The Impact of Air Pollution on Pulmonary Diseases: A Case Study from Brasov County, Romania
Abstract
:1. Introduction
2. Materials and Methods
2.1. Study Data
2.2. Data and Methodology Used
- Understanding pollution sources; to achieve this analysis, we investigated the pollution inventory recorded by the Environment Pollution Agency of Brasov (APM) during 2016–2020. The objective of this activity is to identify the principal economic activity responsible for pollution in Brasov County and the prevalent pollutants that contribute to air quality reduction.
- Analysis of mortality/morbidity data; the objective of this analysis is to identify the mortality/morbidity caused by respiratory disease and its evolution.
- Analysis of the current status of principal air quality data and air quality index assessment. The analysis consists of (i) descriptive statistics to establish the frequency of occurrence for each pollutant and station; (ii) air index calculation based on daily, monthly, and annual data sets. For each daily value and pollutant is assigned a scale from “1”, excellent, to “6” severe with respect to the calculation grid [24]. The aggregated air quality index is calculated using the worst value of all pollutants used for each station.
- Analysis of clinical data of patients diagnosed with primary lung malignancies; the patient’s ages, sex, and domicile were quantified to identify a correlation between pollutants and histological forms of cancer. The diagnosed tissue specimens came from the thoracic Surgery Clinic of the Brasov Military Hospital’s surgery rooms and the Pneumoftiziology Clinic of the Respiratory Diseases Hospital Brasov. Thus, tumorectomies, lung specimens (lobes, segments), endobronchial biopsies, pleural fluids, aspirates, and bronchial lavages were diagnosed. The histopathological specimens were subjected to pathological processing techniques (fixation in 10% buffered formalin, dehydration, and paraffin impregnation by automatic processing, sectioning, staining of sections by hematoxylin-eosin stain. The examined liquids were centrifuged, the sediment being examined both directly and in Papanicolaou and Giemsa staining, and by inclusion in paraffin, in the form of a cytoblock prepared with neutral proteins. For histological confirmation of the microscopic diagnosis, immunohistochemistry was performed, using the panel of mom and polyclonal antibodies specific to primary lung malignancies (TTF1 clone SP141, Napsin A clone MRQ-60, anti-p40 clone BC28, Anti-Pan Keratin clone AE1/AE3/PCK26). Immunohistochemistry was performed automatically using Benchmark Ventana Gx equipment. The microscopic study was performed using a Zeiss Primo Star microscope and capturing images from the paper was performed using an AxioCam 105 color microscopy camera. The Pathology Department owns the medical equipment. To establish the post-surgical treatment, some specimens, depending on the tumor stage, were investigated by molecular biology techniques to develop the prognostic factors.
3. Results
3.1. Analysis of Pollution Sources
3.2. Analysis of SDR and Morbidity Data Sets
3.3. The Current Status of Principal Air Quality Data
3.4. Analysis of Clinical Data of Patients Diagnosed with Primary Histological Forms of Lung Malignancies
4. Discussion
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Conflicts of Interest
References
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Influenza | Pneumonia | Chronic Lower Respiratory Diseases | Asthma and Status Asthmaticus | Other Lower Respiratory Diseases | Other Diseases of the Respiratory System | |
---|---|---|---|---|---|---|
EU −27 1 | 1.0 | 24.3 | 34.2 | 1.2 | 33.0 | 22.0 |
Romania | 0.1 | 42.5 | 39.2 | 1.4 | 37.8 | 11.7 |
Station Indicative | Location | Type | Elevation [m] |
---|---|---|---|
BV1 | Calea Bucureşti Blvd. | traffic | 593 |
BV2 | Castanilor street | urban | 593 |
BV3 | Garii Blvd. | traffic | 593 |
BV4 | Sânpetru village | suburban | 560 |
BV5 | Vlahuta street | industrial | 593 |
EMI | Fundata village | regional | 1360 |
NFR Source Categories | NOx | PM2.5 | PM10 | SOx |
---|---|---|---|---|
commercial and households | 9% | 61.2% | 48.2% | 23.8% |
transport (road and rail) | 54.8% | 11.8% | 10.6% | - |
energy production | 9% | 0.3% | 0.3% | 0.2% |
manufacturing industries and construction | 26.7% | 14.2% | 11.1% | 75.8% |
agriculture | 0.5% | 0.2% | 0.2% | 0.2% |
mineral products | - | 12.3% | 29.6% | - |
Year | Incidence | Prevalence | Hospitalized | |
---|---|---|---|---|
Malign tumors from which neoplasm of the bronchus and lungs | 2017 | 330.3/30.3 * | 2474/86.6 * | 798.6/37.0 * |
2018 | 253.6/25.9 * | 2453.8/319.2 * | 763.9/28.8 * | |
2019 | 110.7/11.6 * | 1928.6/259.2 * | 745.6/42.0 * | |
Chronic obstructive pulmonary disease (COPD) | 2017 | 189.6 | 1940.8 | 331.7 |
2018 | 125.8 | 1940.6 | 310.9 | |
2019 | 157.2 | 2254.7 | 221.2 | |
Asthma | 2017 2018 2019 | 139.9 150.1 184.7 | 25.2 23.9 24.1 |
Pollutant | Station | Observation | Obs. without Missing Data | Minimum | Maximum | Mean | Std. Deviation | No of Days Over Limit/Year |
---|---|---|---|---|---|---|---|---|
NOx | BV1 | 1827 | 1710 | 8.12 | 565.52 | 73.58 | 61.09 | 237 |
BV2 | 1827 | 1547 | 9.62 | 628.90 | 69.96 | 63.63 | 187 | |
BV3 | 1827 | 1692 | 7.97 | 681.83 | 94.57 | 63.57 | 300 | |
BV4 | 1827 | 1682 | 2.14 | 142.60 | 17.24 | 13.89 | 19 | |
BV5 | 1827 | 1235 | 12.21 | 641.04 | 78.78 | 64.72 | 121 | |
EMI | 1827 | 466 | 2.39 | 26.60 | 7.44 | 2.24 | 0 | |
SO2 | BV1 | 1827 | 1076 | 0.47 | 17.02 | 5.73 | 2.07 | 0.00 |
BV2 | 1827 | 1588 | 0.46 | 24.39 | 6.07 | 1.83 | 0.00 | |
BV3 | 1827 | 1227 | 1.40 | 21.56 | 6.87 | 2.66 | 0.00 | |
BV4 | 1827 | 1682 | 2.14 | 142.60 | 17.24 | 13.89 | 0.00 | |
BV5 | 1827 | 1483 | 0.00 | 19.85 | 5.61 | 2.04 | 0.00 | |
EMI | 1827 | 485 | 0.09 | 18.11 | 5.47 | 2.67 | 0.00 | |
PM10 | BV1 | 1827 | 1636 | 2.74 | 179.23 | 27.96 | 18.82 | 27 |
BV2 | 1827 | 1305 | 2.36 | 255.93 | 28.84 | 22.27 | 44 | |
BV3 | 1827 | 1697 | 2.91 | 216.48 | 31.93 | 21.13 | 73 | |
BV4 | 1827 | 1223 | 1.09 | 200.95 | 23.82 | 21.00 | 14 | |
BV5 | 1827 | 659 | 0.43 | 272.09 | 25.24 | 27.24 | 15 | |
EMI | 1827 | 397 | 0.73 | 66.86 | 9.23 | 8.37 | 0 | |
PM2.5 | BV2 | 1827 | 1560 | 1.09 | 198.31 | 19.22 | 17.17 | 10 |
Rating | Index Value for NOx | BV1 | BV2 | BV3 | BV4 | BV5 |
---|---|---|---|---|---|---|
excellent | 0–40 | 31% | 39% | 11% | 94% | 24% |
fine | 40–90 | 41% | 33% | 41% | 5% | 45% |
moderate | 90–120 | 12% | 13% | 26% | 0% | 14% |
poor | 120–230 | 12% | 11% | 17% | 0% | 12% |
very poor | 230–340 | 1% | 2% | 4% | 0% | 3% |
severe | 340–1000 | 3% | 1% | 1% | 0% | 1% |
Year of Study | Cases | Sex Ratio | Cases | Histological Forms | Cases |
---|---|---|---|---|---|
2018 | 25 | Men | 70 | Pulmonary Adenocarcinoma (ADK) | 25 |
2019 | 47 | Women | 34 | Squamous cell carcinoma (SCC) | 79 |
2020 | 9 | ||||
2021 | 23 | ||||
Ages | Cases | Domicile and histological forms | Cases | ||
54–60 | 18 | Urban/ADK | 20 | ||
61–70 | 54 | Domicile | Cases | Urban/SCC | 55 |
71–80 | 29 | Urban | 75 | Rural/ADK | 5 |
81–82 | 3 | Rural | 29 | Rural/SCC | 24 |
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Maftei, C.; Muntean, R.; Poinareanu, I. The Impact of Air Pollution on Pulmonary Diseases: A Case Study from Brasov County, Romania. Atmosphere 2022, 13, 902. https://doi.org/10.3390/atmos13060902
Maftei C, Muntean R, Poinareanu I. The Impact of Air Pollution on Pulmonary Diseases: A Case Study from Brasov County, Romania. Atmosphere. 2022; 13(6):902. https://doi.org/10.3390/atmos13060902
Chicago/Turabian StyleMaftei, Carmen, Radu Muntean, and Ionut Poinareanu. 2022. "The Impact of Air Pollution on Pulmonary Diseases: A Case Study from Brasov County, Romania" Atmosphere 13, no. 6: 902. https://doi.org/10.3390/atmos13060902
APA StyleMaftei, C., Muntean, R., & Poinareanu, I. (2022). The Impact of Air Pollution on Pulmonary Diseases: A Case Study from Brasov County, Romania. Atmosphere, 13(6), 902. https://doi.org/10.3390/atmos13060902