Wastewater-based epidemiology (WBE) has evolved from illicit drug tracking into a population-scale platform for monitoring exposure to hazardous organic contaminants and related health signals. By analyzing composite influent, WBE can quantify trends in pharmaceuticals, personal care products, pesticides, plasticizers, industrial chemicals, and PFAS, while enabling integration with microbial, genetic, and omics indicators. This review synthesizes hazardous-organic classes relevant to WBE and highlights biomarker selection principles that distinguish parent compounds from human metabolites, phase-II conjugates, and sewer- or treatment-derived transformation products. We critically discuss how biomarker specificity, excretion fractions, and in-sewer stability govern back-calculation accuracy and uncertainty. We further examine how wide-scope LC–MS/MS and HRMS workflows, together with automated sampling, IoT context sensors, cloud dashboards, and AI/ML data-fusion, can strengthen multi-biomarker interpretation, anomaly detection, and near-real-time decision support without replacing confirmatory laboratory analysis. Overall, multi-biomarker WBE offers an actionable “wastewater exposome” perspective to support proactive public health protection and environmental risk management.
Wastewater-based epidemiology of hazardous organics: Multi-biomarker insights and intelligent monitoring technologies / M.A.A.M. Hridoy, P. Pastorino, C. Bordin, M. Bodini, M.F. Jamee, A. Farabi, S. Rahman, F. Yeamim, P. Schneider. - In: JOURNAL OF HAZARDOUS MATERIALS. ORGANICS. - ISSN 3051-0597. - 3:(2026 Feb 26), pp. 100022.1-100022.16. [10.1016/j.hazmo.2026.100022]
Wastewater-based epidemiology of hazardous organics: Multi-biomarker insights and intelligent monitoring technologies
M. Bodini;
2026
Abstract
Wastewater-based epidemiology (WBE) has evolved from illicit drug tracking into a population-scale platform for monitoring exposure to hazardous organic contaminants and related health signals. By analyzing composite influent, WBE can quantify trends in pharmaceuticals, personal care products, pesticides, plasticizers, industrial chemicals, and PFAS, while enabling integration with microbial, genetic, and omics indicators. This review synthesizes hazardous-organic classes relevant to WBE and highlights biomarker selection principles that distinguish parent compounds from human metabolites, phase-II conjugates, and sewer- or treatment-derived transformation products. We critically discuss how biomarker specificity, excretion fractions, and in-sewer stability govern back-calculation accuracy and uncertainty. We further examine how wide-scope LC–MS/MS and HRMS workflows, together with automated sampling, IoT context sensors, cloud dashboards, and AI/ML data-fusion, can strengthen multi-biomarker interpretation, anomaly detection, and near-real-time decision support without replacing confirmatory laboratory analysis. Overall, multi-biomarker WBE offers an actionable “wastewater exposome” perspective to support proactive public health protection and environmental risk management.
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