Litcius/Paper detail

A critical analysis of the CFD-DEM simulation of pharmaceutical aerosols deposition in upper intra-thoracic airways: Considerations on air flow

G.H. Spasov, Riccardo Rossi, Andrea Vanossi, C. Cottini, Andrea Benassi

2024Computers in Biology and Medicine18 citationsDOIOpen Access PDF

Abstract

A well-corroborated numerical methodology ensuring reproducibility in the modeling of pharmaceutical aerosols deposition in the respiratory system via CFD-DEM simulations within the RANS framework is currently missing. Often, inadequately clarified assumptions and approximations and the lack of evidences on their quantitative impact on the simulated deposition phenomenology, make a direct comparison among the different theoretical studies and the limited number of experiments a very challenging task. Here, with the ultimate goal of providing a critical analysis of some crucial computational aspects of aerosols deposition, we address the issues of velocity fluctuations propagation in the upper intra-thoracic airways and of the persistence of secondary flows using the SimInhale reference benchmark. We complement the investigation by describing how methodologies used to drive the flow through a truncated lung model may affect numerical results and how small discrepancies are observed in velocity profiles when comparing simulations based on different meshing strategies.

Topics & Concepts

Computational fluid dynamicsReynolds-averaged Navier–Stokes equationsDeposition (geology)Computer scienceMechanicsFlow (mathematics)Benchmark (surveying)SimulationAerospace engineeringEnvironmental scienceGeologyEngineeringPhysicsGeodesySedimentPaleontologyInhalation and Respiratory Drug DeliveryParticle Dynamics in Fluid FlowsAerosol Filtration and Electrostatic Precipitation