Predominance of secondary organic aerosol to particle-bound reactive oxygen species activity in fine ambient aerosol

Zhou, Jun; Elser, Miriam; Huang, Ru‐Jin; Krapf, Manuel; Fröhlich, Roman; Bhattu, Deepika; Stefenelli, Giulia; Zotter, Peter; Bruns, Emily A.; Pieber, Simone M.; Ni, Haiyan; Wang, Qiyuan; Wang, Yichen; Zhou, Yaqing; Chen, Chunying; Xiao, Mao; Slowik, Jay G.; Brown, Samuel; Cassagnes, Laure‐Estelle; Daellenbach, Kaspar R.; Nußbaumer, Thomas; Geiser, Marianne; Prévôt, Andrê S. H.; Haddad, Imad El; Cao, Junji; Baltensperger, Urs; Dommen, Josef

doi:10.5194/acp-19-14703-2019

Cited by 38 publications

(52 citation statements)

References 104 publications

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“…We also observed a clear distinction between the intrinsic OP values for the different PM sources, ranging from 0.044 ± 0.064 nmol min −1 µg −1 to 0.223 ± 0.085 nmol min −1 µg −1 for the OP DTT and from −0.018 ± 0.152 nmol min −1 µg −1 to 0.197 ± 0.104 nmol min −1 µg −1 for the OP AA . Such results agree with previous studies reporting different reactivity (or intrinsic OP) for different sources based on receptor-model techniques (Ayres et al, 2008;Bates et al, 2015;Cesari et al, 2019;Costabile et al, 2019;Fang et al, 2016;Paraskevopoulou et al, 2019;Perrone et al, 2019;Verma et al, 2014;Weber et al, 2018;Zhou et al, 2019;Daellenbach et al, 2020).…”

Section: Different Intrinsic Op Per Sourcessupporting

confidence: 93%

“…The source apportionment of the OP can be performed in two main ways: 1) by including the OP as an input variable for receptor-model (RM) (Verma et al, 2014;Fang et al, 2016;Ma et al, 2018;Cesari et al, 2019) or 2) by conducting source attribution to the PM mass and then, using a multiple linear regression (MLR) model, assigning OP to each of the sources from the source-receptor model (Bates et al, 2015;Verma et al, 2015b;Weber et al, 2018;Cesari et al, 2019;Paraskevopoulou et al, 2019;Zhou et al, 2019;Daellenbach et al, 2020). We decided to use the second approach since adding the OP variable to the PMF may change the source apportionment solution.…”

Section: Source Apportionmentmentioning

confidence: 99%

“…The dithiothreitol (DTT) and ascorbic-acid (AA) assays are widely used in associations with health endpoints (Abrams et al, 2017;Atkinson et al, 2016;Bates et al, 2015;Canova et al, 2014;Fang et al, 2016;Janssen et al, 2015;Strak et al, 2017a;Weichenthal et al, 2016;Yang et al, 2016;Zhang et al, 2016) even if the exact methodologies differ from one study to the other. Results can also differ for the seasonality of OP based on these two assays and some studies report strong seasonality of OP whereas others don't (Bates et al, 2015;Calas et al, 2019;Cesari et al, 2019;Fang et al, 2016;Ma et al, 2018;Paraskevopoulou et al, 2019;Perrone et al, 2016;Pietrogrande et al, 2018;Verma et al, 2014;Fang et al, 2015;Weber et al, 2018;Borlaza et al, 2018;Zhou et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

“…Finally, several studies have already shown that different sources of PM have different reactivity to OP tests (Verma et al, 2014;Bates et al, 2015;Fang et al, 2016;Weber et al, 2018;Paraskevopoulou et al, 2019;Cesari et al, 2019;Zhou et al, 2019;Daellenbach et al, 2020). In particular, sources with high concentrations of transition metals, such as road traffic, appear to have a higher intrinsic oxidative potential (i.e.…”

Section: Introductionmentioning

confidence: 99%

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Source apportionment of atmospheric PM<sub>10</sub> Oxidative Potential: synthesis of 15 year-round urban datasets in France

Weber¹,

Uzu²,

Favez³

et al. 2021

Preprint

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Abstract. Reactive oxygen species (ROS) carried or induced by particulate matter (PM) are suspected to induce oxidative stress in vivo, leading to adverse health impacts, such as respiratory or cardiovascular diseases. The oxidative potential (OP) of PM, displaying the ability of PM to oxidize the lung environment, is gaining a strong interest to examine health risks associated to PM exposure. In this study, OP was measured by two different acellular assays (dithiothreitol, DTT and ascorbic acid, AA) on PM10 filter samples from 15 yearly time series of filters collected at 14 different locations in France between 2013 and 2018, including urban, traffic and Alpine valley site typologies. A detailed chemical speciation was also performed on the same samples allowing the source-apportionment of PM using positive matrix factorization (PMF) for each series, for a total number of more than 1700 samples. This study provides then a large-scale synthesis on the source-apportionment of OP using coupled PMF and multiple linear regression (MLR) models. The primary road traffic, biomass burning, dust, MSA-rich, and primary biogenic sources had distinct positive redox-activity towards the OPDTT assay, whereas biomass burning and road traffic sources only display significant activity for the OPAA assay. The daily median source contribution to the total OPDTT highlighted the dominant influence of the primary road traffic source. Both the biomass burning and the road traffic sources contributed evenly to the observed OPAA. Therefore, it appears clearly that residential wood burning and road traffic are the two main target sources to prioritized in order to decrease significantly the OP in Western Europe and, would the OP being a good proxy of human health impact, to lower the health risks from PM exposure.

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Section: Different Intrinsic Op Per Sourcessupporting

confidence: 93%

Section: Source Apportionmentmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Source apportionment of atmospheric PM<sub>10</sub> Oxidative Potential: synthesis of 15 year-round urban datasets in France

Weber¹,

Uzu²,

Favez³

et al. 2021

Preprint

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“…Other studies have linked ROS formation to organic components [69] and metal components. We therefor investigated the correlation between ROS and the chemical composition.…”

Section: Ros Formation Potential Of Diesel Exhaust Particlesmentioning

confidence: 99%

Effect of Renewable Fuels and Intake O2 Concentration on Diesel Engine Emission Characteristics and Reactive Oxygen Species (ROS) Formation

et al. 2020

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Renewable diesel fuels have the potential to reduce net CO2 emissions, and simultaneously decrease particulate matter (PM) emissions. This study characterized engine-out PM emissions and PM-induced reactive oxygen species (ROS) formation potential. Emissions from a modern heavy-duty diesel engine without external aftertreatment devices, and fueled with petroleum diesel, hydrotreated vegetable oil (HVO) or rapeseed methyl ester (RME) biodiesel were studied. Exhaust gas recirculation (EGR) allowed us to probe the effect of air intake O2 concentration, and thereby combustion temperature, on emissions and ROS formation potential. An increasing level of EGR (decreasing O2 concentration) resulted in a general increase of equivalent black carbon (eBC) emissions and decrease of NOx emissions. At a medium level of EGR (13% intake O2), eBC emissions were reduced for HVO and RME by 30 and 54% respectively compared to petroleum diesel. In general, substantially lower emissions of polycyclic aromatic hydrocarbons (PAHs), including nitro and oxy-PAHs, were observed for RME compared to both HVO and diesel. At low-temperature combustion (LTC, O2 < 10%), CO and hydrocarbon gas emissions increased and an increased fraction of refractory organic carbon and PAHs were found in the particle phase. These altered soot properties have implications for the design of aftertreatment systems and diesel PM measurements with optical techniques. The ROS formation potential per mass of particles increased with increasing engine O2 concentration intake. We hypothesize that this is because soot surface properties evolve with the combustion temperature and become more active as the soot matures into refractory BC, and secondly as the soot surface becomes altered by surface oxidation. At 13% intake O2, the ROS-producing ability was high and of similar magnitude per mass for all fuels. When normalizing by energy output, the lowered emissions for the renewable fuels led to a reduced ROS formation potential.

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Aging Effects on the Toxicity Alteration of Different Types of Organic Aerosols: A Review

et al. 2023

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Predominance of secondary organic aerosol to particle-bound reactive oxygen species activity in fine ambient aerosol

Cited by 38 publications

References 104 publications

Source apportionment of atmospheric PM<sub>10</sub> Oxidative Potential: synthesis of 15 year-round urban datasets in France

Source apportionment of atmospheric PM<sub>10</sub> Oxidative Potential: synthesis of 15 year-round urban datasets in France

Effect of Renewable Fuels and Intake O2 Concentration on Diesel Engine Emission Characteristics and Reactive Oxygen Species (ROS) Formation

Aging Effects on the Toxicity Alteration of Different Types of Organic Aerosols: A Review

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Predominance of secondary organic aerosol to particle-bound reactive oxygen species activity in fine ambient aerosol

Cited by 38 publications

References 104 publications

Source apportionment of atmospheric PM&lt;sub&gt;10&lt;/sub&gt; Oxidative Potential: synthesis of 15 year-round urban datasets in France

Source apportionment of atmospheric PM&lt;sub&gt;10&lt;/sub&gt; Oxidative Potential: synthesis of 15 year-round urban datasets in France

Effect of Renewable Fuels and Intake O2 Concentration on Diesel Engine Emission Characteristics and Reactive Oxygen Species (ROS) Formation

Aging Effects on the Toxicity Alteration of Different Types of Organic Aerosols: A Review

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Source apportionment of atmospheric PM<sub>10</sub> Oxidative Potential: synthesis of 15 year-round urban datasets in France

Source apportionment of atmospheric PM<sub>10</sub> Oxidative Potential: synthesis of 15 year-round urban datasets in France