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空气传播病毒的采样方法。

Methods for sampling of airborne viruses.

作者信息

Verreault Daniel, Moineau Sylvain, Duchaine Caroline

机构信息

Centre de Recherche, Hôpital Laval, Institut Universitaire de Cardiologie et de Pneumologie, 2725 Chemin Ste.-Foy, Quebec City, Quebec, Canada G1V 4G5.

出版信息

Microbiol Mol Biol Rev. 2008 Sep;72(3):413-44. doi: 10.1128/MMBR.00002-08.

DOI:10.1128/MMBR.00002-08
PMID:18772283
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2546863/
Abstract

To better understand the underlying mechanisms of aerovirology, accurate sampling of airborne viruses is fundamental. The sampling instruments commonly used in aerobiology have also been used to recover viruses suspended in the air. We reviewed over 100 papers to evaluate the methods currently used for viral aerosol sampling. Differentiating infections caused by direct contact from those caused by airborne dissemination can be a very demanding task given the wide variety of sources of viral aerosols. While epidemiological data can help to determine the source of the contamination, direct data obtained from air samples can provide very useful information for risk assessment purposes. Many types of samplers have been used over the years, including liquid impingers, solid impactors, filters, electrostatic precipitators, and many others. The efficiencies of these samplers depend on a variety of environmental and methodological factors that can affect the integrity of the virus structure. The aerodynamic size distribution of the aerosol also has a direct effect on sampler efficiency. Viral aerosols can be studied under controlled laboratory conditions, using biological or nonbiological tracers and surrogate viruses, which are also discussed in this review. Lastly, general recommendations are made regarding future studies on the sampling of airborne viruses.

摘要

为了更好地理解空气病毒学的潜在机制,对空气传播病毒进行准确采样至关重要。空气生物学中常用的采样仪器也被用于收集悬浮在空气中的病毒。我们查阅了100多篇论文,以评估目前用于病毒气溶胶采样的方法。鉴于病毒气溶胶的来源多种多样,区分直接接触引起的感染和空气传播引起的感染可能是一项非常艰巨的任务。虽然流行病学数据有助于确定污染源,但从空气样本中获得的直接数据可为风险评估提供非常有用的信息。多年来使用了多种类型的采样器,包括液体冲击器、固体撞击器、过滤器、静电沉淀器等等。这些采样器的效率取决于各种环境和方法因素,这些因素可能会影响病毒结构的完整性。气溶胶的空气动力学粒径分布也对采样器效率有直接影响。可以在受控的实验室条件下,使用生物或非生物示踪剂以及替代病毒来研究病毒气溶胶,本综述中也对此进行了讨论。最后,针对未来空气传播病毒采样研究提出了一般性建议。

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