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小鼠决策过程中先验信息的全脑表征。

Brain-wide representations of prior information in mouse decision-making.

作者信息

Findling Charles, Hubert Felix, Acerbi Luigi, Benson Brandon, Benson Julius, Birman Daniel, Bonacchi Niccolò, Buchanan E Kelly, Bruijns Sebastian, Carandini Matteo, Catarino Joana A, Chapuis Gaelle A, Churchland Anne K, Dan Yang, Davatolhagh Felicia, DeWitt Eric E J, Engel Tatiana A, Fabbri Michele, Faulkner Mayo A, Fiete Ila Rani, Freitas-Silva Laura, Gerçek Berk, Harris Kenneth D, Häusser Michael, Hofer Sonja B, Hu Fei, Huntenburg Julia M, Khanal Anup, Krasniak Chris, Langdon Christopher, Langfield Christopher A, Latham Peter E, Lau Petrina Y P, Mainen Zach, Meijer Guido T, Miska Nathaniel J, Mrsic-Flogel Thomas D, Noel Jean-Paul, Nylund Kai, Pan-Vazquez Alejandro, Paninski Liam, Pillow Jonathan, Rossant Cyrille, Roth Noam, Schaeffer Rylan, Schartner Michael, Shi Yanliang, Socha Karolina Z, Steinmetz Nicholas A, Svoboda Karel, Tessereau Charline, Urai Anne E, Wells Miles J, West Steven Jon, Whiteway Matthew R, Winter Olivier, Witten Ilana B, Zador Anthony, Zhang Yizi, Dayan Peter, Pouget Alexandre

机构信息

University of Geneva, Geneva, Switzerland.

University of Helsinki, Helsinki, Finland.

出版信息

Nature. 2025 Sep;645(8079):192-200. doi: 10.1038/s41586-025-09226-1. Epub 2025 Sep 3.

DOI:10.1038/s41586-025-09226-1
PMID:40903597
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12408363/
Abstract

The neural representations of prior information about the state of the world are poorly understood. Here, to investigate them, we examined brain-wide Neuropixels recordings and widefield calcium imaging collected by the International Brain Laboratory. Mice were trained to indicate the location of a visual grating stimulus, which appeared on the left or right with a prior probability alternating between 0.2 and 0.8 in blocks of variable length. We found that mice estimate this prior probability and thereby improve their decision accuracy. Furthermore, we report that this subjective prior is encoded in at least 20% to 30% of brain regions that, notably, span all levels of processing, from early sensory areas (the lateral geniculate nucleus and primary visual cortex) to motor regions (secondary and primary motor cortex and gigantocellular reticular nucleus) and high-level cortical regions (the dorsal anterior cingulate area and ventrolateral orbitofrontal cortex). This widespread representation of the prior is consistent with a neural model of Bayesian inference involving loops between areas, as opposed to a model in which the prior is incorporated only in decision-making areas. This study offers a brain-wide perspective on prior encoding at cellular resolution, underscoring the importance of using large-scale recordings on a single standardized task.

摘要

关于世界状态的先验信息的神经表征仍未得到充分理解。在此,为了对其进行研究,我们检查了国际大脑实验室收集的全脑Neuropixels记录和宽场钙成像。小鼠经过训练以指示视觉光栅刺激的位置,该刺激以可变长度的块形式出现在左侧或右侧,先验概率在0.2和0.8之间交替。我们发现小鼠能够估计这种先验概率,从而提高它们的决策准确性。此外,我们报告称,这种主观先验在至少20%至30%的脑区中进行编码,值得注意的是,这些脑区跨越了从早期感觉区域(外侧膝状体核和初级视觉皮层)到运动区域(次级和初级运动皮层以及巨细胞网状核)以及高级皮层区域(背侧前扣带区和腹外侧眶额皮层)的所有处理层次。这种先验的广泛表征与涉及区域间循环的贝叶斯推理神经模型一致,这与仅在先决策区域纳入先验的模型不同。这项研究从细胞分辨率的角度提供了全脑层面的先验编码观点,强调了在单一标准化任务上使用大规模记录的重要性。

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