In-silico model of the pregnant uterus as a network of oscillators under sparse adaptive control

arXiv - PHYS - Biological Physics Pub Date : 2024-08-01 DOI:arxiv-2408.00956

Giuseppe Maria Ferro, Andrea Somazzi, Didier Sornette

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Abstract

To ensure optimal survival of the neonate, the biological timing of parturition must be tightly controlled. Medical studies show that a variety of endocrine systems play the role of a control system, establishing a dynamic balance between the forces that cause uterine quiescence during pregnancy and the forces that produce coordinated uterine contractility at parturition. These control mechanism, and the factors that affect their performance, are still poorly understood. To help fill this gap, we propose a model of the pregnant uterus as a network of FitzHugh-Nagumo oscillators, with each cell symbolizing the electrical activity of a myocyte. The model is augmented with sparse adaptive control mechanisms representing the regulating endocrine functions. The control system is characterized by the fraction of controlled sites, and strength of control. We quantitatively find the conditions for which the control system exhibit a balance between robustness (resilience against perturbations) and flexibility (ability to switch function with minimal cost) crucial for optimal neonatal survival. Specifically, we show that Braxton-Hicks and Alvarez contractions, which are observed sporadic contractions of the uterine muscle, serve as a safety valve against over-controlling, strategically suppressed yet retained to optimize the control system's efficiency. Preterm birth is suggested to be understood as a mis-identification of the control boundaries. These insights contribute to advancing our understanding of maternal-fetal health.

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作为稀疏自适应控制下振荡器网络的妊娠子宫内模拟模型

为了确保新生儿的最佳存活率，必须严格控制分娩的生理时间。医学研究表明，各种内分泌系统扮演着控制系统的角色，在怀孕期间导致子宫静止的力量和分娩时产生协调子宫收缩的力量之间建立动态平衡。人们对这些控制机制以及影响其性能的因素仍然知之甚少。为了帮助填补这一空白，我们提出了一个妊娠子宫模型，它是一个由 FitzHugh-Nagumo 振荡器组成的网络，每个细胞象征一个肌细胞的电活动。该模型由代表内分泌调节功能的稀疏自适应控制机制来增强。控制系统的特征在于受控点的比例和控制强度。我们定量地找到了控制系统在稳健性（抵御干扰的能力）和灵活性（以最小代价切换功能的能力）之间取得平衡的条件，这对新生儿的最佳生存至关重要。具体来说，我们发现，子宫肌肉的布拉克斯顿-希克斯收缩和阿尔瓦雷斯收缩是一种可观察到的偶发性收缩，它们是防止过度控制的安全阀，在战略上受到抑制，但仍被保留下来，以优化控制系统的效率。早产被认为是对控制边界的错误识别。这些见解有助于加深我们对母体-胎儿健康的理解。

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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arXiv - PHYS - Biological Physics

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