The shedding of pathogens by infected humans enables the use of sewage monitoring to
conduct wastewater-based epidemiology (WBE). Although most WBE studies use data from
large sewage treatment plants, timely data from smaller catchments are needed for
targeted public health action. Traditional sampling methods, like autosamplers or grab
sampling, are not conducive to quick
ad hoc
deployments and
high-resolution monitoring at these smaller scales. This study develops and validates a
cheap and easily deployable passive sampler unit, made from readily available
consumables, with relevance to the COVID-19 pandemic but with broader use for WBE. We
provide the first evidence that passive samplers can be used to detect SARS-CoV-2 in
wastewater from populations with low prevalence of active COVID-19 infections (0.034 to
0.34 per 10,000), demonstrating their ability for early detection of infections at three
different scales (lot, suburb, and city). A side by side evaluation of passive samplers
(
n
= 245) and traditionally collected wastewater samples
(
n
= 183) verified that the passive samplers were sensitive at
detecting SARS-CoV-2 in wastewater. On all 33 days where we directly compared
traditional and passive sampling techniques, at least one passive sampler was positive
when the average SARS-CoV-2 concentration in the wastewater equaled or exceeded the
quantification limit of 1.8 gene copies per mL (
n
= 7). Moreover, on 13
occasions where wastewater SARS-CoV-2 concentrations were less than 1.8 gene copies per
mL, one or more passive samplers were positive. Finally, there was a statistically
significant (
p
< 0.001) positive relationship between the
concentrations of SARS-CoV-2 in wastewater and the levels found on the passive samplers,
indicating that with further evaluation, these devices could yield semi-quantitative
results in the future. Passive samplers have the potential for wide use in WBE with
attractive feasibility attributes of cost, ease of deployment at small-scale locations,
and continuous sampling of the wastewater. Further research will focus on the
optimization of laboratory methods including elution and extraction and continued
parallel deployment and evaluations in a variety of settings to inform optimal use in
wastewater surveillance.
Wastewater treatment plants (WWTP) typically have a service life of several decades. During this service life, external factors, such as changes in the effluent standards or the loading of the WWTP may change, requiring WWTP performance to be optimized. WWTP modelling is widely accepted as a means to assess and optimize WWTP performance. One of the challenges for WWTP modelling remains the prediction of water quality at the inlet of a WWTP. Recent applications of water quality sensors have resulted in long time series of WWTP influent quality, containing valuable information on the response of influent quality to e.g., storm events. This allows the development of empirical models to predict influent quality. This paper proposes a new approach for water quality modelling, which uses the measured hydraulic dynamics of the WWTP influent to derive the influent water quality. The model can also be based on simulated influent hydraulics as input. Possible applications of the model are filling gaps in time series used as input for WWTP models or to assess the impact of measures such as real time control (RTC) on the performance of wastewater systems.
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