应用监督式机器学习通过脉搏血氧仪自动检测快速和延长的毛细血管再充盈情况。

Supervised Machine Learning Applied to Automate Flash and Prolonged Capillary Refill Detection by Pulse Oximetry.

作者信息

Hunter Ryan Brandon, Jiang Shen, Nishisaki Akira, Nickel Amanda J, Napolitano Natalie, Shinozaki Koichiro, Li Timmy, Saeki Kota, Becker Lance B, Nadkarni Vinay M, Masino Aaron J

机构信息

Department of Anesthesiology and Critical Care Medicine, Children's Hospital of Philadelphia, Philadelphia, PA, United States.

Nihon Kohden Innovation Center, Cambridge, MA, United States.

出版信息

Front Physiol. 2020 Oct 6;11:564589. doi: 10.3389/fphys.2020.564589. eCollection 2020.

DOI:10.3389/fphys.2020.564589

PMID:33117190

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7574820/

Abstract

OBJECTIVE

Develop an automated approach to detect flash (<1.0 s) or prolonged (>2.0 s) capillary refill time (CRT) that correlates with clinician judgment by applying several supervised machine learning (ML) techniques to pulse oximeter plethysmography data.

MATERIALS AND METHODS

Data was collected in the Pediatric Intensive Care Unit (ICU), Cardiac ICU, Progressive Care Unit, and Operating Suites in a large academic children's hospital. Ninety-nine children and 30 adults were enrolled in testing and validation cohorts, respectively. Patients had 5 paired CRT measurements by a modified pulse oximeter device and a clinician, generating 485 waveform pairs for model training. Supervised ML models using gradient boosting (XGBoost), logistic regression (LR), and support vector machines (SVMs) were developed to detect flash (<1 s) or prolonged CRT (≥2 s) using clinician CRT assessment as the reference standard. Models were compared using Area Under the Receiver Operating Curve (AUC) and precision-recall curve (positive predictive value vs. sensitivity) analysis. The best performing model was externally validated with 90 measurement pairs from adult patients. Feature importance analysis was performed to identify key waveform characteristics.

RESULTS

For flash CRT, XGBoost had a greater mean AUC (0.79, 95% CI 0.75-0.83) than logistic regression (0.77, 0.71-0.82) and SVM (0.72, 0.67-0.76) models. For prolonged CRT, XGBoost had a greater mean AUC (0.77, 0.72-0.82) than logistic regression (0.73, 0.68-0.78) and SVM (0.75, 0.70-0.79) models. Pairwise testing showed statistically significant improved performance comparing XGBoost and SVM; all other pairwise model comparisons did not reach statistical significance. XGBoost showed good external validation with AUC of 0.88. Feature importance analysis of XGBoost identified distinct key waveform characteristics for flash and prolonged CRT, respectively.

CONCLUSION

Novel application of supervised ML to pulse oximeter waveforms yielded multiple effective models to identify flash and prolonged CRT, using clinician judgment as the reference standard.

Supervised machine learning applied to pulse oximeter waveform features predicts flash or prolonged capillary refill.

摘要

目的

通过对脉搏血氧饱和度容积描记数据应用多种监督式机器学习（ML）技术，开发一种自动检测与临床医生判断相关的快速（<1.0秒）或延长（>2.0秒）毛细血管再充盈时间（CRT）的方法。

材料与方法

数据收集于一家大型学术儿童医院的儿科重症监护病房（ICU）、心脏ICU、进阶护理病房和手术室。分别有99名儿童和30名成人纳入测试和验证队列。患者通过改良的脉搏血氧饱和度仪设备和临床医生进行了5次配对的CRT测量，生成485个波形对用于模型训练。使用梯度提升（XGBoost）、逻辑回归（LR）和支持向量机（SVM）的监督式ML模型，以临床医生的CRT评估作为参考标准，来检测快速（<1秒）或延长的CRT（≥2秒）。使用受试者操作特征曲线下面积（AUC）和精确召回率曲线（阳性预测值与敏感性）分析对模型进行比较。表现最佳的模型用来自成年患者的90个测量对进行了外部验证。进行特征重要性分析以识别关键波形特征。

结果

对于快速CRT，XGBoost的平均AUC（0.79，95%可信区间0.75 - 0.83）大于逻辑回归（0.77，0.71 - 0.82）和SVM（0.72，0.67 - 0.76）模型。对于延长的CRT，XGBoost的平均AUC（0.77，0.72 - 0.82）大于逻辑回归（0.73，0.68 - 0.78）和SVM（0.75，0.70 - 0.79）模型。成对检验显示，比较XGBoost和SVM时性能有统计学显著改善；所有其他成对模型比较未达到统计学显著性。XGBoost在外部验证中表现良好，AUC为0.88。XGBoost的特征重要性分析分别确定了快速和延长CRT的不同关键波形特征。