Metagenomic detection methods in biopreparedness outbreak scenarios.

Oskar Erik Karlsson, Trine Hansen, Rickard Knutsson, Charlotta Löfström, Fredrik Granberg, Mikael Berg
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引用次数: 18

Abstract

In the field of diagnostic microbiology, rapid molecular methods are critically important for detecting pathogens. With rapid and accurate detection, preventive measures can be put in place early, thereby preventing loss of life and further spread of a disease. From a preparedness perspective, early detection and response are important in order to minimize the consequences. During the past 2 decades, advances in next-generation sequencing (NGS) technology have changed the playing field of molecular methods. Today, it is within reach to completely sequence the total microbiological content of a clinical sample, creating a metagenome, in a single week of laboratory work. As new technologies emerge, their dissemination and capacity building must be facilitated, and criteria for use, as well as guidelines on how to report results, must be established. This article focuses on the use of metagenomics, from sample collection to data analysis and to some extent NGS, for the detection of pathogens, the integration of the technique in outbreak response systems, and the risk-based evaluation of sample processing in routine diagnostics labs. The article covers recent advances in the field, current debate, gaps in research, and future directions. Examples of metagenomic detection, as well as possible applications of the methods, are described in various biopreparedness outbreak scenarios.

生物防备暴发情景中的宏基因组检测方法。
在诊断微生物学领域,快速分子方法对于检测病原体至关重要。通过快速和准确的检测,可以及早采取预防措施,从而防止生命损失和疾病的进一步传播。从防备的角度来看,早期发现和反应是重要的,以便尽量减少后果。在过去的20年里,新一代测序(NGS)技术的进步改变了分子方法的竞争环境。今天,在一个星期的实验室工作中,完全测序临床样品的总微生物含量是可以实现的,创建一个宏基因组。随着新技术的出现,必须促进它们的传播和能力建设,必须制定使用标准以及如何报告结果的准则。本文重点介绍元基因组学的应用,从样本收集到数据分析,以及在某种程度上的NGS,用于检测病原体,将该技术整合到疫情应对系统中,以及在常规诊断实验室对样本处理进行基于风险的评估。这篇文章涵盖了该领域的最新进展、当前的争论、研究中的差距和未来的方向。在各种生物防备暴发情景中描述了宏基因组检测的例子以及这些方法的可能应用。
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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