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通过尺寸排阻进行样品澄清对基于废水的流行病学中病毒检测和多样性的影响。

Impact of sample clarification by size exclusion on virus detection and diversity in wastewater-based epidemiology.

作者信息

Faleye Temitope O C, Skidmore Peter, Elyaderani Amir, Adhikari Sangeet, Kaiser Nicole, Smith Abriana, Yanez Allan, Perleberg Tyler, Driver Erin M, Halden Rolf U, Varsani Arvind, Scotch Matthew

机构信息

Biodesign Center for Environmental Health Engineering, Biodesign Institute, Arizona State University, Tempe, AZ 85287, USA.

College of Health Solutions, Arizona State University, Tempe, AZ, USA.

出版信息

medRxiv. 2022 Oct 25:2022.09.25.22280344. doi: 10.1101/2022.09.25.22280344.

DOI:10.1101/2022.09.25.22280344
PMID:36203558
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9536034/
Abstract

The use of wastewater-based epidemiology (WBE) for early detection of virus circulation and response during the SARS-CoV-2 pandemic increased interest in and use of virus concentration protocols that are quick, scalable, and efficient. One such protocol involves sample clarification by size fractionation using either low-speed centrifugation to produce a clarified supernatant or membrane filtration to produce an initial filtrate depleted of solids, eukaryotes and bacterial present in wastewater (WW), followed by concentration of virus particles by ultrafiltration of the above. While this approach has been successful in identifying viruses from WW, it assumes that majority of the viruses of interest should be present in the fraction obtained by ultrafiltration of the initial filtrate, with negligible loss of viral particles and viral diversity. We used WW samples collected in a population of ~700,000 in southwest USA between October 2019 and March 2021, targeting three non-enveloped viruses (enteroviruses [EV], canine picornaviruses [CanPV], and human adenovirus 41 [Ad41]), to evaluate whether size fractionation of WW prior to ultrafiltration leads to appreciable differences in the virus presence and diversity determined. We showed that virus presence or absence in WW samples in both portions (filter trapped solids [FTS] and filtrate) are not consistent with each other. We also found that in cases where virus was detected in both fractions, virus diversity (or types) captured either in FTS or filtrate were not consistent with each other. Hence, preferring one fraction of WW over the other can undermine the capacity of WBE to function as an early warning system and negatively impact the accurate representation of virus presence and diversity in a population.

摘要

在新冠疫情期间,利用基于废水的流行病学(WBE)进行病毒传播的早期检测及响应,这增加了人们对快速、可扩展且高效的病毒浓缩方案的兴趣及使用。其中一种方案是通过尺寸分级进行样品澄清,可采用低速离心以产生澄清的上清液,或采用膜过滤以产生初始滤液,该滤液不含废水中存在的固体、真核生物和细菌,然后对上述滤液进行超滤以浓缩病毒颗粒。虽然这种方法在从废水中鉴定病毒方面取得了成功,但它假定感兴趣的大多数病毒应存在于通过对初始滤液进行超滤获得的部分中,病毒颗粒损失和病毒多样性可忽略不计。我们使用了2019年10月至2021年3月期间在美国西南部约70万人口中收集的废水样本,针对三种无包膜病毒(肠道病毒[EV]、犬细小核糖核酸病毒[CanPV]和人腺病毒41型[Ad41]),以评估超滤前废水的尺寸分级是否会导致所确定的病毒存在和多样性出现明显差异。我们发现,废水样本两部分(滤膜截留固体[FTS]和滤液)中病毒的存在与否并不相互一致。我们还发现,在两部分均检测到病毒的情况下,FTS或滤液中捕获的病毒多样性(或类型)也不相互一致。因此,偏爱废水的一部分而非另一部分会削弱WBE作为早期预警系统的功能,并对人群中病毒存在和多样性的准确呈现产生负面影响。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/693a/9749538/3fb67a61150f/nihpp-2022.09.25.22280344v2-f0012.jpg
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