Airflow and Deposition of Nano-Particles in a Human Nasal Cavity

Zamankhan, Piroz; Ahmadi, Goodarz; Wang, Zuocheng; Hopke, Philip K.; Cheng, Yung‐Sung; Su, Wei Chung; Leonard, Douglas

doi:10.1080/02786820600660903

Cited by 129 publications

(75 citation statements)

References 19 publications

(20 reference statements)

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“…In this figure, three curves reflect the results obtained for [4][5][6], the remaining four represent calculations for different original models. In four papers [4][5][6][7], the Euler approach was used to calculate particle motion, the others [8,9] and our work used the Lagrange approach. Following the authors of [4], we can recognize the comparison as quite good.…”

Section: Comparison Of Calculation Results With Calculated and Experimentioning

confidence: 99%

Consideration of the respiratory cycle asymmetry in the numerical modeling of the submicron particles deposition in the human nasal cavity

Ganimedov¹,

Muchnaya²

2017

AIP Conference Proceedings

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Abstract.A detailed study of the behavior of the U-shaped curve was conducted, which described deposition efficiency of inhaled particles in human nasal cavity. The particles in the range from 1 nm to 20 μm are considered. Calculations of air flow and particles deposition were carried out for symmetrical (idealized) and asymmetrical (real) breathing cycles at the same volume of inhaled air, which corresponded to calm breathing. The calculations were performed on the base of the mathematical model of the nasal cavity of healthy person using software package ANSYS (FLUENT 12). The comparison of the results was made between these calculations, and also with the results obtained at quasi-stationary statement of the problem for several values of flow rate. The comparison of the results of quasi-stationary calculations with available calculated and experimental data (in vivo in vitro) was fulfilled previously. Good agreement of the results was obtained. It is shown that the real distribution of deposition efficiency as a function of the particle size can be obtained via a certain combination of the results of quasi-stationary calculations, without the use of laborious and timeconsuming non-stationary calculation.

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Section: Comparison Of Calculation Results With Calculated and Experimentioning

confidence: 99%

Consideration of the respiratory cycle asymmetry in the numerical modeling of the submicron particles deposition in the human nasal cavity

Ganimedov¹,

Muchnaya²

2017

AIP Conference Proceedings

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“…Previous numerical studies have considered the transport and deposition of fine and ultrafine particles in the nasal cavity (Liu et al, 2007;Martonen et al, 2003;Schroeter et al, 2001;Shi et al, 2006;Xi and Longest 2009;Yu et al, 1998;Zamankhan et al, 2006). Similar CFD studies have also evaluated the transport and absorption of dilute chemical species in the nasal passages (Cohen Hubal et al, 1996;Scherer et al, 1994;Zhao et al, 2004).…”

mentioning

confidence: 91%

Ultrafine and Fine Aerosol Deposition in the Nasal Airways of a 9-Month-Old Girl, a 5-Year-Old Boy and a 53-Year-Old Male

Xi¹,

Kim²,

Xiuhua³

2012

The Continuum of Health Risk Assessments

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“…Although in vivo studies on human subjects are desirable, the invasive and hazardous nature of the employed aerosols limits the extent of such studies. Experimental measurements of deposition of ultrafine particles in physical casts of extrathoracic airways (in vitro) have been used as a substitute for in vivo studies (Cheng et al , 1993Swift et al 1992;Yamada et al 1988;Gradon and Yu 1989;Guilmette et al 1994;Kelly et al 2004).Computational fluid dynamic (CFD) simulations have been useful for improving our understanding of deposition mechanisms correlated to flow patterns in nasal airways (Yu et al 1998;Zamankhan et al 2006;Shi et al 2006;Wang et al 2009;.…”

Section: Golshahi Et Almentioning

confidence: 99%

Deposition of Inhaled Ultrafine Aerosols in Replicas of Nasal Airways of Infants

Golshahi

Finlay

Olfert

et al. 2010

Aerosol Science and Technology

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Experimentally measured deposition of ultrafine particles, ranging from 13-100 nm in diameter, in nasal airway replicas of ten infants aged 3-18 months is presented. The replicas included the face, nostrils, and nasal airways including the upper trachea. A differential mobility analyzer (DMA) and a condensation particle counter (CPC) were used to quantify the nasal deposition by comparing the number of polydisperse sodium chloride particles, generated by evaporation from a Collison atomizer, at the inlet and outlet of the replicas. Particles were individually classified in size by DMA and subsequently were counted one size bin at a time by CPC upstream and downstream of each replica. Since in vivo data is not available for infants to compare to, we validated our experimental procedure instead by comparing deposition in nasal airway replicas of six adults with in vivo measurements reported in literature. In the infant replicas, tidal inhalation was simulated at two physiologically compatible flow rates and the effect of flow rate on deposition was found to be small. Deposition obtained at constant flow rates is lower than with tidal breathing, indicating the importance of unsteadiness, in contrast to similar data in adults where unsteadiness is known to be unimportant. An empirical equation, containing geometrical features of the nasal airways in the form of related non-dimensional dynamical parameters (Reynolds, Schmidt, and Womersley numbers), was best fitted to the infant data. This equation may be useful for a priori prediction of nasal deposition and intersubject variability during exposure of infants to ultrafine aerosols.

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Airflow and Deposition of Nano-Particles in a Human Nasal Cavity

Cited by 129 publications

References 19 publications

Consideration of the respiratory cycle asymmetry in the numerical modeling of the submicron particles deposition in the human nasal cavity

Consideration of the respiratory cycle asymmetry in the numerical modeling of the submicron particles deposition in the human nasal cavity

Ultrafine and Fine Aerosol Deposition in the Nasal Airways of a 9-Month-Old Girl, a 5-Year-Old Boy and a 53-Year-Old Male

Deposition of Inhaled Ultrafine Aerosols in Replicas of Nasal Airways of Infants

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