Capturing and Quantifying Particle Transcytosis with Microphysiological Intestine‐on‐Chip Models

Understanding the intestinal transport of particles is critical in several fields ranging from optimizing drug delivery systems to capturing health risks from the increased presence of nano‐ and micro‐sized particles in human environment. While Caco‐2 cell monolayers grown on permeable supports are...

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Veröffentlicht in:	Small methods 2023-01, Vol.7 (1), p.e2200989-n/a
Hauptverfasser:	Delon, Ludivine C., Faria, Matthew, Jia, Zhengyang, Johnston, Stuart, Gibson, Rachel, Prestidge, Clive A., Thierry, Benjamin
Format:	Artikel
Sprache:	eng
Schlagworte:	Biological Transport Caco-2 Cells cellular transcytosis Endocytosis - physiology enterocytes Humans intestinal absorption Intestines intestine‐on‐chip Transcytosis
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creator	Delon, Ludivine C. Faria, Matthew Jia, Zhengyang Johnston, Stuart Gibson, Rachel Prestidge, Clive A. Thierry, Benjamin
description	Understanding the intestinal transport of particles is critical in several fields ranging from optimizing drug delivery systems to capturing health risks from the increased presence of nano‐ and micro‐sized particles in human environment. While Caco‐2 cell monolayers grown on permeable supports are the traditional in vitro model used to probe intestinal absorption of dissolved molecules, they fail to recapitulate the transcytotic activity of polarized enterocytes. Here, an intestine‐on‐chip model is combined with in silico modeling to demonstrate that the rate of particle transcytosis is ≈350× higher across Caco‐2 cell monolayers exposed to fluid shear stress compared to Caco‐2 cells in standard “static” configuration. This relates to profound phenotypical alterations and highly polarized state of cells grown under mechanical stimulation and it is shown that transcytosis in the microphysiological model is energy‐dependent and involves both clathrin and macropinocytosis mediated endocytic pathways. Finally, it is demonstrated that the increased rate of transcytosis through cells exposed to flow is explained by a higher rate of internal particle transport (i.e., vesicular cellular trafficking and basolateral exocytosis), rather than a change in apical uptake (i.e., binding and endocytosis). Taken together, the findings have important implications for addressing research questions concerning intestinal transport of engineered and environmental particles. Intestine‐on‐chip model study with in silico modeling demonstrates that the rate of nanoparticle transcytosis is ≈350x higher across Caco‐2 cell monolayers cultured under fluid shear stress compared to “static” configuration in Transwell. This drastically enhanced and energy dependent nanoparticle transport is independent of apical uptake and recapitulate the in vivo transcytotic activity of enterocytes.
doi_str_mv	10.1002/smtd.202200989
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Finally, it is demonstrated that the increased rate of transcytosis through cells exposed to flow is explained by a higher rate of internal particle transport (i.e., vesicular cellular trafficking and basolateral exocytosis), rather than a change in apical uptake (i.e., binding and endocytosis). Taken together, the findings have important implications for addressing research questions concerning intestinal transport of engineered and environmental particles. Intestine‐on‐chip model study with in silico modeling demonstrates that the rate of nanoparticle transcytosis is ≈350x higher across Caco‐2 cell monolayers cultured under fluid shear stress compared to “static” configuration in Transwell. 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subjects	Biological Transport Caco-2 Cells cellular transcytosis Endocytosis - physiology enterocytes Humans intestinal absorption Intestines intestine‐on‐chip Transcytosis
title	Capturing and Quantifying Particle Transcytosis with Microphysiological Intestine‐on‐Chip Models
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