infrastructure data sharing deep learning expectation experimental study flexibility integrated circuit large datasets large scale data mouse model neural circuit neuromechanism next generation novel open source tool optogenetics relating to nervous system theories tool

项目摘要

Summary/Abstract Animals constantly make decisions, such as how to evaluate a potential threat or where to look for food. Yet the same animal in the same environment can produce different decisions on different occasions, because its internal state interacts powerfully with external inputs to determine behavior. This proposal’s overarching goal is to understand how internal states influence decisions and to identify the underlying neural mechanisms. In a mouse decision-making task, these experiments will examine the effects of three types of internal state changes: those arising spontaneously with engagement and disengagement in a task, those resulting from changing expectations during the task, and those resulting from learning within and across days. To determine how internal states affect brain activity and behavior, the team will apply cutting-edge technical advances on a brainwide scale, including statistical tools to infer internal states from behavior; simultaneous recordings from large populations of neurons across many regions during behavior and during optogenetic perturbations; assays that map functionally and molecularly defined cell-type-specific, cross-region connectivity; and computational approaches to model how cross-region neural communication depends on internal states. These ambitious goals go beyond the capabilities of an individual laboratory and are ideally suited for an already- productive consortium. This team is part of the International Brain Laboratory, which has already developed a standardized mouse decision-making task and standardized methods for training, neural measurement, and data analysis, along with a working, scalable infrastructure for sharing data. The proposed research leverages this existing infrastructure and takes it in a new direction. Projects 1-5 will examine simultaneously recorded population activity, evaluate causality, study neural activity and behavior during learning in normal and autism model mice, identify cell types by measuring neuronal activity, gene expression, and axonal projection patterns in the same populations of neurons, and build a comprehensive computational model of all these experimental results. Cores A-D will support the collection, replicability, management, and analysis of the large datasets produced by this brainwide examination of neural circuits. Taken together, the proposed research will rigorously define the neural basis of multiple internal states and evaluate their impact on the flow of decision-relevant information through the brain. The results will greatly advance the field by generating a comprehensive, mechanistic understanding of how internal states are reflected in the brain, and how these states interact with external inputs to guide decisions. Moreover, the team will produce and disseminate open-source tools and protocols that will enable other laboratories to collect and manage large-scale datasets produced through brainwide measurements.

摘要/摘要动物不断做出决定，例如如何评估潜在威胁或去哪里寻找食物。同一动物在同一环境下，在不同场合可能会做出不同的决定，因为内部状态与外部输入强有力地相互作用来确定该提案的总体目标。是了解内部状态如何影响决策并识别潜在的神经机制。小鼠决策任务中，这些实验将检查三种类型的内部状态变化的影响：那些因参与和脱离某项任务而自发产生的那些，那些因改变而产生的任务期间的期望，以及几天内和跨天学习的结果，以确定如何内部。状态影响大脑活动和行为，该团队将在全脑范围内应用尖端技术进步规模，包括从大量同时记录的行为推断内部状态的统计工具；在行为和光遗传学扰动过程中，许多区域的神经元群体；绘制功能和分子定义的细胞类型特异性、跨区域连接和计算；模拟跨区域神经通信如何依赖于内部状态的方法。这些雄心勃勃的目标超出了单个实验室的能力，非常适合已经- 该团队是国际脑实验室的一部分，该实验室已经开发了一个标准化小鼠决策任务和标准化训练、神经测量和数据方法分析以及用于共享数据的工作、可扩展的基础设施。项目 1-5 将检查同时记录的现有基础设施并将其带向新的方向。群体活动，评估因果关系，研究正常人和自闭症患者学习过程中的神经活动和行为模型小鼠，通过测量神经活动、基因表达和轴突投影模式来识别细胞类型在相同的神经元群体中，并建立所有这些实验的综合计算模型 Cores A-D 将支持大型数据集的收集、可复制性、管理和分析。由对神经回路的全脑检查产生的。总而言之，拟议的研究将严格定义多种内部状态的神经基础和评估它们对大脑中决策相关信息流的影响。通过对内部状态如何反映产生全面、先进、机械的理解此外，研究小组还将研究大脑中这些状态如何与外部输入相互作用以指导决策。制作和传播开源工具和协议，使其他实验室能够收集和管理通过全脑测量产生的大规模数据集。