Magnetic nanoparticles: An indicator of health risks related to anthropogenic airborne particulate matter

Due to their small dimensions, airborne particles are able to penetrate through inhalation into many human organs, from the lungs to the cardiovascular system and the brain, which can threaten our health. This work establishes a novel approach of collecting quantitative data regarding the fraction,...

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Bibliographic Details
Published in:Environmental pollution (1987) 2021-02, Vol.271, p.116309, Article 116309
Main Authors: Kermenidou, M., Balcells, Ll, Martinez-Boubeta, C., Chatziavramidis, A., Konstantinidis, I., Samaras, T., Sarigiannis, D., Simeonidis, K.
Format: Article
Language:English
Subjects:
Air Pollutants - analysis
Air Pollution - analysis
Cities
Environmental Monitoring
Greece
Humans
Iron-bearing
Magnetism
Magnetite Nanoparticles
Nanoparticles
Particle Size
Particulate matter
Particulate Matter - analysis
Rhinoscopy
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Summary:Due to their small dimensions, airborne particles are able to penetrate through inhalation into many human organs, from the lungs to the cardiovascular system and the brain, which can threaten our health. This work establishes a novel approach of collecting quantitative data regarding the fraction, the composition and the size distribution of combustion-emitted particulate matter through the magnetic characterization and analysis of samples received by common air pollution monitoring. To this end, SQUID magnetometry measurements were carried out for samples from urban and suburban areas in Thessaloniki, the second largest city of Greece, taking into consideration the seasonal and weekly variation of airborne particles levels as determined by occurring traffic and meteorological conditions. The level of estimated magnetically-responding atmospheric particulate matter was at least 0.5 % wt. of the collected samples, mostly being present in the form of ultrafine particles with nuclei sizes of approximately 14 nm and their aggregates. The estimated quantities of magnetic particulate matter show maximum values during autumn months (0.8 % wt.) when increased commuting takes place, appearing higher in the city center by up to 50% than those in suburban areas. In combination with high-resolution transmission electron imaging and elemental analysis, it was found that Fe3O4 and similar ferrites, some of them attached to heavy metals (Co, Cr), are the dominant magnetic contributors arising from anthropogenic high-temperature processes, e.g. due to traffic emissions. Importantly, nasal cytologic samples collected from residents of both central and suburban areas showed same pattern in what concerns magnetic behavior, thus verifying the critical role of nanosized magnetic particles in the assessment of air pollution threats. Despite the inherent statistical limitations of our study, such findings also indicate the potential transmission of infectious pathogens by means of pollution-derived nanoparticles into the respiratory system of the human body. [Display omitted] •Novel approach to identify airborne magnetic nanoparticles and health risks.•At least 0.5% of PM2.5 in urban sites was defined as magnetically responding.•Ultrafine iron oxide particles are a major fraction of atmosphere pollution.•Nasal samples from residents identifies the possible route of entry to the human.•The findings indicate link between PM2.5 and pathogens transmission. An approach of analyzing
ISSN:0269-7491
1873-6424
DOI:10.1016/j.envpol.2020.116309