Abstract
Exposure to particulate matter (PM) can be considered as a factor affecting human health. The aim of this study was to investigate the concentration of PM2.5 and heavy metals and their influence on survival of A549 human lung cells in exposure to PM2.5 breathing air of Ahvaz city. In order to assess the levels of PM2.5 and heavy metals, air samples were collected from 14 sampling stations positioned across Ahvaz city during both winter and summer seasons. The concentration of heavy metals was determined using ICP OES. Next, the MTT assay [3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide] was employed to ascertain the survival rate of A549 cells. The findings from this research demonstrated that average PM2.5 of the study period was (149.5 μg/m3). Also, the average concentration of PM2.5 in the urban area in winter and summer was (153.3- and 106.9 μg/m3) and in the industrial area this parameter was (191.6 and 158.3 μg/m3). The average concentration of metals (ng/m3) of urban areas against industrial, Al (493 vs. 485), Fe (536 vs. 612), Cu (198 vs. 212), Ni (128 vs. 129), Cr (48.5 vs. 54), Cd (118 vs. 124), Mn (120 vs. 119), As (51 vs. 67), Hg (37 vs. 50), Zn (302 vs. 332) and Pb (266 vs. 351) were obtained. The results of the MTT assay showed that the highest percentage of cell survival according to the exposure concentration was 25 > 50 > 100 > 200. Also, the lowest percentage of survival (58.8%) was observed in the winter season and in industrial areas with a concentration of 200 μg/ml. The carcinogenic risk assessment of heavy metals indicated that except for Cr, whose carcinogenicity was 1.32E−03, other metals were in the safe range (10–4–10–6) for human health. The high concentration of PM2.5 and heavy metals can increase respiratory and cardiovascular diseases and reduce the public health level of Ahvaz citizens.
Similar content being viewed by others
Introduction
PM2.5, which refers to fine particulate matter with an aerodynamic diameter less than 2.5 μm, is recognized as a prominent environmental hazard1,2,3,4,5; resulting in approximately 4.2 million deaths in 2019, globally2,6. There is a correlation between PM2.5 and elevated occurrences of respiratory illnesses such as asthma, bronchitis, chronic obstructive pulmonary disease (COPD), and lung cancer7,8,9, cardiovascular diseases and mortality have been proven over the recent years4,10,11. Of particular interest is the fact that 99% of the global population inhales PM2.5 levels that surpass the Air Quality Guideline set by the World Health Organization (5 µg m−3)1,12. Although PM2.5 constitutes a small percentage of suspended particles3, large surface area13,14, absorption of various chemicals2,14, the ability to penetrate into the lower parts of the lungs8,15,16,17,18 and disrupt the gas exchange makes PM2.5 to cause major health and respiratory-related disorders8,13,18. PM2.5 enter the atmosphere following natural and man-made activities2,19,20. According to the source, location, production time and atmospheric conditions, PM2.5 have different chemical structure with different health effects10,15,19,21. Heavy metals (HMs) and polycyclic aromatic hydrocarbons (PAHs) are amongst the most important chemical components bounded to PM2.53,15,22, which has the ability to deeply penetrate into the lungs and bloodstream21,23. These compounds can lead to DNA damage, cell death and genotoxicity15,16. HMs accumulate in various fat tissues; these compounds difficult to break down have a serious impact on human health, causing cancer after reaching a certain dose23. A549 pulmonary epithelial cell line plays an vital role in protecting other body cells due to exposure to particles and surfactant secretion, stimulation of the immune system and identification the pathogens and warning to leukocyte cells24,25,26. A549 cells are extensively utilized in toxicological research to investigate the impact of particles on the human body within an in-vitro setting4,27.
MTT assay is a colorimetric method used to survey the cell survival and cytotoxic effects of chemical compounds influencing on cells following exposure to particles28,29. Although a growing number of studies have used this approach/method to investigate the effects of PM2.5 on cell survival, results have been mixed around the world and thus the overall evidence remains inconclusive. For instance, Perrone et al.30 conducted a study to examine the impact of PM1 and PM2.5 present in the ambient air of Milan during both winter and summer seasons on the A549 cell line. The authors reported that cell survival percentage in the Winter was higher than those in summer. Furthermore, Chen et al.31 conducted a study to assess the toxicity of PM2.5 present in the ambient air of Nanjing, China during winter and summer. Their findings revealed that PM2.5 particles during the winter season exhibited a higher level of toxicity compared to those observed during the summer season.
Within this framework, the present study represents a pioneering effort aimed at conducting a comprehensive examination of the impacts of ambient PM2.5 in Ahvaz, which is recognized as one of the most heavily polluted cities32.
To the best of our knowledge, this study, for the first time investigate the concentration, spatial distribution, seasonal changes of PM2.5 and heavy metals, the carcinogenic and non-carcinogenic risk of heavy metals bounded PM2.5 and the survival rate of A549 human lung cells contacted to the PM2.5 in all areas of Ahvaz city as the mega city considering land use (urban and industrial). Furthermore, the additional aims of present research were: (1) to assess the concentration and spatial distribution of PM2.5 and heavy metals associated with PM2.5 during both the summer and winter seasons; (2) to conduct a human risk assessment of exposure to heavy metals, and 3) to analyze the toxicity of PM2.5 using the A549 human lung cell line.
Materials and methods
Study area and sampling station
The sampling sites were selected in Ahvaz city, located at 31.3183° N, 48.6706° E longitude and latitude, respectively with elevation of 12 m above the sea level in southwest of Iran. Ahvaz, with a population of around 1.5 million, is recognized as one of the seven major cities in Iran. Based on meteorological records, Ahvaz experiences its coldest months, with an average temperature of 12.4 °C, in January and February, while July and August are the hottest months with an average temperature of 38.6 °C. The average annual rainfall is reported to be 213 mm. Ahvaz city is widely recognized as one of the highly polluted urban areas in both Iran and the world, primarily attributed to factors such as heavy traffic, extensive reliance on fossil fuels, and the presence of numerous industrial activities, including power plants, steel, asphalt, carbon block and pipe manufacturing factories, as well as numerous petrochemical industries and refineries. According to World Health Organization (WHO), Ahvaz city was the most polluted city in the world in terms of ambient PM10 in 201132. In this study, 14 stations including 8 urban stations (US1 to US8) and 6 industrial stations (IS1 to IS6) were sampled in two summer and winter seasons. The stations were chosen to be evenly distributed throughout the city. The sampling was done at a height of 3 m from the ground. Of note, the location of sampling station for urban (stations far away from main streets with heavy traffic and near residential areas and industrial area) and industrial area (stations located in the vicinity of a source or industrial area) were selected according to guidelines33. Figure 1 shows the study area and sampling stations.
Sampling procedure
During the winter of 2020 and summer of 2021, this research was undertaken in Ahvaz, focusing on two distinct areas: industrial sites comprising of six stations and urban sites consisting of eight stations. A total of 28 samples were gathered across the two seasons, encompassing both winter and summer. Sampling of PM2.5 followed the guidelines outlined in EPA TO/13A, employing a peripheral pump (Leland Legacy (SKC)) coupled with a personal modular impactor (PMI2.5) set at a flow rate of 5 L/min. This sampling process spanned a duration of 24 h and utilized a 37 mm diameter fiberglass filter with a pore size of 1 µm. Throughout the sampling period, temperature and pressure measurements were documented using a Lutron model PHB 318 thermometer. Additionally, relative humidity, precipitation, cloud cover, and wind speed data were obtained from the Iran Meteorological Organization (IMO). It is important to note that before and after the sampling, all devices and equipment used were calibrated. To determine the PM2.5 concentrations, fiberglass filters were weighted before and after sampling using a RADWAG digital scale (AS 220.R2) with an accuracy of 0.0001 and placed in a desiccator (temperature 22–24 °C and relative humidity of 35–45%) for 24 h. The flow rate of the pump was measured using a rotameter both at the start and conclusion of the sampling process, allowing for the calculation of the average flow rate. Subsequently, the PM2.5 concentration was determined by subtracting the secondary weight from the primary weight of the filters, employing the formula provided below34.
where CPM2.5 is the concentration of PM2.5 (µg/m3), Wf and Wi are the filter weight at the end and start of sampling (gr), and V denotes the sampling air volume (m3).
PM2.5 extraction
To obtain particles for in vitro exposure, filters collected from various land uses were transferred into 15-mL Falcon tubes. Subsequently, 5 mL of deionized water was added to the Falcon tubes, which were then subjected to a 30-min ultrasonic bath. This process was repeated three times35. At this stage, the filters were separated from the Falcon tubes and the suspension of particles was transferred to the freeze dryer under vacuum conditions in order to remove the water for 24 h at − 40 °C. Then, the prepared samples were stored at − 20 °C until cell exposure experiments. In this study, according to the season (summer and winter) and the land uses (urban and industrial), four types of PM2.5 extractions were obtained.
Cell culture, PM2.5 exposure and cell survival percentage
For the purpose of conducting cell culture experiments in this study, the A549 human lung epithelial cell line was obtained from the National Cell Bank of Iran (NCBI) at the Pasteur Institute. A549 cells were cultivated in a Dulbecco's modified Eagle's medium (DMEM) (Ana Cell, Iran) culture medium supplemented with 1% penicillin/streptomycin, and 10% fetal bovine serum (FBS). The cell culture was maintained in an incubator set at 37 °C, 95% humidity, and 5% CO2. MTT (Sigma-Aldrich, USA) colorimetric assay was used to determine cell survival. The MTT reagent was prepared at 5 mg/mL in phosphate buffered saline (PBS). After several times of cell culture and reaching exponential growth conditions and when 80% of the flask space was filled (80% confluency), A549 cells were trypsinized and counted with Neobar slides. Then, 100 μl cell suspension with a concentration of 2 × 104 was cultured in each well of 96- well flat-bottomed plates. After 24 h (sticking the cells to the bottom of the plate), the cells of each well were exposed to 100 µL of four types of PM2.5 extraction in different concentrations (25, 50, 100 and 200 µg/ml) for 24 and 48 h. The experiment was conducted in triplicate under varying conditions. Following exposure periods of 24 and 48 h, the cells were rinsed with Phosphate-buffered saline (PBS). Subsequently, 10 μl of MTT and 90 μl of culture medium were introduced into each well, and the plate was incubated at 37 °C with 5% CO2 for 4 h. The supernatant was then discarded, and 100 μl of dimethyl sulfoxide (DMSO) was added to the wells. All samples were performed in triplicate. The plate was then gently shaken at 250 rpm at 4 °C for 30 min in a dark setting until the crystals were fully dissolved. The absorbance of each well was assessed using an ELISA device (BIOHIT PLC, Helsinki, Finland) at a wavelength of 570 nm. The obtained data were then compared to the control group, which represented 100% viability, and the results were reported according to the following formula35,36.
where I = Absorbance of tetrazolium salt solution in DMSO containing cell exposed with PM sample, I0 = Absorbance of tetrazolium salt solution in DMSO containing cells without PM sample.
Heavy metals measurement
The concentration of 11 heavy metals bounded with PM2.5 (Cu, Zn, Hg, As, Mn, Cd, Cr, Ni, Cu, Fe and Al) was determined using an ICP OES (Optima 8000, PerkinElmer model, USA). The ideal operational parameters were as follows: generator power set at 1.5 kW, generator frequency at 40 MHz, plasma gas flow rate of 8 L per minute, and pump speed adjusted to 1 ml per minute. To quantify the concentration of heavy metals associated with PM2.5, half of the filters were fragmented into small segments and deposited into a Teflon container. Then, the combination of 3 mL HNO3 (65–68%) and 1 ml hydrochloride (36–38%) was added to the filters and were digested for 2 h in an ultrasonic water bath at a temperature of 90 °C37,38. In order to remove acids, the digested solution was dried at 90 to 100 °C under a hood. Then, HNO3 and ultrapure water were added in a ratio of 1:9 to the samples and shaken for 15 min. The solution was passed through a syringe head filter featuring a pore size of 2.5 µm for filtration. Subsequently, the samples were diluted with ultrapure water to achieve a final volume of 25 ml and stored at a temperature of 4 °C until injection39. Calibration curves were graphed using 6 dots with valid high purity standards purchased from Merck, Germany before injecting main samples. Also, at the same time, a blank fiberglass filter was prepared as a control sample and the concentration of heavy metal was measured for this filter. In order to control the validity of the test, the method of increasing the standard and calculating its recovery percentage was used. Also, by repeating the test for some stations (triplicate) the accuracy of the tests was ensured. In addition, after injecting a number of samples (usually 10 samples), one sample with a certain concentration was injected, if it was within the acceptable range, the rest of the samples were injected.
Human risk assessment
Human risk analysis is a methodical approach that involves evaluating, managing, and establishing the correlation between environmental pollutants and their impact on human health40. In this study, the risk assessment model for human health, as provided by the United States Environmental Protection Agency (EPA)41,42, was employed to evaluate the potential health effects, both carcinogenic and non-carcinogenic, resulting from exposure to heavy metals present in the ambient air of Ahvaz city. For this aim, firstly exposure concentration (EC) were calculated using the following equation:
where C indicates pollutant concentration (µg/m3), ET is exposure time (h/day), EF is exposure frequency (days/ year), ED represents the duration of exposure (years) which is 2 years for infants (0–2 years), 14 years for children (2–15 years), and 55 years for adults (16–70 years). CF is conversion factor (mg/μg), and AT is averaging time (h).
For carcinogenic effects, lifetime cancer risk (LTCR) was calculated as the following Equation43,44:
where UR is unit risk (m3/μg).
Non-cancer risk is quantified by a hazard quotient (HQ) which is the ratio between EC and the inhalation reference concentration (RfC, mg/m3) as shown in the following equation:
When the value of HQ exceeds 1, it indicates the presence of potential risks to human health. Conversely, if HQ is equal to or less than 1, it signifies that no potential health effects are anticipated45,46. Table. 1 presents the parameters to calculate the carcinogenic and non-carcinogenic risk of heavy metals.
Spatial distribution of heavy metals
During the study period, GIS software and the inverse distance weight (IDW) technique were employed to ascertain the spatial dispersion of heavy metals associated with PM2.5 within Ahvaz city43,50.
Statistical analysis
To examine the variation in cell survival rates among different concentrations, seasons, and areas with distinct uses, a one-way ANOVA test was conducted. Statistical significance was determined using a threshold of P < 0.05, indicating significance, while a more stringent threshold of P < 0.01 denoted high significance.
Ethical approval
The study was approved by ethic committee of Iran University of Medical Sciences with ethical code of IR.IUMS.REC.1400.486.
Results and discussion
PM2.5 concentration
In both winter and summer seasons, the levels of PM2.5 were measured in Ahvaz city, considering both urban and industrial land uses. This measurement was carried out utilizing a peripheral pump known as Leland Legacy (SKC). Table 2 summarizes the PM2.5 concentration in different sampling point throughout the Ahvaz city in two seasons (winter and summer). As depicted in Table 2, the mean PM2.5 concentration during the winter season was recorded as 153.34 μg/m3 in urban areas and 191.65 μg/m3 in industrial areas. On the other hand, the average PM2.5 concentration during the summer season in these respective areas was 106.97 μg/m3 and 158.82 μg/m3. In addition, the findings revealed that the average PM2.5 concentration in the industrial region exceeded that of the urban area. Overall, the order of average PM 2.5 concentration was as follows: urban summer < urban winter < industrial summer < industrial winter. These results indicated that in the winter season, due to the decrease in temperature, the increase in the use of fossil fuels, the burning of biomass, the decrease in wind speed, and the creation of inversion conditions, the concentration of particles is higher than that in the summer season51. In addition, in winter, the use of fuels such as diesel and coal by industries can be one of the reasons for high particles in these areas51,52,53. Also, according to the Table 2, it can be seen that the highest average concentration was 273.17 µg/m3 belonging to station 1 (IS1) in industrial landuse, which is close to the carbon block factory and high traffic. However, the lowest average concentration of PM2.5 was 46.29 µg/m3 in station 5 (US5), which is located in urban area. Furthermore, the results of this study showed that all 14 monitored stations had concentrations higher than the World Health Organization's Air Quality Guideline (5 µg/m3). While there was a distinction in the PM2.5 concentration between the summer and winter seasons, no noteworthy variances were detected between the PM2.5 levels in urban and industrial areas. Our results are consistent with the previously conducted studies. In a study conducted by Jahid et al. (2021) in Mahshahr, Iran, it was demonstrated that the concentration of PM2.5 was elevated during the winter season and at the industrial station compared to other seasons52. They reported that Petrochemical industries played an important role in the high concentration of particles. In a study conducted by Kermani et al. in Pakdasht and Varamin, Iran, it was revealed that the concentration of PM2.5 during the winter season (68.39 μg/m3) was higher compared to the summer seasons. This increase in PM2.5 levels was attributed to the utilization of fossil fuels, lower temperatures, and the occurrence of inversions in the region54. Also, Rezaei Rahimi et al. study in 2022 in a number of vehicle parking lots in Qom city showed that the concentration of PM2.5, PM10 suspended particles was higher than the guidelines of the World Health Organization. And these concentrations were higher in the fall season (due to the cold weather) than in the summer season55.
Effect of PM2.5 on A549 cells and cell viability
In the present study, the effects of PM2.5 measured in ambient air of Ahvaz in terms of landuses (Urban and Industrial) on cell survival was in two sampling seasons (hot and cold). In order to achieve this objective, the viability rate of A549 cells was assessed and compared with the control group following exposure to various concentrations of PM2.5 (25, 50, 100, and 200 μg/ml) for durations of 24 and 48 h. Figure 2. shows the cell survival following the exposure to different PM2.5 concentration in terms of landuses in two seasons. As can be seen in the Fig. 2, the survival percentage of A549 cells experienced a decreasing trend with increasing the PM2.5 from 25 to 200 µg/ml. According to Fig. 2(a–d), the highest cell survival in the summer season (%97.8) is related to the concentration of 25 μg/ml with an exposure time of 24 h in the urban area (a) and the lowest cell survival (%66.3) belonged to concentration of 200 μg/ml with an exposure time of 48 in the industrial area (d). According to one-way ANOVA statistical analysis, there was no significant differences between cell survival percentage when exposure to the concentration of 25 μg/ml and control group (P value > 0.05). In addition, in the winter season (See Fig. 2E–H), the highest cell survival (%94.3) belonged to concentration 25 μg/ml with exposure time of 24 h in urban area (e) and the lowest survival (% 58.8) was related to concentration 200 with exposure time of 48 h in industrial area (h). Based on our results, it can be stated that ambient PM had been more toxic in winter and industrial areas compared to those in summer and urban areas. The most important reason for the further reduction of cell survival in the winter can be related to the use of fuels such as diesel and coal in the winter, which can produce chemical compounds with higher toxicity52. Multiple prior studies have suggested that as the concentration of PM2.5 rises and the duration of exposure increases, the rate of cell survival tends to decline56,57,58,59. Moreover, previously conducted studies around the world showed that ambient PM in summer, with the same concentration and usage, have a lower toxic effects on A549 compared to PM2.5 in winter season20,29,31,60.
Heavy metals
In this study, elev shownen heavy metals including (Al, Fe, Cu, Ni, Cr, Cd, Mn, As, Zn, Hg and Pb) were evaluated (Fig. 3). As shown in Fig. 3, the highest average concentration belonged to Fe (721.7 ng/m3) in winter season and industrial area, w shownhile the lowest average concentration belonged to Hg (37.19 ng/m3) in summer season and urban area. In addition, the highest average total concentration of all metals belonged to winter season and the industrial area (2742.19 ng/m3). Nonetheless, the summer season and urban area exhibited the lowest mean total concentration of all metals (2130.17 ng/m3). On the other hand, the order of average concentration of heavy metals from the highest to the lowest were as follows: Fe (568.69 ng/m3), Al (462.595 ng/m3), Zn (316.545 ng/m3), Pb (303.925 ng/m3), Cu (203.41 ng/m3), Ni (128.675 ng/m3), Cd (121.45 ng/m3), Mn (119.665 ng/m3), As (58.47 ng/m3), Cr (50.79 ng/m3), and Hg (44.15 ng/m3). The results indicated that Fe, Al and Zn had the highest concentrations due to their presence in the earth's crust61. In the city of Ahvaz, the presence of heavy metals can be due to the high concentration of suspended particles of internal and external origin, as well as the suspension of soil and dust caused by vehicles on the roads51,62. Conversely, the presence of industrial facilities such as steel plants, power stations, refineries, and petrochemical plants significantly contributes to the escalation of heavy metal concentrations within this city63.The high concentration of Pb in this study can be caused by different industries as well as the low quality of fuel consumed by cars51. The higher concentration of heavy metals in the winter season can be due to the phenomenon of inversion and more consumption of fossil fuels by vehicles and factories. According to the findings of Heydari Farsani et al., the concentration of heavy metals in Ahvaz was found to be greater during the winter season compared to the autumn season. The most possible reason behind this are attributed to decrease in temperature, more fuel consumption by vehicles and industries, and the phenomenon of inversion. And the highest concentration of Al metal was expressed as 34.32 ng/m364. Due to reasons such as high traffic, the establishment of many industries (especially oil and petrochemical) and the proximity to the deserts of Iraq and Arabia, the concentration of heavy metals in Ahvaz city was higher than the study (Ahmed et al.) in Behbahan65.
Spatial distribution
In this study, GIS software was used to interpolate the measured pollutants to the entire area of Ahvaz city. As can be seen in Fig. 4, stations IS1 and IS6, which are located in industrial areas, had the highest average concentrations of PM2.5 (273.2 and 266.9 μg/m3) and heavy metals (359.9 and 373.2 ng/m3). This shows that the citizens near the stations IS1 and IS6 are facing more risks. These two stations have higher concentrations of PM2.5 and heavy metals than other stations due to their proximity to the power plant, the carbon block factory, and high vehicle traffic51,52,53. Two stations IS1 and IS6 are located near industries in addition to vehicle traffic, which are the main sources of heavy metal emissions in urban areas66. Hence, it is crucial to implement mitigation measures aimed at diminishing the presence of such pollutants in these areas.
Risk assessment
Table 3 summarizes the carcinogenic and non-carcinogenic risk of heavy metal measured in ambient air. As shown in Table 3, the LTCR value for all metals was as follows: Cr > Cd > Ni > As. The value of LTCR attributed to Cr in winter and summer as well as urban and industrial areas was higher than the background value (10–4). This study showed that the LTCR of chrome metal in the summer season in the urban area for infants is also higher than the background value. In addition, the highest LTCR value of Cr was found in industrial area and winter season For adults (1.97E−03). Also, according to the age groups, the highest risk of carcinogenesis was calculated for adults > children > infants respectively. Kawichai et al. Rayong, Thailand showed that the carcinogenic risk of chromium for adults and children was higher than 10–4, for infants between 10–4 and 10–6, and the carcinogenicity of other metals was within the safe range48. In addition to the earth's crust, human activities can also increase the concentration of Cr in breathing air. Processes such as wear and mechanical friction of vehicles and smoke from car exhausts can be factors of increasing Cr in the air of cities67. These results indicated that inhalation of Cr bound with PM2.5 can be carcinogenic for residents of Ahvaz city and especially those who live in the proximity of industrial areas. On the other hand, in case of other metals, the value of LTCR were within the recommended by USEPA (10–4 to 10–6), indicating a tolerable risk for the residents of Ahvaz. Moreover, the non-carcinogenic risk of the studied metals was as follows: Ni > Cd > As > Mn > Cr > Hg > Al. In this study, the HQ value for Cd, Ni and As in winter and summer and all three age groups were higher than one. In addition, the highest amount of HQ was obtained, respectively Cd (4.61), Ni (3.47) and As (1.88). These results show that inhalation of these metals can be a health risk for the residents of Ahvaz city. Wang, X., et al. (2018) reported that Pb for children and adults and arsenic metal for coconut had carcinogenic risk, and the total carcinogenic risk of metals for children and adults was 4.64 × 10–4 and 3.12 × 10–4 , respectively68. Li, et al. reported that the As (3.07), Mn (3.06) and Cd (1.2) have non-carcinogenic health effects above the safe limit (HQ = 1) and chromium metal for children 1.44. E 10–4 and adults 5.76E 10–4 was carcinogenic69. Sakunkoo et al. study was conducted in 2022 in four areas (academic, residential, industrial and agricultural) of Khon Kaen, Thailand to assess the risk of carcinogenicity of metals bonded with PM2.5. This study showed that industrial residents (especially children) have a higher risk of carcinogenesis than other areas due to the high concentration of PM2.5 and heavy metals70.
Conclusion
To the best of our knowledge, this study, for the first time investigate the concentration, spatial distribution, seasonal changes of PM2.5 and heavy metals, the carcinogenic and non-carcinogenic risk of heavy metals bounded PM2.5 and the survival rate of A549 human lung cells contacted to the PM2.5 in all areas of Ahvaz city as the mega city considering land use (urban and industrial). The results revealed that the level of PM2.5 and some heavy metals such as As, Ca, Cr and Mn were several times higher than the WHO guidelines. Considering that the concentration of PM2.5 and heavy metals was high in this study. Also because of the effects these pollutants can have on human health. It is expected that the health and environment trustees of Ahvaz city will consider appropriate management measures such as suitable fuel and increasing the quality of fuel consumed by vehicles and industries. The limitations could be considered for this study are: First, the concentration of heavy metals measured in this study was limited to PM2.5-bound values and other particles were not considered. Therefore, the concentration of heavy metals in the air of Ahvaz city can be higher than the measured values. Due to time and financial constraints, this study was conducted in Ahvaz city in two seasons, it is suggested to conduct similar studies in other cities of Khuzestan. Based on the findings of this study, it is necessary to implement management strategies and preventive measures to effectively regulate the levels of these pollutants in the city of Ahvaz.
Data availability
The data supporting the findings of this article is included within the article.
References
Hu, B. et al. Acute 1-NP exposure induces inflammatory responses through activating various inflammatory signaling pathways in mouse lungs and human A549 cells. Ecotoxicol. Environ. Saf. 189, 109977 (2020).
Soca-Chafre, G. et al. Airborne particulate matter upregulates expression of early and late adhesion molecules and their receptors in a lung adenocarcinoma cell line. Environ. Res. 198, 111242 (2021).
Wu, M., Jiang, Y., Liu, M., Shang, Y. & An, J. Amino-PAHs activated Nrf2/ARE anti-oxidative defense system and promoted inflammatory responses: The regulation of PI3K/Akt pathway. Toxicol. Res. 7(3), 465–472 (2018).
Wang, G. et al. Ambient fine particulate matter induce toxicity in lung epithelial-endothelial co-culture models. Toxicol. Lett. 301, 133–145 (2019).
Niu, X. et al. Cytotoxicity of PM2.5 vehicular emissions in the Shing Mun tunnel, Hong Kong. Environ. Pollut. 263, 114386 (2020).
Yue, W. et al. Exposure interval to ambient fine particulate matter (PM2.5) collected in Southwest China induced pulmonary damage through the Janus tyrosine protein kinase-2/signal transducer and activator of transcription-3 signaling pathway both in vivo and in vitro. J. Appl. Toxicol. 41(12), 2042–2054 (2021).
Fernando, I. S. et al. Beijing urban particulate matter-induced injury and inflammation in human lung epithelial cells and the protective effects of fucosterol from Sargassum binderi (Sonder ex J. Agardh). Environ. Res. 172, 150–158 (2019).
Wang, G., Zhang, X., Liu, X. & Zheng, J. Co-culture of human alveolar epithelial (A549) and macrophage (THP-1) cells to study the potential toxicity of ambient PM2.5: A comparison of growth under ALI and submerged conditions. Toxicol. Res. 9(5), 636–651 (2020).
Liu, Q., Baumgartner, J. & Schauer, J. J. Source apportionment of fine-particle, water-soluble organic nitrogen and its association with the inflammatory potential of lung epithelial cells. Environ. Sci. Technol. 53(16), 9845–9854 (2019).
Marchetti, S. et al. Seasonal variation in the biological effects of PM2.5 from greater Cairo. Int. J, Mol. Sci. 20(20), 4970 (2019).
Cheng, W. et al. Inhibition of inflammation-induced injury and cell migration by coelonin and militarine in PM2.5-exposed human lung alveolar epithelial A549 cells. Eur. J. Pharmacol. 896, 173931 (2021).
Faridi, S. et al. Health burden and economic loss attributable to ambient PM2.5 in Iran based on the ground and satellite data. Sci. Rep. 12(1), 1–12 (2022).
Zhang, S.-Y. et al. Metabolomics analysis reveals that benzo [a] pyrene, a component of PM2.5, promotes pulmonary injury by modifying lipid metabolism in a phospholipase A2-dependent manner in vivo and in vitro. Redox Biol. 13, 459–469 (2017).
Zhou, L. et al. MUC5B regulates the airway inflammation induced by atmospheric PM2.5 in rats and A549 cells. Ecotoxicol. Environ. Saf. 221, 112448 (2021).
Dou, C., Zhang, J. & Qi, C. Cooking oil fume-derived PM2.5 induces apoptosis in A549 cells and MAPK/NF-кB/STAT1 pathway activation. Environ. Sci. Pollut. Res. 25(10), 9940–9948 (2018).
Figliuzzi, M. et al. Copper-dependent biological effects of particulate matter produced by brake systems on lung alveolar cells. Arch. Toxicol. 94(9), 2965–2979 (2020).
Chen, X.-C. et al. Indoor, outdoor, and personal exposure to PM2.5 and their bioreactivity among healthy residents of Hong Kong. Environ. Res. 188, 109780 (2020).
Liu, C.-W. et al. PM2.5-induced oxidative stress increases intercellular adhesion molecule-1 expression in lung epithelial cells through the IL-6/AKT/STAT3/NF-κB-dependent pathway. Particle Fibre Toxicol. 15(1), 1–16 (2018).
Pang, Y. et al. In-vitro human lung cell injuries induced by urban PM2.5 during a severe air pollution episode: variations associated with particle components. Ecotoxicol. Environ. Saf. 206, 111406 (2020).
Rahmatinia, T. et al. The effect of PM2.5-related hazards on biomarkers of bronchial epithelial cells (A549) inflammation in Karaj and Fardis cities. Environ. Sci. Pollut. Res. 29(2), 2172–2182 (2022).
Chen, X.-C. et al. Toxicological effects of personal exposure to fine particles in adult residents of Hong Kong. Environ. Pollut. 275, 116633 (2021).
Rönkkö, T. J. et al. Emissions and atmospheric processes influence the chemical composition and toxicological properties of urban air particulate matter in Nanjing, China. Sci. Tot. Environ. 639, 1290–1310 (2018).
Vari, H. K. et al. Associations between land cover categories, gaseous PAH levels in ambient air and endocrine signaling predicted from gut bacterial metagenome of the elderly. Chemosphere 265, 128965 (2021).
Fabbrini, S. & Puetter, U. Integration without supranationalisation: studying the lead roles of the European Council and the Council in post-Lisbon EU politics. J. Eur. Integr. 38(5), 481–495 (2016).
Geiszt, M. et al. NAD (P) H oxidase 1, a product of differentiated colon epithelial cells, can partially replace glycoprotein 91phox in the regulated production of superoxide by phagocytes. J. Immunol. 171(1), 299–306 (2003).
Lieber, M., Todaro, G., Smith, B., Szakal, A. & Nelson-Rees, W. A continuous tumor-cell line from a human lung carcinoma with properties of type II alveolar epithelial cells. Int. J Cancer 17(1), 62–70 (1976).
Orona, N. S. et al. Direct and indirect air particle cytotoxicity in human alveolar epithelial cells. Toxicol. In Vitro 28(5), 796–802 (2014).
Dick, C. et al. Toxic and inflammatory effects of filters frequently used for the collection of airborne particulate matter. At. Environ. 34(16), 2587–2592 (2000).
Bandpi, A. M. et al. Characteristics and sources of water-soluble ionic associated with PM2.5 particles and cytotoxicity effects using MTT assay in Tehran, Iran. Urban Climate 32, 100612 (2020).
Perrone, M. G. et al. Seasonal variations in chemical composition and in vitro biological effects of fine PM from Milan. Chemosphere 78(11), 1368–1377 (2010).
Chen, Y. et al. Summer–winter differences of PM2.5 toxicity to human alveolar epithelial cells (A549) and the roles of transition metals. Ecotoxicol. Environ. Saf. 165, 505–509 (2018).
Goudie, A. S. Desert dust and human health disorders. Environ. Int. 63, 101–113 (2014).
Environment Mft. Good Practice Guide for Air Quality Monitoring and Data Management (2009).
Goudarzi, G., Shirmardi, M., Naimabadi, A., Ghadiri, A. & Sajedifar, J. Chemical and organic characteristics of PM2.5 particles and their in-vitro cytotoxic effects on lung cells: The Middle East dust storms in Ahvaz, Iran. Sci. Tot. Environ. 655, 434–445 (2019).
Wei, H. et al. The mechanisms for lung cancer risk of PM2.5: Induction of epithelial-mesenchymal transition and cancer stem cell properties in human non-small cell lung cancer cells. Environ. Toxicol. 32(11), 2341–2351 (2017).
Das, A., Habib, G., Vivekanandan, P. & Kumar, A. Reactive oxygen species production and inflammatory effects of ambient PM2.5-associated metals on human lung epithelial A549 cells “one year-long study”: The Delhi chapter. Chemosphere 262, 128305 (2021).
Hieu, N. T. & Lee, B.-K. 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 (2010).
Lodge, J. P. Methods of Air Sampling and Analysis (Routledge, 2017).
Faraji Ghasemi, F. et al. Levels and ecological and health risk assessment of PM2.5-bound heavy metals in the northern part of the Persian Gulf. Environ. Sci. Pollut. Res. 27(5), 5305–5313 (2020).
Abdulaziz, M., Alshehri, A., Badri, H., Summan, A. & Sayqal, A. Concentration level and health risk assessment of heavy metals in PM 2.5 in ambient air of Makkah City, Saudi Arabia. Pol. J. Environ. Stud. 31(5), 3991 (2022).
Emergency USEPAOo, Response R. Technology alternatives for the remediation of soils contaminated with As, Cd, Cr, Hg, and Pb: US Environmental Protection Agency, Office of Emergency and Remedial Response (1997).
Means, B. Risk-assessment guidance for superfund. Vol. 1. Human health evaluation manual. Part A. Interim report (Final). Environmental Protection Agency, Washington, DC (USA). Office of Solid Waste (1989).
Miri, M. et al. Investigation of outdoor BTEX: Concentration, variations, sources, spatial distribution, and risk assessment. Chemosphere 163, 601–609 (2016).
Hoseini, M. et al. Characterization and risk assessment of polycyclic aromatic hydrocarbons (PAHs) in urban atmospheric particulate of Tehran Iran. Environ. Sci. Pollut. Res. 23(2), 1820–1832 (2016).
Jan, R., Roy, R., Yadav, S. & Satsangi, P. G. Chemical fractionation and health risk assessment of particulate matter-bound metals in Pune, India. Environ. Geochem. Health 40(1), 255–270 (2018).
Gholamreza, G. et al. Correction to: Association between cancer risk and polycyclic aromatic hydrocarbons’ exposure in the ambient air of Ahvaz, southwest of Iran. Int. J. Biometeorol. 65(12), 2245 (2021).
Duan, X. et al. Seasonal variations, source apportionment, and health risk assessment of trace metals in PM2.5 in the typical industrial city of Changzhi, China. At. Pollut. Res. 12(1), 365–374 (2021).
Kawichai, S., Bootdee, S., Sillapapiromsuk, S. & Janta, R. Epidemiological study on health risk assessment of exposure to PM2.5-bound toxic metals in the industrial metropolitan of Rayong, Thailand. Sustainability 14(22), 15368 (2022).
Wu, Y. et al. Seasonal variations, source apportionment, and health risk assessment of heavy metals in PM2.5 in Ningbo, China. Aerosol Air Qual. Res. 19(9), 2083–2092 (2019).
Mojarrad, H. et al. Spatial trends, health risk assessment and ozone formation potential linked to BTEX. Hum. Ecol. Risk Assess. Int. J. 26(10), 2836–2857 (2020).
Goudarzi, G. et al. Health risk assessment on human exposed to heavy metals in the ambient air PM10 in Ahvaz, southwest Iran. Int. J. Biometeorol. 62(6), 1075–1083 (2018).
Jahedi, F. et al. Polycyclic aromatic hydrocarbons in PM1, PM2.5 and PM10 atmospheric particles: Identification, sources, temporal and spatial variations. J. Environ. Health Sci. Eng. 19(1), 851–866 (2021).
Goudarzi, G. et al. Assessment of incremental lifetime cancer risks of ambient air PM10-bound PAHs in oil-rich cities of Iran. J. Environ. Health Sci. Eng. 19(1), 319–330 (2021).
Kermani, M. et al. Extraction and determination of organic/inorganic pollutants in the ambient air of two cities located in metropolis of Tehran. Environ. Monit. Assess. 194(3), 1–20 (2022).
Rezaei Rahimi, N. et al. The links between microclimatic and particulate matter concentration in a multi-storey car parking: A case study Iran. J. Environ. Health Sci. Eng. 20(2), 775–783 (2022).
Mohseni Bandpi, A. et al. Water-soluble and organic extracts of ambient PM2.5 in Tehran air: Assessment of genotoxic effects on human lung epithelial cells (A549) by the Comet assay. Toxin Rev. 36(2), 116–124 (2017).
Dai, P. et al. The roles of Nrf2 and autophagy in modulating inflammation mediated by TLR4-NFκB in A549 cell exposed to layer house particulate matter 2.5 (PM2.5). Chemosphere 235, 1134–1145 (2019).
Liu, L. et al. MiR-146a regulates PM1-induced inflammation via NF-κB signaling pathway in BEAS-2B cells. Environ. Toxicol. 33(7), 743–751 (2018).
Shang, Y. et al. microRNA-146a-5p negatively modulates PM2.5 caused inflammation in THP-1 cells via autophagy process. Environ. Pollut. 268, 115961 (2021).
Zhang, S. et al. Biotoxic effects and gene expression regulation of urban PM2.5 in southwestern China. Sci. Tot. Environ. 753, 141774 (2021).
Hassanvand, M. S. et al. Characterization of PAHs and metals in indoor/outdoor PM10/PM2.5/PM1 in a retirement home and a school dormitory. Sci. Tot. Environ. 527, 100–110 (2015).
Lee, B.-K. & Dong, T. T. Toxicity and source assignment of polycyclic aromatic hydrocarbons in road dust from urban residential and industrial areas in a typical industrial city in Korea. J. Mater. Cycles Waste Manag. 13(1), 34–42 (2011).
Faridi, S. et al. Source apportionment, identification and characterization, and emission inventory of ambient particulate matter in 22 Eastern Mediterranean Region countries: A systematic review and recommendations for good practice. Environ. Pollut. 2022, 119889 (2022).
Heidari-Farsani, M. et al. The evaluation of heavy metals concentration related to PM10 in ambient air of Ahvaz city, Iran. J. Adv. Environ. Res. 1(2), 120–128 (2013).
Badeenezhad, A. et al. Investigating the relationship between central nervous system biomarkers and short-term exposure to PM10-bound metals during dust storms. At. Pollut. Res. 11(11), 2022–2029 (2020).
Liu, Y., Xing, J., Wang, S., Fu, X. & Zheng, H. Source-specific speciation profiles of PM2.5 for heavy metals and their anthropogenic emissions in China. Environ. Pollut. 239, 544–553 (2018).
Pant, P. & Harrison, R. M. Critical review of receptor modelling for particulate matter: A case study of India. At. Environ. 49, 1–12 (2012).
Wang, X. et al. Spatiotemporal characteristics and health risk assessment of heavy metals in PM2.5 in Zhejiang Province. Int. J. Environ. Res. Public Health 15(4), 583 (2018).
Li, Y. et al. Characteristics, sources and health risk assessment of toxic heavy metals in PM2.5 at a megacity of southwest China. Environ. Geochem. Health 38(2), 353–362 (2016).
Sakunkoo, P. et al. Human health risk assessment of PM2.5-bound heavy metal of anthropogenic sources in the Khon Kaen Province of Northeast Thailand. Heliyon 8(6), 09572 (2022).
Acknowledgements
The present study was adopted from Ph.D thesis of Babak Goodarzi at Iran University of Medical Sciences. The present project was financially funded by grant number 1400-1-2-20025 from Iran University of Medical Sciences.
Funding
This work was supported financially by the Iran University of Medical Science (No. 1400-1-2-20025).
Author information
Authors and Affiliations
Contributions
B.G.: experiment, software, writing, M.A.: study design, methodology, A.J.J.: Study design, data analysis, M.G.: Writing, reviewing, and editing; M.K.: Study, design reviewing, and editing, and software, M.A.A.: Study, design reviewing, and editing, and software, A.S.: study design, methodology.
Corresponding authors
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
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
Goodarzi, B., Azimi Mohammadabadi, M., Jafari, A.J. et al. Investigating PM2.5 toxicity in highly polluted urban and industrial areas in the Middle East: human health risk assessment and spatial distribution . Sci Rep 13, 17858 (2023). https://doi.org/10.1038/s41598-023-45052-z
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-023-45052-z