临床抗生素药敏试验解释与CLSI标准解释的比较

Antimicrobial Stewardship & Healthcare Epidemiology Pub Date : 2023-06-01 DOI:10.1017/ash.2023.392

Erin Hitchingham, Ashley Gambrell, Raquel Villegas, Daniel Muleta

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引用次数: 0

摘要

背景:基于最低抑菌浓度(MIC)断点的临床抗生素敏感性试验(AST)解释对于临床决策和一些可报告的条件标准都很重要。缺乏跨临床实验室的MIC断点标准化;AST仪器通常根据过时的临床和实验室标准协会(CLSI) MIC断点指南进行验证。在这项研究中，我们分析了报告的临床实验室AST解释与指南CLSI解释之间的一致性。方法:利用2019 - 2021年田纳西州多点革兰氏阴性监测倡议(MuGSI)耐碳青霉烯肠杆菌(CRE)监测项目收集的临床实验室AST数据。根据2019-2021 CLSI M100指南，使用临床仪器的MIC值计算CLSI标准解释。使用SAS 9.4版软件计算的加权Cohen κ来衡量临床实验室和CLSI对报告MIC值的解释之间的一致性。总匹配的分离株具有相同的CLSI和临床实验室解释。结果:共评估14种抗生素。其中，9种抗生素至少具有中度一致性(κ >0.41)之间的解释。临床实验室和CLSI解释之间的一致性接近完美(κ >0.81) 3种抗生素。头孢唑林(0.06)和厄他培南(0.14)的临床实验室和CLSI解释之间的一致性较差。头孢噻肟(- 0.07)是唯一不一致的抗生素。结论:在纳入分析的抗生素中，36%的临床实验室和CLSI AST解释之间的一致性低于中等。鉴于全球抗菌素耐药性的增加以及对抗生素管理的重视，应优先考虑跨临床AST小组的标准化。除了对包括CRE在内的应报告疾病的低估或过度识别外，不一致还可能导致不适当的抗生素使用。披露:没有

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Comparison of clinical antibiotic susceptibility testing interpretations to CLSI standard interpretations

Background: Clinical antibiotic susceptibility testing (AST) interpretations based on minimum inhibitory concentrations (MIC) breakpoints are important for both clinical decision making and some reportable condition criteria. Standardization of MIC breakpoints across clinical laboratories is lacking; AST instruments are often validated for outdated Clinical and Laboratory Standards Institute (CLSI) MIC breakpoint guidelines. In this study, we analyzed the agreement between the reported clinical laboratory AST interpretations and the guideline CLSI interpretation. Methods: Clinical laboratory AST data collected from the Multisite Gram-Negative Surveillance Initiative (MuGSI) carbapenem-resistant Enterobacterales (CRE) surveillance program in Tennessee between 2019 and 2021 were utilized. MIC values from the clinical instrument were used to calculate CLSI standard interpretations following the 2019–2021 CLSI M100 guidelines. Agreement between the clinical laboratory and CLSI interpretations of the reported MIC values were measured using a weighted Cohen κ calculated in SAS version 9.4 software. Total matches were isolates with identical CLSI and clinical laboratory interpretations. Results: In total, 14 antibiotics were assessed. Of those, 9 antibiotics had at least moderate agreement (κ > 0.41) between interpretations. Agreement between the clinical laboratory and the CLSI interpretations were near perfect (κ > 0.81) for 3 antibiotics. Agreement between the clinical laboratory and the CLSI interpretations were poor for cefazolin (0.06) and ertapenem (0.14). Cefotaxime (−0.07) was the only antibiotic that suggested no agreement. Conclusions: Of the antibiotics included in the analysis, 36% had less than moderate agreement between clinical laboratory and CLSI AST interpretations. Given the increases in antimicrobial resistance globally and the emphasis placed on antibiotic stewardship, standardization across clinical AST panels should be prioritized. Inconsistencies have the potential to contribute to inappropriate antibiotic use in addition to under- or overidentification of reportable conditions, including CRE. Disclosures: None

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Antimicrobial Stewardship & Healthcare Epidemiology

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