A Deep Learning Framework for Predicting Patient Decannulation on Extracorporeal Membrane Oxygenation Devices: Development and Model Analysis Study.

Joshua Fuller, Alexey Abramov, Dana Mullin, James Beck, Philippe Lemaitre, Elham Azizi
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引用次数: 0

Abstract

Background: Venovenous extracorporeal membrane oxygenation (VV-ECMO) is a therapy for patients with refractory respiratory failure. The decision to decannulate someone from extracorporeal membrane oxygenation (ECMO) often involves weaning trials and clinical intuition. To date, there are limited prognostication metrics to guide clinical decision-making to determine which patients will be successfully weaned and decannulated.

Objective: This study aims to assist clinicians with the decision to decannulate a patient from ECMO, using Continuous Evaluation of VV-ECMO Outcomes (CEVVO), a deep learning-based model for predicting success of decannulation in patients supported on VV-ECMO. The running metric may be applied daily to categorize patients into high-risk and low-risk groups. Using these data, providers may consider initiating a weaning trial based on their expertise and CEVVO.

Methods: Data were collected from 118 patients supported with VV-ECMO at the Columbia University Irving Medical Center. Using a long short-term memory-based network, CEVVO is the first model capable of integrating discrete clinical information with continuous data collected from an ECMO device. A total of 12 sets of 5-fold cross validations were conducted to assess the performance, which was measured using the area under the receiver operating characteristic curve (AUROC) and average precision (AP). To translate the predicted values into a clinically useful metric, the model results were calibrated and stratified into risk groups, ranging from 0 (high risk) to 3 (low risk). To further investigate the performance edge of CEVVO, 2 synthetic data sets were generated using Gaussian process regression. The first data set preserved the long-term dependency of the patient data set, whereas the second did not.

Results: CEVVO demonstrated consistently superior classification performance compared with contemporary models (P<.001 and P=.04 compared with the next highest AUROC and AP). Although the model's patient-by-patient predictive power may be too low to be integrated into a clinical setting (AUROC 95% CI 0.6822-0.7055; AP 95% CI 0.8515-0.8682), the patient risk classification system displayed greater potential. When measured at 72 hours, the high-risk group had a successful decannulation rate of 58% (7/12), whereas the low-risk group had a successful decannulation rate of 92% (11/12; P=.04). When measured at 96 hours, the high- and low-risk groups had a successful decannulation rate of 54% (6/11) and 100% (9/9), respectively (P=.01). We hypothesized that the improved performance of CEVVO was owing to its ability to efficiently capture transient temporal patterns. Indeed, CEVVO exhibited improved performance on synthetic data with inherent temporal dependencies (P<.001) compared with logistic regression and a dense neural network.

Conclusions: The ability to interpret and integrate large data sets is paramount for creating accurate models capable of assisting clinicians in risk stratifying patients supported on VV-ECMO. Our framework may guide future incorporation of CEVVO into more comprehensive intensive care monitoring systems.

用于预测体外膜氧合设备上病人拔管情况的深度学习框架:开发和模型分析研究。
背景:静脉体外膜氧合(VV-ECMO)是治疗难治性呼吸衰竭患者的一种疗法。决定是否让患者脱离体外膜肺氧合(ECMO)常常涉及断流试验和临床直觉。迄今为止,用于指导临床决策以确定哪些患者将成功断奶并脱离监护的预后指标非常有限:本研究旨在使用 "VV-ECMO 结果持续评估"(CEVVO)协助临床医生做出决定,该模型基于深度学习,可预测 VV-ECMO 支持患者的断血成功率。该运行指标每天都可用于将患者分为高风险组和低风险组。利用这些数据,医疗服务提供者可根据其专业知识和 CEVVO 考虑启动断流试验:收集了哥伦比亚大学欧文医疗中心 118 名接受 VV-ECMO 支持的患者的数据。CEVVO 使用基于长短期记忆的网络,是首个能够将离散临床信息与从 ECMO 设备收集的连续数据相结合的模型。该模型共进行了 12 组 5 倍交叉验证来评估其性能,并使用接收者操作特征曲线下面积(AUROC)和平均精度(AP)来衡量。为了将预测值转化为临床有用的指标,对模型结果进行了校准,并将其分为 0(高风险)至 3(低风险)的风险组。为进一步研究 CEVVO 的性能优势,使用高斯过程回归生成了两个合成数据集。第一个数据集保留了患者数据集的长期依赖性,而第二个数据集则没有:结果:CEVVO 的分类性能始终优于当代模型(PC 结论:CEVVO 的分类性能始终优于当代模型:解释和整合大型数据集的能力对于创建准确的模型至关重要,这些模型能够帮助临床医生对接受 VV-ECMO 支持的患者进行风险分层。我们的框架可为将来将 CEVVO 纳入更全面的重症监护系统提供指导。
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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