Computational models of the neural control of breathing

IF 7.9 Q1 Medicine
Y. Molkov, J. Rubin, I. Rybak, Jeffrey C. Smith
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引用次数: 53

Abstract

The ongoing process of breathing underlies the gas exchange essential for mammalian life. Each respiratory cycle ensues from the activity of rhythmic neural circuits in the brainstem, shaped by various modulatory signals, including mechanoreceptor feedback sensitive to lung inflation and chemoreceptor feedback dependent on gas composition in blood and tissues. This paper reviews a variety of computational models designed to reproduce experimental findings related to the neural control of breathing and generate predictions for future experimental testing. The review starts from the description of the core respiratory network in the brainstem, representing the central pattern generator (CPG) responsible for producing rhythmic respiratory activity, and progresses to encompass additional complexities needed to simulate different metabolic challenges, closed‐loop feedback control including the lungs, and interactions between the respiratory and autonomic nervous systems. The integrated models considered in this review share a common framework including a distributed CPG core network responsible for generating the baseline three‐phase pattern of rhythmic neural activity underlying normal breathing. WIREs Syst Biol Med 2017, 9:e1371. doi: 10.1002/wsbm.1371
呼吸神经控制的计算模型
持续的呼吸过程是哺乳动物生命所必需的气体交换的基础。每个呼吸周期都是由脑干中节律性神经回路的活动引起的,由各种调节信号形成,包括对肺膨胀敏感的机械受体反馈和依赖于血液和组织中气体成分的化学受体反馈。本文回顾了各种计算模型,旨在重现与呼吸神经控制相关的实验结果,并为未来的实验测试做出预测。该综述从描述脑干中的核心呼吸网络开始,代表负责产生有节奏的呼吸活动的中枢模式发生器(CPG),并逐步涵盖模拟不同代谢挑战所需的额外复杂性,包括肺在内的闭环反馈控制,以及呼吸和自主神经系统之间的相互作用。本综述中考虑的综合模型共享一个共同的框架,包括一个分布式CPG核心网络,负责产生正常呼吸下节律性神经活动的基线三相模式。中国生物医学工程学报,2017,39(4):571 - 571。doi: 10.1002 / wsbm.1371
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来源期刊
CiteScore
18.40
自引率
0.00%
发文量
0
审稿时长
>12 weeks
期刊介绍: Journal Name:Wiley Interdisciplinary Reviews-Systems Biology and Medicine Focus: Strong interdisciplinary focus Serves as an encyclopedic reference for systems biology research Conceptual Framework: Systems biology asserts the study of organisms as hierarchical systems or networks Individual biological components interact in complex ways within these systems Article Coverage: Discusses biology, methods, and models Spans systems from a few molecules to whole species Topical Coverage: Developmental Biology Physiology Biological Mechanisms Models of Systems, Properties, and Processes Laboratory Methods and Technologies Translational, Genomic, and Systems Medicine
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