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Asian Journal of Atmospheric Environment - Vol. 16 , No. 3
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[ Research Article ]
Asian Journal of Atmospheric Environment - Vol. 16, No. 3
Abbreviation: Asian J. Atmos. Environ
ISSN: 1976-6912 (Print) 2287-1160 (Online)
Print publication date 30 Sep 2022
Received 22 Jun 2022 Revised 19 Aug 2022 Accepted 11 Sep 2022
DOI: https://doi.org/10.5572/ajae.2022.062

Comparison of the Chemical Characteristics and Toxicity of PM2.5 Collected Using Different Sizes of Cyclones
Zikrilla Bobamuratovich Alimov1), 2), * ; Hyunwoo Youn1) ; Ayumi Iwata1) ; Kohei Nakano1) ; Takuma Okamoto1) ; Ayaha Sasaki1) ; Takuya Katori1) ; Tomoaki Okuda1)
1)Department of Applied Chemistry, Faculty of Science and Technology, Keio University, 3-14-1 Hiyoshi, Kohoku-ku, Yokohama 223-8522, Japan
2)Uzbek-Japan Innovation Center of Youth at the Tashkent State Technical University, 2B, Universitet street, Tashkent 100095, Uzbekistan

Correspondence to : * Tel: +81-45-566-1572 E-mail: zikrillaalimov@gmail.com


Copyright © 2022 by Asian Association for Atmospheric Environment
This is an open-access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/), which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
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Abstract

Cyclone sampling devices have been helpful in assessing the toxic effects of fine particulate matter (PM2.5). The particle collection efficiency of sampling devices is critical. This study investigated the effect of cyclone size on particle size, chemical composition, and particle toxicity. Three cyclones with different inner diameters (12-68 mm) were tested for penetration using an aerodynamic particle sizer, fluorescent polystyrene latex, and a differential mobility analyzer. The elemental and water-soluble ion compositions of the particles collected by different cyclones were compared. An evaluation of the particles’ toxicity was conducted by comparing the results of dithiothreitol (DTT), limulus amebocyte lysate (LAL), and cell exposure assays. The experimental evaluation showed a 50% cut-size of the cyclones between 0.17-0.28, 0.34-0.36, and 0.70 μm for the small, medium, and large cyclones, respectively. To collect PM2.5 and evaluate separation performance in the real environment, the small and large cyclones were selected according to the particle penetration and flow rate. A comparison of chemical composition and enrichment factor values found that the particles in the small cyclone samples contained smaller and more anthropogenic sources than those in the large cyclone samples. The oxidative potential (OP) measured by the DTT assay of the samples collected using the small and large cyclones differed across sampling periods and associated with the transition metals. The viability of human epithelial A549 cells after exposure to the collected particles using the cyclones was different across sampling periods and associated with OP. The endotoxin concentrations measured in the LAL assay were found only in the large cyclone samples; they affected the estimated level of cytokine based on IL(interleukin)-6 release from human leukemia monocytic (THP-1) cells derived macrophage-like cells. Regardless of the size, the cyclone techniques used in this study to collect aerosol particles would be a powerful tool for a detailed evaluation of particle toxicity.

Keywords: Cyclone, Cyclone size, Cyclone performance, Powder sample, PM2.5, Chemical composition, Oxidative potential, Endotoxin, Cell exposure, Particle toxicity
1. INTRODUCTION

Epidemiological studies have linked the inhalation of fine particulate matter (PM2.5) with increased respiratory (Harkema et al., 2004) and cardiovascular (Lippmann, 2014; Pope et al., 2004) diseases that can cause premature death (Anderson et al., 2012). Major ongoing studies of atmospheric aerosol particles have investigated physicochemical characteristics and toxicity using acellular and cellular assays (in vitro and in vivo) to identify the origins of ambient particles and assess their effect on the environment and human health (Patel and Rastogi, 2021; Lin and Yu, 2019; Fang et al., 2016; Diaz et al., 2011; Godleski et al., 2011).

In significant studies of toxicological or chemical assays of ambient air, filter-based sampling is commonly used to collect PM2.5 samples because of its high collection efficiency (Honda et al., 2017; Roper et al., 2015; Yang et al., 2014). However, the filter-based method requires crude particle extraction when the particle is attached to the filter, which may lead to a loss of PM components and alter particle toxicity (Chowdhury et al., 2018; Roper et al., 2018; Van Winkle et al., 2015; McWhinney et al., 2013; Pan et al., 2004). Moreover, the levels of the components in the filter samples can be changed by unexpected artifacts due to the adsorption of gases, chemical reactions, volatile compounds, and other factors in the ambient air (Hasegawa, 2016; Kameda et al., 2010).

To avoid the issues related to filter sampling, researchers have investigated cyclone devices to collect PM samples globally (Honda et al., 2021; Youn et al., 2021; Du et al., 2020; Okuda et al., 2015; Rule et al., 2010; Gussman et al., 2002; Vanderpool et al., 2001). Exposure to cyclone-collected particles may cause stronger biological responses than those observed after exposure to extracted particles from filter materials and induce lung inflammation (Honda et al., 2021). A powder sample can be directly subjected to in vitro and in vivo assays exposed to cells and experimental animals without losing of components in the extraction process or unexpected artifacts during sample collection (Ko et al., 2021; Sagawa et al., 2021; Chowdhury et al., 2019; Ogino et al., 2019, 2017; Onishi et al., 2018; Okuda and Isobe, 2017; Okuda et al., 2015; Rule et al., 2010).

In general, cyclone efficiency for ambient aerosols is enhanced by the gas inlet velocity and cyclone dimensions, with the 50% cut size of a cyclone (Dp50) decreasing as the particle collection efficiency increases (Cooper and Forrest, 2010; Wang et al., 2004). This presents that as the cyclone efficiency increases, the abundance (mass per unit weight) of larger particles in PM decreases and vice versa. In recent years, the toxic effects of airborne particles have been strongly linked with distribution of size and their compositions because the peak of the mass concentration and toxicity of each particle in the ambient air are found at different particle diameters (Fang et al., 2017; Fujitani et al., 2017; Voutsa et al., 2015). This emphasizes the importance of particle size distribution in assessing the adverse effects of airborne aerosols on human health, but also the relevance of PM compositions that respond with highly toxic potential (e.g., transition metals, carbonaceous materials, and bioaerosols) (Faraji et al., 2018; Fujitani et al., 2017; Vuong et al., 2017; Voutsa et al., 2015; Charrier and Anastasio, 2012; Schins et al., 2004). Thus, it is critical to focus on the interdependence of the inlet velocity and cyclone dimensions when sampling for particle toxicity analysis. Previous studies have shown almost no data on impacts of cyclone size and inlet velocity on particle toxicity analyses (Youn et al., 2021; Du et al., 2020; Lin et al., 2018; Peters et al., 2001; Chen et al., 1999). In this work, we have investigated to continue our previous research and contribute to achieve more reliable data when using cyclones in particle toxicity assessment to evaluate of health effects (Kurihara et al., 2022; Honda et al., 2021; Ogino et al., 2019; Onishi et al., 2018; Okuda et al., 2007).

This study aimed to evaluate the separation performance of different cyclone sizes and impacts of them on the chemical compositions of the samples and toxicity analyses. Three cyclones (large, medium, and small) were tested for penetration using an aerodynamic particle sizer, fluorescent polystyrene latex, and a differential mobility analyzer to investigate the optimal cyclone size for a reliable evaluation of the health effects of PM2.5. Two cyclones (small and large) with different separation efficiency were selected and simultaneously collected PM2.5 samples throughout the year. The ion species of the particles collected using the two cyclones were compared to evaluate the separation characteristics of the cyclones. For the detailed comparison of the samples, elemental analysis, oxidative potential (OP), endotoxin analyses, and cell exposure were conducted primarily to evaluate the relationship between the particle toxicity and separation performance of the cyclones.

2. MATERIALS AND METHODS
2. 1 Evaluation of the Separation Characteristics of Cyclones Using Particle Penetration Measurement

The particle size distribution measurement of the cyclone sampling devices, expressed using the equation for particle penetration (Okuda et al., 2015), is a significant factor in assessing the health hazards of PM (Grahame and Schlesinger 2010; McCreanor et al., 2007). This is because the particles of major health-hazardous particles, such as transition and heavy metals and water-soluble and insoluble fractions are contained in fine region of typical atmospheric aerosols (De Kok et al., 2006). The increase in flow rate decreases the particle penetration through cyclones (Youn et al., 2021). Therefore, penetration measurement of the cyclones is important to assess their performance when the flow rate increases.

The cyclones and their dimensions, and the pump models in the sampling system are shown in Table 1. The instruments included large (HVS3, CS3 Inc., Sandpoint, ID), medium (URG-2000-30EH, URG), and small (URG-2000-30EHB, URG) cyclones. Individual cyclones were tested by the following three experiments for measuring particle penetration: measurement of particle size distribution using aerodynamic particle sizer (APS), particle number counts of each monodisperse particle classified using differential mobility analyzer (DMA), and measurement of fluorescence intensity using fluorescent monodisperse polystyrene latex (PSL) particles with and without a cyclone.

Table 1. 
Dimensions and specifications of the cyclones used in this study.
Dimensions and specifications Small Medium Large
Model of the cyclones URG-2000-30EHB URG-2000-30EH HVS3
Cyclone diameter (mm) 12 20* 68
Width and height (or diameter) of the inlet pipe (mm) 3×6 5×10 18.5
Diameter of the outlet pipe (mm) 6 10 36
Diameter of the bottom outlet pipe (mm) 3 5 32
Height of the cylindrical region (mm) 27 43* 90
Height of the conical region (mm) 23 37* 170
Flow rate to the 50% cut-size of 2.5 μm (L/min) 5.5 16.7 No data
Experimental flow rate (L/min) 100 150 1200
Inlet velocity (m/s) 93 78 71
Model of the pump ULVAC DA-241S ULVAC DA-241S Ho Hsing RB60-620
*Dimensions were calculated using cut-cyclone measurements (URG-2000-30EHB) because no data was available for the inner sizes.

The flow rates for the cyclones were designed experimentally according to the pumps to investigate the impacts of cyclone size on the collection efficiency and chemical compositions, without getting greater pressure loss. In order to determine the inlet velocity, the selection of a pump is critical. From engineering point of view, it is useful any strong pump to overcome high pressure drop of cyclone. From economical point of view, the cost of pump is important. From the environmental and analytical point of view, the use of an oil-free pump is required to prevent sample contamination (Cooper and Forrest, 2010; Wang et al., 2004). In this study, we chose the pump (Table 1) according to economical, environmental and analytical points of view, in particular, the environmental aspects. Therefore, according to economic and environmental points of view, an affordable oil-free pumps were chosen and operated them in the maximum power in order to obtain the particulate samples as much as possible. To measure particle penetration through the cyclones, the airflow rates were set at 100 L/min (small), 150 L/min (medium), and 1,200 L/min (large).

2. 1. 1 Particle Penetration of the Cyclones Measured Using APS

An APS spectrometer (Model 3321, TSI Inc., USA) measured the aerosol size distributions in the ambient air from 0.5 to 20 μm and analyzes the time-of-flight of individual particles in an accelerating flow field (Volckens and Peters, 2005; Peters and Leith, 2003). The experimental system for measuring the separation characteristics of a cyclone using the APS is shown in Fig. 1. The particle size distribution in the air flow before and after the cyclones were measured using the APS. This measurement was conducted six times for 6 min at each flow rate of the cyclones.


Fig. 1. 
Schematic diagram of the APS system to evaluate the particle penetration of the cyclones.

2. 1. 2 Particle Penetration of Cyclones Measured using Fluorescent PSL Monodisperse Particles

Additional experiments were required to determine the penetration of particles with a size of 0.5 μm or smaller through the cyclones. The system for measuring the cyclone’s separation characteristics using fluorescent PSL particles (Polyscience Inc., Warrington, PA, USA) is shown in Fig. 2. The fluorescent PSL particles were supplied by an atomizer and collected with a filter for 20 min, each with and without a cyclone. The filter sample without a cyclone was designated as a reference filter, and the filter sample after the cyclone was designated as a backup filter (BF). The flow rate for the cyclones and reference filters was measured using a mass flow meter and set to the same value before each test. The flow rate of the introduced clean air was carefully adjusted that the flow of the air contained the PSL particles was 2 L/min, with and without each cyclone. Moreover, we confirmed that the number concentration of the generated PSL particles did not differ significantly with or without cyclones using a condensation particle counter (CPC, Model 3750). Fluorescent particles of 0.1, 0.2, 0.5, and 1.0 μm were supplied. The fluorescent PSL particle solution in the atomizer was diluted 20 times with ultra-pure water from the fluorescent solution of PSL to make it 0.05 mL/mL.


Fig. 2. 
Schematic diagrams of the experimental system to evaluate the performance of the cyclones using the fluorescent PSL monodisperse particles.

The filters collected the PSL particles dissolved in ethyl acetate and shaken at 150 rpm for 120 min. After that, the solution was filtered through a quartz fiber filter to eliminate impurities, and the obtained solution was measured using a spectrofluorophotometer (RF-6000, Shimadzu Corporation, Japan). The fluorescent PSL particle concentration was measured at 441 nm of the excitation wavelength, 470-510 nm of fluorescence wavelength, 600 nm/min scan speed, 1.0 nm of the data interval, auto sensitivity, 5.0 nm of spectral bandwidth excitation side, and 5.0 nm of fluorescence side.

2. 1. 3 Particle Penetration of Cyclones Measured Using the DMA System

Fig. 3 shows the DMA system (DMA-5180, SHIBATA) for measuring particle penetration through the cyclones. An Am-241 neutralizer between the diffusion dryer and the DMA was also used. Test particles were generated using an atomizer using 4% ammonium sulfate solution. The flow rate of the introduced clean air is the same as in the above method using the fluorescent PSL particles. The particles were classified in order by the DMA in a size range from 100 nm to 500 nm in diameter. The classified monodisperse particles with one diameter were measured the number concentration by CPC at front of and back of the cyclone to calculate the penetration rate. In addition, we used an isokinetic sampling probe to avoid particle separation by the small flow rate of the CPC against that of pump.


Fig. 3. 
Schematic diagrams of the DMA system to evaluate the particle penetration of the cyclones.

2. 2 Parallel Field Sampling Using the Large and Small Cyclones

Total ten sets of PM2.5 were simultaneously collected from 2 April 2020 to 14 April 2021 using the small cyclone (URG-2000-30EHB) and the large cyclone (HVS3) on the rooftop at the Yagami campus of Keio University, Yokohama, Japan. Detailed information about the sampling site was provided in a previous study (Honda et al., 2021). Both sampling cyclones were selected as having the most productive flow rate and separation performance. A schematic diagram of the experimental cyclone sampling system of PM2.5 samples is shown in Fig. 4. The flow rates of the small and large cyclones were 100 L/min and 1200 L/min, respectively. The samples were set between 21 and 60 days depending on the atmospheric concentration of PM2.5 to collect adequate amount of samples for detailed analysis.


Fig. 4. 
Schematic diagram of the PM2.5 sampling system for small and large cyclones.

2. 3 Sample Analysis

The samples were analyzed to determine total water-soluble ions using ion chromatography as described in the following section. The ion species were compared to evaluate the separation characteristics of the small and large cyclones for individual elements, because the total ions are the predominant chemical components of the ambient aerosol particles (Okuda et al., 2018; Okuda et al., 2015). Moreover, the ion components essentially comprise the secondary aerosols formed during warm and cold periods (Shen et al., 2008; Song et al., 2006). Two sets of PM2.5 samples out of all the samples collected between 10 December 2020 and 6 January 2021 and 10 March and 14 April 2021 were chosen for detailed analysis (elemental and water-soluble ion analyses, dithiothreitol (DTT) and limulus amebocyte lysate (LAL) assays, and cytotoxicity assays using human epithelial A549 cells and macrophage-like cells). The ion contents of the two samples were different enough to evaluate the effects of composition on the detailed toxicity analysis.

2. 4 Water-Soluble Ion Analysis

The powder sample weighed about 2 mg was extracted using ultra-pure water. The sample solution was analyzed using an ion chromatography (IC) system (Dionex AS-AP, ICS-2100 and ICS-1100, Thermo Fisher Scientific Inc., USA) for anion species (Cl-, NO3-, SO42-) and cation species (Na+, NH4+, K+, Mg2+, Ca2+). Chromeleon Chromatography Data System version 7.2 was used to analyze the chromatogram. The standard material CRM#28 (Urban Aerosols, NIES, National Institute for Environmental Studies Onogawa, Tsukuba, Japan) was used as a reference material to check the accuracy of the analysis. Abundance of ions in the sample was expressed as part per million weights of sample (ppmw). The samples were weighed using electric balance Sartorius ME235S (resolution d=0.01 mg) in room temperature 24±3°C, and relative humidity <35%. The limit of detection (LOD) for Cl-, NO3-, SO42-, Na+, NH4+, K+, Mg2+, and Ca2+ was 750, 6200, 4437, 323, 260, 154, 229, and 463 ppmw, respectively; the LOD value was calculated with standard deviation multiplied by five of the replication analyses of standard solution. The precision (coefficient of variation) for five times repetition analysis of standard solution was less than 7%.

2. 5 Detailed Comparison of the Particles Collected by the Large and Small Cyclones Using Chemical Composition and Toxicity Analysis
2. 5. 1 Elemental Analysis

Inductively Coupled Plasma–Mass Spectrometry (ICP-MS, iCAP TQ, Thermo Fisher Scientific) was used to analyze the samples in the Atmospheric Environment Innovation Center at Seikan Kensa Center Inc. for ICP-MS analysis. The powder sample was weighed at about 1 mg and decomposed in 5 mL nitric acid, 1 mL hydrogen peroxide, and 2 mL hydrofluoric acid with a microwave decomposition device. The decomposed liquid was transferred to a 50 mL centrifuge tube, and the volume was adjusted to 50 mL. Finally, the sample solutions were analyzed. The quantification of metals (e.g., Al, Ti, V, Cr, Mn, Fe, Cu, Zn, Ni, Pb) was performed. The standard solution was diluted 10, 100, and 1000 times with a mixed solution of 5% nitric acid and 1% hydrofluoric acid to drive for an appropriate concentration for the target element. The LOD for Al, Ti, V, Cr, Mn, Fe, Cu, Zn, Ni, and Pb was 40, 1.9, 0.1, 0.4, 0.4, 5.0, 0.8, 1.4, 0.26, and 0.3 ppmw, respectively. Recovery rate of the target elements ranged from 87% to 97%, measured using standard reference materials (CRM).

2. 5. 2 Identification of Metal Emission Sources

Enrichment factors (EFs) were used to assess the contribution of anthropogenic emissions to the atmosphere for each metal in PM2.5 (Jing et al., 2022; Ny and Lee, 2010). The reference element is often taken to be Al and Fe (for terrestrial sources) and Na (for oceanic sources) (Ny and Lee, 2010; Zoller et al., 1974; Chester and Stoner, 1973). Moreover, Ti and Mn have been used successfully (Jing et al., 2022; Obiajunwa et al., 2002; Loska et al., 1997). In this study, we avoid using of Al or Fe as reference elements because the small and large cyclones are made of aluminium and stainless steel, respectively. We focused on assessing the enrichment levels of V, Cr, Mn, Fe, Cu, Zn, Ni, and Pb in samples because the transition metals mainly come from anthropogenic activities (Chen et al., 2010; Okuda et al., 2007; Song et al., 2006). Therefore, Ti was used as the reference element in the following equation to avoid Al and Fe, which may be contaminated by cyclones, and to focus on heavy metals and transition metals:

EFi=Ci/CTiPM2.5Ci/CTicrust (1) 

where Ci and CTi refer to the abundance of each element and Ti in PM2.5 and the Earth’s crust. The average crustal concentrations were obtained from a study by Taylor (1964).

2. 5. 3 DTT Assay

The reactive oxygen species (ROS) generation ability (or OP) of PM is one of the comprehensive and realistic toxicity indicators which reflects physicochemical properties (e.g., size, surface area, chemical composition) of PM. Redox-active particles deplete antioxidants, damaging biomolecules, and leading to acute and chronic diseases (Gao et al., 2020; Delfino et al., 2011). In particular, the dithiothreitol-measured OP of aerosol particles has been extensively used worldwide as a suitable indicator for evaluating the oxidation properties of ambient particles (Wang et al., 2019). First, to measure the OP of PM2.5, a phosphate buffer (0.1 M Na2HPO4+0.1 M KH2PO4) at pH 7.4 was treated with Chelex resin to remove trace metals used as a solvent (Charrier and Anastasio, 2012). Then, the powders of DTT and 5,5-dithiobis-(2-nitrobenzoic acid) (DTNB, FUJIFILM Wako Pure Chemical Corporation, Japan) were dissolved in the phosphate buffer to prepare 1.0 mM DTT and 6.25 mM DTNB solutions. The powder samples weighed about 2 mg were sonicated in 19 mL of the phosphate buffer for 15 min at a temperature <15°C. Next, 1.9 mL of each sample solution was transferred to a microtube, and 2 μL of Tween-20 solution (10% in H₂O, BioVision, Inc., USA) was added. The reaction continued at 37°C for 30 min in a Thermo block (ND-M01, Nissin, Japan). A total of 100 μL of the 1.0 mM DTT solution was added to the microtube. After 6 min of the start of the reaction with the DTT solution, 20 μL of the DTNB solution was added quickly to develop color (the reaction stopped there) and put in a refrigerator. More detailed information about the preparation of the standard solution and measurement absorbance is given in the previous study (Kurihara et al., 2022). The precision of the DTT assay was checked using the reference material CRM#28. The sample’s DTT consumption rate (μM/mg/min) was calculated as the regression slope between DTT concentration and time. LOD was 0.09 μM/mg/min; the LOD value was calculated on the standard solution curves set using a linear regression model (Piehler et al., 2020).

2. 5. 4 LAL Assay

Endotoxin (a component of the exterior cell membrane of Gram-negative bacteria) is a group of toxic and proinflammatory compounds of lipopolysaccharide (LPS) responsible for releasing and activating cytokine production (Carty et al., 2003; Heinrich et al., 2003). A certain type of bacteria causes symptoms involving airway inflammation, fever, and lung function decline due to their strong immune-modulating properties (Heinrich et al., 2003; Reed and Milton, 2001). Endotoxins were assayed using the quantitative kinetic chromogenic LAL method. Before experiments, all glassware such as triangular flasks, test tubes with aluminum caps, and reservoirs were sterilized at 250°C for 2 hours. First, a 0.05% Tween solution was prepared using Tween-20 (10% in H₂O, BioVision, Inc., USA) and endotoxin-free distilled water/LAL reagent water (Otsuka Pharmaceutical Factory, Inc., Tokushima, Japan). Then, 2 mg of each powder sample was dissolved in 4 mL 0.05% Tween solution at room temperature using a horizontal shaker for 1 hour and sonicated at low temperature for 15 min. An endotoxin standard solution was prepared at 7 concentrations (1, 0.5, 0.25, 0.1, 0.05, 0.025, 0.0125 EU mL-1) using a control standard endotoxin (Associates of Cape Cod. Inc., MA, USA). After 7 min of centrifugation at 5000 rpm, 50 μL of supernatant per sample, blank (LAL reagent water), and standard endotoxin solution was transferred to a 96-well microplate. Then 50 μL of a lysate reagent (Pyro Color-MP: Chromogenic Diazo-Coupling Kit, Associates of Cape Cod. Inc., MA, USA) was added to the microplate using an 8-series pipette and the microplate was stirred manually to mix. The plate was immediately put on an ice pack after warming in 96-well shaking incubators at 37.0°C for 25 min. After the incubation was completed, the PyroColor Diaza Reagent DIA150-MP (Associates of Cape Cod. Inc.) was added to each well. A total of a 50 μL of HCl solution, ammonium sulfamate and N-(1-Naphthyl) polyethylenediamine (NEDA) were added to each well using an 8-unit pipettor and stirred. Absorbance was measured at 540 nm using a microplate reader (AS ONE: MPR-A100). Endotoxin concentrations were expressed as endotoxin units per milligram of sample (EU mg-1). The correlation coefficient of a calibration curve was taken to 0.980 or more to confirm the experiment’s accuracy. The accuracy of the DTT assay was checked using the reference materials CRM#28 and CRM#30 (Urban Aerosols and Gobi Kosa Dust, NIES, National Institute for Environmental Studies Onogawa, Tsukuba, Japan). LOD was 0.1 EU mg-1; the LOD value was calculated using a linear regression model fitted to the standard solution curves (Piehler et al., 2020).

2. 5. 5 Cell Viability and Cytokine Measurements

The cytotoxicity of the collected particles was evaluated by the viability of human epithelial A549 cells and the IL (interleukin)-6 production of macrophage-like cells differentiated from human leukemia monocytic (THP-1) cells. A549 cells derived from human alveolar cell carcinoma of lung cancer cells are frequently used in toxicity research to evaluate the biological effects of particles on human respiratory systems (Jia et al., 2017). Macrophage cells, which are antigen-presenting cells, are one of the most potent producers of proinflammatory cytokines in the airways and lungs and play roles as the driver of local and systemic inflammatory responses. Moreover, exposure of atmospheric particles to macrophage cells has also confirmed a significant release of IL-6, one of those important cytokines (Jia et al., 2017; Hiraiwa and van Eeden, 2013).

The A549 cells used to measure this viability were purchased from Japanese Cancer Research Resources Bank (JCRB), National Institutes of Biomedical Innovation, Health and Nutrition, Japan. And they were maintained with Minimum Essential Medium (MEM, Thermo Fisher Scientific, Waltham, MA, USA) including 10% deactivated fetal bovine serum (FBS, Origin South America, CCP-FBS-BR-500, Cosmo Bio Co., Ltd., Tokyo, Japan), 1% penicillin-streptomycin solution (PS, FUJIFILM Wako Chemicals Corporation, Osaka, Japan), and 1% MEM Non-Essential Amino Acids (Thermo Fisher Scientific, Waltham, MA, USA) at 37°C in a humidified atmosphere containing 95% air and 5% CO2. The cells were seeded with a concentration of 1,000 cells/well on 96 well plates 24 hours before the particles were exposed. It should be noted that the small seeding concentration and culture time in this study differ from the typical cell density exposed in the subconfluently cell state. However, although the actual effect may be overestimated, the toxicity of the particles can be accurately characterized due to be grasped with higher sensitivity. Incubated cells were exposed for 24 hours to a solution suspended in the above-prepared culture medium at particle concentrations of 7.5, 75, and 150 μg mL-1. The viability of exposed cells was measured by the Premix Water-soluble tetrazolium salt-1 (WST-1) Cell Proliferation Assay System (MK-400, TAKARA BIO INC., Shiga, Japan). Following a standard protocol in this analysis, we added 10 μL of WST-1 solution to each well, incubated for 4 hours for the reaction, and measured their absorbance at 450 nm and 630 nm. Cell viability was calculated as a ratio and compared with the control cells. Each concentration was repeated in three wells (n=3).

To provide additional data on PM2.5 cytotoxicity, inflammatory mediator release, cytokines (IL-6) were measured after treating of macrophage-like cells with PM2.5. IL-6 is promptly and transiently produced during infections and tissue injuries and stimulates acute-phase responses and immune reactions. Moreover, high-level IL-6 exerts pathologically on chronic inflammation and autoimmunity (Tanaka et al., 2014). Before exposure, THP-1 was treated with phorbol 12-myristate 13-acetate (PMA, FUJIFILM Wako Chemicals Corporation, Osaka, Japan) for differentiation into functional macrophages (Starr et al., 2018). Human monocytic leukemia THP-1 cells purchased from the JCRB were maintained in RPMI-1640 (FUJIFILM Wako Chemicals Corporation, Osaka, Japan) containing 1% deactivated FBS, 1% PS and stored in a humidified atmosphere containing 95% air and 5% CO2 at 37°C. In this measurement, THP-1 cells were seeded at 4.8×104 cells/well on 12 well plates with PMA (200 nM). After incubating for 72 hours, the medium was replaced with a PMA-free medium and additional incubated for 72 hours until the sample is exposed. The exposure time of the sample was set 24 hours, similar to the cell viability described above. The levels of IL-6 in the centrifuged supernatants were measured by Human IL-6 enzyme-linked immunosorbent assay (ELISA) Kit (LBIS Human IL-6 ELISA Kit, AKH-IL6, FUJIFILM Wako Shibayagi, Gunma, Japan) 24 hours after particle exposure, according to the manufacturer’s instructions. The absorbance was observed under the microplate reader at 450 nm and 630 nm. LOD was 0.98 pg/mL; the LOD value was calculated on the standard solution curves set using a linear regression model (Piehler et al., 2020). The amount of cytokine release is determined by the concentration from the absorbance of the measured sample by their calibration curve that was obtained the absorbance measured by seven concentrations of IL-6 standard regent (i.e., positive control). For each experiment, the mean values were obtained from the replicate analysis (e.g., n=3).

2. 5. 6 Statistical Analysis

T-test was used to compare the differences between cell viability and cytokine levels for a similar dose-manners. *p<0.05 implies statistically significant and **p<0.01 is highly significant.

3. RESULTS AND DISCUSSION
3. 1 Evaluation of the Separation Characteristics of Cyclones Using Penetration Measurement Systems

Fig. 5 shows the penetration curves for the three cyclones measured using the aerodynamic particle sizer (APS), fluorescent monodisperse polystyrene latex (PSL), and differential mobility analyzer (DMA) systems. Fig. 5a shows the penetration curves of the APS for the cyclones. The penetration of particles for cyclones with an aerodynamic diameter of 0.54 μm was 25% for the small cyclone, and 34% for the medium cyclone; with an aerodynamic diameter of 0.84 μm, it was 30% for the large cyclone. However, we must explain the measurement problems that lead to the uncertainty of this result by APS. The pressure dropped at the downstream of the cyclone. In particular, the small diameter of the cyclone at large flow rates to reduce the cutoff diameter can be expected to result in greater pressure loss. Therefore, it is possible that the instrument conditions were not sufficient under such reduced pressure for the suctioned air volume, for the flow ratios between sample and sheath flow, or for the correction of measurement results. In fact, the pressure when measured with a small cyclone was below 600 mbar, and traditional measurements at that pressure led to strange results. Fig. 5b shows the penetration curves of the PSL particles, whereby the 50% cut size of a cyclone (Dp50) of the small, medium and large cyclones were 0.28 μm, 0.36 μm, and 0.7 μm, respectively. Dp50 for the PSL system for the small and medium cyclones were almost similar. Therefore, we conducted additional measurements using the DMA system for the small and medium cyclones. The penetration measurement for the large cyclone was not conducted using the DMA system because the high flow rate reduces the number of particles and required considerable time. In Fig. 5c, the penetration curves of the DMA system for the small and medium cyclones are shown. The penetration curves of the DMA system crossed the line of Dp50 at 0.17 μm and 0.34 μm for the small and medium cyclones, respectively. These three approaches for the evaluation of these cyclones showed similar tendency in their cutoff diameters, but with strictly different the diameters. As described above, the cut-off diameter, especially small cyclone, measured by APS could be needed to consider carefully about their accuracy. The other two methods also have potential differences such as the density of the used particles and the particle diameter defined based on the measurement method, and uncertainties such as the low resolution for the particle size of the fluorescent particles and the measurement error. Considering them, at least the results of these two approaches are rather consistent, and the results by APS also supported this.


Fig. 5. 
Particle penetrations of the three cyclones measured using the (a) APS, (b) PSL monodisperse particles, and (c) DMA systems. The error bars were calculated according to the changing of particle number during measurement. Small, medium, and large are the small, medium and large cyclones, respectively.

In this study, the values of Dp50 were from 0.17 μm to 0.28 μm for the small cyclone, from 0.34 μm to 0.36 μm for the medium cyclone and 0.70 μm for the large cyclone. The Dp50 of the small cyclone measured using the APS, PSL, and DMA systems was smaller than that of the medium cyclone.

The aerodynamic diameters of the most hazardous and high DTT active species begin at 0.1 μm in a typical atmosphere (Fang et al., 2017). Moreover, previous studies corresponding to the mass size distribution of aerosol particles showed that particles in PM2.5 were mainly distributed with the main peak in 0.3-1.8 μm (Fang et al., 2017; Voutsa et al., 2015; Xue et al., 2014; Feng et al., 2009; Yao et al., 2002). In addition, the high flow rate allows the collection of large amounts of PM2.5 samples in a short period. Thus, we chose small and large cyclones based on Dp50 and the flow rate to collect the powder samples of PM2.5 to compare the effects of their separation performance on the particle toxicity.

3. 2 Comparison of the Chemical Composition of the Particles Collected by Small and Large Cyclones

In Fig. 6, water-soluble ionic components in atmospheric particulates are compared to differentiate the separation characteristics between the large and small cyclones. Fig. 6a shows that the abundance of total ions in the small cyclone samples was higher (1.2-3.2 times) than in the large cyclone samples. The mean quantity of total ions in PM2.5 for all periods was 257,670 part per million weight (ppmw) for the small cyclone and 123,800 ppmw for the large cyclone. Comparing the composition of total water-soluble ions, SO42- and NH4+ exhibited significantly higher mass portions in the small cyclone samples than in the large ones, whereas Cl- and Ca2+ were found to have higher mass portions in the large cyclone samples than in the small ones during all sampling periods. The decrease of NO3- in the cold period and the increase of SO42- in the warm period occurred. This tendency was observed mainly in the small cyclone samples (Fig. 6a and 6b). In the samples of both cyclones, sulfate, nitrate, and ammonium were the most abundant ions studied; they accounted for 73.9-93.1% of the total ions for the small cyclone and 59.6-72.7% of the total for the large cyclone.


Fig. 6. 
Ion chromatography analysis of the ambient aerosol samples collected using the small and large cyclones from 2 April 2020 to 14 April 2021. The abundance of total ions in the PM2.5 (a) and the percentage variations of ions in total water-soluble ion components of the PM2.5 (b) are shown.

Ion chromatography analysis of atmospheric particulates collected using the small and large cyclones for oneyear sampling periods showed that the major components of total water-soluble ions in the small cyclone samples were primarily comprised of SO42- during the warm period (2 April 2020 to 14 October 2020), and SO42- and NO3- during the cold period (12 November 2020 to 14 April 2021) (Fig. 6). In the small cyclone samples, NO3- showed winter maxima, but SO42- was highest in summer, consistent with other studies conducted with ordinary filter samplings (Okuda et al., 2018; Song et al., 2006). Seasonal variations of SO42- and NO3- were observed, especially in the small cyclone samples. It has been reported that fine particles in the air are enriched with secondary aerosols formed from the oxidation of SO2 and NOx and neutralization of NH3 under certain meteorological conditions, and in particular, ammonium sulfate tends to be generated in summer (warm season), whereas, nitrates tend to enrich in particular phase due to gas/particle partitioning depends on ambient temperature (Segalin et al., 2020; Okuda et al., 2018; Song et al., 2006; Yao et al., 2003). The major ions in the large cyclone samples comprised almost similar SO42- and NO3- levels in both periods. The abundance of Cl- and Ca2+ was more elevated than that in the small cyclone samples. This study showed that the small cyclone for smaller particles (e.g., secondary SO42-, NO3-, NH4+) had higher collection efficiency than the large cyclone.

3. 3 Detailed Comparison of the Particles Collected by the Large and Small Cyclones

Fig. 7 shows the elemental analysis results of the PM2.5 samples collected using the small and large cyclones. The transition metals, such as Ti, V, Cr, Mn, Fe, Cu, Zn, Ni, and Pb, were compared. We have excluded Al data from further discussion due to possible contamination because the small cyclone was made of aluminum. The total metal abundance in the PM2.5 collected from 10 December 2020 to 6 January 2021 and 10 March to 14 April 2021 was 6,504 and 18,516 ppmw for the small cyclone and 46,002 and 21,704 ppmw for the large cyclone, respectively. Fig. 7 is presented without Fe data because the difference between the metal components was somewhat invisible due to the high content of Fe compared with other metals in the samples of both cyclones. The abundance of Fe (out of nine metal components in total) collected from 10 December 2020 to 6 January 2021 and 10 March to 14 April 2021 was 59.1% and 72.9% for the small cyclone and 84.8% and 83.4% for the large cyclone, respectively. V, Cr, Ni, and Pb were determined to be less than 1% of the sum of the total metal components for both cyclones. Cu and V exhibited a higher mass portion in the small cyclone samples than in the large cyclone samples, whereas Fe and Ti were higher in the large cyclone samples than in the small cyclone samples for both periods. The abundance of Cr, Zn, Mn, Ni, and Pb in the small and large cyclone samples varied for the sampling periods.


Fig. 7. 
Percentage variations of elements in total elemental components (except Fe) of the PM2.5 collected using the small and large cyclones.

Table 2 shows the crustal enrichment factors (EFs) (vs. Ti) of the samples collected using the small and large cyclones. The EF values of all elements (except Fe in samples collected from 10 December 2020 to 6 January 2021) were higher in the small cyclone samples than in the large cyclone ones; in particular, a significant difference was observed for V, Cr, Cu, Zn, and Pb. This suggests that the small cyclone samples had crustal elements that are much smaller than those in the large cyclone samples. The higher EF values exist in much smaller particles, indicating that they originated from more anthropogenic sources (Obiajunwa et al., 2002).

Table 2. 
Enrichment factors for the analyzed trace elements in PM2.5 collected using the small and large cyclones.
Sampling period Cyclone V Cr Mn Fe Ni Cu Zn Pb Ti
2020/12/10-2021/1/6 Small 13.2 48.5 2.9 1.2 7.0 383.9 63.6 27.6 1.00
Large 1.3 9.2 1.7 1.3 5.9 15.9 47.3 15.7 1.00
2021/3/10-20214/14 Small 5.2 39.5 6.5 2.1 9.5 133.9 187.5 177.5 1.00
Large 1.3 3.3 2.2 1.3 2.8 18.3 55.9 28.8 1.00

A comparison of the chemical compositions of PM2.5 showed that the metals (e.g., V, Cr, Mn, Ni, Cu, Zn, Pb) exhibited a higher mass portion in the small cyclone samples than in the large ones, which were formed primarily from anthropogenic sources (Chen et al., 2010; Okuda et al., 2007; Song et al., 2006). EF values also showed that these elements contained more anthropogenic sources than soil. Moreover, SO42-, NO3-, and NH4+ ions with higher abundance were in the small cyclone samples, which originated from oxidation and neutralization under certain meteorological conditions in the form of secondary aerosols (Segalin et al., 2020; Song et al., 2006; Yao et al., 2003). The metals that exhibited higher content in the large cyclone samples than that of the small cyclones were light (e.g., Mg2+ and Ca2+) and crustal elements (e.g., Ti and Fe) (Hieu and Lee, 2010). This can be seen in the calculation of EFs (Table 2). The particles in the large cyclone samples contained coarse and more crustal sources than anthropogenic sources. In contrast, the particles in the small cyclone samples comprised smaller and more anthropogenic sources than crustal sources.

3. 3. 1 DTT Assay

The results of the redox activity of the PM2.5 samples collected using the small and large cyclones are summarized in Fig. 8. The DTT loss rates were 0.21 and 0.96 μM/mg/min for the small cyclone samples, and 0.82 and 0.62 μM/mg/min for the large cyclone samples collected from 10 December 2020 to 6 January 2021 and 10 March 2021 to 14 April 2021, respectively.


Fig. 8. 
DTT oxidizing ability of samples collected using the small and large cyclones (n=3).

In this study, the DTT loss rate of the samples collected using small and large cyclones differed in the sampling periods, consistent with other studies (Fang et al., 2017; Fujitani et al., 2017). Fujitani et al. (2017) found that transition metals in the sample were a significant contributor to DTT consumption (more than 80%). In our study, the difference in the DTT oxidization ability is likely associated with the difference between transition metal concentrations (e.g., Cu, Mn, Ni, Fe, Zn, Pb) in the samples.

3. 3. 2 Endotoxin Analysis

Fig. 9 shows the endotoxin concentrations in the samples collected using the small and large cyclones. The endotoxin content of the particles was 129.58 EU/mg and 60.49 EU/mg in the large cyclone samples collected from 10 December 2020 to 6 January 2021 and 10 March to 14 April 2021, respectively. Endotoxins were not detected in the small cyclone samples.


Fig. 9. 
Concentration of endotoxin in PM2.5 collected using the small and large cyclones (n=3).

The endotoxin level in the large cyclone samples was detected significantly high compared to that in the small cyclone samples. This is consistent with other studies (Khan et al., 2018; Schins et al., 2004). Khan et al. (2018) found that concentrations of endotoxin in coarse particles were significantly higher than those in fine particles in Japan. In this study, the abundance of smaller particles in the samples of the small cyclone was higher than in the samples of the large cyclone. This indicates that the distribution of small particles significantly decreased the endotoxin levels in the small cyclone samples.

3. 3. 3 PM2.5 Cytotoxicity in A549 and Macrophage-Like THP-1 Cells

Fig. 10 shows the cytotoxic effects of PM2.5 collected using large and small cyclones evaluated with A549 cells in MEM. The results show the ratio of the metabolic activity of exposed cells to the metabolic activity of unseeded cells. The highest toxicity of the large cyclone samples was greater than in the small cyclone samples, except for the samples collected from 10 March to 14 April 2021 at 75 μg/mL and 150 μg/mL of PM2.5 concentrations. The difference between the small and large cyclone samples was insignificant (p<0.1) at 7.5 μg/mL, significant (p<0.05) at 75 μg/mL and highly significant (p<0.01) at 150 μg/mL.


Fig. 10. 
PM2.5 concentration-dependent cell-manner viability for A549 cells (*p<0.05, **p<0.01 imply that the difference between the small and large cyclone samples was significant, n=3). The samples were collected (a) from 10 December 2020 to 6 January 2021 and (b) from 10 March to 14 April 2021.

Fig. 11 shows the estimated levels of cytokines using the IL-6 release measurement for macrophage-like cells in the collected PM2.5. The value of the control shows IL-6 levels in the blank medium used in the experiments. The level of IL-6 released after exposure to the samples collected using the large cyclone was markedly higher than that observed after exposure to the samples collected using the small cyclone.


Fig. 11. 
PM2.5 concentration-dependent manners in cytokines estimated using IL-6 release measurement for macrophage-like cells (*p<0.05 imply that the difference between the small and large cyclone samples was significant, n=3). The samples were collected (a) from 10 December 2020 to 6 January 2021 and (b) from 10 March to 14 April 2021.

An in vitro toxicity assay of PM2.5 collected using the small and large cyclones was conducted on lung epithelial A549 cells. The A549 cell viability after exposure to the PM2.5 collected from both cyclones decreased corresponding with the DTT loss rate, consistent with previous studies (Zou et al., 2016; Cao et al., 2015), which found that smaller particles can enter cells or induce ROS production and damage cells.

To evaluate whether the PM2.5 collected using small and large cyclones had proinflammatory effects on macrophage-like THP-1 cells, the production of IL-6 was examined. The cytokine level estimated using IL-6 release measurement was higher in the large cyclone samples than in the small ones, which is supported by other studies (Gorbet and Sefton, 2005; Huang et al., 2004; Schins et al., 2004). Schins et al. (2004) found that the cytokine levels were higher in coarse particles than in fine ones due more to their biological components (e.g., endotoxin) than metal content. Gorbet and Sefton (2005) reported that Gram-negative bacteria cause an inflammatory response to local infection by stimulating the synthesis of inflammatory mediators (e.g., IL-6). Zou et al. (2016) showed that the proapoptotic effects of particles are unrelated to their proinflammatory properties, and water-soluble ions and individual soluble metals (V, Ni, Fe) were relatively inactive for apoptosis and inflammation in macrophages.

The chemical composition analyses of PM2.5 collected using the small and large cyclones showed that the small cyclone samples had higher concentrations of water-soluble ions and transition metals, except for Fe and Ti, than the larger cyclone samples. The comparison of the samples collected using large and small cyclones significantly reflected the significant toxicity of the particles. ROS generation was associated with transition metals and they decreased the viability of the human lung epithelial A549 cells. The endotoxin concentration was detected only in the large cyclone samples and significantly affected the level of cytokines estimated using the IL-6 release measurement.

4. CONCLUSIONS

In this study, we investigated the effect of cyclone size on particle size, chemical composition analysis and toxicity assays (DTT, LAL, cell-level) of PM2.5. Three cyclones with different inner diameters (12 mm for small, 20 mm for medium and 68 mm for large cyclones) were tested using the APS, PSL, and DMA systems. The toxicity of the particles was evaluated using by comparing the results of chemical composition analysis, DTT, and LAL, and cell exposure assays.

The experimental values of Dp50 measured using the APS, PSL, and DMA systems were from 0.17 μm to 0.28 μm for the small cyclone, 0.34 μm to 0.36 μm for the medium cyclone, and 0.70 μm for the large cyclone. To compare their separation performances, small and large cyclones were chosen based on Dp50 and the flow rate to collect PM2.5.

A comparison of the chemical compositions of PM2.5 showed that the metals (e.g., V, Cr, Mn, Ni, Cu, Zn, Pb) exhibited a higher mass portion in the small cyclone samples than in the large ones. Moreover, SO42-, NO3-, and NH4+ ions with higher abundance were in the small cyclone samples. The metals that determined a higher content in the large cyclone samples than in the small ones were light (e.g., Mg2+ and Ca2+) and crustal elements (e.g., Ti and Fe). A comparison of the chemical composition and EF values showed that the particles in the small cyclone samples contained smaller and anthropogenic sources than those in the large cyclone samples.

The DTT loss rate of the samples collected using the small and large cyclones became different across the sampling periods, which were associated with the transition metals. Endotoxin contents were detected only in the large cyclone samples. The viability of A549 cells after exposure to the small and large cyclone samples was different across the cyclone samples and sampling periods associated with ROS generation determined in the DTT assay. IL-6 release was higher in the large cyclone samples than in the small cyclone samples, consistent with the endotoxin concentrations measured in the LAL assay.

The cyclone technique used in this study to collect aerosol particles would be a powerful tool for a detailed evaluation of particle toxicity.

Acknowledgments

Part of this research was supported by JST CREST (JPMJCR19H3), the Environmental Research and Technology Development Fund of the Environmental Restoration and Conservation Agency (ERCA) (JPMEERF20165051 and JPMEERF20205007), JSPS KAKENHI Grant Numbers JP17H04480, JP18K19856, JP20H00636, JP20K20614, the Keio Leading-edge Laboratory Science and Technology Specified Research Projects, Tokyo Dylec Corp., and Steel Foundation for Environmental Protection Technology. The research and studying of Alimov Z.B. in the Ph.D. program at Keio University were supported by Japan International Cooperation Agency (JICA) and Uzbek-Japan Innovation Center of Youth (UJICY). The authors would like to thank the Seikan Kensa Center Inc., to achieve the ICP-MS analysis.

References
1. Anderson, J.O., Thundiyil, J.G., Stolbach, A. (2012) Clearing the air: a review of the effects of particulate matter air pollution on human health. Journal of Medical Toxicology, 8(2), 166-175.
2. Cao, L., Zeng, J., Liu, K., Bao, L., Li, Y. (2015) Characterization and Cytotoxicity of PM<0.2, PM0.2-2.5 and PM2.5-10 around MSWI in Shanghai, China. International Journal of Environmental Research and Public Health, 12(5), 5076-5089.
3. Carty, C.L., Gehring, U., Cyrys, J., Bischof, W., Heinrich, J. (2003) Seasonal variability of endotoxin in ambient fine particulate matter. Journal of Environmental Monitoring, 5(6), 953-958.
4. Chester, R., Stoner, J.H. (1973) Pb in particulates from the lower atmosphere of the eastern Atlantic. Nature, 245, 27-28.
5. Charrier, J.G., Anastasio, C. (2012) On dithiothreitol (DTT) as a measure of oxidative potential for ambient particles: evidence for the importance of soluble transition metals. Atmospheric Chemistry and Physics, 12(5), 11317-11350.
6. Chen, C.C., Lai, C.Y., Shih, T.S., Hwang, J.S. (1999). Laboratory performance comparison of respirable samplers. American Industrial Hygiene Association Journal, 60(5), 601-611.
7. Chen, X., Xia, X., Zhao, Y., Zhang, P. (2010) Heavy metal concentrations in roadside soils and correlation with urban traffic in Beijing, China. Journal of Hazardous Materials, 181(1-3), 640-646.
8. Chowdhury, P.H., Honda, A., Ito, S., Okano, H., Onishi, T., Higashihara, M., Okuda, T., Tanaka, T., Hirai, S., Takano, H. (2019) Effects of ambient PM2.5 collected from Asian cities using cyclone technique on human airway epithelial cells. Aerosol and Air Quality Research, 19(8), 1808-1819.
9. Chowdhury, P.H., Okano, H., Honda, A., Kudou, H., Kitamura, G., Ito, S., Ueda, K., Takano, H. (2018) Aqueous and organic extract of PM2.5 collected in different seasons and cities of Japan differently affect respiratory and immune systems. Environmental Pollution, 235, 223-234.
10. Cooper, C.D. and Forrest, Ch.A. (2010) Air pollution control: A design approach. 4rh ed., Waveland press, USA, pp. 135-152.
11. De Kok, T.M., Driece, H.A., Hogervorst, J.G., Briedé, J.J. (2006) Toxicological assessment of ambient and traffic-related particulate matter: a review of recent studies. Mutation Research/Reviews in Mutation Research, 613(2-3), 103-122.
12. Delfino, R.J., Staimer, N., Tjoa, T. (2011) Personal endotoxin exposure in a panel study of school children with asthma. Environmental Health, 10(1), 1-14.
13. Diaz, E.A., Lemos, M., Coull, B., Long, M.S., Rohr, A.C., Ruiz, P., Gupta, T., Kang, C.M., Godleski, J.J. (2011) Toxicological evaluation of realistic emission source aerosols (TERESA)—power plant studies: assessment of breathing pattern. Inhalation Toxicology, 23, 42-59.
14. Du, P., Liu, J., Gui, H., Zhang, J., Yu, T., Wang, J., Cheng, Y., Lu, Y., Yao, Y., Fu, Q., Chen, C. (2020) Development of a static test apparatus for evaluating the performance of three PM2.5 separators commonly used in China. Journal of Environmental Sciences, 87, 238-249.
15. Fang, T., Verma, V., Bates, J.T., Abrams, J., Klein, M., Strickland, M.J., Sarnat, S.E., Chang, H.H., Mulholland, J.A., Tolbert, P.E., Russell, A.G., Weber, R.J. (2016) Oxidative potential of ambient water-soluble PM2.5 in the southeastern United States: contrasts in sources and health associations between ascorbic acid (AA) and dithiothreitol (DTT) assays. Atmospheric Chemistry and Physics, 16, 3865-3879.
16. Fang, T., Zeng, L., Gao, D., Verma, V., Stefaniak, A.B., Weber, R.J. (2017) Ambient size distributions and lung deposition of aerosol dithiothreitol-measured oxidative potential: contrast between soluble and insoluble particles. Environmental Science & Technology, 51, 6802-6811.
17. Faraji, M., Nodehi, R.N., Naddafi, K., Pourpak, Z., Alizadeh, Z., Rezaei, S., Mesdaghinia, A. (2018) Cytotoxicity of airborne particulate matter (PM10) from dust storm and inversion conditions assessed by MTT assay. Journal of Air Pollution and Health, 3(3), 135-142. https://www.researchgate.net/publication/328451231.
18. Feng, X., Dang, Z., Huang, W., Shao, L., Li, W. (2009) Microscopic morphology and size distribution of particles in PM2.5 of Guangzhou City. Journal of Atmospheric Chemistry, 64(1), 37-51.
19. Fujitani, Y., Furuyama, A., Tanabe, K., Hirano, S. (2017) Comparison of oxidative abilities of PM2.5 collected at traffic and residential sites in Japan. Contribution of transition metals and primary and secondary aerosols. Aerosol and Air Quality Research, 17(2), 574-587.
20. Gao, D., Mulholland, J.A., Russell, A.G., Weber, R.J. (2020) Characterization of water-insoluble oxidative potential of PM2.5 using the dithiothreitol assay. Atmospheric Environment, 224, 117327.
21. Godleski, J.J., Rohr, A.C., Coull, B.A., Kang, C.M., Diaz, E.A., Koutrakis, P. (2011) Toxicological evaluation of realistic emission source aerosols (TERESA): summary and conclusions. Inhalation Toxicology, 23(sup2), 95-103.
22. Gorbet, M.B., Sefton, M.V. (2005) Endotoxin: the uninvited guest. Biomaterials, 26(34), 6811-6817.
23. Grahame, T.J., Schlesinger, R.B. (2010) Cardiovascular health and particulate vehicular emissions: a critical evaluation of the evidence. Air Quality, Atmosphere & Health, 3(1), 3-27.
24. Gussman, R.A., Kenny, L.C., Labickas, M., Norton, P. (2002) Design, calibration, and field test of a cyclone for PM1 ambient air sampling. Aerosol Science & Technology, 36(3), 361-365.
25. Harkema, J.R., Keeler, G., Wagner, J., Morishita, M., Timm, E., Hotchkiss, J., Marsik, F., Dvonch, T., Kaminski, N., Barr, E. (2004) Effects of concentrated ambient particles on normal and hyper-secretory airways in rats. Research Report (Health Effects Institute), 120, 1-68.
26. Hasegawa, S. (2016) Influence of positive artifact in PM2.5 carbonaceous measurement. Journal of Japan Society for Atmospheric Environment, 51(1), 58-63 (in Japanese).
27. Heinrich, J., Pitz, M., Bischof, W., Krug, N., Borm, P.J. (2003) Endotoxin in fine (PM2.5) and coarse (PM2.5-10) particle mass of ambient aerosols, A temporo-spatial analysis. Atmospheric Environment, 37(26), 3659-3667.
28. Hieu, N.T., Lee, B.K. (2010) Characteristics of particulate matter and metals in the ambient air from a residential area in the largest industrial city in Korea. Atmospheric Research, 98(2-4), 526-537.
29. Hiraiwa, K., van Eeden, S.F. (2013) Contribution of lung macrophages to the inflammatory responses induced by exposure to air pollutants. Mediators of Inflammation, 2013, 619523.
30. Honda, A., Fukushima, W., Oishi, M., Tsuji, K., Sawahara, T., Hayashi, T., Kudo, H., Kashima, Y., Takahashi, K., Sasaki, H., Ueda, K. (2017) Effects of components of PM2.5 collected in Japan on the respiratory and immune systems. International Journal of Toxicology, 36(2), 153-164.
31. Honda, A., Okuda, T., Nagao, M., Miyasaka, N., Tanaka, M., Takano, H. (2021) PM2.5 collected using cyclonic separation causes stronger biological responses than that collected using a conventional filtration method. Environmental Research, 198, 110490.
32. Huang, Y.T., Li, Z., Harder, S.D., Soukup, J.M. (2004) Apoptotic and inflammatory effects induced by different particles in human alveolar macrophages. Inhalation Toxicology, 16(14), 863-878.
33. Jia, Y.Y., Wang, Q., Liu, T. (2017) Toxicity research of PM2.5 compositions in vitro. International Journal of Environmental Research and Public Health, 14(3), 232.
34. Jing, W., Saito, K., Okamoto, T., Saito, H., Sugimoto, K., Nishita-Hara, C., Hara, K., Hayashi, M., Hasegawa, S., Okuda, T. (2022) Characterization of elemental composition and valence state of cyclone-collected aerosol particles using EDXRF and XAFS at three sites in Japan. Asian Journal of Atmospheric Environment, 16(2), 2021137.
35. Kameda, T., Akiyama, A., Toriba, A., Tang, N., Hayakawa, K. (2010) Determination of particle-associated hydroxy-nitropyrenes with correction for chemical degradation on a quartz fibre filter during high volume air sampling. International Journal of Environmental Analytical Chemistry, 90(13), 976-987.
36. Khan, M.S., Coulibaly, S., Matsumoto, T., Yano, Y., Miura, M., Nagasaka, Y., Shima, M., Yamagishi, N., Wakabayashi, K., Watanabe, T. (2018) Association of airborne particles, protein, and endotoxin with emergency department visits for asthma in Kyoto, Japan. Environmental Health and Preventive Medicine, 23(1), 1-9.
37. Ko, R., Hayashi, M., Tanaka, M., Okuda, T., Nishita-Hara, C., Ozaki, H., Uchio, E. (2021) Effects of ambient particulate matter on a reconstructed human corneal epithelial model. Scientific Reports, 11, 3417.
38. Kurihara, K., Iwata, A., Murray Horwitz, S.G., Ogane, K., Sugioka, T., Matsuki, A., Okuda, T. (2022) Contribution of Physical and Chemical Properties to Dithiothreitol-Measured Oxidative Potentials of Atmospheric Aerosol Particles at Urban and Rural Sites in Japan. Atmosphere, 13(2), 319.
39. Lin, C.W., Chen, T.J., Huang, S.H., Kuo, Y.M., Gui, H.Q., Chen, C.C. (2018) Effect of aerosol loading on separation performance of PM2.5 cyclone separators. Aerosol and Air Quality Research, 18(6), 1366-1374.
40. Lin, M., Yu, J.Z. (2019) Dithiothreitol (DTT) concentration effect and its implications on the applicability of DTT assay to evaluate the oxidative potential of atmospheric aerosol samples. Environmental Pollution, 251, 938-944.
41. Lippmann, M. (2014) Toxicological and epidemiological studies of cardiovascular effects of ambient air fine particulate matter (PM2.5) and its chemical components: coherence and public health implications. Critical Reviews in Toxicology, 44(4), 299-347.
42. Loska, K., Cebula, J., Pelczar, J., Wiechuła, D., Kwapuliński, J. (1997) Use of enrichment, and contamination factors together with geoaccumulation indexes to evaluate the content of Cd, Cu, and Ni in the Rybnik water reservoir in Poland. Water, Air, and Soil Pollution, 93(1), 347-365.
43. McCreanor, J., Cullinan, P., Nieuwenhuijsen, M.J., Stewart-Evans, J., Malliarou, E., Jarup, L., Harrington, R., Svartengren, M., Han, I.-K., Ohman-Strickland, P., Chung, K.F., Zhang, J. (2007) Respiratory effects of exposure to diesel traffic in persons with asthma. New England Journal of Medicine, 357(23), 2348-2358.
44. McWhinney, R.D., Badali, K., Liggio, J., Li, S.M., Abbatt, J.P. (2013) Filterable redox cycling activity: a comparison between diesel exhaust particles and secondary organic aerosol constituents. Environmental Science & Technology, 47(7), 3362-3369.
45. Ny, M.T., Lee, B.K. (2010) Size Distribution and Source Identification of Airborne Particulate Matter and Metallic Elements in a Typical Industrial City. Asian Journal of Atmospheric Environment, 4(1), 9-19.
46. Obiajunwa, E.I., Pelemo, D.A., Owolabi, S.A., Fasasi, M.K., Johnson-Fatokun, F.O. (2002) Characterisation of heavy metal pollutants of soils and sediments around a crude-oil production terminal using EDXRF. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 194(1), 61-64.
47. Ogino, K., Nagaoka, K., Ito, T., Takemoto, K., Okuda, T., Nakayama, S., Ogino, N., Seki, Y., Hamada, H., Takashiba, S., Fujikura, Y. (2019) Involvement of PM2.5-bound protein and metals in PM2.5-induced allergic airway inflammation in mice. Inhalation Toxicology, 30(13-14), 498-508.
48. Ogino, K., Nagaoka, K., Okuda, T., Oka, A., Kubo, M., Eguchi, E., Fujikura, Y. (2017) PM2.5 induced airway inflammation and hyperresponsiveness in NC/Nga mice. Environmental Toxicology, 32(3), 1047-1054.
49. Okuda, T., Isobe, R. (2017) Improvement of a high-volume aerosol particle sampler for collecting submicron particles through the combined use of a cyclone with a smoothened inner wall and a circular cone attachment. Asian Journal of Atmospheric Environment, 11(2), 131-137.
50. Okuda, T., Isobe, R., Nagai, Y., Okahisa, S., Funato, K., Inoue, K. (2015) Development of a high-volume PM2.5 particle sampler using impactor and cyclone techniques. Aerosol and Air Quality Research, 15(3), 59-767.
51. Okuda, T., Nakao, S., Katsuno, M., Tanaka, S. (2007) Source identification of nickel in TSP and PM2.5 in Tokyo, Japan. Atmospheric Environment, 41(35), 7642-7648.
52. Okuda, T., Shishido, D., Terui, Y., Fujioka, K., Isobe, R., Iwaki, Y., Funato, K., Inoue, K. (2018) Development of a High-Volume Simultaneous Sampler for Fine and Coarse Particles using Virtual Impactor and Cyclone Techniques. Asian Journal of Atmospheric Environment, 12(1), 78-86.
53. Onishi, T., Honda, A., Tanaka, M., Chowdhury, P.H., Okano, H., Okuda, T., Shishido, D., Terui, Y., Hasegawa, S., Kameda, T., Tohno, S., Hayashi, M., Nishita-Hara, C., Hara, K., Inoue, K., Yasuda, M., Hirano, S., Takano, H. (2018) Ambient fine and coarse particles in Japan affect nasal and bronchial epithelial cells differently and elicit varying immune response. Environmental Pollution Part B, 242, 1693-1701.
54. Pan, C.-J.G., Schmitz, D.A., Cho, A.K., Froines, J., Fukuto, J.M. (2004) Inherent redox properties of diesel exhaust particles: catalysis of the generation of reactive oxygen species by biological reductants. Toxicological Sciences, 81(1), 225-232.
55. Patel, A., Rastogi, N. (2021) Oxidative Potential of Ambient PM and Related Health Endpoints over South Asia: A Review. Asian Journal of Atmospheric Environment, 15(1), 2020123.
56. Peters, T.M., Gussman, R.A., Kenny, L.C., Vanderpool, R.W. (2001) Evaluation of PM2.5 size selectors used in speciation samplers. Aerosol Science & Technology, 34(5), 422-429.
57. Peters, T.M., Leith, D. (2003) Concentration measurement and counting efficiency of the aerodynamic particle sizer 3321. Journal of Aerosol Science, 34(5), 627-634.
58. Piehler, M., Roeder, R., Blessing, S., Reich, J. (2020) Comparison of LAL and rFC Assays—Participation in a Proficiency Test Program between 2014 and 2019. Microorganisms, 8(3), 418.
59. Pope, C.A., Burnett, R.T., Thurston, G.D., Thun, M.J., Calle, E.E., Krewski, D., Godleski, J.J. (2004) Cardiovascular mortality and long-term exposure to particulate air pollution: epidemiological evidence of general patho-physiological pathways of disease. Circulation, 109, 71-77.
60. Reed, C.E., Milton, D.K. (2001) Endotoxin-stimulated innate immunity: a contributing factor for asthma. Journal of Allergy and Clinical Immunology, 108(2), 157-166.
61. Roper, C., Chubb, L.G., Cambal, L., Tunno, B., Clougherty, J.E., Mischler, S.E. (2015) Characterization of ambient and extracted PM2.5 collected on filters for toxicology applications. Inhalation Toxicology, 27(13), 673-681.
62. Roper, C., Delgado, L.S., Barrett, D., Massey Simonich, S.L., Tanguay, R.L. (2018) PM2.5 filter extraction methods: implications for chemical and toxicological analyses. Environmental Science & Technology, 53(1), 434-442.
63. Rule, A.M., Geyh, A.S., Ramos-Bonilla, J.P., Mihalic, J.N., Margulies, J.D., Polyak, L.M., Kesavan, J., Breysse, P.N. (2010) Design and characterization of a sequential cyclone system for the collection of bulk particulate matter. Journal of Environmental Monitoring, 12, 1807-1814.
64. Sagawa, T., Tsujikawa, T., Honda, A., Miyasaka, N., Tanaka, M., Kida, T., Hasegawa, K., Okuda, T., Kawahito, Y., Takano, H. (2021) Exposure to particulate matter upregulates ACE2 and TMPRSS2 expression in the murine lung. Environmental Research, 195, 110722.
65. Schins, R.P.F., Lightbody, J.H., Borm, P.J.A., Shi, T., Donaldson, K., Stone, V. (2004) Inflammatory effects of coarse and fine particulate matter in relation to chemical and biological constituents. Toxicology and Applied Pharmacology, 195(1), 1-11.
66. Segalin, B., Fornaro, A., Kumar, P., Klemm, O., Andrade, M.F., Trezza, B.M., Busse, A., Filho, W.J., Gonçalves, F.L. (2020) Chemical Composition of Quasi-ultrafine Particles and their Sources in Elderly Residences of São Paulo Megacity. Aerosol Air Quality Research, 20(5), 1100-1015.
67. Shen, Z., Arimoto, R., Cao, J., Zhang, R., Li, X., Du, N., Okuda, T., Nakao, S., Tanaka, S. (2008) Seasonal variations and evidence for the effectiveness of pollution controls on water-soluble inorganic species in total suspended particulates and fine particulate matter from Xi’an, China. Journal of the Air & Waste Management Association, 58(12), 1560-1570.
68. Song, Y., Xie, S., Zhang, Y., Zeng, L., Salmon, L.G., Zheng, M. (2006) Source apportionment of PM2.5 in Beijing using principal component analysis/absolute principal component scores and UNMIX. Science of the Total Environment, 372(1), 278-286.
69. Starr, T., Bauler, T.J., Malik-Kale, P., Steele-Mortimer, O. (2018) The phorbol 12-myristate-13-acetate differentiation protocol is critical to the interaction of THP-1 macrophages with Salmonella Typhimurium. PLoS One, 13(3), e0193601.
70. Tanaka, T., Narazaki, M., Kishimoto, T. (2014) IL-6 in inflammation, immunity, and disease. Cold Spring Harbor Perspectives in Biology, 6(10), a016295.
71. Taylor, S. (1964) Abundance of chemical elements in the continental crust: a new table. Geochimica et Cosmochimica Acta, 28(8), 1273-1285.
72. Van Winkle, L.S., Bein, K., Anderson, D., Pinkerton, K.E., Tablin, F., Wilson, D., Wexler, A.S. (2015) Biological dose response to PM2.5: effect of particle extraction method on platelet and lung responses. Toxicological Sciences, 143(2), 349-359.
73. Vanderpool, R.W., Peters, T.M., Natarajan, S., Gemmill, D.B., Wiener, R.W. (2001) Evaluation of the loading characteristics of the EPA WINS PM2.5 separator. Aerosol Science & Technology, 34(5), 444-456.
74. Volckens, J., Peters, T.M. (2005) Counting and particle transmission efficiency of the aerodynamic particle sizer. Journal of Aerosol Science, 36(12), 1400-1408.
75. Voutsa, D., Anthemidis, A., Giakisikli, G., Mitani, K., Besis, A., Tsolakidou, A., Samara, C. (2015) Size distribution of total and water-soluble fractions of particle-bound elements–assessment of possible risks via inhalation. Environmental Science and Pollution Research, 22(17), 13412-13426.
76. Vuong, N.Q., Breznan, D., Goegan, P., O’Brien, J.S., Williams, A., Karthikeyan, S., Kumarathasan, P., Vincent, R. (2017) In vitro toxicoproteomic analysis of A549 human lung epithelial cells exposed to urban air particulate matter and its water-soluble and insoluble fractions. Particle and Fiber Toxicology, 14(1), 39.
77. Wang, J., Lin, X., Lu, L., Wu, Y., Zhang, H., Lv, Q., Liu, W., Zhang, Y., Zhuang, S. (2019) Temporal variation of oxidative potential of water soluble components of ambient PM2.5 measured by dithiothreitol (DTT) assay. Science of the Total Environment, 649, 969-978.
78. Wang, L.K., Pereira, N.C. and Hung, Y.T. (2004) Air pollution control engineering. Humana Press: Totowa, New Jersey, USA, v. 1, pp. 97-147.
79. Xue, J., Yuan, Z., Lau, A.K., Yu, J.Z. (2014) Insights into factors affecting nitrate in PM2.5 in a polluted high NOx environment through hourly observations and size distribution measurements. Journal of Geophysical Research: Atmospheres, 119(8), 4888-4902.
80. Yang, A., Jedynska, A., Hellack, B., Kooter, I., Hoek, G., Brunekreef, B., Kuhlbusch, T.A.J., Cassee, F.R., Janssen, N.A.H. (2014) Measurement of the oxidative potential of PM2.5 and its constituents: The effect of extraction solvent and filter type. Atmospheric Environment, 83, 35-42.
81. Yao, X., Chan, C.K., Fang, M., Cadle, S., Chan, T., Mulawa, P., He, K., Ye, B. (2002) The water-soluble ionic composition of PM2.5 in Shanghai and Beijing, China. Atmospheric Environment, 36(26), 4223-4234.
82. Yao, X., Lau, A.P.S., Fang, M., Chan, C.K., Hu, M. (2003) Size distributions and formation of ionic species in atmospheric particulate pollutants in Beijing, China: 1-Inorganic ions. Atmospheric Environment, 37(21), 2991-3000.
83. Youn, J.S., Han, S., Yi, J.S., Kang, D.I., Jang, K.W., Jung, Y.W., Park, Y.K., Jeon, K.J. (2021) Development of PM10 and PM2.5 cyclones for small sampling ports at stationary sources: Numerical and experimental study. Environmental Research, 193, 110507.
84. Zoller, W.H., Gladney, E.S., Duce, R.A. (1974) Atmospheric concentrations and sources of trace metals at the South Pole. Science, 183(4121), 198-200.
85. Zou, Y., Jin, C., Su, Y., Li, J., Zhu, B. (2016) Water soluble and insoluble components of urban PM2.5 and their cytotoxic effects on epithelial cells (A549) in vitro. Environmental Pollution, 212, 627-635.
 
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The Editorial Office : Asian Association for Atmospheric Environment
AJAE (Asian Journal of Atmospheric Environment)
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Submission platform : http://mc03.manuscriptcentral.com/ajae

KOSAE (Korean Society for Atmospheric Environment)
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Tel : +82-2-387-1400, 0242 / FAX : +82-2-387-1881
E-mail : webmaster@kosae.or.kr / Homepage : http://www.kosae.or.kr

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No. 54, Hongnian Village, Haidian District, Beijing, China
Tel : +86-10-82211021
E-mail : cses@chinacses.org / Homepage : http://www.chinacses.org

JSAE (Japan Society for Atmospheric Environment)
358-5, Yamabuki-cho, Shinjuku-ku, Tokyo 162-0801, Japan
Tel : +81-3-6824-9392 / FAX : +81-3-5227-8631
E-mail : jsae-post@bunken.co.jp / Homepage : http://www.jsae-net.org


Copyright ⓒ 2020 Asian Association for Atmospheric Environment


This is an open-access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/), which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.