Experimental research on the effect of functional residual capacity on the deposition of inhalable particles in human alveoli region_Journal of Biomedical Engineering

Authors：

LI Rong ^1,2 ,  XU Xinxi ¹ , QIAO Yang ¹ , ZHAO Xiuguo ¹

1. Institute of Medical Support Technology, Academy of Military Sciences, Tianjin 300161, P.R.China;
2. Department of Military Protective Medicine, Logistics University of Chinese People’s Armed Police Force, Tianjin 300309, P.R.China;

Corresponding author：

XU Xinxi, Email: xuxx1@sohu.com

Keywords：

pulmonary alveoli; inhalable particle; deposition; functional residual capacity

DOI：

10.7507/1001-5515.201711054

Video：

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Research on the deposition of inhalable particles in the alveoli of the lungs is important to the causes, development for common respiratory diseases such as emphysema, and even the optimization of clinical treatment and prevention programs of them. In this paper, an in vitro experimental model was established to simulate the deposition of terminal bronchioles and pulmonary acinus particles. The deposition rate of inhalable particles with different particle sizes in the pulmonary acinus was studied under different functional residual capacity. The results showed that the particle diameter was an important factor affecting the deposition of particles in the lung alveoli. Particles with 1 μm diameter had the highest deposition rate. With the functional residual capacity increasing, particulate deposition rate significantly reduced. The results of this study may provide data support and optimization strategy for target inhalation therapy of respiratory diseases such as emphysema and pneumoconiosis. The established model may also provide a feasible in vitro experimental model for studying the deposition of inhalable particles in the pulmonary alveoli.

Citation： LI Rong, XU Xinxi, QIAO Yang, ZHAO Xiuguo. Experimental research on the effect of functional residual capacity on the deposition of inhalable particles in human alveoli region. Journal of Biomedical Engineering, 2018, 35(4): 557-563. doi: 10.7507/1001-5515.201711054 Copy

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13.	Sznitman J. Respiratory flows in the pulmonary acinus and insights on the control of alveolar flows// International Conference on Sensors and Control Techniques (ICSC2000). Wuhan: International Society for Optics and Photonics, 2008: 496-499.
14.	王兴华, 周鸣镝, 成红娟. 湿空气热物性参数的计算//中国建筑学会建筑热能动力分会全国区域能源专业委员会年会. 牡丹江: 中国建筑学会建筑热能动力分会, 2013.
15.	丁玉龙, 苍大强, 杨天钧. 稀相气固两相垂直管流内的固相浓度和粘度. 北京科技大学学报, 1994, 16(1): 20-25.
16.	Chhabra S, Prasad A K. Flow and particle dispersion in a pulmonary alveolus--part Ⅰ: velocity measurements and convective particle transport. J Biomech Eng, 2010, 132(5): 051009.
17.	黄俊. 可吸入颗粒在肺泡中沉积的数值模拟. 杭州: 浙江大学, 2016.
18.	郭西龙. 颗粒物在人体肺部沉积规律及影响因素研究. 长沙: 中南大学, 2013.
19.	符乃方, 董志超, 李羡筠, 等. 职业性尘肺病治疗方法研究进展. 职业与健康, 2016, 32(24): 3452-3456.

1. Fernández Tena A, Casan Clarà P. Deposition of inhaled particles in the lungs. Arch Bronconeumol, 2012, 48(7): 240-246.
2. Tsuda A, Henry F S, Butler J P. Chaotic mixing of alveolated duct flow in rhythmically expanding pulmonary acinus. J Appl Physiol, 1995, 79(3): 1055-1063.
3. Darquenne C, Harrington L, Prisk G K. Alveolar duct expansion greatly enhances aerosol deposition: a three-dimensional computational fluid dynamics study. Philos Trans A Math Phys Eng Sci, 2009, 367(1896): 2333-2346.
4. Sznitman J, Heimsch T, Wildhaber J H, et al. Respiratory flow phenomena and gravitational deposition in a three-dimensional space-filling model of the pulmonary acinar tree. J Biomech Eng, 2009, 131(3): 031010.
5. Ma Baoshun, Darquenne C. Aerosol deposition characteristics in distal acinar airways under cyclic breathing conditions. J Appl Physiol, 2011, 110(5): 1271-1282.
6. 李振振. 肺腺泡内颗粒物的沉积及阻塞影响的数值模拟研究. 西安: 西安建筑科技大学, 2016.
7. Oakes J M, Day S, Weinstein S J, et al. Flow field analysis in expanding healthy and emphysematous alveolar models using particle image velocimetry. J Biomech Eng, 2010, 132(2): 021008.
8. Berg E J, Weisman J L, Oldham M J, et al. Flow field analysis in a compliant acinus replica model using particle image velocimetry (PIV). J Biomech, 2010, 43(6): 1039-1047.
9. Fishler R, Mulligan M K, Sznitman J. Acinus-on-a-chip: a microfluidic platform for pulmonary acinar flows. J Biomech, 2013, 46(16): 2817-2823.
10. International Commissionon Radiological Protection (ICRP). Human respiratory tract model for radiological protection. ICRP Publication 66. Annals of ICRP, 1994, 24(1-3).
11. Haefeli-Bleuer B, Weibel E R. Morphometry of the human pulmonary acinus. Anat Rec, 1988, 220(4): 401-414.
12. Żywczyk Ł, Moskal A. Modeling of the influence of tissue mechanical properties on the process of aerosol particles deposition in a model of human alveolus. J Drug Deliv Sci Tec, 2012, 22(2): 153-159.
13. Sznitman J. Respiratory flows in the pulmonary acinus and insights on the control of alveolar flows// International Conference on Sensors and Control Techniques (ICSC2000). Wuhan: International Society for Optics and Photonics, 2008: 496-499.
14. 王兴华, 周鸣镝, 成红娟. 湿空气热物性参数的计算//中国建筑学会建筑热能动力分会全国区域能源专业委员会年会. 牡丹江: 中国建筑学会建筑热能动力分会, 2013.
15. 丁玉龙, 苍大强, 杨天钧. 稀相气固两相垂直管流内的固相浓度和粘度. 北京科技大学学报, 1994, 16(1): 20-25.
16. Chhabra S, Prasad A K. Flow and particle dispersion in a pulmonary alveolus--part Ⅰ: velocity measurements and convective particle transport. J Biomech Eng, 2010, 132(5): 051009.
17. 黄俊. 可吸入颗粒在肺泡中沉积的数值模拟. 杭州: 浙江大学, 2016.
18. 郭西龙. 颗粒物在人体肺部沉积规律及影响因素研究. 长沙: 中南大学, 2013.
19. 符乃方, 董志超, 李羡筠, 等. 职业性尘肺病治疗方法研究进展. 职业与健康, 2016, 32(24): 3452-3456.

Journal of Biomedical Engineering

Experimental research on the effect of functional residual capacity on the deposition of inhalable particles in human alveoli region

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