Sources of Personal Exposure to Fine Particles in Toronto, Ontario, Canada

Kim, David; Sass-Kortsāk, Andrew; Purdham, James T.; Dales, Robert; Brook, Jeffrey R.

doi:10.1080/10473289.2005.10464710

Cited by 22 publications

(15 citation statements)

References 40 publications

(60 reference statements)

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“…The median personal exposure to PM 2.5 in this study was comparable to levels reported from Boston , Seattle (Liu et al, 2003), and from Helsinki (Janssen et al, 2005;Lanki et al, 2007), but lower than levels reported from Minneapolis (Adgate et al, 2002), Toronto (Kim et al, 2005), Copenhagen (Sorensen et al, 2005), Vancouver (Ebelt et al, 2000), and Boston (Rojas-Bracho et al, 2004). Personal exposure to BS was lower than in Copenhagen (Sorensen et al, 2005), Helsinki, and Amsterdam (Janssen et al, 2005;Lanki et al, 2007).…”

Section: Discussionsupporting

confidence: 68%

“…Factors that influence personal exposures to ambient particulate air pollution have been investigated in several studies with repeated-measures designs via mixed-effects models (e.g., Janssen et al, 1998Janssen et al, , 2005Ebelt et al, 2000;Liu et al, 2003;Rojas-Bracho et al, 2004;Kim et al, 2005;Sorensen et al, 2005;Adgate et al, 2007;Lanki et al, 2007;Brown et al, 2009). However, only a few studies of environmental exposures to various air pollutants also reported between-person and within-person variance components for the study groups (e.g., Lee et al, 2004;Rappaport and Kupper, 2004;Egeghy et al, 2005;Lin et al, 2005;Sorensen et al, 2005;Lanki et al, 2007;Sarnat et al, 2009), two of these studies investigated exposure to PM 2.5 and BS (Sorensen et al, 2005;Lanki et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

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Variability of environmental exposure to fine particles, black smoke, and trace elements among a Swedish population

Johannesson

Rappaport

Sällsten

2011

J Expo Sci Environ Epidemiol

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Mixed-effects models were used to estimate within-person and between-person variance components, and some determinants of environmental exposure to particulate matter (PM 2.5 ), black smoke (BS) and trace elements (Cl, K, Ca, Ti, Fe, Ni, Cu, Zn, and Pb) for personal measurements from 30 adult subjects in Gothenburg, Sweden. The within-person variance component dominated the total variability for all investigated compounds except for PM 2.5 and Zn (in which the variance components were about equal). Expressed as fold ranges containing 95% of the underlying distributions, the within-person variance component ranged between 5-fold and 39-fold (median: sixfold), whereas the between-person variance component was always osixfold (median: threefold). The relatively large within-person variance components can lead to attenuation bias in exposure-response relationships and point to the importance of obtaining repeated samples of PM exposure from study subjects in epidemiological investigations of urban air pollution. On the basis of the variance components estimated for the various particulate species, between 3 and 39 repeated measurements per subject would be required to limit attenuation bias to 20%. Significant determinants for personal exposure levels were urban background air concentrations (PM 2.5 , BS, Cl, Zn, and Pb), cigarette smoking (PM 2.5 , BS, K, and Ti), season (PM 2.5 , Fe, and Pb), and the time spent outdoors or in traffic (Fe).

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Section: Discussionsupporting

confidence: 68%

Section: Introductionmentioning

confidence: 99%

Variability of environmental exposure to fine particles, black smoke, and trace elements among a Swedish population

Johannesson

Rappaport

Sällsten

2011

J Expo Sci Environ Epidemiol

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“…As a result, personal exposure to airborne substances is more closely related to indoor rather than outdoor pollution. 3,4 We review the sources, health effects and control strategies for several of the most important sources of residential biological and chemical contaminants.…”

mentioning

confidence: 99%

Quality of indoor residential air and health

Dales¹,

Liu²,

Wheeler³

et al. 2008

Canadian Medical Association Journal

165

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About 90% of our time is spent indoors where we are exposed to chemical and biological contaminants and possibly to carcinogens. These agents may influence the risk of developing nonspecific respiratory and neurologic symptoms, allergies, asthma and lung cancer. We review the sources, health effects and control strategies for several of these agents. There are conflicting data about indoor allergens. Early exposure may increase or may decrease the risk of future sensitization. Reports of indoor moulds or dampness or both are consistently associated with increased respiratory symptoms but causality has not been established. After cigarette smoking, exposure to environmental tobacco smoke and radon are the most common causes of lung cancer. Homeowners can improve the air quality in their homes, often with relatively simple measures, which should provide health benefits.

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“…As listed in Table 2(a), personal OC ad EC concentrations measured in other developed countries usually have considerably lower values than Hong Kong, such as personal OC and EC ranging from 5.4 to 8.3 µg m -3 and 0.2 to 1.4 µg m -3 in the United State. (Wilson et al, 2000;Landis et al, 2001;Turpin et al, 2007;Brinkman et al, 2009); personal EC varied from 0.6 to 1.0 µg m -3 in Toronto and Prince George, Canada (Kim et al, 2005;Noullett et al, 2006). Individual's OC and EC exposure in urban cities of China were considerably higher than that in Hong Kong (Du et al, 2010;Zhang et al, 2015).…”

Section: Personal Exposure To Pm 25 and Carbonaceous Aerosolmentioning

confidence: 99%

“…The average personal PM 2.5 concentrations measured in the present study were compared with other studies (Table 2(a)). The average personal exposure to PM 2.5 measured in the developed countries show lower values than in Hong Kong, such as in American cities (ranging from 8.4 to 44.8 µg m -3 ) (Williams et al, 2000;Larson et al, 2004;Turpin et al, 2007;Brinkman et al, 2009), Canadian cities (varying from 18.0 to 22.0 µg m -3 ) (Kim et al, 2005;Noullett et al, 2006), and European cities (winter = 25.1 µg m -3 ; summer = 8.8 µg m -3 ) (Zmirou et al, 2000). In contrast, personal exposure to PM 2.5 measured in Chinese cities usually have higher values (ranging from 45.4 to 122.4 µg m -3 ) than that in Hong Kong.…”

Section: Personal Exposure To Pm 25 and Carbonaceous Aerosolmentioning

confidence: 99%

Relationships between Outdoor and Personal Exposure of Carbonaceous Species and Polycyclic Aromatic Hydrocarbons (PAHs) in Fine Particulate Matter (PM2.5) at Hong Kong

Fan

Chen

Lui

et al. 2017

Aerosol Air Qual. Res.

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Personal and ambient fine particulate matter (PM 2.5 ) samples were simultaneously collected at Hong Kong during winter in 2014. Mass concentration, organic carbon (OC), elemental carbon (EC), and polycyclic aromatic hydrocarbons (PAHs) relationships were analyzed. The correlations of personal and ambient concentrations of PM 2.5 , OC, and EC indicated the ambient concentrations were the factors showing influences on the personal exposures. Personal to ambient (P/A) ratios in PM 2.5 , OC, and EC were all > 1, suggesting influences between indoor sources and/or personal activities. Significant higher ambient ΣPAHs concentrations with P/A ratios were nevertheless < 1. The Σ15 U.S. EPA priority PAHs accounted for 50.6% and 70.8% of ΣPAHs in personal and ambient samples, respectively. The ratios of indicator compounds confirmed the origin of PAHs in personal PM 2.5 , which were found to be associated predominantly with traffic emissions and the influence by the indoor sources.

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Sources of Personal Exposure to Fine Particles in Toronto, Ontario, Canada

Cited by 22 publications

References 40 publications

Variability of environmental exposure to fine particles, black smoke, and trace elements among a Swedish population

Variability of environmental exposure to fine particles, black smoke, and trace elements among a Swedish population

Quality of indoor residential air and health

Relationships between Outdoor and Personal Exposure of Carbonaceous Species and Polycyclic Aromatic Hydrocarbons (PAHs) in Fine Particulate Matter (PM2.5) at Hong Kong

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