使用可解释的机器学习算法个性化预测肾切除术后的长期肾功能预后:病例对照研究。

IF 3.1 3区 医学 Q2 MEDICAL INFORMATICS
Lingyu Xu, Chenyu Li, Shuang Gao, Long Zhao, Chen Guan, Xuefei Shen, Zhihui Zhu, Cheng Guo, Liwei Zhang, Chengyu Yang, Quandong Bu, Bin Zhou, Yan Xu
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引用次数: 0

摘要

背景:急性肾损伤(AKI)是肾切除术后常见的不良后果。从急性肾损伤发展为急性肾病(AKD),进而发展为慢性肾病(CKD)仍然是一个令人担忧的问题;然而,这些转变的预测机制尚未完全明了。可解释的机器学习(ML)模型提供了关于临床特征如何影响肾切除术后长期肾功能结果的见解,为识别高危患者提供了更精确的框架,并支持改善临床决策过程:本研究旨在:(1) 评估肾切除术后 AKI、AKD 和 CKD 的发生率,分析不同轨迹的长期肾功能预后;(2) 使用 Shapley Additive Explanations 值和 Local Interpretable Model-Agnostic Explanations 算法解释 AKD 和 CKD 模型;(3) 开发一种基于网络的工具,用于估计肾切除术后 AKD 或 CKD 风险:我们进行了一项回顾性队列研究,涉及 2012 年 7 月至 2019 年 6 月间接受肾切除术的患者。患者数据被随机分成训练集、验证集和测试集,保持 76.5:8.5:15 的比例。八种 ML 算法用于构建术后 AKD 和 CKD 的预测模型。我们使用各种指标评估了表现最佳模型的性能。我们使用各种夏普利相加解释图和局部可解释模型-诊断解释条形图来解释模型,并生成有向无环图来探索特征之间的潜在因果关系。此外,我们还利用预测 AKD 的前 10 个特征和预测 CKD 的前 5 个特征开发了基于网络的预测工具:研究队列由 1559 名患者组成。AKI、AKD 和 CKD 的发病率分别为 21.7%(n=330)、15.3%(n=238)和 10.6%(n=165)。在所评估的 ML 模型中,轻梯度增强机(LightGBM)模型表现出卓越的性能,其 AKD 预测的接收器操作特征曲线下面积为 0.97,CKD 预测的接收器操作特征曲线下面积为 0.96。性能指标和曲线图凸显了该模型在辨别、校准和临床应用方面的能力。手术时间、血红蛋白、失血量、尿蛋白和血细胞比容被确定为与预测 AKD 相关的前 5 个特征。基线估计肾小球滤过率、病理学、肾功能轨迹、年龄和总胆红素是与预测的 CKD 相关的前 5 个特征。此外,我们还利用 LightGBM 模型开发了一个网络应用程序,用于估算 AKD 和 CKD 风险:结论:可解释的 ML 模型通过列举关键特征,有效地阐明了在肾切除术后识别有 AKD 和 CKD 风险的患者的决策过程。在 LightGBM 模型中发现的基于网络的计算器可以帮助制定更加个性化的循证临床策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Personalized Prediction of Long-Term Renal Function Prognosis Following Nephrectomy Using Interpretable Machine Learning Algorithms: Case-Control Study.

Background: Acute kidney injury (AKI) is a common adverse outcome following nephrectomy. The progression from AKI to acute kidney disease (AKD) and subsequently to chronic kidney disease (CKD) remains a concern; yet, the predictive mechanisms for these transitions are not fully understood. Interpretable machine learning (ML) models offer insights into how clinical features influence long-term renal function outcomes after nephrectomy, providing a more precise framework for identifying patients at risk and supporting improved clinical decision-making processes.

Objective: This study aimed to (1) evaluate postnephrectomy rates of AKI, AKD, and CKD, analyzing long-term renal outcomes along different trajectories; (2) interpret AKD and CKD models using Shapley Additive Explanations values and Local Interpretable Model-Agnostic Explanations algorithm; and (3) develop a web-based tool for estimating AKD or CKD risk after nephrectomy.

Methods: We conducted a retrospective cohort study involving patients who underwent nephrectomy between July 2012 and June 2019. Patient data were randomly split into training, validation, and test sets, maintaining a ratio of 76.5:8.5:15. Eight ML algorithms were used to construct predictive models for postoperative AKD and CKD. The performance of the best-performing models was assessed using various metrics. We used various Shapley Additive Explanations plots and Local Interpretable Model-Agnostic Explanations bar plots to interpret the model and generated directed acyclic graphs to explore the potential causal relationships between features. Additionally, we developed a web-based prediction tool using the top 10 features for AKD prediction and the top 5 features for CKD prediction.

Results: The study cohort comprised 1559 patients. Incidence rates for AKI, AKD, and CKD were 21.7% (n=330), 15.3% (n=238), and 10.6% (n=165), respectively. Among the evaluated ML models, the Light Gradient-Boosting Machine (LightGBM) model demonstrated superior performance, with an area under the receiver operating characteristic curve of 0.97 for AKD prediction and 0.96 for CKD prediction. Performance metrics and plots highlighted the model's competence in discrimination, calibration, and clinical applicability. Operative duration, hemoglobin, blood loss, urine protein, and hematocrit were identified as the top 5 features associated with predicted AKD. Baseline estimated glomerular filtration rate, pathology, trajectories of renal function, age, and total bilirubin were the top 5 features associated with predicted CKD. Additionally, we developed a web application using the LightGBM model to estimate AKD and CKD risks.

Conclusions: An interpretable ML model effectively elucidated its decision-making process in identifying patients at risk of AKD and CKD following nephrectomy by enumerating critical features. The web-based calculator, found on the LightGBM model, can assist in formulating more personalized and evidence-based clinical strategies.

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来源期刊
JMIR Medical Informatics
JMIR Medical Informatics Medicine-Health Informatics
CiteScore
7.90
自引率
3.10%
发文量
173
审稿时长
12 weeks
期刊介绍: JMIR Medical Informatics (JMI, ISSN 2291-9694) is a top-rated, tier A journal which focuses on clinical informatics, big data in health and health care, decision support for health professionals, electronic health records, ehealth infrastructures and implementation. It has a focus on applied, translational research, with a broad readership including clinicians, CIOs, engineers, industry and health informatics professionals. Published by JMIR Publications, publisher of the Journal of Medical Internet Research (JMIR), the leading eHealth/mHealth journal (Impact Factor 2016: 5.175), JMIR Med Inform has a slightly different scope (emphasizing more on applications for clinicians and health professionals rather than consumers/citizens, which is the focus of JMIR), publishes even faster, and also allows papers which are more technical or more formative than what would be published in the Journal of Medical Internet Research.
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