Detection of Omicron variant in November 2021: a retrospective analysis through wastewater in Halifax, Canada

IF 4.3 3区材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC

ACS Applied Electronic Materials Pub Date : 2024-06-28 DOI:10.1039/d4ew00350k

Emalie K. Hayes, Crystal Sweeney, Amina K. Stoddart, Graham A. Gagnon

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Abstract

This study evaluates the efficacy of wastewater surveillance (WWS) for the early detection of the Omicron variant of SARS-CoV-2 in a university setting in Halifax, Canada. Utilizing an allele-specific RT-qPCR assay, that targets a distinctive Omicron–Lambda mutation (N: P13L; C28311T), we retrospectively analyzed wastewater samples collected from four university residences between 01 September and 31 December 2021. We analyzed 276 passive wastewater samples from four university residences and 51 composite wastewater samples from the wastewater treatment facility (WWTF) which is located downstream of the university. Our findings reveal the presence of the C28311T mutation in wastewater collected before the clinical identification of the Omicron variant in the province. Retrospective analysis of SARS-CoV-2-positive samples using the C28311T RT-qPCR assay showed detections in wastewater collected at the university on 05 November 2021 and 06 November 2021 and in the WWTF samples on 26 November 2021. SARS-CoV-2 N2 RNA was detected in 51 campus samples and 20 treatment facility samples (18 and 39% detection rate, respectively). The study emphasizes the utility of passive sampling for its cost-effectiveness and minimal maintenance, enabling rapid testing and prompt health interventions within an institutional setting. The comparison between the localized approach at the university and the broader community surveillance at the WWTF illustrates the nuanced understanding provided by targeted WWS. While the WWTF samples reflect a community-wide perspective with less variability, the university's targeted surveillance captures localized outbreaks, offering actionable insights for campus management. These findings underscore the strategic value of integrating passive wastewater sampling into public health strategies for variant detection and outbreak prevention, particularly in institutional settings with high-density populations.

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2021 年 11 月检测到 Omicron 变体：对加拿大哈利法克斯废水的回顾性分析

本研究评估了废水监测 (WWS) 在加拿大哈利法克斯一所大学环境中早期检测 SARS-CoV-2 奥米克龙变异体的效果。利用一种针对独特的 Omicron-Lambda 变异（N：P13L；C28311T）的等位基因特异性 RT-qPCR 检测方法，我们对 2021 年 9 月 1 日至 12 月 31 日期间从四所大学宿舍收集的废水样本进行了回顾性分析。我们分析了来自四所大学宿舍的 276 份被动废水样本和来自大学下游废水处理设施（WWTF）的 51 份复合废水样本。我们的研究结果表明，在该省临床发现奥米克隆变异体之前采集的废水中就存在 C28311T 突变。使用 C28311T RT-qPCR 法对 SARS-CoV-2 阳性样本进行的回顾性分析表明，2021 年 11 月 5 日和 2021 年 11 月 6 日在大学收集的废水中以及 2021 年 11 月 26 日在污水处理厂收集的样本中均检测到了 C28311T 突变。在 51 份校园样本和 20 份污水处理设施样本中检测到了 SARS-CoV-2 N2 RNA（检出率分别为 18% 和 39%）。这项研究强调了被动采样的效用，即成本效益高，维护费用低，可在机构环境中进行快速检测并及时采取卫生干预措施。大学的本地化方法与污水处理厂的更广泛社区监测之间的比较说明了有针对性的 WWS 所提供的细微差别。虽然污水处理厂的样本反映的是整个社区的情况，变异性较小，但该大学的定向监测捕捉到了局部爆发的情况，为校园管理提供了可操作的见解。这些发现强调了将被动式废水采样纳入公共卫生策略以进行变异检测和疫情预防的战略价值，尤其是在人口密度较高的机构环境中。

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来源期刊

ACS Applied Electronic Materials Multiple-

CiteScore

7.20

自引率

4.30%

发文量

567