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Abstract

The human respiratory tract has a complex airflow pattern. If any obstruction is present in the airways, it will change the airflow pattern and deposit particles inside the airways. This is the concern of breath quality (inspired air), and it is decreasing due to the unplanned production of material goods. This is a primary cause of respiratory illness (asthma, cancer, etc.). Therefore, it is important to identify the flow characteristics in the human airways and airways with a glomus tumour with particle deposition. A numerical diagnosis is presented with an asymmetric unsteady-state light breathing condition (10 l/min). An in vitro human respiratory tract model has been reconstructed using computed tomography scan techniques and an artificial glomus tumour developed 2 cm above a carina on the posterior wall of the trachea. The transient flow characteristics are numerically simulated with a realizable (low Reynolds number) k–ɛ turbulence model. The flow disturbance is captured around the tumour, which influenced the upstream and downstream of the flow. The flow velocity pattern, wall shear stress and probable area of inflammation (hotspot) due to suspended particle deposition are determined, which may assist doctors more effectively in aerosol therapy and prosthetics of human airways illness.

Keywords

Human respiratory tract computational fluid dynamics computed tomography air quality index

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References

Mathers

Loncar

. Projections of global mortality and burden of disease from 2002 to 2030. PLoS Med 2006; 3: 2011–2030.

Martonenan

Guan

. Effect of tumors on inhaled pharmacological drugs. I. Flow patterns. Cell Biochem Biophys 2001; 35: 233–234.

Riazuddin

Zubair

Abdullah

, et al. Numerical study of inspiratory and expiratory flow in a human nasal cavity. J Med Biol Eng 2010; 31: 201–206.

Kleinstreuer

Zhang

. Targeted drug aerosol deposition analysis for a four generation lung airway model with hemispherical tumors. J Biomed Eng 2003; 125: 197–206.

Martonenan

Guan

. Effect of tumors on inhaled pharmacological drugs. II. Flow patterns. Cell Biochem Biophys 2001; 35: 245–253.

Segal

Guan

Shearer

, et al. Mathematical model of airflow in the lung of children: effect of tumor sizes and locations. J Theoret Med 1999; 2: 199–213.

Luo

Liu

Yang

. Particle deposition in obstructed airways. J Biomech 2007; 40: 3096–3104.

Zhang

Kleinstreuer

Kin

. Flow structure and particle transport in a triple bifurcation airway model. J Fluid Eng 2001; 123: 320–333.

Zhang

Kleinstreure

. Transient airflow and particle transport in a sequentially branching lung airway model. Phys Fluids 2002; 14: 862–879.

10.

Yang

Liu

Luo

. Respiratory flow in obstructed airways. J Biomech 2006; 39: 2743–2751.

11.

Bora

Anders

Michael

, et al. A computational study of the respiratory airflow characteristics in normal and obstructed human airways. Comput Biol Med, 2014; 52: 130–143.

12.

Soni

Aliabadi

. Large-scale simulations of airflow and particle deposition in lung airway. Comput Fluid, 2013; 88: 804–812.

13.

Rahimi-Gorji

Pourmehram

Gorji-Bandpy

, et al. CFD simulation of airflow behavior and particle transport and deposition in different breathing conditions through the realistic model of human airways. J Mol Liq 2015; 209: 121–133.

14.

Yue

, et al. Computational fluid dynamics simulation of airflow in the trachea and main bronchi for the subjects with left pulmonary artery sling. Bio-Med Eng On Line 2014; 13, 1–15.

15.

Watanabe

Keigo

Katsuaki

, et al. Successful resection of a glomus tumor arising from the lower trachea: report of a case. Jpn J Surg 1988; 28: 332–334.

16.

Srivastava

Kumar

Shukla

, et al. Airflow and aerosol drug delivery in a CT-scan based human respiratory tract with tumor using CFD. J Appl Fluid Mech 2014; 7: 345–356.

17.

Luo

Hinton

Liew

, et al. LES Modelling of flow in a simple airways model. Med Eng Phys 2004; 26: 403–413.

18.

Watanabe

Takagi

Ono

, et al. Successful resection of a glomus tumor arising from lower trachea: report of a case. Jpn J Surg 1998; 28: 332–334.

19.

Shang

Dong

Tian

, et al. Detailed computational analysis of flow dynamics in an extended respiratory airway model. J Clin Biomech 2019; 61: 105–111.

20.

Srivastava

Paul

Jain

. Capture the wall turbulence in CFD simulation of human respiratory tract. J Math Comput Simul 2019; 160: 23–38.

21.

Hahn

Scherer

Mozell

. Velocity profiles measured for airflow through a large-scale model of the human nasal cavity. J Appl Physiol 1993; 75: 2273–2287.

22.

Keyhani

Scherer

Mozell

. Numerical simulation of airflow in the human nasal cavity. J Biomech Eng 1995; 11: 429–414.

23.

Piglione

Fontana

Vni

. Simulation of particle deposition in human central airways. Eur J B/Fluid 2012; 31: 91–101.

24.

Mutuku

Chen

W-H

. Flow characterization in healthy airways and airways with chronic obstructive pulmonary disease (COPD) during different inhalation conditions. Aerosol Air Qual Res 2018; 18: 2680–2694.

25.

Weihold

Mlynski

. Numerical simulation of airflow in the human nose. Eur Arch Otorhinolaryngoi 2003; 261: 452–455.

26.

Wen

Inthavong

, et al. Numerical simulations for detailed airflow dynamics in a human nasal cavity. Respir Physiol Neurobiol 2008; 61: 125–135.

27.

Wang

Liu

Sun

, et al. Numerical analysis of respiratory flow patterns within human upper airway. Acta Mech Sin. 2009; 25: 737–746.

28.

Kelly

Bahman Asgharian

Julia

, et al. Particle deposition in human nasal airway replicas manufactured by different methods. Part 1: Inertial regime particles. Aerosol Sci Technol 2004; 38: 1063–1073.

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Numerical assessment of natural respiration and particles deposition in the computed tomography scan airway with a glomus tumour

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