生产设施中意外释放的人造纳米材料职业暴露建模及吸入内剂量计算。

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

作者信息

Pilou Marika, Vaquero-Moralejo Celina, Jaén María, Lopez De Ipiña Peña Jesús, Neofytou Panagiotis, Housiadas Christos

机构信息

a Thermal Hydraulics & Multiphase Flow Laboratory , INRASTES, National Centre for Scientific Research "Demokritos" , Agia Paraskevi , Greece.

b Industry and Transport Division , Tecnalia Research and Innovation , Miñano , Spain.

出版信息

Int J Occup Environ Health. 2016 Jul;22(3):249-258. doi: 10.1080/10773525.2016.1226535. Epub 2016 Sep 27.

DOI:10.1080/10773525.2016.1226535

PMID:27670588

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5102221/

Abstract

BACKGROUND

Occupational exposure to manufactured nanomaterials (MNMs) and its potential health impacts are of scientific and practical interest, as previous epidemiological studies associate exposure to nanoparticles with health effects, including increased morbidity of the respiratory and the circulatory system.

OBJECTIVES

To estimate the occupational exposure and effective internal doses in a real production facility of TiO MNMs during hypothetical scenarios of accidental release.

METHODS

Commercial software for geometry and mesh generation, as well as fluid flow and particle dispersion calculation, were used to estimate occupational exposure to MNMs. The results were introduced to in-house software to calculate internal doses in the human respiratory tract by inhalation.

RESULTS

Depending on the accidental scenario, different areas of the production facility were affected by the released MNMs, with a higher dose exposure among individuals closer to the particles source.

CONCLUSIONS

Granted that the study of the accidental release of particles can only be performed by chance, this numerical approach provides valuable information regarding occupational exposure and contributes to better protection of personnel. The methodology can be used to identify occupational settings where the exposure to MNMs would be high during accidents, providing insight to health and safety officials.

摘要

背景

职业性接触人造纳米材料（MNMs）及其潜在的健康影响具有科学和实际意义，因为先前的流行病学研究表明，接触纳米颗粒会对健康产生影响，包括呼吸系统和循环系统发病率增加。

目的

在二氧化钛纳米材料实际生产设施中，估计假设意外释放情况下的职业接触和有效内剂量。

方法

使用用于几何形状和网格生成以及流体流动和颗粒扩散计算的商业软件来估计职业性接触纳米材料的情况。将结果引入内部软件，以计算通过吸入在人体呼吸道中的内剂量。

结果

根据意外情况，生产设施的不同区域受到释放的纳米材料的影响，靠近颗粒源的个体接触剂量更高。

结论

鉴于颗粒意外释放的研究只能偶然进行，这种数值方法提供了有关职业接触的有价值信息，并有助于更好地保护人员。该方法可用于识别事故期间纳米材料接触量高的职业环境，为健康和安全官员提供见解。

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