Abstract
Air pollution, including PM2.5 concentration in Ulaanbaatar (capital of Mongolia) is a serious matter of concern. As the majority of households use coal in large areas of the city, indoor air quality is also posing a serious risk to human health. This study investigated the concentration of polycyclic aromatic compounds (PAHs) in indoor particulate matter (PM2.5) in 10 non-smoker households. Sampling was conducted in winter of 2018, between 27 January and 09 February. Concentrations of PM2.5 in the indoor air of households ranged between 62.8 and 324.8 µg m−3. Total concentration of PAHs also varied in a relatively wide range, between 46.2 and 175.7 ng m−3. Five-ring PAHs represented a considerably high fraction of total PAHs between 25 and 53%, benzo[b]fluoranthene (BbF) and benzo[a]pyrene (BaP) were the two predominant compounds within five-ring PAHs. Significant correlation was found between indoor and outdoor particulate matter levels in wintertime. Considering individual characteristic PAHs, heavier PAHs homologues (4- to 5-ring and 6-ring PAHs) were detected in all households, which suggested the influence of coal combustion and traffic exhaust. Health risk of children attributed to PAHs inhalation was assessed by taking into account the lifetime-average daily dose (LADD) and corresponding lifetime cancer risk. Lifetime average daily dose for children in only one household were slightly higher than health-based guideline level (1.0 × 10−5), defined by WHO, whereas LADD for adults and children of other households were within acceptable limit. The cancer risks from the exposure of children to air pollutants in all households except HH-3 were found high. In the Vibrio fischeri bioluminescence inhibition assay, according to the toxic unit (TU) values of indoor PM2.5 from ten households, all samples were classified as toxic.
Similar content being viewed by others
Explore related subjects
Discover the latest articles, news and stories from top researchers in related subjects.Avoid common mistakes on your manuscript.
Introduction
Air quality in Ulaanbaatar (capital of Mongolia) is a serious matter of concern. Threshold levels are established for 10-μm-diameter (PM10) and 2.5-μm-diameter (PM2.5) particles. Since 2009, PM2.5 has been recorded to be higher than the standard of WHO (WHO, 2021) and Mongolian National Ambient Air Quality Standard (MNS 4585/2007, Mongolian Agency for Standardization and Measurement, 2008) which prescribes 50.0 µg m−3 24-h ambient PM2.5 concentration and 25.0 μg m−3 1-year ambient PM2.5 concentration (Batmunkh et al., 2013). The World Air Quality report listed Ulaanbaatar as having worst air quality in the world (WIAQ, 2020).
According to a World Bank survey (World Bank, 2013), 98% of households use coal in ger areas of Ulaanbaatar (‘ger’ refers to traditional Mongolian yurt; more than 60% of the population of Ulaanbaatar lives in gers in peripheral area called ger area or ger district without primary service). Unprocessed coal is often burned inside poorly ventilated spaces with traditional stoves. Combustion of solid fuels is the main source of elevated levels of PM and polycyclic aromatic hydrocarbons (PAHs) in indoor environments. In a South African study, in winter 24-h average PM4 concentration in a solid fuel burning (SFB) house was about 3–4 times higher than in a non-solid fuel burning (NSFB) house (Adesina et al., 2020). Chinese studies also report that on the average, concentration of fine particles (PM2.5 and PM4) is app. twice in SFB residential homes (Du et al., 2018). Twenty-four-hour personal exposure to PM2.5 was measured in a study of Secrest et al. (2016) involving rural women in Inner Mongolia who typically used biomass fuels for cooking and lignite for heating. The geometric mean PM2.5 exposure was as high as 249 µg m−3.
According to Allen et al. (2013), up to 25% of deaths are caused by PM pollution annually in Ulaanbaatar. Respiratory diseases have been widely reported such as asthma (Po et al., 2011), lung inflammation (Wang et al., 2015), decreased lung immunity (Feng et al., 2016), and resulting bacterial infections (Zhao et al., 2014). Chronic obstructive pulmonary disease (COPD) and lung cancer were associated with women who were exposed during cooking with solid fuels (Barabad et al., 2018). In 2015, more than 430 children under the age of 5 years died in pneumonia in Ulaanbaatar. Children living in a highly polluted district of Ulaanbaatar were found to have app. 40% higher incidence of lung diseases than children living in a rural area (UNICEF, 2018).
In addition to respiratory problems, winter ambient air pollution was found to correlate strongly with spontaneous abortion in a Mongolian study (Enkhmaa et al., 2014) as well as reduced fecundity (Badarch et al., 2021). A meta-analysis revealed that the use of household solid fuel can be significantly associated with an increased risk of hypertension (Li et al., 2020). Neurodevelopmental disorders in Mongolian children have also been reported (Jadambaa et al., 2015).
Indoor PM2.5 levels should deserve more attention, following some indoor pollutant studies such as coal combustion in yurt district during winter time (Lim et al., 2018), determination of indoor PM2.5 concentration in Mongolian traditional yurt (Ahn et al., 2019; Ban et al., 2017), as well as characteristics of lifestyles and living condition (So et al., 2019). Lim et al. (2018) reported that the 24-h average PM2.5 concentration was 203 µg m−3 in yurt with conventional stove, whereas 257 µg m−3 in yurt with improved stove. On the other hand, it is possible that high levels of ambient air pollution have a negative impact on indoor air quality, including PM2.5 concentration (e.g., Bai et al., 2020; Hu et al., 2018; So et al., 2019; Sonomdagva et al., 2017).
Airborne particles bind potentially toxic compounds such as PAHs which are generated by incomplete combustion of fossil fuels, in urban and rural environments the major sources are household heating and transportation (Gelencsér et al., 2007; Nagy & Szabó, 2019; Pandey et al., 2013). An early study revealed that the concentration of PAHs in indoor air samples highly varied with the aerodynamic diameter of the particles, fine particles contained high concentrations of PAH and mutagens (Ando et al., 1996). In a study conducted in Athens during the winter and summer periods of 2003–2004, Valavanidis et al. (2006) also demonstrated that concentration of particulate-bound PAHs was higher in fine particles than in coarse particular matter. Hassanvand et al. (2015) investigated PAH concentrations and profiles in indoor PM10, PM2.5, and PM1 in a retirement home and a school dormitory in Tehran and reported that the total PM-bound PAHs were predominantly found in the PM2.5 fraction.
The US Environmental Protection Agency (EPA) registered 16 priority PAHs that were identified as probable human carcinogens and posing the highest environmental risk (reviewed by Abdel-Shafy & Mansour, 2016). Some PAHs, such as chrysene, benzo[a]anthracene, and benzo[a]pyrene are procarcinogens. Ohura et al. (2005) reported that these carcinogenic PAHs are associated with PM2.5.
People spend on an average as much as 87% of their time in enclosed buildings (Klepeis et al., 2001), which makes public health issue in the built environment a top priority (Sojobi & Liew, 2022; Sojobi & Zayed, 2022). They are often ignorant that they can be constantly exposed to air pollution, especially in cold regions (Leech et al., 2002). As Mongolia is located at high latitude, having dry and cold continental climate, people spend quite little time outside in winter as they prefer warm places, similarly to inhabitants of other cold countries. Naturally, during this time, fuel usage increases significantly.
In order to characterize the ecotoxicity of particle-bound potentially toxic compounds, the bioassay based on the bioluminescence inhibition of the marine bacterium Vibrio fischeri has been widely used (reviewed by Kováts & Horváth, 2016). Most studies, however, discuss only outdoor pollution, much less works have addressed indoor ecotoxicity (e.g. Alves et al., 2021).
Taking into consideration that practically no data exist on health risk of indoor air pollution from Mongolia, our study was targeted to assess indoor air quality (PM2.5 concentration, PAH distribution pattern, and resulting ecotoxicity as well as cancer risk estimation) in 10 households located in the region around the Khan-Uul (one of the districts in Ulaanbaatar capital). Contrary to exceptionally polluted districts, the sample area can be regarded as average regarding ambient air quality (Sonomdagva et al., 2017). Figure 1 shows the flowchart of the steps completed within the study.
Materials and methods
Sampling site
The criteria of selected households for our study were as follows: 60% of Mongolians live in the ger area (Guttikunda et al., 2013), app. half of the dwellings in the ger area are made of brick or clay, typically constructed by the owner of each house. We wanted to represent both types, as well as different size of households and different ages of the dwellings. On the other hand, similarities were location relatively close to the main road; heating type (usage of conventional stoves and coal in each household); and only non-smokers lived in the selected families. Naturally, consent of the families was also an important factor. Ten households were selected in Khan-Uul district, Ulaanbaatar (hereinafter named HH-1 to HH-10). Households (HH-8, HH-9, and HH-10) were located app. 500 m from main road, whereas HH-2, HH-4, HH-5, and HH-7 were app. 200 m. Other three households were located between 50 m and 1 km from main road (HH-1—50 m, HH-3—300 m, and HH-6—1 km). A map of the sampling locations is shown in Fig. 2.
In addition, basic characteristics of sample sites (households) are given in Table 1 which were used to identify the factors that might affect indoor air quality.
Fine indoor particulate matter (PM2.5) samples were collected on Teflon filter between 27 January and 09 February 2018 using AirChek XR5000 (SKC Ltd.). The flow rate for sampling was 1.5–2.0 L min−1 for 24 h, the instrument was placed at 1 to 1.5 m above ground level to simulate breathing zone.
Indoor PM2.5 samples were stored in labeled plastic cassette in a cooler box filled with dry ice and transported to the laboratory at the Department of Public Health, Mongolian National University of Medical Sciences. After gravimetric measurement of PM2.5 mass, samples were kept in the freezer at – 20 °C before being transported for further processing to the Centre of Natural Sciences, University of Pannonia, Hungary.
Analytical measurements
Polycyclic aromatic hydrocarbon (PAH) concentrations were measured by gas chromatographic mass spectrometry (Agilent 6890GC 5973E MSD GC–MS according to MSZ (Hungarian Standard) 1484–6:2003). One half of the filters was extracted with 20 ml n-hexane three times for 20 min in a sonication bath. Prior to extraction, 10 ml acetone was added and the samples were spiked with 100 µl of 0.01 µg ml−1 deuterated PAHs surrogate mixture containing Naphtalene-d8, Acenaphtalene-d10, Phenanthrene-d10, Chrysene-d12, Benzo(a)pyrene-d12, and Perylene-d12 (Resteck Corporation, USA). Extracts were concentrated in a dry nitrogen stream to a volume of 1 ml; the clean-up of each sample was completed via alumina oxide and solid phase silica gel. For GC–MS measurements, an HP-6890 gas chromatograph was coupled to an HP-5973 quadrupled mass spectrometer (low-resolution single MS) (Agilent Technologies, Palo Alto, USA). The concentration of 19 individual PAHs including US EPA priority pollutants (Naphthalene (Nap), 2-methyl Naphthalene (Methy-Nap), 1-methyl Naphthalene (Me-Nap), Acenaphthylene (Acl), Acenaphthene (Ace), Fluorene (Fle), Phenanthrene (Phe), Anthracene (Ant), Fluoranthene (Flu), Pyrene (Pyr), Benz[a]anthracene (BaA), Chrysene (Cry), Benzo[b]fluoranthene (BbF), Benzo[k]fluoranthene (BkF), Benzo[e]pyrene (BeP), Benzo[a]pyrene (BaP), Dibenzo[a,h]anthracene (DBahA), Indeno[1,2,3CD]pyrene (IDP), Benzo[g,h,i]perylene (BghiP)) were analyzed in each household indoor air sample.
For quality assurance/quality control, (QA/QC) internal standard (p-Terphenyl-d14, 2-fluorobiphenyl from Restek Corporation, Bellefonte, Pennsylvania US) and surrogate standard (Naphtalene-d8, Acenaphthene-d10, Phenanthrene-d10, Chryzene-d12 Benzo(a)pyrene-d12, and Perylene-d12, from Restek Corporation, Bellefonte, Pennsylvania US) were used for quantification and quantifying of sample and for procedural recovery. Before the analysis, standards were freshly prepared and diluted with GC grade solvents (Sigma-Aldrich, St. Louis, Missouri USA). Recoveries for the compounds ranging between 73.5 and 119.4%, this achieved good by the regulatory requirements of the USA-EPA and EU. In our measurement, the recoveries were 96–104% for 2-fluorobiphenyl and 108–114% for p-Terphenyl-d14. The recoveries of surrogate standards were acceptable for the standards (Naphtalene-d8, Acenaphthene-d10 82–102%, Phenanthrene-d10 92–109%, Chrysene-d12 95–107%, perylene-D12 82–91%), which were good for making results reliable.
Analytical determinations were performed by courtesy of the Laboratory of the ELGOSCAR-2000 Environmental Technology and Water Management Ltd. accredited by the National Accreditation Authority (complies with criteria of Standard MSZ EN ISO/IEC 17,025:2018), registration number NAH-1–1278/2015.
Health risk characterization
Health risk assessment can be established using PAHs exposure, based on one of the approaches is inhalation exposure. In our case, inhalation of indoor air particles containing PAHs was assessed via the use of toxicity equivalency factor (TEFs) based on BaP, and estimated BaP equivalent concentration (BaPeq) (Bari et al., 2010). The list of TEFs composed by Lu et al. (2008) was adopted (Fig. 6), and the total PAH-associated carcinogenicity was calculated based on the following formula:
BaPeq = ∑ (Ci × TEF) where Ci is concentration of PAHs in indoor PM2.5 sample.
Lifetime average daily dose (LADD) of PAHs was calculated based on the guideline of Boström et al. (2002) as follows:
Cancer risk was estimated as follows: incremental lifetime cancer risk (ILCR) = Lifetime average daily dose (LADD) × cancer slope factor (CSF).
LADD is intake of chemical compounds suspected for causing adverse health effects expressed as mg kg−1 of bodyweight per day. In general, chronic exposure is assumed. Ci is concentration of particular PAHs (ng m−3); IR is the intake rate (for an adult 0.83 m3 h−1; for up to 14 year child—0.87 m3 h−1); ET is exposure time (21 h day−1); EF is the exposure frequency (350 days year−1). ED represents exposure duration, 70 years for adults and 14 years for children. CF is the unit of the conversion factor (10−6). BW is the average body weight (for adults: – 70 kg, for children: 59.4 kg), AT represents the average timing (for adults: 25,550 days (70 × 365); for children:– 5110 days (14 × 365)) (Bozek et al., 2009; Iwegbue et al., 2019; Ortega-García et al., 2017). In this case, we used values of cancer slope factor for carcinogenic-PAHs, which were compiled (USEPA, 1992), and the LADD and ILCR estimations for adult and child in indoor air sample were also presented in Table 3.
Source apportionment
Calculation of certain PAHs diagnostic ratio is widely used technique to estimate the presented PAHs origin in various environment media such as air sample. Diagnostic ratios were calculated as follows: fluoranthene to fluoranthene plus pyrene [Flt/(Flt + Pyr)]; benz[a]anthracene to benz[a]anthracene plus chrysene [BaA/(BaA + Cry)]; indene[1,2,3-cd]pyrene to indene[1,2,3-cd]pyrene plus benzo[ghi]perylene [Ind/(Ind + BghiP)] (Yunker et al., 2002).
Toxicity assessment
Ecotoxicity testing was carried out according to ISO 21338:2010: water quality – kinetic determination of the inhibitory effects of sediment, other solids and colored samples on the light emission of Vibrio fischeri (kinetic luminescent bacteria test). The kinetic protocol was specially designed to measure the light output of test bacteria in turbid or colored samples. Prior to measurement, freeze-dried inactivated luminous V. fischeri (NRRL-B-11177, supplier Hach Lange Co.) were rehydrated with reconstitution solution (glucose/sodium chloride, buffered to PH 7.0 in a PE bottle) and then incubated at 15 °C for 40 min.
Measurements were done in 96 multi-well plate using 1:2 dilutions in 2 replicates. After the sample was injected into the bacterial suspension, bioluminescence intensity was continuously recorded for the first 30 s. After 30 min of exposure, luminescence intensity was read again. The light output of the unstressed bacteria (the first 30 s) was used as a reference in calculating the results. EC50 (calculated percent concentration of original extract which causes 50% of effect) values were calculated from the light inhibition percentages by the Aboatox software provided with the Luminoskan Ascent Luminometer (Thermo Scientific).
Each EC50 was transformed into dimensionless toxic unit (TU) calculated using the formula as follows (Chang et al., 2013):
TU = (1/EC50) × 100%
TU categories are generally classified as: non-toxic (< 1), toxic (1–10), very toxic (10–100), extremely toxic (> 100), respectively.
Results and discussion
Concentration of PM2.5 in indoor air of households
Concentrations of PM2.5 ranged between 62.8 and 324.8 µg m−3. The highest concentrations were found in HH-6 (324.8 µg m−3), HH-2 (320 µg m−3), and HH-8 (246.2 µg m−3), while the lowest concentrations in HH-5 (93.6 µg m−3) and HH-9 (62.8 µg m−3) (see Table 1). However, values of all household indoor air significantly exceeded limits of WHO (10 µg m−3). Kim et al. (2021) compared personal PM2.5 exposure of Ger residents vs. apartment residents and found that the first group was exposed to a significantly higher PM2.5 concentration.
PAH concentrations in indoor air of households
Concentrations of 19 individual PAHs in indoor air of each household were measured (Table 2); the highest total concentrations were found in HH-7 (175.7 ng m−3), followed by HH-2 (137.3 ng m−3), HH-5 (105.1 ng m−3), HH-4 (74.1 ng m−3), HH-1 (70.2 ng m−3), HH-10 (69.7 ng m−3), HH-6 (69.5 ng m−3), HH-8 (63.0 ng m−3), and HH-3 (46.7 ng m−3). The lowest concentration (46.2 ng m−3) was detected in HH-9.
Although PAH concentrations in winter samples collected in warm regions might also reach rather high values (e.g., Li and Ro, 2000), for our study comparison with colder regions seems to be more relevant, as the contribution from home heating and more representative meteorological conditions can be taken into consideration. Mohammed et al. (2016) investigated the distribution patterns of PM2.5-bound PAHs in indoor samples collected in Harbin city (northeastern China). The mean concentration of the sum of 16 US EPA priority PAHs was 102 ± 75 ng m−3. The concentration of total PAHs in the PM2.5 fraction of indoor school samples collected in a campaign during the heating season in Kaunas (Lithuania) ranged from 20.3 to 131.1 ng m−3 (Krugly et al., 2014). In a comparative study, Lu et al. (2011) measured total concentration of 8 PAHs which amounted to 320 ng m−3 in residential air of Hangzhou (China). In an Indian study, the average PAH concentration in residential homes was 233 ng m−3 in winter (Masih et al., 2012). Li et al. (2017) measured an average of 39.6 ng m–3 PAH concentration in indoor PM2.5 samples collected in January from suburban hotels in Jinan (China).
While our results fall into a similar range, some studies report exceptionally high concentrations: e.g., Zhu et al. (2009) measured as high as 36.200 ng m−3 total concentration of PAHs in residential air in Hangzhou (China).
Figure 3 shows the total amount of different molecular weight PAHs in each household. Concentrations of heavy PAHs (five- and six-rings) were significantly higher in HH-7 and HH-2 than in others. It should be noted that prevalent group was five-ring PAHs in indoor air of all households except HH-3. The results indicated that benzo[b]fluoranthene (BbF) and benzo[a]pyrene (BaP) represented a significant fraction of five-ring PAHs in each sample.
The percentage contribution of different molecular weight PAHs is shown in Fig. 4. The results indicated that five-ring PAHs represented 54% of total PAHs in HH-7, followed by HH-2 (52%), HH-6 (46%), HH-10 (46%), HH-1 (42%), HH-8 (41%), HH-9 (34%), HH-5 (32%), and HH-1 (25%). Four-ring PAHs also represented a relatively high ratio in indoor air of all households in decreasing order: HH-5 (28%; 17.58%), HH-7 (21.71%; 6.42%), HH-8 (20.87%; 18.33%), HH-2 (18.75%; 8.57%). Six-ring PAHs accounted for 8.8% to 14% of total PAHs concentrations in indoor air of the sampled households.
In our study, 5- and 6-ring PAHs made up relatively high fraction of total PAHs in each household. These results are in concordance with finding of Wu et al. (2015). While PAHs are distributed between vapor and particulate phases, heavier PAHs with 5–6 aromatic rings are predominantly found in particles (Lu et al., 2008).
According to literature, PAH emission from different sources can be identified based on different PAHs rings: Flu, Pyr, BaA, Cry, and DbaA are considered as tracers of coal combustion, whereas BkF, IDP, and BghiP are considered markers of vehicle exhaust (Eiguren-Fernandez et al., 2004; Ma et al., 2010; Pant et al., 2017). Considering individual characteristic PAHs, 4 rings PAHs including Flu, Pyr, BaA, and Cry were detected in all households; they were most abundant in HH-7, followed by HH-5 and HH-2, respectively. DbaA is one of the best marker, which is typically associated with coal combustion (Pant et al., 2017). DbaA was detected in all households with the exception of HH-5. The individual homologues such as lower molecular weight (LMW) Nap, Ace, and Fle are not specifically related to traffic emission. However, Nap, Ace, and Fle were detected in all households with the exception of Ace which did not occur in HH-5. In all households, the markers of vehicle emission were detected, the highest concentrations of IDP and BghiP were found in HH-7 (14.4 ng/m3 and 9.15 ng/m3), followed by HH-2 (11.8 ng/m3 and 7.7 ng/m3), HH-5 (5.4 ng/m3 and 4.8 ng/m3), and HH-10 (5.08 ng/m3 and 3.49 ng/m3).
BkF was detected in all households; high concentrations were measured in HH-7 (12.6 ng/m3) and HH-2 (8.9 ng/m3) respectively. Heavier PAH homologues (5- to 6-ring PAHs) were detected in all households, which suggested the influence of traffic exhaust (Rogula-Kozłowska et al., 2018). Our result indicated that BaP, BaA, Cry, Pyr, BkF, BbF, IDP, and BghiP were the most dominant PAHs in indoor air PM2.5, especially for the BaP, BaA, BkF, IDP, and BghiP, due to both sources of solid fuel combustion and traffic (Byambaa et al., 2019).
In addition to indoor and outdoor sources, many factors also influence indoor air quality such as household age, construction quality and family income, etc. (So et al., 2019). We also compared the construction age, room size of household, and people activities. Difference was found between in HH-7, HH-2, and HH-5 to other households (Table 1). The lowest total amount of PAHs (46.8 ng m−3) was measured in HH-3 (7 years old), while household with highest total amount of PAHs (175.7 ng m−3) was a relatively old building (40 year old). The concentration of 16 individual PAHs in residential air of 10 non-smokers from Chicago area homes were measured (Li et al., 2005). The lowest total concentration was found in a new building (8 years old), whereas the highest total PAHs was detected in an old one (age 80 years). Lower concentration of indoor PM2.5 were attributed to the presence of airtight windows in winter in Italy (Simoni et al., 2004) and large room size of household in California, USA (Klepeis et al., 2017), while higher concentration of PM-bound PAHs was associated with low-income families (Chuang et al., 1999) and movement of people (Vardoulakis et al., 2020). These results suggested that accumulated PAHs in indoor air might be related to household age and construction quality.
Correlation factor between outdoor PM2.5 and indoor PM2.5
In this case, we used data of ambient PM2.5 concentrations from the National Agency of Meteorology and Environmental Monitoring. As far, there are 15 air monitoring stations in Ulaanbaatar city (http://agaar.mn/index). Nisekh and Misheel Expo air monitoring stations in Khan-Uul district, Ulaanbaatar city, are located quite close to these ten households. HH-1, HH-2, HH-3, and HH-4 are located app. 5 to 5.3 km from both air monitoring stations. The distances between HH-5, HH-6, and HH-7 and the Nisekh air monitoring station are app. 4.4 km, whereas HH-8, HH-9, and HH-10 are located quite closely to the Nisekh monitoring station (345 to 500 m).
Model-based correlation between average concentrations of ambient and indoor PM2.5 shown in Fig. 5 was found to be moderately positive (R2 = 0.66, P value < 0.015).
In other studies, significant correlation was found between indoor and outdoor particulate matter levels in wintertime (e.g., Bai et al., 2020; Hu et al., 2018). Rogula-Kozłowska et al. (2018) showed positive correlation between PM1-bound PAH levels in Gliwice (Poland). Byambatseren et al. (2018) reported that in winter 24 h average concentration of PM2.5 pollution of indoor and outdoor was measured in a household which was located between ger area and the residential district in Ulaanbaatar capital at simultaneous duration and point. The result indicated that pollution of indoor ambient was strongly related to outdoor ambient. Enkhbat et al. (2016) defined outdoor pollution originating from coal burning as a main source of continuous indoor pollution. Hill et al. (2017) also states that indoor PM2.5 exposure is considerably influenced by infiltrated outdoor pollution.
Lim et al. (2018) determined the characteristics of indoor PM2.5 concentration in ger with coal stoves during winter period around the non-connected heating system area, Ulaanbaatar capital. The result showed that the average 24-h PM2.5 concentration was higher with improved stove than conventional stoves, and also mentioned the combustion method of the stoves. During controlled burning of Mongolian coal samples of different origin, Barabad et al. (2018) found that PM2.5 emission would depend on the coal used in the household.
PAHs source identification in an indoor air of households
In order to estimate the pollution source, established ratios of PAH isomers were used (Yunker et al., 2002). Fluoranthene to (fluoranthene + pyrene) [Flt/(Flt + Pyr)] ratio below 0.4 indicates petroleum source, between 0.4 and 0.5 indicates petroleum combustion while values above 0.5 grass, wood and coal combustion. Flt/(Flt + Pyr) ratio were above 0.5 for all household which implies combustion of solid fuel (Yunker et al., 2002). Flt/(Flt + Pyr) ratio was 0.48 in HH-7 which likely implied petroleum combustion. It was very interesting to note that Flt/(Flt + Pyr) ratio was < 0.4 in case of only 1 household, HH-5 (0.38) which indicated petroleum input. The results from this study suggested that combustion of wood and coal is important source of PM2.5-bound PAHs in indoor air for all households with the exception of HH-7 and HH-5. Benzo{a}anthracene to ( benzo{a}anthracene + chrysene) [BaA/(BaA + Cry)] ratio over 0.35 implies combustion of vegetation and fossil fuel, less than 0.35 likely implies mixed source. This ratio value was above 0.35 for all households except only one household, HH-4, suggesting combustion input and value in HH-4 was exactly 0.29 suggesting mixed source. Figure 6 shows the crossplots of BaA/(BaA + Cry) against Flt/(Flt + Pyr), suggesting that the main important source in case of the majority of households was coal and wood combustion (Yunker et al., 2002). The crossplot of BaA/(BaA + Cry) against Flt/(Flt + Pyr) indicated that in this case considering the indoor air PM2.5 air samples in HH-7 and HH-5 petroleum combustion and petroleum input might be the main source. It is most interesting to note that the environment of these two households was highly differing from each other; one of the most possible sources might be the vicinity of an old mini power plant and petroleum station.
Indene[1,2,3-cd]pyrene to indene[1,2,3-cd]pyrene + benzo[ghi]peryene [Ind/(Ind + BghiP)] ratio above 0.5 implies combustion of grass, wood, and coal while, between 0.2 and 0.5 petroleum combustion while less than 0.2 petroleum. Figure 6 shows the cross plot for Ind/(Ind + BghiP) and Flt/(Flt + Pyr). In the majority of the households (except HH-5 and HH-7), grass, wood, and coal combustion was indicated as the major source, most possibly wood and coal for heating and cooking (Anenberg et al., 2013; Bonjour et al., 2013; Yunker et al., 2002). Several studies have reported coal combustion as the main source of air particulate matter emission in ger districts during winter season in Ulaanbaatar (e.g., Davy et al., 2011). Coal, which was burned in all households sampled in our study, has been identified as a main indoor pollution source as well. It is common that coal is used as a source of fuel for heating and cooking in winter in ger districts in Ulaanbaatar (Battsengel et al., 2021).
Cancer and health risk assessment of PAHs contamination in indoor air of households
In order to estimate the health and cancer risk for adults and children posed by PM2.5-bound PAHs through inhalation in indoor environment, lifetime average daily dose (LADD) and the corresponding incremental lifetime cancer risk (ILCR) values were calculated (see Table 3). The values of LADD PAHs ranged from 3.5 × 10−8 to 9.0 × 10−6 in adults, whereas 4.4 × 10−10 to 1.1 × 10−5 in children, respectively. ILCR values associated to carcinogenic-PAHs ranged between 4.0 × 10−10 and 5.5 × 10−5 for adults, and between 4.9 × 10−10 and 6.8 × 10−5 for children.
Lifetime-average daily dose for children exceeded the health based guideline level (1.0 × 10−5) defined by WHO (Boström et al., 2002) in only one household (see Table 3), whereas LADD for adults and children of other households were within acceptable limit. The cancer risks from the exposure of children to air pollutants in all households except HH-3 were found high. It should be noted, however, that USEPA (2005) suggests the use of adjustment factors due to toxicokinetic and toxicodynamic differences between children and adults.
This means that the excess lifetime cancer risks were one order of magnitude higher than 10−6 which was set by US EPA as a risk level for carcinogenic individual compounds. High level of these pollutants was detected in indoor air, which might cause specific long-term health effects, e.g., lung cancer. The lifetime inhalation cancer risk was estimated in the ger area due to winter pollution in the study of Byambaa et al. (2019). Estimated values were as follows: 1.2 × 10−5 for child and 2.1 × 10−5 for adult exposures.
Considering cancer risk, our results were comparable to, e.g., the study conducted in residential homes in winter and summer period in Shimizu, Japan, an industrial area (Ohura et al., 2004). However, Lu et al. (2008) reported two order of magnitude higher values for PAHs exposure in indoor air of public places in Hangzhou (ranging from 0.6 × 10−3 to 2.4 × 10−3).
Indoor air exposure to PAHs in all studied households seems to raise health issues. BaP equivalent concentrations are 1.2, 0.12, and 0.012 ng m−3 producing an excess life time cancer risk 1:10,000; 1:100,000; and 1:1,000,000; respectively (Bari et al., 2010).
In our study, ∑BaPeq in indoor air of households ranged between 5.4 and 34 ng m−3. Highest ∑BaPeq were found in HH-7 (34.41 ng m−3), HH-2 (27.64 ng m−3), and HH-5 (12.51 ng m−3), while lowest concentrations in HH-3 (5.41 ng/m3) and HH-9 (6.21 ng m−3) (Fig. 7). BaP concentration alone of total ∑BaPeq in all household indoor air exceeded 1 ng m−3 which is prescribed by the Chinese Air Quality Standards (Wu et al., 2015). The highest concentrations in indoor air were found in HH-7 (25.13 ng m−3) and HH-2 (20.37 ng m−3), while lowest concentrations occurred in HH-3 (4.06 ng m−3) and HH-9 (4.78 ng m−3) respectively.
BaP concentration alone in PM2.5 fraction of indoor air of the households ranged between 4.06 and 25.13 ng m−3. Similar result was found in the study of Yury et al. (2018) in which mean ∑BaPeq concentration in PM2.5 sampled for 24 h in an empty room ranged from 5.5 to 25.4 ng m−3. It should be noted, however, that exceptionally high level of BaP (3249 ng m−3) was measured in rural households in Xuanwei (Mumford et al., 1990).
Risk of lifetime cancer to children and adult was substantially higher in cold period and that indoor air quality are more pay attention to effectively mitigate the health risk to prevent early exposure as follows: most important few approaches might be used (i) to replace raw coal with processed coal (Byambajav et al., 2021), (ii) more focus on electricity usage (Amod et al., 2015), and (iii) can be used the different types of air filter to reduce indoor PM2.5 (Prabjit et al., 2018; Ching-Huang et al., 2021).
Ecotoxicity assessment of indoor PM2.5 of households
The present study was the first application of the V. fischeri bioluminescence inhibition assay on indoor samples in Mongolia using the bioluminescence inhibition bacterium test. Based on calculated toxic units (TUs) (Chang et al., 2013), all samples were classified as toxic (Fig. 8). Differences in the ecotoxicity can be partially explained by the PAH concentrations: percentage of HMW PAHs (5- to 6-rings) was the highest in HH-2 (66.5%), TU was also outstanding in this sample (5.4). Ratio of HMW PAHs was also high in HH-6 (57%), TU was 5.5. In HH-5, TU was 5.5, whereas HMW PAHs amounted to 42.2%.
In the study of Evagelopoulos et al. (2009), good correlation was found between PAHs content and ecotoxicity for urban samples collected in Kozani (Greece). Alves et al. (2021) assessed the ecotoxicity of indoor PM10 samples collected during cooking in domestic kitchen using the bioluminescence inhibition bioassay. The result proved that LMW PAHs did not show any correlation with toxicity values, whereas good correlation was found between HMW PAHs and toxicity values (r2 = 0.94). Kováts et al. (2020) used the V. fischeri bioassay to evaluate the seasonal differences in rural particular matter ecotoxicity. The results revealed that PAHs content (5- to 6- rings PAHs) was higher in winter and autumn, Vibrio results also showed higher ecotoxicity for these seasons. A similar tendency appeared in other studies (Isidori et al., 2003; Triolo et al., 2008).
In our study, good correlation was found between indoor PM2.5 levels and TU values (t = 2.4803, df = 8, p value = 0.03809; R2 = 0.6593202). Vibrio inhibition seems to reflect the overall ecotoxicity of the samples, which in addition to PAHs, might be attributed to heavy metals such as Cr, Cu, Zn, Ni, Cd, and Pb (Wang et al., 2021). Figure 9 shows the output of cluster analysis of different households based on the individual PAH concentrations, TU, and indoor PM2.5 concentrations. Three groups could be identified. Significant difference was found between group I. and group III (t = − 2.2638, df = 21, p = 0.0343) and non-significant differences were found between group I and group II (t = − 1.2537, df = 21, p = 0.2237) and group II and group III (t = − 0.70335, df = 21, p = 0.4896). The proximity of HH2, HH6, and HH8 also reflects the similarities between households having high indoor toxicity.
Conclusions
Concentrations of 19 individual PAHs in indoor PM2.5 samples of ten households were determined in Khan-Uul district, Ulaanbaatar. Sampling was carried out in winter of 2018. Typical fuel for heating in all households is coal. The results show that HMW PAHs (5- and 6-ring) contributed to a large fraction of total PAHs in each sample, and the potentially most carcinogenic PAH, BaP was predominant among the 5-ring PAHs. Significant correlation was found between indoor and ambient particulate matter levels in wintertime. Much more of the daily time spent by people in developed and developing countries is in enclosed buildings and by the very young and elderly, even more. Thus, indoor air quality in an enclosed building is of significance to human health.
Health risk of children attributed to PAHs inhalation was assessed by taking into account the lifetime-average daily dose (LADD) and corresponding lifetime cancer risk. LADD for children in indoor air of only one household were slightly higher than health-based guideline level (1.0 × 10−5) set by the WHO. The cancer risks from the exposure of children to air pollutants in all households except HH-3 were found high. In the Vibrio fischeri bioluminescence inhibition assay, according to the TU values of indoor PM2.5 from ten households of Mongolia, all samples were classified as toxic. It should be noted that as the Vibrio test measures the aggregate toxicity of the samples, strong relationship could be detected between TUs and PM2.5 concentrations.
Children spend a significant part of their time in enclosed buildings such as home, school etc., also, they are more sensitive to air pollution compared to adults. To our best knowledge, this is the first study dealing with indoor air quality of Ulaanbaatar city which is among the most polluted capitals in the world. Our results are partially comparable to other studies completed in other cold regions, showing elevated risk to inhabitants. The results of the current study will most possibly provide a starting point for future air quality studies and for implementing a strategy to control air quality in places where children reside.
Data availability
Data generated during the study are included in the manuscript.
Abbreviations
- Acl:
-
Acenaphthylene
- Ace:
-
Acenaphthene
- Ant:
-
Anthracene
- AT:
-
Average timing
- BaA:
-
Benz[a]anthracene
- BbF:
-
Benzo[b]fluoranthene
- BkF:
-
Benzo[k]fluoranthene
- BeP:
-
Benzo[e]pyrene
- BaP:
-
Benzo[a]pyrene
- BghiP:
-
Benzo[g,h,i]perylene
- BW:
-
Body weight
- CF:
-
Unit of conversion factor
- CSF:
-
Cancer slope factor
- GC_MS:
-
Gas chromatography-mass spectrometry
- Cry:
-
Chrysene
- DBahA:
-
Dibenzo[a,h]anthracene
- ED:
-
Exposure duration
- EF:
-
Exposure frequency
- EPA:
-
Environmental Protection Agency
- ET:
-
Exposure time
- Fle:
-
Fluorene
- Flu:
-
Fluoranthene
- HH:
-
Household
- HMW:
-
High molecular weight
- ILCR:
-
Incremental life cancer risk
- IR:
-
Intake rate
- IDP:
-
Indeno[1,2,3CD]pyrene
- LADD:
-
Lifetime average daily dose
- LMW:
-
Low molecular weight
- NSFB:
-
Non-solid fuel burning
- Nap:
-
Naphthalene
- Methy-Nap:
-
2-Methyl Naphthalene
- Me-Nap:
-
1-Methyl Naphthalene
- QA:
-
Quality assurance
- QC:
-
Quality control
- PAH:
-
Polycyclic aromatic hydrocarbon
- PM:
-
Particulate matter
- Phe:
-
Phenanthrene
- Pyr:
-
Pyrene
- SFB:
-
Solid fuel burning
- TEF:
-
Toxic equivalency factor
- TU:
-
Toxic unit
- WHO:
-
World Health Organization
- WAQ:
-
World Air Quality
References
Abdel-Shafy, H. I., & Mansour, M. S. M. (2016). A review on polycyclic aromatic hydrocarbons: Source, environmental impact, effect on human health and remediation. Egyptian Journal of Petroleum, 25, 107–123. https://doi.org/10.1016/j.ejpe.2015.03.011
Adesina, J. A., Piketh, S. J., & Qhekwana, M. (2020). Contrasting indoor and ambient particulate matter concentrations and thermal comfort in coal and non-coal burning households at South Africa Highveld. Science of the Total Environment, 699, 134403. https://doi.org/10.1016/j.scitotenv.2019.134403
Ahn, J. Y., Song, L., & Shin, H. (2019). Determinants of Indoor PM2.5 Concentrations in Ger, a Traditional Residence, in Mongolia. Korean Journal of Public Health, 55, 22–30. https://doi.org/10.17262/kjph.2018.12.55.2.22
Allen, R. W., Gombojav, E., & Barkhasragchaa, B. (2013). An assessment of air pollution and its attributable mortality in Ulaanbaatar, Mongolia. Air Quality, Atmosphere and Health, 6, 137–150. https://doi.org/10.1007/s11869-011-0154-3
Alves, C. A., Vicente, E. D., & Evtyugina, M. (2021). Cooking activities in a domestic kitchen: Chemical and toxicological profiling of emissions. Science of the Total Environment, 772, 145412. https://doi.org/10.1016/j.scitotenv.2021.145412
Amod, K. P., Michael, N. B., Jiwan, A., Palle, V. B., Ram, K. C., Prakash, S. S., Anil, K. R., & Kirk, R. S. (2015). PM2.5 in household kitchens of Bhaktapur, Nepal, using four different cooking fuels. Atmospheric Environment, 113, 159–168. https://doi.org/10.1016/j.atmosenv.2015.04.060
Ando, M., Katagiri, K., Tamura, K., Yamamoto, S., Matsumoto, M., Li, Y. F., et al. (1996). Indoor and outdoor air pollution in Tokyo and Beijing supercities. Atmospheric Environment, 30(5), 695–702. https://doi.org/10.1016/1352-2310(94)00216-9
Anenberg, S. C., Balakrishnan, K., & Jetter, J. (2013). Cleaner cooking solutions to achieve health, climate, and economic cobenefits. Environmental Science and Technology, 47, 3944–3952. https://doi.org/10.1021/es304942e
Badarch, J., Harding, J., Dickinson-Craig, E., Azen, C., & Ong, H. (2021). Winter air pollution from domestic coal fired heating in Ulaanbaatar, Mongolia, is strongly associated with a major seasonal cyclic decrease in successful fecundity. International Journal of Environmental Research and Public Health, 18, 2750. https://doi.org/10.3390/ijerph18052750
Bai, L., He, Z., Li, C., & Chen, Z. (2020). Investigation of yearly indoor/outdoor PM2.5 levels in the perspectives of health impacts and air pollution control: Case study in Changchun, in the northeast of China. Sustain Cities Society, 53, 101871. https://doi.org/10.1016/j.scs.2019.101871
Ban, H., Hwang, Y., Lim, M., Ochir, C., & Lee, K. (2017). Daytime profile of residential PM2.5 concentrations in a ger, a traditional residence in Mongolia. Korean Journal of Public Health, 54, 23–30. https://doi.org/10.17262/kjph.2017.03.54.1.23
Barabad, M. L., Jung, W., & Versoza, M. E. (2018). Emission characteristics of particulate matter, volatile organic compounds, and trace elements from the combustion of coals in Mongolia. International Journal of Environment Research Public Health, 15(8). https://doi.org/10.3390/ijerph15081706
Bari, M., Baumbach, G., Kuch, B., & Scheffknecht, G. (2010). Particle-phase concentrations of polycyclic aromatic hydrocarbons in ambient air of rural residential areas in southern Germany. Air Quality, Atmosphere and Health, 3(2), 103–116. https://doi.org/10.1007/s11869-009-0057-8
Batmunkh, T., Kim, Y. J., & Jung, J. S. (2013). Chemical characteristics of fine particulate matters measured during severe winter haze events in Ulaanbaatar, Mongolia. Journal of the Air and Waste Management Association, 63, 659–670. https://doi.org/10.1080/10962247.2013.776997
Battsengel, E., Murayama, T., Nishikizawa, S., & Chonokhuu, S. (2021). Evaluation of daily behaviors related to health risks of the ger residents in Ulaanbaatar, Mongolia. Sustainability, 13(9), 4817. https://doi.org/10.3390/su13094817
Bonjour, S., Adair-Rohani, H., & Wolf, J. (2013). Solid fuel use for household cooking: Country and regional estimates for 1980–2010. Environmental Health Perspectives, 121, 784–790. https://doi.org/10.1289/ehp.1205987
Boström, C. E., Gerde, P., & Hanberg, A. (2002). Cancer risk assessment, indicators, and guidelines for polycyclic aromatic hydrocarbons in the ambient air. Environmental Health Perspectives, 110, 451–488. https://doi.org/10.1289/ehp.110-1241197
Bozek, F., Adamec, V., & Navratil, J. (2009). Health risk assessment of air contamination caused by polycyclic aromatic hydrocarbons from traffic. Energy Environment Engineering Service, 104–108.
Byambaa, B., Yang, L., & Matsuki, A. (2019). Sources and characteristics of polycyclic aromatic hydrocarbons in ambient total suspended particles in Ulaanbaatar City, Mongolia. International Journal of Environment Research Public Health, 15(3). https://doi.org/10.3390/ijerph16030442
Byambajav, G., Batbaatar, B., Ariunsaikhan, A., & Chonokhuu. S. (2021). Particulate matter concentrations during winter seasons of 2016–2020 in Ulaanbaatar, Mongolia. Proceedings of the Mongolian Academy of Sciences, 61(01), 237. https://doi.org/10.5564/pmas.v61i1.1559
Byambatseren, Ch., Michidmaa, N., Sonomdagva, Ch., & Yutaka, M. (2018). The some results of study on outdoor and indoor ambient PM2.5. Proceedings of the Mongolian Academy of Sciences, 58(225), 40–54. https://doi.org/10.5564/pmas.v58i1.971
Chang, S. C., Wang, Y. F., & You, S. J. (2013). Toxicity evaluation of fly ash by Microtox®. Aerosol and Air Quality Research, 13, 1002–1008. https://doi.org/10.4209/aaqr.2012.10.0267
Ching-Huang, H., Jianbang, X., Elena, A., Jeff, S., Yisi, L., Christopher, S., Catherine J. K., Amber, L. F., Thomas, K. L., & Edmund. S. (2021). Impacts of using auto-mode portable air cleaner on indoor PM2.5 levels: An intervention study. Building and Environment, 188, 107444. https://doi.org/10.1016/j.buildenv.2020.107444
Chuang, J. C., Callahan, P. J., Lyu, C. W., & Wilson, N. K. (1999). Polycyclic aromatic hydrocarbon exposures of children in low-income families. Journal of Exposure Analysis & Environmental Epidemiology, 9(2).
Davy, P. K., Gunchin, G., Markwitz, A., Trompetter, W. J., & Barry, B. J. (2011). Air particulate matter pollution in Ulaanbaatar, Mongolia: Determination of composition, source contributions and source locations. Atmospheric Pollution Research, 2, 126–137. https://doi.org/10.5094/APR.2011.017
Du, W., Li, X., Chen, Y., & Shen, G. (2018). Household air pollution and personal exposure to air pollutants in rural China—A review. Environmental Pollution, 237, 625–638. https://doi.org/10.1016/j.envpol.2018.02.054
Eiguren-Fernandez, A., Miguel, A. H., & Froines, J. R. (2004). Seasonal and spatial variation of polycyclic aromatic hydrocarbons in vapor-phase and PM2.5 in Southern California urban and rural communities. Aerosol Science and Technology, 38, 447–455. https://doi.org/10.1080/02786820490449511
Enkhbat, U., Rule, A. M., & Resnick, C. (2016). Exposure to PM2.5 and blood lead level in two populations in ulaanbaatar, Mongolia. International Journal of Environmental Research and Public Health, 13, 1–11. https://doi.org/10.3390/ijerph13020214
Enkhmaa, D., Warburton, N., Javzandulam, B., Uyanga, J., & Khishigsuren, Y. (2014). Seasonal ambient air pollution correlates strongly with spontaneous abortion in Mongolia. BMC Pregnancy and Childbirth, 14, 146. http://www.biomedcentral.com/1471-2393/14/146
Evagelopoulos, V. S., Zoras, P., Samaras, A. G., Triantafyllou, T. A., & Albanis, P. K. (2009). Toxicity of fine and coarse atmospheric particles using Vibrio fischeri. 2" International Conference on Environmental Management, Engineering, Planning and Economics (CEMEPE 2009) & SECOTOX Conference.
Feng, S., Gao, D., & Liao, F. (2016). The health effects of ambient PM2.5 and potential mechanisms. Ecotoxicology and Environmental Safety, 128, 67–74. https://doi.org/10.1016/j.ecoenv.2016.01.030
Gelencsér, A., Barbara, M., David, S., Asuncion, S. A., Kasper, G., Hans, P., et al. (2007). Source apportionment of PM2.5 organic aerosol over Europe: Primary/secondary, natural/anthropogenic, and fossil/biogenic origin. Journal of Geophysical Research-Atmospheres, 112, 1–12. https://doi.org/10.1029/2006JD008094
Guttikunda, S. K., Lodoysamba, S., Bulgansaikhan, B., & Dashdondog, B. (2013). Particulate pollution in Ulaanbaatar, Mongolia. Air Quality, Atmosphere & Health, 6(3), 589–601. https://doi.org/10.1007/s11869-013-0198-7
Hassanvand, M. S., Naddafi, K., Faridi, S., Nabizadeh, R., Sowlat, M. H., Momeniha, F., & Yunesian, M. (2015). Characterization of PAHs and metals in indoor/outdoor PM10/PM2. 5/PM1 in a retirement home and a school dormitory. Science of the Total Environment, 527, 100–110. https://doi.org/10.1016/j.scitotenv.2015.05.001
Hill, L. D., Edwards, R., & Turner, J. R. (2017). Health assessment of future PM2.5 exposures from indoor, outdoor, and secondhand tobacco smoke concentrations under alternative policy pathways in Ulaanbaatar, Mongolia. PLoS ONE, 12, 1–26. https://doi.org/10.1371/journal.pone.0186834
Hu, Y. J., Bao, L. J., & Huang, C. L. (2018). Exposure to air particulate matter with a case study in Guangzhou: Is indoor environment a safe haven in China? Atmospheric Environment, 191, 351–359. https://doi.org/10.1016/j.atmosenv.2018.08.025
Isidori, M., Ferrara, M., & Lavorgna, M. (2003). In situ monitoring of urban air in Southern Italy with the tradescantia micronucleus bioassay and semipermeable membrane devices (SPMDs). Chemosphere, 52, 121–126. https://doi.org/10.1016/S0045-6535(03)00183-8
Iwegbue, Ch. M., Elo-Oghene, C. I., Eze, W. O., Francis, E. E., Godswill, O. T., Godwin, E. N., & Bice, S. M. (2019). Distribution, sources and health risks of polycyclic aromatic hydrocarbons (PAHs) in household dusts from rural, semi-urban and urban areas in the Niger Delta, Nigeria, Exposure and Health. Springer, Netherlands, 11(3), 209–225. https://doi.org/10.1007/s12403-018-0276-z
Jadambaa, A., Spickett, J., Badrakh, B., & Norman, R. E. (2015). The impact of the environment on health in Mongolia: A systematic review. Asia-Pacific Journal of Public Health, 27, 45–75.
Kim, D., Shin, H., & Guak, S. (2021). Personal PM2.5 exposures of husband and wife by residential characteristics in Ulaanbaatar, Mongolia. Air Quality, Atmosphere and Health, 14, 1849–1856. https://doi.org/10.1007/s11869-021-01060-4
Klepeis, N. E., Bellettiere, J., & Hughes, S. C. (2017). Fine particles in homes of predominantly lowincome families with children and smokers: Key physical and behavioral determinants to inform indoor-Air-quality interventions. PLoS ONE, 12, 1–24. https://doi.org/10.1371/journal.pone.0177718
Klepeis, N. E., Nelson, W. C., Ott, W. R., Robinson, J. P., Tsang, A. M., Switzer, P., & Engelmann, W. H. (2001). The National Human Activity Pattern Survey (NHAPS): a resource for assessing exposure to environmental pollutants. Journal of Exposure Science & Environmental Epidemiology, 11(3), 231–252. https://doi.org/10.1038/sj.jea.7500165
Kováts, N., Adrienn, V., Katalin, F., Sainnokhoi, T. A., Zsófa, B., & Gábor, T. (2020). Seasonal differences in rural particulate matter ecotoxicity. Aerosol Science Engineering. https://doi.org/10.1007/s41810-020-00063-5
Kováts, N., & Horváth, E. (2016). Bioluminescence-based assays for assessing eco- and genotoxicity of airborne emissions. Luminescence, 31, 918–923. https://doi.org/10.1002/bio.3102
Krugly, E., Martuzevicius, D., Sidaraviciute, R., Ciuzas, D., Prasauskas, T., Kauneliene, V., & Kliucininkas, L. (2014). Characterization of particulate and vapor phase polycyclic aromatic hydrocarbons in indoor and outdoor air of primary schools. Atmospheric Environment, 82, 298–306. https://doi.org/10.1016/j.atmosenv.2013.10.042
Leech, J. A., Nelson, W. C., & Burnett, R. T. (2002). It’s about time: A comparison of Canadian and American time-activity patterns. Journal of Exposure Analysis and Environmental Epidemiology, 12, 427–432. https://doi.org/10.1038/sj.jea.7500244
Li, A., Schoonover, T. M., Zou, Q., Norlock, F., Conroy, L. M., Scheff, P. A., & Wadden, R. A. (2005). Polycyclic aromatic hydrocarbons in residential air of ten Chicago area homes: Concentrations and influencing factors. Atmospheric Environment, 39(19), 3491–3501. https://doi.org/10.1016/j.atmosenv.2005.02.029
Li, C. S., & Ro, Y. S. (2000). Indoor characteristics of polycyclic aromatic hydrocarbons in the urban atmosphere of Taipei. Atmospheric Environment, 34(4), 611–620. https://doi.org/10.1016/S1352-2310(99)00171-5
Li, L., Yang, A., & He, X. (2020). Indoor air pollution from solid fuels and hypertension: A systematic review and meta-analysis. Environmental Pollution, 259, 113914. https://doi.org/10.1016/j.envpol.2020.113914
Li, Y., Yang, L., Chen, X., Gao, Y., Jiang, P., Zhang, J., ... Wang, W. (2017). PM2.5-bound PAHs in indoor and outdoor of hotels in urban and suburban of Jinan, China: Concentrations, sources, and health risk impacts. Aerosol and Air Quality Research, 17(10), 2463–2473. https://doi.org/10.4209/aaqr.2017.08.0286
Lim, M., Myagmarchuluun, S., & Ban, H. (2018). Characteristics of indoor PM2.5 concentration in gers using coal stoves in ulaanbaatar, Mongolia. International Journal of Environment Research Public Health, 15(11). https://doi.org/10.3390/ijerph15112524
Lu, H., Amagai, T., & Ohura, T. (2011). Comparison of polycyclic aromatic hydrocarbon pollution in Chinese and Japanese residential air. Journal of Environmental Sciences, 23(9), 1512–1517. https://doi.org/10.1016/S1001-0742(10)60589-X
Lu, H., Zhu, L., & Chen, S. (2008). Pollution level, phase distribution and health risk of polycyclic aromatic hydrocarbons in indoor air at public places of Hangzhou, China. Environmental Pollution, 152, 569–575. https://doi.org/10.1016/j.envpol.2007.07.005
Ma, W. L., Li, Y. F., & Qi, H. (2010). Seasonal variations of sources of polycyclic aromatic hydrocarbons (PAHs) to a northeastern urban city, China. Chemosphere, 79, 441–447. https://doi.org/10.1016/j.chemosphere.2010.01.048
Masih, J., Singhvi, R., Kumar, K., Jain, V. K., & Taneja, A. (2012). Seasonal variation and sources of polycyclic aromatic hydrocarbons (PAHs) in indoor and outdoor air in a semi arid tract of northern India. Aerosol and Air Quality Research, 12(4), 515–525. https://doi.org/10.4209/aaqr.2011.11.0192
Mohammed, M. O., Song, W. W., Ma, Y. L., Liu, L. Y., Ma, W. L., Li, W. L., & Khan, A. U. (2016). Distribution patterns, infiltration and health risk assessment of PM2.5-bound PAHs in indoor and outdoor air in cold zone. Chemosphere, 155, 70–85. https://doi.org/10.1016/j.chemosphere.2016.04.023
Mongolian Agency for Standardization and Measurement (MASM). (2008). Air quality standard MNS 4585/2007 [in Mongolian]. http://www.ub-air.info/ubair/about/air-quality-standard.html. Last accessed 4 April 2022.
Mumford, J. L., Helmes, C. T., & Lee, X. (1990). Mouse skin tumorigemicity studies of indoor coil and wood combustion emissioins from homes of Xuan Wei, China with high lung cancer mortality. Carcinogenesis, 11, 397–403.
Nagy, A. S., & Szabó, J. (2019). Characterization of PM2.5-bound polycyclic aromatic hydrocarbons in the ambient air of Győr, Hungary. Polycyclic Aromatic Compounds, 39, 332–345. https://doi.org/10.1080/10406638.2017.1326950
Ohura, T., Amagai, T., Fusaya, M., & Matsushita, H. (2004). Polycyclic aromatic hydrocarbons in indoor and outdoor environments and factors affecting their concentrations. Environmental Science and Technology, 38, 77–83. https://doi.org/10.1021/es030512o
Ohura, T., Noda, T., Amagai, T., & Fusaya, M. (2005). Prediction of personal exposure to PM2.5 and carcinogenic polycyclic aromatic hydrocarbons by their concentrations in residential microenvironments. Environmental Science and Technology, 39, 5592–5599. https://doi.org/10.1021/es050571x
Ortega-García, J. A., López-Hernández, F. A., Cárceles-Álvarez, A., Fuster-Soler, J. L., Sotomayor, D. I., & Ramis, R. (2017). Childhood cancer in small geographical areas and proximity to air-polluting industries. Environmental Research, 156, 63–73. https://doi.org/10.1016/j.envres.2017.03.009
Pandey, P., Patel, D. K., & Khan, A. H. (2013). Temporal distribution of fine particulates (PM 2.5, PM 10), potentially toxic metals, PAHs and Metal-bound carcinogenic risk in the population of Lucknow City, India. Journal Environment Science Health - Part A Toxic/hazardous Substance Environment Engineering, 48, 730–745. https://doi.org/10.1080/10934529.2013.744613
Pant, P., Shi, Z., Pope, F. D., & Harrison, R. M. (2017). Characterization of traffic-related particulate matter emissions in a road tunnel in Birmingham, UK: Trace metals and organic molecular markers. Aerosol and Air Quality Research, 17, 117–130. https://doi.org/10.4209/aaqr.2016.01.0040
Po, J., Fitzgerald, J., & Carlsten, C. (2011). Respiratory disease associated with solid biomass fuel exposure in rural women and children: Systematic review and meta-analysis. Thorax, 66, 232–239.
Prabjit, B., Enkhjargal, G., Chimedsuren, O., Bayarkhuu, L., Bolor, B., Gerel, N., Buyantushig, B., Jargalsaikhan, G., Tsogtbaatar, B., Craig, J., Patricia, A. J., Bruce, P. L., Tim, K. T., Scott, A. V., Glenys, M. W., Weiran, Y., Christopher, D. P., Patrick, J. P., Young, M. R., & Ryan, W. A. (2018). The effect of portable HEPA filter air cleaners on indoor PM2.5 concentrations and second hand tobacco smoke exposure among pregnant women in Ulaanbaatar, Mongolia: The UGAAR randomized controlled trial. Science of the Total Environment, 615, 1379–1389. https://doi.org/10.1016/j.scitotenv.2017.09.291
Rogula-Kozłowska, W., Kozielska, B., & Majewski, G. (2018). Submicron particle-bound polycyclic aromatic hydrocarbons in the Polish teaching rooms: Concentrations, origin and health hazard. Journal of Environmental Sciences (china), 64, 235–244. https://doi.org/10.1016/j.jes.2017.06.022
Secrest, M. H., Schauer, J. J., & Carter, E. M. (2016). The oxidative potential of PM2.5 exposures from indoor and outdoor sources in rural China. Science of the Total Environment, 571, 1477–1489. https://doi.org/10.1016/j.scitotenv.2016.06.231
Simoni, M., Scognamiglio, A., & Carrozzi, L. (2004). Indoor exposures and acute respiratory effects in two general population samples from a rural and an urban area in Italy. Journal of Exposure Analysis and Environmental Epidemiology. https://doi.org/10.1038/sj.jea.7500368
So, Y., Lee, N., & Kim, S. (2019). Characteristics of lifestyle and living environment of Ger District Residents in Ulaanbaatar, Mongolia. Korean Journal Public Health, 55, 12–21. https://doi.org/10.17262/kjph.2018.12.55.2.12
Sojobi, A. O., & Liew, K. M. (2022). Multi-objective optimization of high performance bio-inspired prefabricated composites for sustainable and resilient construction. Composite Structures, 279, 114732. https://doi.org/10.1016/j.compstruct.2021.114732
Sojobi, A. O., & Zayed, T. (2022). Impact of sewer overflow on public health: A comprehensive scientometric and systematic review. Environmental Research, 203, 111609. https://doi.org/10.1016/j.envres.2021.111609
Sonomdagva, C., Byambatseren, C., & Batdelger, B. (2017). Assessment of air pollution of settlement areas in Ulaanbaatar city, Mongolia. IOP Conf Ser Earth Environ Sci. https://doi.org/10.1088/1755-1315/67/1/012029
Triolo, L., Binazzi, A., & Cagnetti, P. (2008). Air pollution impact assessment on agroecosystem and human health characterisation in the area surrounding the industrial settlement of Milazzo (Italy): A multidisciplinary approach. Environmental Monitoring and Assessment, 140, 191–209. https://doi.org/10.1007/s10661-007-9859-z
UNICEF. (2018). Mongolia’s air pollution crisis: A call to action to protect children’s health.
USEPA. (1992). Health effects assessment summary tables. U.S. EPA.
USEPA. (2005). Supplemental guidance for assessing susceptibility from early-life exposure to carcinogens. In Risk assessment forum. Washington, DC: US Environmental Protection Agency.
Valavanidis, A., Fiotakis, K., & Vlahogianni, T. (2006). Characterization of atmospheric particulates, particle-bound transition metals and polycyclic aromatic hydrocarbons of urban air in the centre of Athens (Greece). Chemosphere, 65, 760–768. https://doi.org/10.1016/j.chemosphere.2006.03.052
Vardoulakis, S., Giagloglou, E., & Steinle, S. (2020). Indoor exposure to selected air pollutants in the home environment: A systematic review. International Journal of Environmental Research and Public Health, 17, 1–24. https://doi.org/10.3390/ijerph17238972
Wang, B., Li, Y., Tang, Z., Cai, N., Zhang, N., & Liu, J. (2021). The heavy metals in indoor and outdoor PM2.5 from coal-fired and non-coal-fired area. Urban Climate, 40, 101000. https://doi.org/10.1016/j.uclim.2021.101000
Wang, G., Zhao, J., Jiang, R., & Song, W. (2015). Rat lung response to ozone and fine particulate matter (PM2.5) exposures. Environmental Toxicology, 30(3), 343–356. https://doi.org/10.1002/tox.21912
World Air Quality Report (WIAQ). (2020). Region & city PM2.5 ranking. pp. 1–41. Available at: https://www.iqair.com/world-most-polluted-cities/world-air-quality-report-2020-en.pdf
World Bank. (2013). Mongolia: heating stove market trends in poor, peri-urban ger areas of Ulaanbaatar and selected markets outside Ulaanbaatar. 1–96. http://documents.worldbank.org/curated/en/2013/02/19403129/mongolia-heating-stove
World Health Organization (WHO). (2021). Ambient (outdoor) air pollution 2021. Available from: https://www.who.int/news-room/fact-sheets/detail/ambient-(outdoor)-air-quality-and-health. Last accessed on 31 May 2022.
Wu, F., Liu, X., Wang, W., Man, Y. B., Chan, C. Y., Liu, W., & Tao, S. W. (2015). Characterization of particulate-bound PAHs in rural households using different types of domestic energy in Henan Province, China. Science of the Total Environment, 536, 840–846. https://doi.org/10.1016/j.scitotenv.2015.07.101
Yunker, M. B., Macdonald, R. W., & Vingarzan, R. (2002). PAHs in the Fraser River basin: A critical appraisal of PAH ratios as indicators of PAH source and composition. Organic Geochemistry, 33, 489–515.
Yury, B., Zhang, Z., & Ding, Y. (2018). Distribution, inhalation and health risk of PM2.5 related PAHs in indoor environments. Ecotoxicology and Environmental Safety, 164, 409–415. https://doi.org/10.1016/j.ecoenv.2018.08.044
Zhao, H., Li, W., & Gao, Y. (2014). Exposure to particular matter increases susceptibility to respiratory Staphylococcus aureus infection in rats via reducing pulmonary natural killer cells. Toxicology, 325, 180–188. https://doi.org/10.1016/j.tox.2014.09.006
Zhu, L., Lu, H., Chen, S., & Amagai, T. (2009). Pollution level, phase distribution and source analysis of polycyclic aromatic hydrocarbons in residential air in Hangzhou, China. Journal of Hazardous Materials, 162, 1165–1170. https://doi.org/10.1016/j.jhazmat.2008.05.150
Acknowledgements
Financial support was provided by the BIONANO_GINOP-2.3.2-15-2016-00017 project, open access funding was provided by University of Pannonia (PE). Aerosol samples were kindly provided by research groups of school of Public Health, Mongolian National University of Medical Sciences and Department of non-infectious Diseases, School of Veterinary Medicine. Many thanks to the ELGOSCAR-2000 Environmental Technology and Water Management Ltd. (Head Office: 164 Soroksári u. H-1095 Budapest, Laboratory: H-8184 Balatonfűzfő) for analytical measurements.
Funding
Open access funding provided by University of Pannonia. The work was supported by the BIONANO_GINOP-2.3.2–15-2016–00017 project.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Ethics approval
Not relevant.
Consent to participate
Not relevant.
Consent for publication
Not relevant.
Conflict of interest
The authors declare no conflict of interest.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Highlights
• Concentration of PAHs was studied in indoor PM2.5 samples in 10 non-smoker households in Ulaanbaatar.
• Total concentration of PAHs varied in a relatively wide range, maximum value was 175.7 ng m−3.
• Incremental lifetime cancer risk for children and adult in all households except 2 households exceeded guideline level.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Sainnokhoi, TA., Kováts, N., Gelencsér, A. et al. Characteristics of particle-bound polycyclic aromatic hydrocarbons (PAHs) in indoor PM2.5 of households in the Southwest part of Ulaanbaatar capital, Mongolia. Environ Monit Assess 194, 665 (2022). https://doi.org/10.1007/s10661-022-10297-0
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s10661-022-10297-0