Optimal selection of monitoring sites in cities for SARS-CoV-2 surveillance in sewage networks

https://doi.org/10.1016/j.envint.2021.106768Get rights and content
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Highlights

  • Algorithms are proposed for optimal selection of sampling locations in sewers.

  • Are framed within the scope of SARS-CoV-2 surveillance.

  • Optimal locations are suggested for a predefined number of monitoring sites.

  • Algorithms are evaluated for a real case-study of a city of 100,000 inhabitants.

Abstract

Selecting sampling points to monitor traces of SARS-CoV-2 in sewage at the intra-urban scale is no trivial task given the complexity of the networks and the multiple technical, economic and socio-environmental constraints involved. This paper proposes two algorithms for the automatic selection of sampling locations in sewage networks. The first algorithm, is for the optimal selection of a predefined number of sampling locations ensuring maximum coverage of inhabitants and minimum overlapping amongst selected sites (static approach). The second is for establishing a strategy of iterations of sample&analysis to identify patient zero and hot spots of COVID-19 infected inhabitants in cities (dynamic approach). The algorithms are based on graph-theory and are coupled to a greedy optimization algorithm. The usefulness of the algorithms is illustrated in the case study of Girona (NE Iberian Peninsula, 148,504 inhabitants). The results show that the algorithms are able to automatically propose locations for a given number of stations. In the case of Girona, always covering more than 60% of the manholes and with less than 3% of them overlapping amongst stations. Deploying 5, 6 or 7 stations results in more than 80% coverage in manholes and more than 85% of the inhabitants. For the dynamic sensor placement, we demonstrate that assigning infection probabilities to each manhole as a function of the number of inhabitants connected reduces the number of iterations required to detect the zero patient and the hot spot areas.

Keywords

COVID-19
Wastewater-based epidemiology
Sewer
Sensor placement
Graph theory

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