柴油车排放颗粒物在人体呼吸道沉积特征的模拟研究
A Simulation Study on Deposition of Particulate Matter from Diesel Vehicles in Human Respiratory Tract
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摘要: 柴油车会排放出不同化学性质和粒径的颗粒物,颗粒物会引起人呼吸系统的各种问题,但不同粒径大小的颗粒物在人肺部的沉积仍需要进一步阐明。本文使用DLPI对高原地区柴油机排放的颗粒物进行分级采样,使用多路径粒子剂量测量模型模拟估算不同呼吸模式、生理状态和年龄下,不同粒径的柴油车排放颗粒物在人呼吸系统中不同部位的沉积分数。结果表明,颗粒物沉积在肺区域,往往多于头部和气管及支气管区域。不同年龄段的人呼吸系统的各个部位的沉积分数存在着明显差异,8岁儿童的呼吸系统的沉积分数较其他年龄段高;运动与休息状态相比,沉积分数有着明显的增加;鼻呼吸也比嘴呼吸更利于颗粒物的沉积。颗粒物质量浓度的差异,对颗粒物的沉积并没有太大影响。Abstract: Diesel vehicles emit particulate matter with different chemical properties and particle sizes, which will cause various problems to the human respiratory system, but the deposition of particles with different sizes in the human lung still needs further explanation. In this paper, the particulate matter emitted by diesel engine in plateau area was sampled by using DLPI device, and the deposition fractions of particles with different sizes in different parts of the human respiratory system under different breathing patterns, physiological states and ages were simulated and estimated by using the multi-path particle dose measurement model. The results showed that the particulate matter is more easily deposited in the lung area more than the head, trachea and bronchial area. The deposition fractions are significantly different in various parts of the respiratory system of people of different ages, and the deposition fractions of 8-year-old children are higher than those in other age groups. The deposition fractions in exercise increased significantly compared with the rest state. As well as the deposition of particles under the nasal breathing are also more conductive than the mouth breathing. But the concentration difference of particulate matter has little impact on the deposition of particulate matter.
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Key words:
- particulate matter /
- respiratory system /
- deposition
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庄加玮, 刁永发, 楚明浩, 等. 可吸入颗粒物在不同阻塞性呼吸道内运动与沉积特性[J]. 中国环境科学, 2021, 41(7):3349-3359 Zhuang J W, Diao Y F, Chu M H, et al. Transport and deposition characteristics of inhalable particulate matters in different obstructive airways[J]. China Environmental Science, 2021, 41(7):3349-3359(in Chinese)
刘婉莹. 人体上呼吸道内颗粒物-气体两相流动模拟研究[D]. 哈尔滨:哈尔滨工业大学, 2020:35-37 Liu W Y. Numerical study on gas-particle two-phase flow in the upper respiratory tract of human body[D]. Harbin:Harbin Institute of Technology, 2020:35 -37(in Chinese)
阎晓丹, 胡广, 靳洪涛. 可吸入颗粒物的体内暴露模型及沉积剂量学评价[J]. 毒理学杂志, 2020, 34(1):81-86 Yan X D, Hu G, Jin H T. In vivo exposure model and dosimetry evaluation of inhalable particulate matter[J]. Journal of Toxicology, 2020, 34(1):81-86(in Chinese)
李鹏辉, 李蓉, 乔扬, 等. 人体肺腺泡区吸入颗粒物沉积状况数值模拟的研究进展[J]. 生物医学工程学杂志, 2019, 36(3):499-503 Li P H, Li R, Qiao Y, et al. Progress on numerical simulation of the deposition of inhaled particles in human pulmonary acinus region[J]. Journal of Biomedical Engineering, 2019, 36(3):499-503(in Chinese)
李蓉, 徐新喜, 乔杨, 等. 不同功能残气量对可吸入颗粒物在人体肺腺泡区沉积影响的实验研究[J]. 生物医学工程学杂志, 2018, 35(4):557-563 Li R, Xu X X, Qiao Y, et al. Experimental research on the effect of functional residual capacity on the deposition of inhalable particles in human alveoli region[J]. Journal of Biomedical Engineering, 2018, 35(4):557-563(in Chinese)
李鹏辉. 人体肺腺泡区流场特性与吸入颗粒物沉积状态的数值模拟研究[D]. 北京:军事科学院, 2020:10-15 Li P H. Numerical simulation on the flow field and deposition of inhaled particles in human pulmonary acinus region[D]. Beijing:Academy of Military Sciences, 2020:10 -15(in Chinese)
李鹏辉, 徐新喜, 李蓉, 等. 人体肺腺泡区多肺泡模型的建立和重力方向对颗粒物沉积影响的数值模拟研究[J]. 军事医学, 2019, 43(6):460-463 Li P H, Xu X X, Li R, et al. Multi-alveolar model and numerical simulation of influence of gravity direction on inhaled particle deposition in human pulmonary acinus region[J]. Military Medical Sciences, 2019, 43(6):460-463(in Chinese)
段梦婕. 工业建筑中不同粒径颗粒物的迁移及人体暴露特性研究[D]. 西安:西安建筑科技大学, 2018:20-22 Duan M J. Transportation and human exposure to particles with different diameter in industrial buildings[D]. Xi'an:Xi'an University of Architecture and Technology, 2018:20 -22(in Chinese)
梁静舒. 南京北郊气溶胶数浓度分布与人体内粒子沉积特性研究[D]. 南京:南京信息工程大学, 2018:15-18 Liang J S. Study of aerosol number concentration distribution and modeled deposition in human airway in Nanjing northern suburbs[D]. Nanjing:Nanjing University of Information Science & Technology, 2018:15 -18(in Chinese)
段栋丹. 呼吸强度对颗粒物在下呼吸道暴露量影响的研究[D]. 西安:西安建筑科技大学, 2018:22-26 Duan D D. Mechanism of respiration intensity on the lower respiratory tract exposure of particulates[D]. Xi'an:Xi'an University of Architecture and Technology, 2018:22 -26(in Chinese)
郭西龙. 颗粒物在人体肺部沉积规律及影响因素研究[D]. 长沙:中南大学, 2013:20-22 Guo X L. Particle deposition in human lungs:Mechanisms and factors[D]. Changsha:Central South University, 2013:20 -22(in Chinese)
Kiasadegh M, Emdad H, Ahmadi G, et al. Transient numerical simulation of airflow and fibrous particles in a human upper airway model[J]. Journal of Aerosol Science, 2020, 140:105480 Tohidi R, Sajadi B, Ahmadi G. The effect of nasal airway obstruction on the dispersion and deposition of inhaled volatile droplets in the human nasal cavity:A numerical study[J]. Journal of Aerosol Science, 2020, 150:105650 Deng Q H, Ou C Y, Shen Y M, et al. Health effects of physical activity as predicted by particle deposition in the human respiratory tract[J]. The Science of the Total Environment, 2019, 657:819-826 Baur X, Sanyal S, Abraham J L. Mixed-dust pneumoconiosis:Review of diagnostic and classification problems with presentation of a work-related case[J]. Science of the Total Environment, 2019, 652:413-421 尹万青, 葛淼, 何进伟, 等. 17-60岁男性潮气量参考值的地理分布规律[J]. 安徽师范大学学报:自然科学版, 2009, 32(2):173-177 Yin W Q, Ge M, He J W, et al. The geographical distribution rule of tidal volume for males aged 17 to 60[J]. Journal of Anhui Normal University:Natural Science, 2009, 32(2):173-177(in Chinese)
Daniel M, Helen M. High altitude physiology and medicine[J]. Encyclopedia of Respiratory Medicine, 2020, 38(6):81-87 曹志发, 孟昭琴, 姚为俊. 新编运动生理学[M]. 北京:人民体育出版社, 2004:100-130 Fajardo O A, Rojas N Y. Particulate matter exposure of bicycle path users in a high-altitude city[J]. Atmospheric Environment, 2012, 46:675-679 Chalupa D C, Morrow P E, Oberdörster G, et al. Ultrafine particle deposition in subjects with asthma[J]. Environmental Health Perspectives, 2004, 112(8):879-882 Yamada Y, Fukutsu K, Kurihara O, et al. Influences of biometrical parameters on aerosol deposition in the ICRP 66 human respiratory tract model:Japanese and Caucasians[J]. Earozoru KenKyu, 2007, 22(3):236-243 Sánchez-Soberón F, Mari M, Kumar V, et al. An approach to assess the particulate matter exposure for the population living around a cement plant:Modelling indoor air and particle deposition in the respiratory tract[J]. Environmental Research, 2015, 143(Pt A):10-18 谢梦茜. 可吸入颗粒物在人体气管内的沉积模拟研究[D]. 武汉:华中科技大学, 2013:10-15 Xie M Q. Numerical simulation of inhalational particle deposition in human trachea[D]. Wuhan:Huazhong University of Science and Technology, 2013:10 -15(in Chinese)
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