Emergence of informative higher scales in biological systems: a computational toolkit for optimal prediction and control.

Q2 Agricultural and Biological Sciences Communicative and Integrative Biology Pub Date : 2020-08-15 DOI:10.1080/19420889.2020.1802914

Erik Hoel, Michael Levin

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Abstract

The biological sciences span many spatial and temporal scales in attempts to understand the function and evolution of complex systems-level processes, such as embryogenesis. It is generally assumed that the most effective description of these processes is in terms of molecular interactions. However, recent developments in information theory and causal analysis now allow for the quantitative resolution of this question. In some cases, macro-scale models can minimize noise and increase the amount of information an experimenter or modeler has about "what does what." This result has numerous implications for evolution, pattern regulation, and biomedical strategies. Here, we provide an introduction to these quantitative techniques, and use them to show how informative macro-scales are common across biology. Our goal is to give biologists the tools to identify the maximally-informative scale at which to model, experiment on, predict, control, and understand complex biological systems.

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生物系统中信息量更大尺度的出现：优化预测和控制的计算工具包。

生物科学跨越许多空间和时间尺度，试图了解胚胎发生等复杂系统级过程的功能和进化。一般认为，对这些过程最有效的描述是分子相互作用。然而，信息论和因果分析的最新发展现在可以定量地解决这个问题。在某些情况下，宏观模型可以最大限度地减少噪音，增加实验者或建模者关于 "什么做什么 "的信息量。这一结果对进化、模式调控和生物医学策略有诸多影响。在这里，我们将介绍这些定量技术，并用它们来说明信息量巨大的宏观尺度是如何在生物学中普遍存在的。我们的目标是为生物学家提供工具，以确定信息量最大的尺度，从而对复杂的生物系统进行建模、实验、预测、控制和理解。

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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