Early detection of bloodstream infection in critically ill children using artificial intelligence.

IF 1.7 Q3 CRITICAL CARE MEDICINE

Acute and Critical Care Pub Date : 2024-11-01 Epub Date: 2024-11-22 DOI:10.4266/acc.2024.00752

Hye-Ji Han, Kyunghoon Kim, June Dong Park

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Abstract

Background: Despite the high mortality associated with bloodstream infection (BSI), early detection of this condition is challenging in critical settings. The objective of this study was to create a machine learning tool for rapid recognition of BSI in critically ill children.

Methods: Data were extracted from a derivative cohort comprising patients who underwent at least one blood culture during hospitalization in the pediatric intensive care unit (PICU) of a tertiary hospital from January 2020 to June 2023 for model development. Data from another tertiary hospital were utilized for external validation. Variables selected for model development were age, white blood cell count with segmented neutrophil count, C-reactive protein, bilirubin, liver enzymes, glucose, body temperature, heart rate, and respiratory rate. Algorithms compared were extra trees, random forest, light gradient boosting, extreme gradient boosting, and CatBoost.

Results: We gathered 1,806 measurements and recorded 290 hospitalizations from 263 patients in the derivative cohort. Median age on admission was 43 months, with an interquartile range of 10-118.75 months, and a male predominance was observed (n=160, 55.2%). Candida albicans was the most prevalent pathogen, and median duration to confirm BSI was 3 days (range, 3-4). Patients with BSI experienced significantly higher in-hospital mortality and prolonged stays in the PICU than patients without BSI. Random forest classifier achieved the highest area under the receiver operating characteristic curve of 0.874 (0.762 for the validation set).

Conclusions: We developed a machine learning model that predicts BSI with acceptable performance. Further research is necessary to validate its effectiveness.

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利用人工智能早期检测重症儿童的血流感染。

背景：尽管血流感染（BSI）导致的死亡率很高，但在危重症环境中早期发现这种情况却很困难。本研究的目的是创建一种机器学习工具，用于快速识别重症儿童中的 BSI：从一个衍生队列中提取数据，该队列包括 2020 年 1 月至 2023 年 6 月期间在一家三级医院儿科重症监护室（PICU）住院期间接受过至少一次血液培养的患者，用于模型开发。另一家三级医院的数据用于外部验证。模型开发所选的变量包括年龄、白细胞计数和中性粒细胞计数、C 反应蛋白、胆红素、肝酶、葡萄糖、体温、心率和呼吸频率。比较的算法有额外树、随机森林、轻梯度提升、极梯度提升和 CatBoost：我们收集了衍生队列中 263 名患者的 1,806 次测量数据和 290 次住院记录。入院年龄中位数为 43 个月，四分位数范围为 10-118.75 个月，男性占多数（160 人，55.2%）。白色念珠菌是最常见的病原体，确认 BSI 的中位时间为 3 天（3-4 天不等）。与未发生 BSI 的患者相比，发生 BSI 的患者的院内死亡率明显更高，在重症监护病房的住院时间也更长。随机森林分类器的接收者操作特征曲线下面积最高，为0.874（验证集为0.762）：我们开发了一种机器学习模型，该模型可以预测 BSI，其性能可以接受。有必要进一步研究以验证其有效性。

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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