基于高保真动脉压力波形分析的低血压预测机器学习算法。

Machine-learning Algorithm to Predict Hypotension Based on High-fidelity Arterial Pressure Waveform Analysis.

机构信息

From Edwards Lifesciences Critical Care, Irvine, California (F.H., Z.J., S.B., C.L., J.S.) the Department of Anesthesiology and Perioperative Care, School of Medicine (C.L., J.R., M.C.) Department of Computer Sciences (C.L.) Department of Biomedical Engineering (C.L., M.C.), University of California, Irving, California the Department of Anesthesiology and Perioperative Medicine, David Geffen School of Medicine, University of California Los Angeles, Los Angeles, California (K.S., M.C.).

出版信息

Anesthesiology. 2018 Oct;129(4):663-674. doi: 10.1097/ALN.0000000000002300.

DOI:10.1097/ALN.0000000000002300

PMID:29894315

Abstract

WHAT WE ALREADY KNOW ABOUT THIS TOPIC

WHAT THIS ARTICLE TELLS US THAT IS NEW: BACKGROUND:: With appropriate algorithms, computers can learn to detect patterns and associations in large data sets. The authors' goal was to apply machine learning to arterial pressure waveforms and create an algorithm to predict hypotension. The algorithm detects early alteration in waveforms that can herald the weakening of cardiovascular compensatory mechanisms affecting preload, afterload, and contractility.

METHODS

The algorithm was developed with two different data sources: (1) a retrospective cohort, used for training, consisting of 1,334 patients' records with 545,959 min of arterial waveform recording and 25,461 episodes of hypotension; and (2) a prospective, local hospital cohort used for external validation, consisting of 204 patients' records with 33,236 min of arterial waveform recording and 1,923 episodes of hypotension. The algorithm relates a large set of features calculated from the high-fidelity arterial pressure waveform to the prediction of an upcoming hypotensive event (mean arterial pressure < 65 mmHg). Receiver-operating characteristic curve analysis evaluated the algorithm's success in predicting hypotension, defined as mean arterial pressure less than 65 mmHg.

RESULTS

Using 3,022 individual features per cardiac cycle, the algorithm predicted arterial hypotension with a sensitivity and specificity of 88% (85 to 90%) and 87% (85 to 90%) 15 min before a hypotensive event (area under the curve, 0.95 [0.94 to 0.95]); 89% (87 to 91%) and 90% (87 to 92%) 10 min before (area under the curve, 0.95 [0.95 to 0.96]); 92% (90 to 94%) and 92% (90 to 94%) 5 min before (area under the curve, 0.97 [0.97 to 0.98]).

CONCLUSIONS

The results demonstrate that a machine-learning algorithm can be trained, with large data sets of high-fidelity arterial waveforms, to predict hypotension in surgical patients' records.

摘要

背景

通过适当的算法，计算机可以学习检测大数据集中的模式和关联。作者的目标是将机器学习应用于动脉压力波形，并创建一种预测低血压的算法。该算法检测到波形的早期变化，这些变化可以预示着影响前负荷、后负荷和收缩性的心血管代偿机制的减弱。

方法

该算法使用两个不同的数据源开发：（1）回顾性队列，用于训练，包含 1334 名患者的记录，有 545959 分钟的动脉波形记录和 25461 次低血压发作；（2）前瞻性、当地医院队列，用于外部验证，包含 204 名患者的记录，有 33236 分钟的动脉波形记录和 1923 次低血压发作。该算法将从高保真动脉压力波形计算得出的一大组特征与即将发生的低血压事件（平均动脉压<65mmHg）的预测联系起来。接受者操作特征曲线分析评估了该算法预测低血压的成功率，定义为平均动脉压<65mmHg。

结果

该算法使用每个心动周期的 3022 个个体特征，在低血压事件发生前 15 分钟预测动脉低血压的敏感性和特异性分别为 88%（85%至 90%）和 87%（85%至 90%）（曲线下面积，0.95[0.94 至 0.95]）；在低血压事件发生前 10 分钟分别为 89%（87%至 91%）和 90%（87%至 92%）（曲线下面积，0.95[0.95 至 0.96]）；在低血压事件发生前 5 分钟分别为 92%（90%至 94%）和 92%（90%至 94%）（曲线下面积，0.97[0.97 至 0.98]）。