In-vitro 3D models of human nasal mucosa cells can offer a deeper understanding of airway pathophysiology and drug discovery. In this work, a microfluidic chip was designed with an air-liquid interface (ALI) as a model to mimicry the in vivo environment of the respiratory mucosa. A biopolymeric scaffold was integrated to act as biocompatible ALI membrane. The platform was structured using a rapid prototyping technique. A computational fluid dynamic (CFD) analysis was conducted to evaluate the air-induced shear stress on the scaffold. CFD was employed to find the target flow rate to replicate desired mechanical characteristics within a specific region of the human nasal cavity. According to this data, peristaltic pumps for air and liquid flows, were programmed to replicate physiological flows and dynamic air-induced shear stresses shear stresses on the culture.
Testa, M., Lopresti, F., Manna, O., Burgio, S., Intilli, G., Fucarino, A., et al. (2023). Rapid prototyping of a microfluidic platform for nasal mucosa models. In Convegno nazionale di Bioingegneria 2023. Patron Editore S.r.l..
Rapid prototyping of a microfluidic platform for nasal mucosa models
Testa M.
;Lopresti F.;Manna O.;Burgio S.;Fucarino A.;La Carrubba V.Ultimo
2023-01-01
Abstract
In-vitro 3D models of human nasal mucosa cells can offer a deeper understanding of airway pathophysiology and drug discovery. In this work, a microfluidic chip was designed with an air-liquid interface (ALI) as a model to mimicry the in vivo environment of the respiratory mucosa. A biopolymeric scaffold was integrated to act as biocompatible ALI membrane. The platform was structured using a rapid prototyping technique. A computational fluid dynamic (CFD) analysis was conducted to evaluate the air-induced shear stress on the scaffold. CFD was employed to find the target flow rate to replicate desired mechanical characteristics within a specific region of the human nasal cavity. According to this data, peristaltic pumps for air and liquid flows, were programmed to replicate physiological flows and dynamic air-induced shear stresses shear stresses on the culture.
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