Influence of the Inhalation Route on Tracheal Flow Structures in Patient-Specific Airways using 3D PTV

TL;DR

This study investigates how different inhalation routes affect tracheal flow structures using 3D particle-tracking velocimetry in a patient-specific airway model, revealing minimal differences between oral and nasal inhalation.

Contribution

It provides detailed 3D flow measurements in a realistic airway model, highlighting the impact of inlet conditions and showing similar flow structures for oral and nasal inhalation.

Findings

Presence of nasal/oral cavities significantly alters flow compared to idealized conditions.

Flow structures are nearly identical for oral and nasal inhalation.

Inlet conditions influence the complexity of tracheal flow patterns.

Abstract

The tracheal flow field shapes particle transport into the lower airways and thus influences both the spread of inhaled pathogens and the effectiveness of aerosol-based therapies. Identifying how different inhalation routes modify the flow field is therefore crucial for understanding lower-airway disease transmission and for guiding targeted drug delivery. To gain a detailed understanding of the influence of the inhalation route on the flow structures in the human trachea, the flow field in the trachea is investigated in vitro in a non-compliant, refractive-index matched silicone model of the human respiratory tract. The investigations comprise steady inhalation, and oscillatory flow to simulate calm breathing. A realistic breathing pattern is approximated by a sinusoidal waveform for two Reynolds numbers of $Re_{Tr} = [400, 1200]$, based on the bulk velocity at maximum volume flux and the hydraulic diameter of the trachea and two Womersley numbers of $Wo = [3, 4.5]$, representing the oscillation time scales. To capture the inherently three-dimensional and asymmetric nature of the flow field, 3D particle-tracking velocimetry measurements are performed using the Shake-The-Box algorithm. Using a refractive-index matched fluid consisting of water and glycerin, the complex flow structures inside the trachea are fully resolved. The PTV measurements confirm that the nasal and/or oral cavity must be considered when analyzing the flow field in the lower respiratory tract. In particular, we find that the presence of both cavities significantly alters the flow field compared to idealised, fully developed inflow conditions. However, velocity profiles in the sagittal and coronal plane in the trachea as well as contour plots of the of the normalized velocity magnitude evidence nearly identical flow structures for oral and nasal inhalation, indicating minimal influence of the inhalation route.