A biomechanical model of swallowing for understanding the influence of saliva and food bolus viscosity on flavor release

After swallowing a liquid or a semi-liquid food product, a thin film responsible for the dynamic profile of aroma release coats the pharyngeal mucosa. The objective of the present article was to understand and quantify physical mechanisms explaining pharyngeal mucosa coating. An elastohydrodynamic m...

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Veröffentlicht in:Journal of theoretical biology 2011-07, Vol.280 (1), p.180-188
Hauptverfasser: de Loubens, Clément, Magnin, Albert, Doyennette, Marion, Tréléa, Ioan Cristian, Souchon, Isabelle
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Sprache:eng
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Zusammenfassung:After swallowing a liquid or a semi-liquid food product, a thin film responsible for the dynamic profile of aroma release coats the pharyngeal mucosa. The objective of the present article was to understand and quantify physical mechanisms explaining pharyngeal mucosa coating. An elastohydrodynamic model of swallowing was developed for Newtonian liquids that focused on the most occluded region of the pharyngeal peristaltic wave. The model took lubrication by saliva film and mucosa deformability into account. Food bolus flow rate and generated load were predicted as functions of three dimensionless variables: the dimensionless saliva flow rate, the viscosity ratio between saliva and the food bolus, and the elasticity number. Considering physiological conditions, the results were applied to predict aroma release kinetics. Two sets of conditions were distinguished. The first one was obtained when the saliva film is thin, in which case food bolus viscosity has a strong impact on mucosa coating and on flavor release. More importantly, we demonstrated the existence of a second set of conditions. It was obtained when the saliva film is thick and the food bolus coating the mucosa is very diluted by saliva during the swallowing process and the impact of its viscosity on flavor release is weak. This last phenomenon explains physically in vivo observations for Newtonian food products found in the literature. Moreover, in this case, the predicted thickness of the mix of food bolus with saliva coating the mucosa is approximately of 20 μm; value in agreement with orders of magnitude found in the literature. ► We modeled pharyngeal peristalsis. ► We analyzed the great role of saliva and mucosa deformability on mucosa coating by Newtonian food bolus. ► We concluded that the food bolus coating the mucosa is very diluted by saliva during the swallowing process. ► Thus the impact of product viscosity on flavor release is weak.
ISSN:0022-5193
1095-8541
DOI:10.1016/j.jtbi.2011.04.016