从钙成像到图拓扑

IF 3.6 3区 医学 Q2 NEUROSCIENCES Network Neuroscience Pub Date : 2022-10-01 eCollection Date: 2022-01-01 DOI:10.1162/netn_a_00262
Ann S Blevins, Dani S Bassett, Ethan K Scott, Gilles C Vanwalleghem
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引用次数: 0

摘要

系统神经科学正面临着不断增长的海量数据。蛋白质工程和显微镜的最新进展共同导致了神经科学的范式转变;利用荧光,我们现在可以通过行为动物的整个大脑对每个神经元的活动进行成像。即使在较大的生物体中,我们可以同时记录的神经元数量也随着时间呈指数增长。数据维数的增加引起了计算和数学方法的爆炸式增长,每种方法都使用不同的术语、不同的方法和不同的数学概念。在这里,我们收集、整理和解释了多种数据分析技术,这些技术已经或可能应用于全脑成像,并以斑马鱼幼虫为例模型。我们从线性回归等方法开始,这些方法旨在检测两个变量之间的关系。接下来,我们将通过网络科学和应用拓扑方法进行研究,重点关注许多变量之间的关系模式。最后,我们强调了生成模型的潜力,它可以提供关于连接规则和网络随时间或疾病进展的可测试假设。虽然我们使用的是幼体斑马鱼的成像例子,但这些方法适用于任何种群规模的神经网络建模,实际上,也适用于系统神经科学以外的应用。来自网络科学和应用拓扑的计算方法并不局限于斑马鱼幼虫,甚至不限于系统神经科学,因此,我们最后讨论了如何将这些方法应用于生物科学中的各种问题。
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From calcium imaging to graph topology.

Systems neuroscience is facing an ever-growing mountain of data. Recent advances in protein engineering and microscopy have together led to a paradigm shift in neuroscience; using fluorescence, we can now image the activity of every neuron through the whole brain of behaving animals. Even in larger organisms, the number of neurons that we can record simultaneously is increasing exponentially with time. This increase in the dimensionality of the data is being met with an explosion of computational and mathematical methods, each using disparate terminology, distinct approaches, and diverse mathematical concepts. Here we collect, organize, and explain multiple data analysis techniques that have been, or could be, applied to whole-brain imaging, using larval zebrafish as an example model. We begin with methods such as linear regression that are designed to detect relations between two variables. Next, we progress through network science and applied topological methods, which focus on the patterns of relations among many variables. Finally, we highlight the potential of generative models that could provide testable hypotheses on wiring rules and network progression through time, or disease progression. While we use examples of imaging from larval zebrafish, these approaches are suitable for any population-scale neural network modeling, and indeed, to applications beyond systems neuroscience. Computational approaches from network science and applied topology are not limited to larval zebrafish, or even to systems neuroscience, and we therefore conclude with a discussion of how such methods can be applied to diverse problems across the biological sciences.

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来源期刊
Network Neuroscience
Network Neuroscience NEUROSCIENCES-
CiteScore
6.40
自引率
6.40%
发文量
68
审稿时长
16 weeks
期刊最新文献
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