Your search keyword '"Lagrée PY"' showing total 2 results

1. Modelling the human pharyngeal airway: validation of numerical simulations using in vitro experiments.

Author

Chouly F, Van Hirtum A, Lagrée PY, Pelorson X, and Payan Y

Subjects

Air Pressure, Humans, Rheology, Tongue physiopathology, Models, Biological, Pharynx physiopathology, Sleep Apnea, Obstructive physiopathology

Abstract

In the presented study, a numerical model which predicts the flow-induced collapse within the pharyngeal airway is validated using in vitro measurements. Theoretical simplifications were considered to limit the computation time. Systematic comparisons between simulations and measurements were performed on an in vitro replica, which reflects asymmetries of the geometry and of the tissue properties at the base of the tongue and in pathological conditions (strong initial obstruction). First, partial obstruction is observed and predicted. Moreover, the prediction accuracy of the numerical model is of 4.2% concerning the deformation (mean quadratic error on the constriction area). It shows the ability of the assumptions and method to predict accurately and quickly a fluid-structure interaction.

Published

2009

2. In vitro validation of some flow assumptions for the prediction of the pressure distribution during obstructive sleep apnoea.

Author

Van Hirtum A, Pelorson X, and Lagrée PY

Subjects

Air Pressure, Humans, Models, Anatomic, Pharynx physiopathology, Rheology, Tongue physiopathology, Models, Biological, Sleep Apnea, Obstructive physiopathology

Abstract

An adequate description of the pressure distribution exerted by the fluid flow on pharyngeal walls is a first requirement to enhance the understanding, modelling and, consequently, the prediction of airway collapse during obstructive sleep apnoea. From a fluid mechanical point of view, several flow assumptions can be formulated to reduce the governing flow equations. The relevance of some major flow assumptions and the accuracy of the resulting flow description with respect to obstructive sleep apnoea was investigated on a rigid geometrical replica of the pharynx. Special attention was given to the influence of geometrical asymmetry and to the position of the flow separation point. An in vitro experimental and theoretical study of steady pharyngeal fluid flow is presented for different constriction heights and upstream pressures. Pressure and velocity distributions along a rigid in vitro replica of the oro-pharyngeal cavity were compared with different flow predictions based on various assumptions. Fluid flow models were tested for volume flow rates ranging from 5 to 120 1 min(-1) and for minimum apertures between 1.45 and 3.00 mm. Two-dimensional flow models were required and predicted experimental results with an accuracy of 15%. Flow theories classically used in the case of a Starling resistor provided poor agreement.

Published

2005