Transient Absorption of Inhaled Vapors into a Multilayer Mucus–Tissue–Blood System

Tian, Geng; Longest, P. Worth

doi:10.1007/s10439-009-9808-9

Cited by 24 publications

(10 citation statements)

References 34 publications

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“…However, 1-D models and experiments clearly show that blood concentrations increase over longer timescales (Kumagai and Matsunaga, 1995). An analytical solution of this system was previously developed by Tian and Longest (2010a) and extended to formulate a CFD boundary condition including the air phase by Tian and Longest (2010b). The analytical solution for the concentration of an absorbed species in the mucus and tissue layers is briefly reviewed below.…”

Section: Analytical Solution For Mass Transport In Mucus and Tissue Lmentioning

confidence: 97%

“…The validity of this assumption has recently been questioned by Longest et al Specifically, Tian and Longest (2010a) showed that transient wall absorption significantly influences uptake over the timescale of one inhalation cycle in the upper airways. For example, Tian and Longest (2010a) found that the uptake of highly and moderately soluble compounds modelled with transient fluxes varied from steady state flux estimates by a factor of ∼30 in nasal and upper TB models after 1 s. As a result, it appears important to consider a time-dependent (or transient) flux value when estimating absorption into the respiratory airway walls. This is especially true in the early stages of exposure where blood concentration values of the inhaled species are near zero.…”

mentioning

confidence: 96%

“…This is especially true in the early stages of exposure where blood concentration values of the inhaled species are near zero. The results of Tian and Longest (2010a) were based analytical and numerical solutions of transient absorption into a simple mucus-tissue-blood wall representation. However, a constant vapour concentration was assumed at the air-mucus interface and the air phase transport was neglected.…”

mentioning

confidence: 99%

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Application of a new dosimetry program TAOCS to assess transient vapour absorption in the upper airways

Tian

Longest²

2010

Inhalation Toxicology

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Most previous models of vapour absorption in the respiratory tract have assumed steady state flow fields and steady state diffusion into the airway walls. However, recent studies have shown that transient absorption flux into the walls of the upper airways can significantly influence predicted uptake or deposition values. The disadvantage of accounting for transient absorption into the airway walls is a more complex boundary condition and numerical model. The objective of this study was to evaluate the effects of both transient flow fields and transient mass absorption on the uptake of highly and moderately soluble compounds in an upper airway model. The geometry consisted of the mouth-throat region coupled with a multilayer wall model containing air, mucus, tissue, and blood phases. Based on previous studies, a boundary condition that represents transient absorption into the airway walls was applied. A new dosimetry program, named transient absorption of chemical species (TAOCS) 1.0, was developed and implemented to determine the coefficients needed for the transient boundary condition expression and to apply the boundary condition to the computational fluid dynamics (CFD) model. Both steady state and transient conditions were considered for the airflow field and wall absorption. The case of perfect wall absorption with a zero surface concentration was also considered. Results indicated that steady state airflow provided a reasonable approximation to transient airflow conditions in terms of total and local deposition (values within 10-30%). However, the simulation of transient wall absorption was critical unless the compound was highly soluble (with a mucus-air partition coefficient ≥320), in which case a perfect absorption boundary condition was accurate to within a relative difference of 50%. Still, the perfect absorption boundary condition did not accurately capture local deposition enhancement factor values. Based on these findings, implementation of the transient absorption boundary condition appears critical to predict local deposition characteristics for even highly soluble compounds. Use of the TAOCS program simplified the implementation of the complex transient absorption condition making the CFD simulation process more efficient and user-friendly.

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Section: Analytical Solution For Mass Transport In Mucus and Tissue Lmentioning

confidence: 97%

mentioning

confidence: 96%

mentioning

confidence: 99%

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Application of a new dosimetry program TAOCS to assess transient vapour absorption in the upper airways

Tian

Longest²

2010

Inhalation Toxicology

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“…25,36 In these studies, the transport of vapor in the tissue has been considered steady state, leading to one-way vapor transport from the air to tissue phases. However, Tian and Longest 41 showed that based on the calculated mass transfer Fourier number, this process is unsteady. Recently, Tian and Longest [39][40][41] published a series of articles on the transient absorption of vapors in respiratory airways using an uptake model that included a mucus-tissue-blood layer.…”

Section: Introductionmentioning

confidence: 95%

“…However, Tian and Longest 41 showed that based on the calculated mass transfer Fourier number, this process is unsteady. Recently, Tian and Longest [39][40][41] published a series of articles on the transient absorption of vapors in respiratory airways using an uptake model that included a mucus-tissue-blood layer. They developed a wall-flux boundary condition for transient absorption that was applied to CFD models of vapor uptake in the respiratory tract.…”

Section: Introductionmentioning

confidence: 95%

Derivation of Mass Transfer Coefficients for Transient Uptake and Tissue Disposition of Soluble and Reactive Vapors in Lung Airways

et al. 2011

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Evaluation of vapor uptake by lung airways and subsequent dose to lung tissues provides the bridge connecting exposure episode to biological response. Respiratory vapor absorption depends on chemical properties of the inhaled material, including solubility, diffusivity, and metabolism/reactivity in lung tissues. Inter-dependent losses in the air and tissue phases require simultaneous calculation of vapor concentration in both phases. Previous models of lung vapor uptake assumed steady state, one-way transport into tissues with first-order clearance. A new approach to calculating lung dosimetry is proposed in which an overall mass transfer coefficient for vapor transport across the air-tissue interface is derived using air-phase mass transfer coefficients and analytical expressions for tissue-phase mass transfer coefficients describing unsteady transport by diffusion, first-order, and saturable pathways. Feasibility of the use of mass transfer coefficients was shown by calculating transient concentration levels of inhaled formaldehyde in the human tracheal airway and surrounding tissue. Formaldehyde tracheal air concentration and wall-flux declined throughout the breathing cycle. After the inhalation period, peak tissue concentration moved from the air-tissue interface into the tissue due to desorption into the air and continued diffusional transport across the tissue layer. While model predictions were performed for formaldehyde, which serves as a model of physiologically relevant, highly reactive vapors, the model is equally applicable to other soluble and reactive compounds.

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Absorption and Clearance of Pharmaceutical Aerosols in the Human Nose: Effects of Nasal Spray Suspension Particle Size and Properties

2015

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The nasal-DAC model was demonstrated to be a useful tool in determining the nasal exposure of spray formulations with different drug particle sizes and solubilities. Furthermore, the model illustrated a new strategy for topical nasal drug delivery in which drug particle size is selected to increase the region of epithelial surface exposure using mucociliary clearance while minimizing the drug dose exiting the nasopharynx.

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Transient Absorption of Inhaled Vapors into a Multilayer Mucus–Tissue–Blood System

Cited by 24 publications

References 34 publications

Application of a new dosimetry program TAOCS to assess transient vapour absorption in the upper airways

Application of a new dosimetry program TAOCS to assess transient vapour absorption in the upper airways

Derivation of Mass Transfer Coefficients for Transient Uptake and Tissue Disposition of Soluble and Reactive Vapors in Lung Airways

Absorption and Clearance of Pharmaceutical Aerosols in the Human Nose: Effects of Nasal Spray Suspension Particle Size and Properties

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