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人工智能驱动的呼吸力学预后:使用长短期记忆和连续传感器数据预测组织滞后性。

Artificial Intelligence-Driven Prognosis of Respiratory Mechanics: Forecasting Tissue Hysteresivity Using Long Short-Term Memory and Continuous Sensor Data.

机构信息

Department of Electromechanics, System and Metal Engineering, Ghent University, Tech Lane Science Park 125, 9052 Ghent, Belgium.

Department of Control and Automation Engineering, Istanbul Technical University, Maslak, Istanbul 34469, Turkey.

出版信息

Sensors (Basel). 2024 Aug 27;24(17):5544. doi: 10.3390/s24175544.

DOI:10.3390/s24175544
PMID:39275455
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11397974/
Abstract

Tissue hysteresivity is an important marker for determining the onset and progression of respiratory diseases, calculated from forced oscillation lung function test data. This study aims to reduce the number and duration of required measurements by combining multivariate data from various sensing devices. We propose using the Forced Oscillation Technique (FOT) lung function test in both a low-frequency prototype and the commercial RESMON device, combined with continuous monitoring from the Equivital (EQV) LifeMonitor and processed by artificial intelligence (AI) algorithms. While AI and deep learning have been employed in various aspects of respiratory system analysis, such as predicting lung tissue displacement and respiratory failure, the prediction or forecasting of tissue hysteresivity remains largely unexplored in the literature. In this work, the Long Short-Term Memory (LSTM) model is used in two ways: (1) to estimate the hysteresivity coefficient η using heart rate (HR) data collected continuously by the EQV sensor, and (2) to forecast η values by first predicting the heart rate from electrocardiogram (ECG) data. Our methodology involves a rigorous two-hour measurement protocol, with synchronized data collection from the EQV, FOT, and RESMON devices. Our results demonstrate that LSTM networks can accurately estimate the tissue hysteresivity parameter η, achieving an R2 of 0.851 and a mean squared error (MSE) of 0.296 for estimation, and forecast η with an R2 of 0.883 and an MSE of 0.528, while significantly reducing the number of required measurements by a factor of three (i.e., from ten to three) for the patient. We conclude that our novel approach minimizes patient effort by reducing the measurement time and the overall ambulatory time and costs while highlighting the potential of artificial intelligence methods in respiratory monitoring.

摘要

组织硬度是一种用于确定呼吸系统疾病发作和进展的重要标志物,可通过强迫振荡肺功能测试数据计算得出。本研究旨在通过组合来自各种传感设备的多元数据来减少所需测量的数量和持续时间。我们提出在低频原型和商业 RESMON 设备中使用强迫振荡技术(FOT)肺功能测试,同时结合 Equivital(EQV)LifeMonitor 的连续监测,并由人工智能(AI)算法进行处理。虽然 AI 和深度学习已被应用于呼吸系统分析的各个方面,如预测肺组织位移和呼吸衰竭,但在文献中,组织硬度的预测或预测在很大程度上仍未得到探索。在这项工作中,长短期记忆(LSTM)模型以两种方式使用:(1)使用 EQV 传感器连续收集的心率(HR)数据估计滞后系数η,(2)通过首先从心电图(ECG)数据预测心率来预测η值。我们的方法涉及严格的两小时测量方案,同时从 EQV、FOT 和 RESMON 设备同步收集数据。我们的结果表明,LSTM 网络可以准确估计组织滞后参数η,实现了 0.851 的 R2 和 0.296 的均方误差(MSE)的估计,并且预测 η 的 R2 为 0.883,MSE 为 0.528,同时通过将患者的测量次数减少三分之一(即从十次减少到三次),显著减少了所需的测量次数。我们得出的结论是,我们的新方法通过减少测量时间和整体流动时间和成本来最小化患者的努力,同时突出了人工智能方法在呼吸监测中的潜力。

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