使用机器学习预测新型冠状病毒肺炎机械通气患者俯卧位通气的反应者

Predicting responders to prone positioning in mechanically ventilated patients with COVID-19 using machine learning.

作者信息

Dam Tariq A, Roggeveen Luca F, van Diggelen Fuda, Fleuren Lucas M, Jagesar Ameet R, Otten Martijn, de Vries Heder J, Gommers Diederik, Cremer Olaf L, Bosman Rob J, Rigter Sander, Wils Evert-Jan, Frenzel Tim, Dongelmans Dave A, de Jong Remko, Peters Marco A A, Kamps Marlijn J A, Ramnarain Dharmanand, Nowitzky Ralph, Nooteboom Fleur G C A, de Ruijter Wouter, Urlings-Strop Louise C, Smit Ellen G M, Mehagnoul-Schipper D Jannet, Dormans Tom, de Jager Cornelis P C, Hendriks Stefaan H A, Achterberg Sefanja, Oostdijk Evelien, Reidinga Auke C, Festen-Spanjer Barbara, Brunnekreef Gert B, Cornet Alexander D, van den Tempel Walter, Boelens Age D, Koetsier Peter, Lens Judith, Faber Harald J, Karakus A, Entjes Robert, de Jong Paul, Rettig Thijs C D, Arbous Sesmu, Vonk Sebastiaan J J, Machado Tomas, Herter Willem E, de Grooth Harm-Jan, Thoral Patrick J, Girbes Armand R J, Hoogendoorn Mark, Elbers Paul W G

机构信息

Department of Intensive Care Medicine, Laboratory for Critical Care Computational Intelligence, Amsterdam Medical Data Science, Amsterdam UMC, Vrije Universiteit, Amsterdam, The Netherlands.

Quantitative Data Analytics Group, Department of Computer Science, Faculty of Science, VU University, Amsterdam, The Netherlands.

出版信息

Ann Intensive Care. 2022 Oct 20;12(1):99. doi: 10.1186/s13613-022-01070-0.

DOI:10.1186/s13613-022-01070-0

PMID:36264358

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9583049/

Abstract

BACKGROUND

For mechanically ventilated critically ill COVID-19 patients, prone positioning has quickly become an important treatment strategy, however, prone positioning is labor intensive and comes with potential adverse effects. Therefore, identifying which critically ill intubated COVID-19 patients will benefit may help allocate labor resources.

METHODS

From the multi-center Dutch Data Warehouse of COVID-19 ICU patients from 25 hospitals, we selected all 3619 episodes of prone positioning in 1142 invasively mechanically ventilated patients. We excluded episodes longer than 24 h. Berlin ARDS criteria were not formally documented. We used supervised machine learning algorithms Logistic Regression, Random Forest, Naive Bayes, K-Nearest Neighbors, Support Vector Machine and Extreme Gradient Boosting on readily available and clinically relevant features to predict success of prone positioning after 4 h (window of 1 to 7 h) based on various possible outcomes. These outcomes were defined as improvements of at least 10% in PaO/FiO ratio, ventilatory ratio, respiratory system compliance, or mechanical power. Separate models were created for each of these outcomes. Re-supination within 4 h after pronation was labeled as failure. We also developed models using a 20 mmHg improvement cut-off for PaO/FiO ratio and using a combined outcome parameter. For all models, we evaluated feature importance expressed as contribution to predictive performance based on their relative ranking.

RESULTS

The median duration of prone episodes was 17 h (11-20, median and IQR, N = 2632). Despite extensive modeling using a plethora of machine learning techniques and a large number of potentially clinically relevant features, discrimination between responders and non-responders remained poor with an area under the receiver operator characteristic curve of 0.62 for PaO/FiO ratio using Logistic Regression, Random Forest and XGBoost. Feature importance was inconsistent between models for different outcomes. Notably, not even being a previous responder to prone positioning, or PEEP-levels before prone positioning, provided any meaningful contribution to predicting a successful next proning episode.

CONCLUSIONS

In mechanically ventilated COVID-19 patients, predicting the success of prone positioning using clinically relevant and readily available parameters from electronic health records is currently not feasible. Given the current evidence base, a liberal approach to proning in all patients with severe COVID-19 ARDS is therefore justified and in particular regardless of previous results of proning.

摘要

背景

对于接受机械通气的危重症新型冠状病毒肺炎患者，俯卧位通气已迅速成为一项重要的治疗策略，然而，俯卧位通气需要大量人力，且存在潜在不良反应。因此，确定哪些危重症插管新型冠状病毒肺炎患者将从中获益，可能有助于合理分配人力资源。

方法

从25家医院的多中心荷兰新型冠状病毒肺炎重症监护病房患者数据仓库中，我们选取了1142例有创机械通气患者的3619次俯卧位通气记录。我们排除了持续时间超过24小时的记录。未正式记录柏林急性呼吸窘迫综合征（ARDS）标准。我们使用监督式机器学习算法逻辑回归、随机森林、朴素贝叶斯、K近邻、支持向量机和极端梯度提升，基于现有的临床相关特征，根据不同的可能结果预测4小时（1至7小时窗口）后俯卧位通气的成功情况。这些结果定义为动脉血氧分压/吸入氧浓度（PaO/FiO）比值、通气比、呼吸系统顺应性或机械功率至少提高10%。针对每个结果创建单独的模型。俯卧位通气后4小时内恢复仰卧位被标记为失败。我们还使用PaO/FiO比值提高20 mmHg的截断值以及综合结果参数开发了模型。对于所有模型，我们根据特征的相对排名评估其对预测性能的贡献，以此来评估特征重要性。

结果

俯卧位通气的中位持续时间为17小时（中位数和四分位间距为11 - 20，N = 2632）。尽管使用了大量机器学习技术和大量潜在的临床相关特征进行广泛建模，但使用逻辑回归、随机森林和极端梯度提升算法，根据PaO/FiO比值计算的受试者工作特征曲线下面积为0.62，区分反应者和无反应者的能力仍然较差。不同结果的模型之间特征重要性不一致。值得注意的是，即使是之前俯卧位通气有反应的患者，或者俯卧位通气前的呼气末正压水平，对预测下一次俯卧位通气成功与否也没有任何有意义的贡献。

结论

在接受机械通气的新型冠状病毒肺炎患者中，利用电子健康记录中的临床相关且现有的参数预测俯卧位通气的成功目前是不可行的。鉴于目前的证据基础，因此对所有重症新型冠状病毒肺炎ARDS患者采取宽松的俯卧位通气方法是合理的，特别是无论之前俯卧位通气的结果如何。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9319/9583962/323ebb49e33a/13613_2022_1070_Fig1_HTML.jpg

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使用机器学习预测新型冠状病毒肺炎机械通气患者俯卧位通气的反应者

Predicting responders to prone positioning in mechanically ventilated patients with COVID-19 using machine learning.

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