Predicting antibiotic resistance in Enterobacterales to support optimal empiric treatment of urinary tract infections in outpatient veterans.

Antimicrobial stewardship & healthcare epidemiology : ASHE Pub Date : 2024-09-09 eCollection Date: 2024-01-01 DOI:10.1017/ash.2024.377

Ben J Brintz, Karl Madaras-Kelly, McKenna Nevers, Kelly L Echevarria, Matthew B Goetz, Matthew H Samore

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Abstract

Objective: Bacterial resistance is known to diminish the effectiveness of antibiotics for treatment of urinary tract infections. Review of recent healthcare and antibiotic exposures, as well as prior culture results is recommended to aid in selection of empirical treatment. However, the optimal approach for assessing these data is unclear. We utilized data from the Veterans Health Administration to evaluate relationships between culture and treatment history and the subsequent probability of antibiotic-resistant bacteria identified in urine cultures to further guide clinicians in understanding these risk factors.

Methods: Using the XGBoost algorithm, a retrospective cohort of outpatients with urine culture results and antibiotic prescriptions from 2017 to 2022 was used to develop models for predicting antibiotic resistance for three classes of antibiotics: cephalosporins, fluoroquinolones, and trimethoprim/sulfamethoxazole (TMP/SMX) obtained from urine cultures. Model performance was assessed using Area Under the Receiver Operating Characteristic curve (AUC) and Precision-Recall AUC (PRAUC).

Results: There were 392,647 prior urine cultures identified in 214,656 patients. A history of bacterial resistance to the specific treatment was the most important predictor of subsequent resistance for positive cultures, followed by a history of specific antibiotic exposure. The models performed better than previously established risk factors alone, especially for fluoroquinolone resistance, with an AUC of .84 and PRAUC of .70. Notably, the models' performance improved markedly (AUC = .90, PRAUC = .87) when applied to cultures from patients with a known history of resistance to any of the antibiotic classes.

Conclusion: These predictive models demonstrate potential in guiding antibiotic prescription and improving infection management.

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预测肠杆菌的抗生素耐药性，为门诊退伍军人尿路感染的最佳经验疗法提供支持。

目的：众所周知，细菌耐药性会降低抗生素治疗尿路感染的效果。建议审查近期的医疗保健和抗生素接触情况以及之前的培养结果，以帮助选择经验性治疗。然而，评估这些数据的最佳方法尚不明确。我们利用退伍军人健康管理局的数据评估了培养和治疗史与随后在尿培养中发现的抗生素耐药菌概率之间的关系，以进一步指导临床医生了解这些风险因素：利用XGBoost算法，对2017年至2022年期间有尿培养结果和抗生素处方的门诊患者进行回顾性队列分析，建立了预测三类抗生素耐药性的模型：头孢菌素类、氟喹诺酮类和三甲双胍/磺胺甲恶唑（TMP/SMX）。使用接收者工作特征曲线下面积（AUC）和精确度-召回AUC（PRAUC）评估模型性能：结果：在 214,656 名患者中发现了 392,647 次尿培养。细菌对特定治疗的耐药史是预测阳性培养物后续耐药的最重要因素，其次是特定抗生素接触史。这些模型的表现优于之前单独建立的风险因素，尤其是对氟喹诺酮类药物的耐药性，其 AUC 为 0.84，PRAUC 为 0.70。值得注意的是，当这些模型应用于已知对任何一类抗生素有耐药史的患者的培养物时，其性能明显提高（AUC = .90，PRAUC = .87）：这些预测模型在指导抗生素处方和改善感染管理方面具有潜力。

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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Antimicrobial stewardship & healthcare epidemiology : ASHE

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