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Next generation risk assessment for occupational chemical safety – A real world example with sodium-2-hydroxyethane sulfonate

Adam Wood, C. Breffa, Caroline Chaine, Richard Cubberley, Matthew Dent, Joachim Eichhorn, Susann Fayyaz, Fabian A. Grimm, Jade Houghton, Reiko Kiwamoto, Predrag Kukić, M. Lee, Sophie Malcomber, Suzanne M. Martin, Beate Nicol, Joe Reynolds, G C Riley, Sharon Scott, Colin Smith, Carl Westmoreland, Willemien H. Wieland, Mesha Williams, Kathryn Wolton, Tristan Zellmann, Steve Gutsell

2024Toxicology16 citationsDOIOpen Access PDF

Abstract

Next Generation Risk Assessment (NGRA) is an exposure-led approach to safety assessment that uses New Approach Methodologies (NAMs). Application of NGRA has been largely restricted to assessments of consumer use of cosmetics and is not currently implemented in occupational safety assessments, e.g. under EU REACH. By contrast, a large proportion of regulatory worker safety assessments are underpinned by toxicological studies using experimental animals. Consequently, occupational safety assessment represents an area that would benefit from increasing application of NGRA to safety decision making. Here, a workflow for conducting NGRA under an occupational safety context was developed, which is illustrated with a case study chemical; sodium 2-hydroxyethane sulphonate (sodium isethionate or SI). Exposures were estimated using a standard occupational exposure model following a comprehensive life cycle assessment of SI and considering factory-specific data. Outputs of this model were then used to estimate internal exposures using a Physiologically Based Kinetic (PBK) model, which was constructed with SI specific Absorption, Distribution, Metabolism and Excretion (ADME) data. PBK modelling indicated a worst-case plasma maximum concentration (Cmax) of 0.8 μM across the SI life cycle. SI bioactivity was assessed in a battery of NAMs relevant to systemic, reproductive, and developmental toxicity; a cell stress panel, high throughput transcriptomics in three cell lines (HepG2, HepaRG and MCF-7 cells), pharmacological profiling and specific assays relating to developmental toxicity (Reprotracker and devTOX quickPredict). Points of Departure (PoDs) for SI ranged from 104 to 5044 µM. Cmax values obtained from PBK modelling of occupational exposures to SI were compared with PoDs from the bioactivity assays to derive Bioactivity Exposure Ratios (BERs) which demonstrated the safety for workers exposed to SI under current levels of factory specific risk management. In summary, the tiered and iterative workflow developed here represents an opportunity for integrating non animal approaches for a large subset of substances for which systemic worker safety assessment is required. Such an approach could be followed to ensure that animal testing is only conducted as a “last resort” e.g. under EU REACH.

Topics & Concepts

Risk assessmentContext (archaeology)ADMEExposure assessmentOccupational exposureOccupational safety and healthComputer scienceEnvironmental scienceRisk analysis (engineering)Environmental healthMedicinePharmacologyPharmacokineticsPathologyComputer securityBiologyPaleontologyPesticide Exposure and ToxicityEffects and risks of endocrine disrupting chemicalsChemical Safety and Risk Management
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