A simple passive sampling protocol using cheesecloth and electronegative filters coupled with a Tween®20-based elution technique provided reliable detection of SARS-CoV-2 in wastewater at targeted locations in a region of low COVID-19 prevalence.
We are in unprecedented times with the ongoing COVID-19 pandemic. The pandemic has impacted public health, the economy and our society on a global scale. In addition, the impacts of COVID-19 permeate into our environment and wildlife as well. Here, we discuss the essential role of wastewater treatment and management during these times. A consequence of poor wastewater management is the discharge of untreated wastewater carrying infectious SARS-CoV-2 into natural water systems that are home to marine mammals. Here, we predict the susceptibility of marine mammal species using a modelling approach. We identified that many species of whale, dolphin and seal, as well as otters, are predicted to be highly susceptible to infection by the SARS-CoV-2 virus. In addition, geo-mapping highlights how current wastewater management in Alaska may lead to susceptible marine mammal populations being exposed to the virus. Localities such as Cold Bay, Naknek, Dillingham and Palmer may require additional treatment of their wastewater to prevent virus spillover through sewage. Since over half of these susceptibility species are already at risk worldwide, the release of the virus via untreated wastewater could have devastating consequences for their already declining populations. For these reasons, we discuss approaches that can be taken by the public, policymakers and wastewater treatment facilities to reduce the risk of virus spillover in our natural water systems. Thus, we indicate the potential for reverse zoonotic transmission of COVID-19 and its impact on marine wildlife; impacts that can be mitigated with appropriate action to prevent further damage to these vulnerable populations.
This study examined sulfate deposition in Nova Scotia from 1999 to 2015, and its association with increased pH and organic matter in two protected surface water supplies (Pockwock Lake and Lake Major) located in Halifax, Nova Scotia. The study also examined the effect of lake water chemistry on drinking water treatment processes. Sulfate deposition in the region decreased by 68%, whereas pH increased by 0.1-0.4 units over the 16-year period. Average monthly color concentrations in Pockwock Lake and Lake Major increased by 1.7 and 3.8×, respectively. Accordingly, the coagulant demand increased by 1.5 and 3.8× for the water treatment plants supplied by Pockwock Lake and Lake Major. Not only was this coagulant increase costly for the utility, it also resulted in compromised filter performance, particularly for the direct-biofiltration plant supplied by Pockwock Lake that was found to already be operating at the upper limit of the recommended direct filtration thresholds for color, total organic carbon and coagulant dose. Additionally, in 2012-2013 geosmin occurred in Pockwock Lake, which could have been attributed to reduced sulfate deposition as increases in pH favor more diverse cyanobacteria populations. Overall, this study demonstrated the impact that ambient air quality can have on drinking water supplies.
Conversion from direct filtration to biofiltration in a full‐scale drinking water treatment plant in Halifax, N.S., was assessed in terms of filter performance (e.g., turbidity, head loss) and water quality during a 48‐month project. Conversion was achieved by removing prechlorination, with the overall objective of reducing disinfection by‐product formation. As a result of prechlorine removal, it was hypothesized that the anthracite‐sand filters would provide both particle removal and biological treatment in a single process step. When prechlorine was removed, adenosine triphosphate concentrations on the filter media increased from ∼50 to ∼200–500 ng/cm3. Filter performance analysis revealed that conversion increased the filter effluent turbidity and reduced the filter head loss accumulation rate. Unit filter run volumes and filter run times were maintained. Water quality monitoring indicated that finished water total disinfection by‐products were reduced by ∼10–20 μg/L for trihalomethanes and ∼6–10 μg/L for haloacetic acids.
We are in unprecedented times with the ongoing COVID-19 pandemic. The pandemic has impacted public health, the economy and our society on a global scale. In addition, the impacts of COVID-19 permeate into our environment and wildlife as well. Here, we discuss the essential role of wastewater treatment and management during these times. A consequence of poor wastewater management is the discharge of untreated wastewater carrying infectious SARS-CoV-2 into natural water systems that are home to marine mammals. Here, we predict the susceptibility of marine mammal species using a modelling approach. Many species of whale, dolphin and seal, as well as otters, are predicted to be highly susceptible to infection by the SARS-CoV-2 virus. In addition, geo-mapping highlights how current wastewater management in Alaska may lead to susceptible marine mammal populations being exposed to the virus. Since over half of these susceptibility species are already at risk worldwide, the release of the virus via untreated wastewater could have devastating consequences for their already declining populations. For these reasons, we discuss approaches that can be taken by the public, policymakers and wastewater treatment facilities to reduce the risk of virus spillover in our natural water systems. Thus, we highlight the potential for reverse zoonotic transmission of COVID-19 and its impact on marine wildlife; impacts that can be mitigated with appropriate action to prevent further damage to these vulnerable populations.
In developing an effective monitoring program for the wastewater surveillance of
SARS-CoV-2 ribonucleic acid (RNA), the importance of sampling methodology is paramount.
Passive sampling has been shown to be an effective tool to detect SARS-CoV-2 RNA in
wastewater. However, the adsorption characteristics of SARS-CoV-2 RNA on passive
sampling material are not well-understood, which further obscures the relationship
between wastewater surveillance and community infection. In this work, adsorption
kinetics and equilibrium characteristics were evaluated using batch-adsorption
experiments for heat-inactivated SARS-CoV-2 (HI-SCV-2) adsorption to electronegative
filters. Equilibrium isotherms were assessed or a range of total suspended solids (TSS)
concentrations (118, 265, and 497 mg L
–1
) in wastewater, and a modeled
q
max
of 7 × 10
3
GU cm
–2
was found. Surrogate adsorption kinetics followed a pseudo-first-order model in
wastewater with maximum concentrations achieved within 24 h. In both field and isotherm
experiments, equilibrium behavior and viral recovery were found to be associated with
wastewater and eluate TSS. On the basis of the results of this study, we recommend a
standard deployment duration of 24–48 h and the inclusion of eluate TSS
measurement to assess the likelihood of solids inhibition during analysis.
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