Learning to combine top-down context and feed-forward representations under ambiguity with apical and basal dendrites.

IF 2.9 2区医学 Q2 NEUROSCIENCES

Cerebral cortex Pub Date : 2025-06-04 DOI:10.1093/cercor/bhaf134

Nizar Islah, Guillaume Etter, Mashbayar Tugsbayar, Busra Tugce Gurbuz, Blake Richards, Eilif B Muller

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引用次数: 0

Abstract

One of the hallmark features of neocortical anatomy is the presence of extensive top-down projections into primary sensory areas. It is hypothesized that one of the roles of these top-down projections is to carry contextual information that helps animals to resolve ambiguities in sensory data. One proposed mechanism of contextual integration is a combination of input streams at distinct apical and basal dendrites of pyramidal neurons. Computationally, however, it is yet to be demonstrated how such an architecture could leverage distinct compartments for flexible contextual integration and sensory processing. Here, we implement a deep neural network with distinct apical and basal compartments that integrates (a) contextual information from top-down projections to apical compartments and (b) sensory representations driven by bottom-up projections to basal compartments. In addition, we develop a new contextual integration task using generative modeling. The performance of deep neural networks augmented with our "apical prior" exceeds that of single-compartment networks. We find that a sparse subset of neurons of the context-relevant categories receive the largest top-down signals. We further show that this sparse gain modulation is necessary. Altogether, this suggests that the "apical prior" could be key for handling the ambiguities that animals encounter in the real world.

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学习结合自上而下的上下文和顶端和基部树突模糊情况下的前馈表征。

新皮质解剖学的标志性特征之一是存在广泛的自上而下的投射到初级感觉区。据推测，这些自上而下的投射的作用之一是携带上下文信息，帮助动物解决感官数据中的模糊性。上下文整合的一种被提出的机制是锥体神经元不同的顶端和基部树突的输入流的组合。然而，在计算上，还没有证明这种结构如何利用不同的隔间进行灵活的上下文整合和感觉处理。在这里，我们实现了一个具有不同根尖和基底隔室的深度神经网络，该网络集成了(a)自上而下投射到根尖隔室的上下文信息和(b)自下而上投射到基底隔室的感觉表征。此外，我们开发了一个使用生成建模的新的上下文集成任务。我们的“顶点先验”增强的深度神经网络的性能超过了单室网络。我们发现，上下文相关类别的神经元的稀疏子集接收最大的自上而下的信号。我们进一步证明了这种稀疏增益调制是必要的。总之，这表明“顶端先验”可能是处理动物在现实世界中遇到的模糊性的关键。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Cerebral cortex 医学-神经科学

CiteScore

6.30

自引率

8.10%

发文量

510

审稿时长

2 months

期刊介绍： Cerebral Cortex publishes papers on the development, organization, plasticity, and function of the cerebral cortex, including the hippocampus. Studies with clear relevance to the cerebral cortex, such as the thalamocortical relationship or cortico-subcortical interactions, are also included. The journal is multidisciplinary and covers the large variety of modern neurobiological and neuropsychological techniques, including anatomy, biochemistry, molecular neurobiology, electrophysiology, behavior, artificial intelligence, and theoretical modeling. In addition to research articles, special features such as brief reviews, book reviews, and commentaries are included.