Annette Rohr scite author profile

While most in the scientific community are of the opinion that the composition of fine particulate matter (PM 2.5 ) is an important driver of resultant health effects, there is still some degree of uncertainty regarding those components considered to be most harmful. Reviews of the subject from several perspectives have been published, but to our knowledge a comprehensive review of the epidemiological and toxicological literature related to long-term exposure to PM 2.5 components does not exist. We reviewed published epidemiological studies that were of a cohort design, included at least one PM component as well as PM 2.5 mass, and included quantitative analysis to relate health outcomes to individual components. Toxicological studies were included if they were ≥5 months in duration and either included at least one PM component as well as PM mass or focused on a specific PM or emissions type. Overall, we find that epidemiological and toxicological evidence for long-term effects of PM components is limited, in contrast to the short-term literature, which is more plentiful. Epidemiological literature suggests that a number of components are associated with health effects, and that no component is unequivocally not so associated. Toxicological studies that can more easily identify potentially causal components are generally limited to long-term studies using concentrated ambient particles (CAPs), of which few long-term studies exist. Epidemiological study designs that utilize existing monitoring data routinely collected by the U.S. Environmental Protection Agency would be valuable additions to the literature, as would novel toxicological studies that incorporate innovative designs to separate components or groups of components, such as denuders, filtration, or other approaches. From a policy perspective, it is important to more comprehensively investigate this issue so that if particular constituents are determined to be more potent in inducing health effects, their sources can be controlled.Implications: Understanding the components of PM 2.5 that are most harmful to human health is a critical policy issue. This review examined the epidemiological and toxicological literature related to long-term exposure to PM components and found that, unlike the literature on short-term health effects, there is insufficient information to make clear inferences about causal components. There is a need for further research in this area to exploit existing PM monitoring data in epidemiological studies and to design experimental studies that are able to tease out the effects of multiple constituents.

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The health significance of gas- and particle-phase terpene oxidation products: A review

Rohr

2013

Environment International

100

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Generation and Quantification of Ultrafine Particles through Terpene/Ozone Reaction in a Chamber Setting

Rohr

Weschler

Koutrakis³

et al. 2003

Aerosol Science and Technology

110

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Terpene/ozone reactions produce gas-and condensed-phase products and thus contribute to both indoor and outdoor aerosol. These reactions may be important in indoor settings, where terpenes are generated from indoor sources and ambient ozone can reach significant levels. Moreover, airway irritation has been observed in mice exposed to terpene oxidation products (OPs). The aim of this study was to characterize a system for generating and quantifying ultrafine particles formed through terpene/ozone reactions in preparation for inhalation toxicology experiments. Two common monoterpenes, α-pinene and d-limonene, and a hemiterpene, isoprene, were investigated. Ozone and gas-phase terpene were introduced continuously into a reaction flow tube, from which reaction products entered a plexiglass chamber. Particle number, mass, and size distribution (∼15-750 nm) were monitored in the chamber for various reactant concentrations and air exchange rates (AERs). In all experiments, ozone was the limiting reagent and the reaction rate was much more rapid than the AER. Particles formed rapidly and in high concentrations in the pinene and limonene systems. Particle formation was slower in the isoprene system and fewer particles were formed; moreover, particle diameters were smaller. In all 3 systems, progressive growth of particles was observed due to condensation and coagulation processes. The isoprene system displayed instability with respect to aerosol characteristics and did not reach steady-state conditions. In the pinene system, ozone concentration was a strong predictor of steady-state particle number and mass concentration and particle diameter. The particle number was greater at higher AERs, but particles were smaller. This study is the first to incorporate measurement of ultrafine particles formed from terpene/ozone reactions into a controlled exposure Address correspondence to Annette C. Rohr, EPRI, 3412 Hillview Avenue, Palo Alto, CA 94304-1395. E-mail: arohr@epri.com chamber setting. Following system characterization, we will conduct mouse exposures to further investigate the respiratory effects of gas-and particle-phase terpene OPs.

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Annette Rohr

Attributing health effects to individual particulate matter constituents

Comparative acute lung inflammation induced by atmospheric PM and size-fractionated tire particles

Long-term particulate matter exposure: Attributing health effects to individual PM components

The health significance of gas- and particle-phase terpene oxidation products: A review

Generation and Quantification of Ultrafine Particles through Terpene/Ozone Reaction in a Chamber Setting

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