经超声处理和下一代测序技术检测的心脏植入式电子设备感染的微生物学诊断。
Microbiological diagnosis in cardiac implantable electronic device infections detected by sonication and next-generation sequencing.
机构信息
Department of Cardiology, Odense University Hospital, Odense, Denmark; Department of Clinical Research, University of Southern Denmark, Odense, Denmark.
Department of Clinical Research, University of Southern Denmark, Odense, Denmark; Department of Clinical Microbiology, Odense University Hospital, Odense, Denmark.
出版信息
Heart Rhythm. 2022 Jun;19(6):901-908. doi: 10.1016/j.hrthm.2022.01.039. Epub 2022 Feb 4.
BACKGROUND
Device-related infection (DRI) is a severe complication of treatment with cardiac implantable electronic devices. Identification of the causative pathogen is essential for optimal treatment, but conventional methods often are inadequate.
OBJECTIVE
The purpose of this study was to improve microbiological diagnosis in DRI using sonication and next-generation sequencing analysis. The primary objective was identification of causative pathogens. The secondary objective was estimation of the sensitivity of different microbiological methods in detecting the causative pathogen.
METHODS
Consecutive patients with clinical signs of DRI between October 2016 and January 2019 from 3 tertiary centers in Denmark were included in the study. Patients underwent a diagnostic approach, including blood cultures and perioperative collection of microbiological samples (pocket swab, pocket tissue biopsies, generator, and leads). Conventional culturing was performed, and device components were sonicated and examined with an amplicon-based metagenomic analysis using next-generation sequencing. The results were compared with a reference standard-identified causative pathogen.
RESULTS
In 110 patients with clinical signs of pocket (n = 50) or systemic DRI (n = 60), we collected 109 pocket swabs, 220 pocket tissue biopsies, 106 generators, 235 leads, and a minimum 1 set of blood cultures from 102 patients. Combining all findings, we identified the causative pathogen in 95% of cases, irrespective of DRI type. The usability of each microbiological method differed between DRI types. In pocket DRI, next-generation sequencing analysis of generators achieved sensitivity of 90%. For systemic DRI, blood cultures reached sensitivity of 93%.
CONCLUSION
Using a strategy including sonication and next-generation sequencing, we identified the causative pathogen in 95% of DRI. Sensitivity of microbiological methods differed according to the type of DRI.
背景
器械相关感染(DRI)是心脏植入式电子设备治疗的严重并发症。确定病原体对于最佳治疗至关重要,但传统方法往往不够充分。
目的
本研究旨在通过超声处理和下一代测序分析提高 DRI 的微生物诊断水平。主要目标是确定病原体。次要目标是估计不同微生物方法检测病原体的敏感性。
方法
连续纳入 2016 年 10 月至 2019 年 1 月丹麦 3 家三级中心出现 DRI 临床症状的患者。患者接受了诊断方法,包括血培养和围手术期采集微生物样本(囊袋拭子、囊袋组织活检、发生器和导联)。进行了常规培养,并对器械部件进行超声处理,并使用基于扩增子的宏基因组分析进行下一代测序检查。结果与参考标准确定的病原体进行比较。
结果
在 110 例有囊袋(n=50)或全身 DRI(n=60)临床症状的患者中,我们从 102 例患者中采集了 109 个囊袋拭子、220 个囊袋组织活检、106 个发生器、235 个导联和至少 1 套血培养。综合所有发现,我们确定了 95%的病例的病原体,而与 DRI 类型无关。不同 DRI 类型的每种微生物方法的可用性不同。在囊袋 DRI 中,发生器的下一代测序分析达到 90%的敏感性。对于全身 DRI,血培养达到 93%的敏感性。
结论
使用包括超声处理和下一代测序的策略,我们确定了 95%的 DRI 的病原体。微生物方法的敏感性根据 DRI 类型而不同。
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