基于纳米孔的宏基因组测序在疑似感染免疫功能低下的癌症患者中快速准确地检测病原体。

Nanopore-based metagenomic sequencing for the rapid and precise detection of pathogens among immunocompromised cancer patients with suspected infections.

机构信息

Anhui Province Key Laboratory of Medical Physics and Technology, Institute of Health and Medical Technology, Hefei Institutes of Physical Science, Chinese Academy of Science, Hefei, China.

Science Island Branch, Graduate School of University of Science and Technology of China, Hefei, China.

出版信息

Front Cell Infect Microbiol. 2022 Sep 20;12:943859. doi: 10.3389/fcimb.2022.943859. eCollection 2022.

DOI:10.3389/fcimb.2022.943859

PMID:36204638

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9530710/

Abstract

Cancer patients are at high risk of infections and infection-related mortality; thereby, prompt diagnosis and precise anti-infectives treatment are critical. This study aimed to evaluate the performance of nanopore amplicon sequencing in identifying microbial agents among immunocompromised cancer patients with suspected infections. This prospective study enlisted 56 immunocompromised cancer patients with suspected infections. Their body fluid samples such as sputum and blood were collected, and potential microbial agents were detected in parallel by nanopore amplicon sequencing and the conventional culture method. Among the 56 body fluid samples, 47 (83.9%) samples were identified to have at least one pathogen by nanopore amplicon sequencing, but only 25 (44.6%) samples exhibited a positive finding by culture. Among 31 culture-negative samples, nanopore amplicon sequencing successfully detected pathogens in 22 samples (71.0%). Nanopore amplicon sequencing showed a higher sensitivity in pathogen detection than that of the conventional culture method (83.9% vs. 44.6%, P<0.001), and this advantage both existed in blood samples (38.5% vs. 0%, P=0.039) and non-blood samples (97.7% vs. 58.1%, P<0.001). Compared with the culture method, nanopore amplicon sequencing illustrated more samples with bacterial infections (P<0.001), infections from fastidious pathogens (P=0.006), and co-infections (P<0.001). The mean turnaround time for nanopore amplicon sequencing was about 17.5 hours, which was shorter than that of the conventional culture assay. This study suggested nanopore amplicon sequencing as a rapid and precise method for detecting pathogens among immunocompromised cancer patients with suspected infections. The novel and high-sensitive method will improve the outcomes of immunocompromised cancer patients by facilitating the prompt diagnosis of infections and precise anti-infectives treatment.

摘要

癌症患者感染和感染相关死亡率风险高；因此，及时诊断和精准抗感染治疗至关重要。本研究旨在评估纳米孔扩增测序在识别免疫功能低下癌症合并疑似感染患者中的微生物病原体中的表现。这项前瞻性研究纳入了 56 名免疫功能低下合并疑似感染的癌症患者。采集他们的体液样本，如痰液和血液，并通过纳米孔扩增测序和传统培养方法并行检测潜在的微生物病原体。在 56 个体液样本中，47 个（83.9%）样本通过纳米孔扩增测序至少鉴定出一种病原体，但仅 25 个（44.6%）样本通过培养呈阳性。在 31 个培养阴性样本中，纳米孔扩增测序成功在 22 个样本中检测到病原体（71.0%）。纳米孔扩增测序在病原体检测中的敏感性高于传统培养方法（83.9% vs. 44.6%，P<0.001），且这种优势在血液样本中（38.5% vs. 0%，P=0.039）和非血液样本中（97.7% vs. 58.1%，P<0.001）均存在。与培养方法相比，纳米孔扩增测序显示更多的样本存在细菌感染（P<0.001）、苛养病原体感染（P=0.006）和混合感染（P<0.001）。纳米孔扩增测序的平均周转时间约为 17.5 小时，短于传统培养检测。本研究表明，纳米孔扩增测序是一种快速、精准的方法，可用于检测免疫功能低下癌症合并疑似感染患者中的病原体。这种新颖且高灵敏度的方法将通过促进感染的及时诊断和精准抗感染治疗，改善免疫功能低下癌症患者的结局。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/472d/9530710/13a3251f9886/fcimb-12-943859-g001.jpg

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基于纳米孔的宏基因组测序在疑似感染免疫功能低下的癌症患者中快速准确地检测病原体。

Nanopore-based metagenomic sequencing for the rapid and precise detection of pathogens among immunocompromised cancer patients with suspected infections.

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