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Approach to Predicting the Size-Dependent Inhalation Intake of Particulate Novel Brominated Flame Retardants

Peng-Tuan Hu, Wan-Li Ma, Zi-Feng Zhang, Liyan Liu, Wei-Wei Song, Zhiguo Cao, Robie W. Macdonald, Anatoly Nikolaev, Li Li, Yi-Fan Li

2021Environmental Science & Technology42 citationsDOI

Abstract

The risk of human exposure to particulate novel brominated flame retardants (NBFRs) in the atmosphere has received increasing attention from scientists and the public, but currently, there is no reliable approach to predict the intake of these compounds on the basis of their size distribution. Here, we develop a reliable approach to predict the size-dependent inhalation intake of particulate NBFRs, based on the gas/particle (G/P) partitioning behavior of the NBFRs. We analyzed the concentrations of eight NBFRs in 363 size-segregated particulate samples and 99 paired samples of gaseous and bulk particles. Using these data, we developed an equation to predict the G/P partitioning quotients of NBFRs in particles in different size ranges (KPi) based on particle size. This equation was then successfully applied to predict the size-dependent inhalation intake of particulate NBFRs in combination with an inhalation exposure model. This new approach provides the first demonstration of the effects of the temperature-dependent octanol–air partitioning coefficient (KOA) and total suspended particle concentration (TSP) on the intake of particulate NBFRs by inhalation. In an illustrative case where TSP = 100 μg m–3, inhalation intake of particulate NBFRs exceeded the intake of gaseous NBFRs when log KOA > 11.4.

Topics & Concepts

ParticulatesInhalationParticle sizeInhalation exposureEnvironmental chemistryUltrafine particleParticle (ecology)Environmental scienceChemistryMedicineOrganic chemistryBiologyAnesthesiaEcologyPhysical chemistryToxic Organic Pollutants ImpactAir Quality and Health ImpactsAtmospheric chemistry and aerosols
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