Leveraging intrinsic non-sinusoidal patterns to infer search behavior to predict exposure to respiratory stressors.

IF 3.6 2区医学 Q1 PHYSIOLOGY

American journal of physiology. Lung cellular and molecular physiology Pub Date : 2025-07-01 Epub Date: 2025-05-27 DOI:10.1152/ajplung.00379.2024

Anju Bimal, Szilard L Beres, Victoria Ribeiro Rodrigues, Barbara K Smith, Paul W Davenport, Nicholas J Napoli

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引用次数: 0

Abstract

This study introduces a novel entropy-based methodology to quantitatively characterize nonlinear transient breathing dynamics under respiratory stress. Environmental and pathophysiological stressors can disrupt the respiratory system's gas exchange, leading to compromise and compensatory mechanisms. We present a data-driven approach that systematically evaluates classical respiratory features alongside novel entropic features as key indicators under respiratory stress. We demonstrate that conventional metrics like breathing rate (B_R), time of inspiration (T_I), and expiration (T_E) fail to capture discriminating features needed to detect early ventilatory instability and predict intervention needs. An exhaustive analysis of key respiratory fiducial points using entropic methods led to novel features for understanding respiratory mechanics and classifying respiratory states. We found that the nonlinear dynamics of the transition times between inspiratory and expiratory phases (interphases) are crucial for assessing adaptability to respiratory challenges. This metric quantifies the complexity of transition duration (acceleration and deceleration between phases) and is essential for predicting declining breathing states. Our predictive model incorporating these novel approaches showed superior discriminating ability over models using classical features, achieving a 50.76% increase in predictive power as measured by the area under the curve (AUC). These findings underscore the effectiveness of this entropy-based approach for early detection of respiratory compromise, with the best model achieving an AUC of 0.784. The results have significant implications for improving clinical monitoring of acute respiratory failure and managing chronic respiratory conditions.NEW & NOTEWORTHY Entropy-based metrics analyzing respiratory phase transitions (inspiration-to-expiration and expiration-to-inspiration) detect respiratory compromise under hypoxic conditions better than standard breathing rate measurements. Analysis of nonlinear dynamics during these transitions reveals key ventilatory adaptations during exposure to respiratory stressors. Measuring timing variations at phase transitions improves predictive model performance in detecting exposure to hypoxic environments by a 50.76% increase in area under the curve (AUC) vs. classical methods.

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利用固有的非正弦模式来推断搜索行为以预测呼吸压力源的暴露。

本研究引入一种新的基于熵的方法来定量表征呼吸压力下的非线性瞬态呼吸动力学。环境和病理生理压力源可以破坏呼吸系统的气体交换，导致妥协和补偿机制。我们提出了一种数据驱动的方法，系统地评估经典呼吸特征和新的熵特征作为呼吸应激下的关键指标。我们证明，呼吸频率（BR）、吸气时间（TI）和呼气时间（TE）等传统指标无法捕捉到早期呼吸不稳定和预测干预需求所需的判别特征。利用熵方法对关键呼吸基准点进行详尽的分析，为理解呼吸力学和分类呼吸状态提供了新的特征。我们发现，吸气期和呼气期（间期）之间过渡时间的非线性动力学对于评估对呼吸挑战的适应性至关重要。这个指标量化了过渡持续时间（阶段之间的加速和减速）的复杂性，对于预测呼吸状态的下降至关重要。结合这些新方法的预测模型比使用经典特征的模型具有更好的区分能力，通过曲线下面积（AUC）测量，预测能力提高了50.76%。这些发现强调了这种基于熵的方法在早期检测呼吸损害方面的有效性，最佳模型的AUC为0.784。该结果对改善急性呼吸衰竭的临床监测和慢性呼吸疾病的管理具有重要意义。

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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来源期刊

American journal of physiology. Lung cellular and molecular physiology 医学-呼吸系统

CiteScore

9.20

自引率

4.10%

发文量

146

审稿时长

2 months

期刊介绍： The American Journal of Physiology-Lung Cellular and Molecular Physiology publishes original research covering the broad scope of molecular, cellular, and integrative aspects of normal and abnormal function of cells and components of the respiratory system. Areas of interest include conducting airways, pulmonary circulation, lung endothelial and epithelial cells, the pleura, neuroendocrine and immunologic cells in the lung, neural cells involved in control of breathing, and cells of the diaphragm and thoracic muscles. The processes to be covered in the Journal include gas-exchange, metabolic control at the cellular level, intracellular signaling, gene expression, genomics, macromolecules and their turnover, cell-cell and cell-matrix interactions, cell motility, secretory mechanisms, membrane function, surfactant, matrix components, mucus and lining materials, lung defenses, macrophage function, transport of salt, water and protein, development and differentiation of the respiratory system, and response to the environment.