Modeling of occupational exposure to accidentally released manufactured nanomaterials in a production facility and calculation of internal doses by inhalation

Pilou, Marika; Vaquero, C.; Jaén, María; Peña, Jesús Lopez De Ipiña; Neofytou, Panagiotis; Housiadas, C.

doi:10.1080/10773525.2016.1226535

Cited by 6 publications

(3 citation statements)

References 40 publications

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“…The total number of particles inhaled over time was calculated using Equation (3), where D t is the dosage or the number of particles inhaled over a specific time period t , Npt is the number of particles (maximum, minimum, or mean) in the breathing zone for time t , f is the fraction of particles that will enter the respiratory tracts based on a particle size of 0.05, and fRt accounts for breathing over the time period t , assuming a representative adult population and that the amount of particles that can be breathed in t time is Npt [28]. Dt=Npt×f×fRt.…”

Section: Results and Analysismentioning

confidence: 99%

Coupling Computational Fluid Dynamics Simulations and Statistical Moments for Designing Healthy Indoor Spaces

Hoque

Omar

2019

IJERPH

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Cross-contamination between occupants in an indoor space may occur due to transfer of infectious aerosols. Computational fluid dynamics (CFD) provides detailed insight into particle transport in indoor spaces. However, such simulations are site-specific. This study couples CFD with statistical moments and establishes a framework that transitions site-specific results to generating guidelines for designing “healthy” indoor spaces. Eighteen cases were simulated, and three parameters were assessed: inlet/outlet location, air changes per hour, and the presence/absence of desks. Aerosol release due to a simulated “sneeze” in a two-dimensional ventilated space was applied as a test case. Mean, standard deviation, and skewness of the velocity profiles and particle locations gave an overall picture of the spread and movement of the air flow in the domain. A parameter or configuration did not dominate the values, confirming the significance of considering the combined influence of multiple parameters for determining localized air-flow characteristics. Particle clustering occurred more when the inlet was positioned above the outlet. The particle dispersion pattern could be classified into two time zones: “near time”, <60 s, and “far time”, >120 s. Based on dosage, the 18 cases were classified into three groups ranging from worst case scenario to best case scenario.

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Section: Results and Analysismentioning

confidence: 99%

Coupling Computational Fluid Dynamics Simulations and Statistical Moments for Designing Healthy Indoor Spaces

Hoque

Omar

2019

IJERPH

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“…MPPD, RETRAC) or other organs for humans and animals. The inventory also reports advanced computational fluidparticle dynamics (CFD) numerical methodologies and software for the prediction of particle transport and deposition within the respiratory system (Pilou et al, 2011) or simulation of NM dispersion within indoor spaces (Pilou et al, 2016), and also models for calculation of key physicochemical properties of NMs based on their toxicity (e.g. nano-QSAR, NanoBRIDGES).…”

Section: An Incubator For Novel Services Supporting Sbdmentioning

confidence: 99%

Blueprint for a self-sustained European Centre for service provision in safe and sustainable innovation for nanotechnology

Marcoulaki

Ipiña²,

Vercauteren

et al. 2021

NanoImpact

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“…Observational researchers have reported breathing difficulties and intestinal inflammation in occupational workers exposed to microplastic particles and fibers [ 17 ]. Accidental occupational exposure to manufactured nanomaterials also affects the individuals in dose-dependent manners [ 18 ].…”

Section: Introductionmentioning

confidence: 99%

A549 as an In Vitro Model to Evaluate the Impact of Microplastics in the Air

Shahzadi,

Di Serafino,

Aruffo

et al. 2023

Biology

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Airborne microplastics raise significant concerns due to their potential health impacts. Having a small size, larger surface area, and penetrative ability into the biological system, makes them hazardous to health. This review article compiles various studies investigating the mechanism of action of polystyrene micro- and nanoplastics affecting lung epithelial cells A549. These inhalable microplastics damage the respiratory system, by triggering a proinflammatory environment, genotoxicity, oxidative stress, morphological changes, and cytotoxic accumulation in A549 cells. PS-NP lung toxicity depends on various factors such as size, surface modifications, concentration, charge, and zeta potential. However, cellular uptake and cytotoxicity mechanisms depend on the cell type. For A549 cells, PS-NPs are responsible for energy imbalance by mitochondrial dysfunction, oxidative stress-mediated cytotoxicity, immunomodulation, and apoptosis. Additionally, PS-NPs have the ability to traverse the placental barrier, posing a risk to offspring. Despite the advancements, the precise mechanisms underlying how prolonged exposure to PS-NPs leads to the development and progression of lung diseases have unclear points, necessitating further investigations to unravel the root cause. This review also sheds light on data gaps, inconsistencies in PS-Nos research, and provides recommendations for further research in this field.

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Modeling of occupational exposure to accidentally released manufactured nanomaterials in a production facility and calculation of internal doses by inhalation

Cited by 6 publications

References 40 publications

Coupling Computational Fluid Dynamics Simulations and Statistical Moments for Designing Healthy Indoor Spaces

Coupling Computational Fluid Dynamics Simulations and Statistical Moments for Designing Healthy Indoor Spaces

Blueprint for a self-sustained European Centre for service provision in safe and sustainable innovation for nanotechnology

A549 as an In Vitro Model to Evaluate the Impact of Microplastics in the Air

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