Enhanced detection of viruses for improved water safety

Maximizing viral nucleic acid yield from passive samplers: Evaluating elution and extraction protocols

The COVID-19 pandemic has underscored the need for effective viral tracking in aqueous environments, particularly for non-enteric viruses. Despite advances in wastewater monitoring, surveillance of viruses in freshwater remains limited due to traditional sampling challenges. This study refines GAC-based passive sampling protocols by determining optimal extraction and elution methods for enhancing the recovery of viral nucleic acids in freshwater. Three commercially available total nucleic acid (TNA) extraction kits and four elution buffers were assessed for their ability to recover SARS-CoV-2 and bacteriophage MS2 from GAC-based samplers. The Promega Wizard® Enviro Total Nucleic Acid Kit, paired with a Tween®20-based buffer, provided the highest virus recovery efficiency for GAC-based passive sampling. Field-scale applications demonstrated the effectiveness of GAC-based passive samplers in capturing SARS-CoV-2, INFA, RSV, and MeV using the optimized protocols. The combination of the Tween®20 based buffer and the Promega kit led to increased detection frequencies in grab samples, which remained lower in recovery than passive sampling. This study underscores the importance of selecting appropriate TNA extraction kits and elution buffers to maximize virus recovery from passive samples. By optimizing these protocols, we enhance the sensitivity and reliability of viral surveillance in freshwater ecosystems.

A comprehensive review on human enteric viruses in water: Detection methods, occurrence, and microbial risk assessment

Human enteric viruses, such as norovirus, adenovirus, rotavirus, and enterovirus, are crucial targets in controlling biological contamination in water systems worldwide. Due to their small size and low concentrations in water, effective virus concentration and detection methods are essential for ensuring microbial safety. This paper reviews the typical and innovative methods for concentrating and detecting human enteric viruses, highlights viral contamination levels across different water bodies, and discusses the removal efficiencies of virus through various treatment technologies. The application and current gaps of quantitative microbial risk assessment (QMRA) for evaluating the risks of human enteric viruses is also explored. Innovative methods such as digital polymerase chain reaction and isothermal amplification show promise in sensitivity and convenience, however, distinguishing between infectious and non-infectious viruses should be a key focus of future detection techniques. The highest concentrations of human enteric viruses were detected in wastewater, ranging from 103 to 106 copies/L, while drinking water showed significantly lower concentrations, often below 102 copies/L. QMRA studies suggest that exposure to human enteric viruses, whether through contaminated drinking water, occupational contact, or accidental wastewater discharge, could result in a life expectancy of 1.96 × 10-4 to 4.53 × 10-1 days/year.

From capture to detection: A critical review of passive sampling techniques for pathogen surveillance in water and wastewater

Water quality, critical for human survival and well-being, necessitates rigorous control to mitigate contamination risks, particularly from pathogens amid expanding urbanization. Consequently, the necessity to maintain the microbiological safety of water supplies demands effective surveillance strategies, reliant on the collection of representative samples and precise measurement of contaminants. This review critically examines the advancements of passive sampling techniques for monitoring pathogens in various water systems, including wastewater, freshwater, and seawater. We explore the evolution from conventional materials to innovative adsorbents for pathogen capture and the shift from culture-based to molecular detection methods, underscoring the adaptation of this field to global health challenges. The comparison highlights passive sampling's efficacy over conventional techniques like grab sampling and its potential to overcome existing sampling challenges through the use of innovative materials such as granular activated carbon, thermoplastics, and polymer membranes. By critically evaluating the literature, this work identifies standardization gaps and proposes future research directions to augment passive sampling's efficiency, specificity, and utility in environmental and public health surveillance.