Entropy of Neuronal Spike Patterns.

IF 2.1 3区 物理与天体物理 Q2 PHYSICS, MULTIDISCIPLINARY Entropy Pub Date : 2024-11-11 DOI:10.3390/e26110967
Artur Luczak
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Abstract

Neuronal spike patterns are the fundamental units of neural communication in the brain, which is still not fully understood. Entropy measures offer a quantitative framework to assess the variability and information content of these spike patterns. By quantifying the uncertainty and informational content of neuronal patterns, entropy measures provide insights into neural coding strategies, synaptic plasticity, network dynamics, and cognitive processes. Here, we review basic entropy metrics and then we provide examples of recent advancements in using entropy as a tool to improve our understanding of neuronal processing. It focuses especially on studies on critical dynamics in neural networks and the relation of entropy to predictive coding and cortical communication. We highlight the necessity of expanding entropy measures from single neurons to encompass multi-neuronal activity patterns, as cortical circuits communicate through coordinated spatiotemporal activity patterns, called neuronal packets. We discuss how the sequential and partially stereotypical nature of neuronal packets influences the entropy of cortical communication. Stereotypy reduces entropy by enhancing reliability and predictability in neural signaling, while variability within packets increases entropy, allowing for greater information capacity. This balance between stereotypy and variability supports both robustness and flexibility in cortical information processing. We also review challenges in applying entropy to analyze such spatiotemporal neuronal spike patterns, notably, the "curse of dimensionality" in estimating entropy for high-dimensional neuronal data. Finally, we discuss strategies to overcome these challenges, including dimensionality reduction techniques, advanced entropy estimators, sparse coding schemes, and the integration of machine learning approaches. Thus, this work summarizes the most recent developments on how entropy measures contribute to our understanding of principles underlying neural coding.

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神经元尖峰模式的熵
神经元尖峰模式是大脑神经通信的基本单位,但人们对它的了解仍不全面。熵测量为评估这些尖峰模式的可变性和信息含量提供了一个量化框架。通过量化神经元模式的不确定性和信息含量,熵指标可以帮助人们深入了解神经编码策略、突触可塑性、网络动力学和认知过程。在此,我们将回顾基本的熵指标,然后举例说明最近在使用熵作为工具来提高我们对神经元处理过程的理解方面取得的进展。我们特别关注神经网络中临界动力学的研究,以及熵与预测编码和皮层通信的关系。我们强调了将熵测量从单个神经元扩展到多神经元活动模式的必要性,因为大脑皮层回路通过协调的时空活动模式(称为神经元包)进行交流。我们讨论了神经元包的顺序性和部分刻板性如何影响大脑皮层通信的熵。刻板性通过增强神经信号传递的可靠性和可预测性来降低熵,而数据包内的可变性则会增加熵,从而允许更大的信息容量。刻板性和可变性之间的这种平衡既支持大脑皮层信息处理的稳健性,也支持其灵活性。我们还回顾了应用熵分析这种时空神经元尖峰模式所面临的挑战,特别是在估算高维神经元数据熵时的 "维度诅咒"。最后,我们讨论了克服这些挑战的策略,包括降维技术、高级熵估计器、稀疏编码方案以及机器学习方法的整合。因此,这项工作总结了关于熵测量如何有助于我们理解神经编码基本原理的最新进展。
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来源期刊
Entropy
Entropy PHYSICS, MULTIDISCIPLINARY-
CiteScore
4.90
自引率
11.10%
发文量
1580
审稿时长
21.05 days
期刊介绍: Entropy (ISSN 1099-4300), an international and interdisciplinary journal of entropy and information studies, publishes reviews, regular research papers and short notes. Our aim is to encourage scientists to publish as much as possible their theoretical and experimental details. There is no restriction on the length of the papers. If there are computation and the experiment, the details must be provided so that the results can be reproduced.
期刊最新文献
Inferring About the Average Value of Audit Errors from Sequential Ratio Tests. How Do Transformers Model Physics? Investigating the Simple Harmonic Oscillator. "In Mathematical Language": On Mathematical Foundations of Quantum Foundations. Derangetropy in Probability Distributions and Information Dynamics. Generalized Filter Bank Orthogonal Frequency Division Multiplexing: Low-Complexity Waveform for Ultra-Wide Bandwidth and Flexible Services.
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