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机器学习用于预测急诊科尿培养抗生素敏感性

Machine learning to predict urine culture antibiotic sensitivities in the emergency department.

作者信息

Sheele Johnathan M, Campbell Ronna L, Jones Derick D

机构信息

Department of Emergency Medicine, Mayo Clinic, Jacksonville, FL, USA.

Department of Emergency Medicine, Mayo Clinic, Rochester, MN, USA.

出版信息

Heliyon. 2025 Feb 18;11(4):e42737. doi: 10.1016/j.heliyon.2025.e42737. eCollection 2025 Feb 28.

DOI:10.1016/j.heliyon.2025.e42737
PMID:40070953
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11894297/
Abstract

BACKGROUND

Urinary tract infections (UTIs) are among the most common bacterial infections diagnosed in the emergency department. Treatment of UTIs is largely empiric because urine culture results are not rapidly available.

OBJECTIVES

We examined whether machine learning could predict antibiotic sensitivities of the urine cultures by using only data available during the clinical encounter.

METHODS

We used extreme gradient boosting (XGBoost) to examine 62,963 emergency department patient encounters from January 1, 2017, through December 31, 2021. All encounters included a urinalysis and urine culture. We included 1303 variables in the full model and examined 21 antibiotics. An antibiotic was characterized as only if all bacteria in the culture were susceptible; if ≥ 1 bacteria was not susceptible, then it was characterized as .

RESULTS

We predicted urine cultures to be sensitive vs intermediate or resistant with area under the receiver operating curve (AUROC) values ranging from 70 % (for amikacin) to 90 % (for linezolid) (median, 82 %) when negative urine cultures were characterized as antibiotic susceptible. AUROCs were as follows: nitrofurantoin (84 %); trimethoprim + sulfamethoxazole (80 %); ciprofloxacin (85 %); levofloxacin (85 %); first-generation cephalosporins (84 %); and third-generation cephalosporins (80 %). When models excluded urine cultures with no bacterial growth, AUROCs ranged from 66 % (for ampicillin) to 87 % (for amikacin) (median, 74 %). When models included only patients diagnosed with a UTI plus bacteriuria (≥10,000 colony-forming units per mL in urine culture), AUROCs ranged from 63 % (for ampicillin) to 85 % (for tetracycline) (median, 74 %).

CONCLUSION

XGBoost can predict bacteriuria antibiotic sensitivities.

摘要

背景

尿路感染(UTIs)是急诊科诊断出的最常见细菌感染之一。由于尿液培养结果不能很快获得,UTIs的治疗很大程度上是经验性的。

目的

我们研究了机器学习是否可以仅使用临床就诊期间可用的数据来预测尿液培养的抗生素敏感性。

方法

我们使用极端梯度提升(XGBoost)来分析2017年1月1日至2021年12月31日期间急诊科的62963例患者就诊情况。所有就诊都包括尿液分析和尿液培养。我们在完整模型中纳入了1303个变量,并研究了21种抗生素。只有当培养物中的所有细菌都敏感时,一种抗生素才被表征为敏感;如果≥1种细菌不敏感,那么它被表征为不敏感。

结果

当阴性尿液培养被表征为抗生素敏感时,我们预测尿液培养对敏感、中度敏感或耐药的受试者工作特征曲线下面积(AUROC)值范围为70%(阿米卡星)至90%(利奈唑胺)(中位数为82%)。AUROC如下:呋喃妥因(84%);甲氧苄啶+磺胺甲恶唑(80%);环丙沙星(85%);左氧氟沙星(85%);第一代头孢菌素(84%);和第三代头孢菌素(80%)。当模型排除无细菌生长的尿液培养时,AUROC范围为66%(氨苄西林)至87%(阿米卡星)(中位数为74%)。当模型仅纳入被诊断为UTI加菌尿症(尿液培养中每毫升≥10000个菌落形成单位)的患者时,AUROC范围为63%(氨苄西林)至85%(四环素)(中位数为74%)。

结论

XGBoost可以预测菌尿症的抗生素敏感性。