Michael J. Rempe , Janne Grønli , Torhild Thue Pedersen , Jelena Mrdalj , Andrea Marti , Peter Meerlo , Jonathan P. Wisor
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引用次数: 5
Abstract
Millions of people worldwide are required to work when their physiology is tuned for sleep. By forcing wakefulness out of the body’s normal schedule, shift workers face numerous adverse health consequences, including gastrointestinal problems, sleep problems, and higher rates of some diseases, including cancers. Recent studies have developed protocols to simulate shift work in rodents with the intention of assessing the effects of night-shift work on subsequent sleep (Grønli et al., 2017). These studies have already provided important contributions to the understanding of the metabolic consequences of shift work (Arble et al., 2015; Marti et al., 2016; Opperhuizen et al., 2015) and sleep-wake-specific impacts of night-shift work (Grønli et al., 2017). However, our understanding of the causal mechanisms underlying night-shift-related sleep disturbances is limited. In order to advance toward a mechanistic understanding of sleep disruption in shift work, we model these data with two different approaches. First we apply a simple homeostatic model to quantify differences in the rates at which sleep need, as measured by slow wave activity during slow wave sleep (SWS) rises and falls. Second, we develop a simple and novel mathematical model of rodent sleep and use it to investigate the timing of sleep in a simulated shift work protocol (Grønli et al., 2017). This mathematical framework includes the circadian and homeostatic processes of the two-process model, but additionally incorporates a stochastic process to model the polyphasic nature of rodent sleep. By changing only the time at which the rodents are forced to be awake, the model reproduces some key experimental results from the previous study, including correct proportions of time spent in each stage of sleep as a function of circadian time and the differences in total wake time and SWS bout durations in the rodents representing night-shift workers and those representing day-shift workers. Importantly, the model allows for deeper insight into circadian and homeostatic influences on sleep timing, as it demonstrates that the differences in SWS bout duration between rodents in the two shifts is largely a circadian effect. Our study shows the importance of mathematical modeling in uncovering mechanisms behind shift work sleep disturbances and it begins to lay a foundation for future mathematical modeling of sleep in rodents.
全世界数以百万计的人在生理机能调整到睡眠状态时需要工作。通过强迫清醒脱离身体的正常作息,轮班工人面临着许多不利的健康后果,包括胃肠道问题、睡眠问题和更高的疾病发病率,包括癌症。最近的研究制定了模拟啮齿动物轮班工作的方案,旨在评估夜班工作对随后睡眠的影响(Grønli等人,2017)。这些研究已经为理解轮班工作的代谢后果提供了重要贡献(Arble et al., 2015;Marti等人,2016;Opperhuizen et al., 2015)和夜班工作对睡眠-觉醒的特定影响(Grønli et al., 2017)。然而,我们对夜班相关睡眠障碍的因果机制的理解是有限的。为了进一步了解轮班工作中睡眠中断的机制,我们用两种不同的方法对这些数据进行了建模。首先,我们应用一个简单的稳态模型来量化睡眠需求率的差异,通过慢波睡眠(SWS)期间慢波活动的上升和下降来衡量。其次,我们开发了一个简单而新颖的啮齿动物睡眠数学模型,并用它来研究模拟轮班工作协议中的睡眠时间(Grønli et al., 2017)。这个数学框架包括两过程模型的昼夜节律和稳态过程,但另外还包含一个随机过程来模拟啮齿动物睡眠的多相性质。通过仅改变啮齿动物被迫醒来的时间,该模型再现了先前研究中的一些关键实验结果,包括每个睡眠阶段的正确时间比例作为昼夜节律时间的函数,以及代表夜班工人和代表白班工人的啮齿动物的总清醒时间和SWS持续时间的差异。重要的是,该模型可以更深入地了解昼夜节律和体内平衡对睡眠时间的影响,因为它证明了两个班次中啮齿动物的SWS回合持续时间的差异在很大程度上是昼夜节律的影响。我们的研究显示了数学建模在揭示轮班工作睡眠障碍背后的机制方面的重要性,并开始为未来啮齿动物睡眠的数学建模奠定基础。
期刊介绍:
Neurobiology of Sleep and Circadian Rhythms is a multidisciplinary journal for the publication of original research and review articles on basic and translational research into sleep and circadian rhythms. The journal focuses on topics covering the mechanisms of sleep/wake and circadian regulation from molecular to systems level, and on the functional consequences of sleep and circadian disruption. A key aim of the journal is the translation of basic research findings to understand and treat sleep and circadian disorders. Topics include, but are not limited to: Basic and translational research, Molecular mechanisms, Genetics and epigenetics, Inflammation and immunology, Memory and learning, Neurological and neurodegenerative diseases, Neuropsychopharmacology and neuroendocrinology, Behavioral sleep and circadian disorders, Shiftwork, Social jetlag.
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