Modelling of aerosol deposition in human lungs
D.J. Kokkedee (TU Delft - Applied Sciences)
S Kenjeres – Mentor (TU Delft - ChemE/Transport Phenomena)
Cornelis Vuik – Graduation committee member (TU Delft - Numerical Analysis)
Jos M. Thijssen – Graduation committee member (TU Delft - QN/Thijssen Group)
HM Schuttelaars – Graduation committee member (TU Delft - Mathematical Physics)
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Abstract
A one-dimensional model of respiratory deposition is developed based on an Eulerian approach. The model simulates aerosol deposition in all generations of the respiratory tract by numerically solving the aerosol general dynamics equation (GDE) for a range of aerosol diameters. The lung geometry is described by Weibel’s morphometric model, with a time varying alveolar geometry to accommodate inhalation dynamics. The model is first valuated by comparing it with numerical and experimental results. Afterwards a series of parameter studies is performed by changing breathing conditions, particle parameters and lung geometries. An increase in Tidal volume and decrease of breathing period resulted in an increase of the total deposition fraction for coarse particles and a decrease of the total deposition fraction for ultrafine particles. An increase in the particle density resulted in an increase in the total deposition fraction. A decrease in the airway diameter generally resulted in an increase of the total deposition fraction. This difference was most noticeable in the tracheobronchial region. Decreasing the airway diameter in the tracheobronchial region mostly effects coarse particles while decreasing the airway diameter in the alveolar region mostly effects ultrafine particles.